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3b9d4819c4 MANAK BHAVAN, 9 BAHADUR SHAH ZAFAR MARG, NEW DELHI 1100022 MANAK BHAVAN, 9 BAHADUR SHAH ZAFAR MARG, . + 91 11 23230131, 23233375, 23239402 Extn 4402; Fax: + 9 1 11 23235529 . that is IS 875 (Part 1) : .is : 875 ( part 2 ) - 1987 indian standard code of practice design loads (other than for earthquake) for buildings and sttiuctures part 2 imposed loadsIS : 875 (Part 1) -1987 Indian Standard PART 1 DEAD LOADS .is : 875 (part 1) -1987 indian standard part 1 dead loads unit weights of building materials and stored materials b u r e a u o f i n d i a n s t a n d a r d sFashion & AccessoriesIS 875 (Part 2): Code of Practice for Design Loads (Other Than Earthquake) For Buildings and Structures.IS 875-2 (pdf) - Internet ArchiveIS 875-2: Code of Practice for Design Loads (Other Than Earthquake) For Buildings And Structures, Part 2: Imposed Loads Item PreviewIS: 875(Part3): Wind Loads on Buildings and Structures .Code & Commentary IS 875 (Part 3) CODE COMMENTARY Foreword 0.1 This Indian Standard IS:875 (Part 3) (Third Revision) was adopted by the Bureau of Indian Standards onIS 875 (Part 3) 2015.pdf - ScribdIS 875 (Part 3) 2015.pdf. Uploaded by maggidiravinder. Rating and Stats. 2.0 (9) Document Actions. Download. Share or Embed Document. . 875 PART 3 2015. IS 1343 .Download IS 875 part 1 2 3 Is 456.2000 PDF Free Engineer .Download IS 875 part 1 2 3 Is 456.2000 PDF Free, download indian standard pdf, download IS PDF, Download BIS pdf, . 11/09 (2) 10/19 (1) .IS 875 part 1-1987 - ScribdDownload as PDF, TXT or read online . 11 IS : 875 (Part 1) - 1987 .Download IS 875 part 1 2 3 Is 456.2000 PDF Free itunecafeThe Bureau of Indian Standards (BIS) is the national Standards Body of India working under the aegis of Ministry of Consumer Affairs, Food & Public .
IS 875 (Part 3) : 2015
Indian Standard
— 3
Design Loads (Other than Earthquake) for Buildings and Structures — Structures — Code of Practice Part 3 Wind Loads
( Thir Third d Rev Revis isio ion n)
ICS 91.100.10
© BIS 2015
B U RE A U O F I N DI A N ST A ND AR D S
110002 9 MANAK BHAVAN, 9 BAHADUR SHAH ZAFAR MARG NEW DELHI-110002 www.bis.org.in www.standardsbis.in
April 2015
Price Group 14
Structural Safety Sectional Committee, CED 37
FOREWORD This Indian Standard (Part 3) (Third Revision) was adopted by the Bureau of Indian Standards after the draft finalized by the Structural Safety Sectional Committee had been approved by the Civil Engineering Division Council. A building has to perform many functions satisfactorily. Amongst these functions are the utility of the building for the intended use and occupancy, structural safety, fire safety and compliance with hygienic, sanitation, ventilation and daylight standards. The design of the building is dependent upon the minimum requirements prescribed for each one of the above functions. The minimum requirements pertaining to the structural safety of buildings are being covered in loading codes by way of laying down minimum design loads, which have to be assumed for dead loads, imposed loads, wind loads and other external loads, the structure would be required to bear. Strict conformity to loading standards, it is hoped , will not only ensures the structur al safety of the buildings and structures which are being designed and constructed in the country and thereby reduce loss of life and property caused by unsafe structures, but also eliminates the wastage caused by assuming unnecessarily heavy loadings without proper assessment. This standard was first published in 1957 for the guidance of civil engineers, designers and architects associated with the planning and design of buildings. It included the provisions for the basic design loads (dead loads, live loads, wind loads and seismic loads) to be assumed in the design of t he buildings. In its first revision in 1964, the wind pressure provisions were modified on the basis of studies of wind phenomenon and its effect on structures, undertaken by the special Committee in consultation with the Indian Meteorological Department. In addition to this, new clauses on wind loads for butterfly type structures were included; wind pressure coefficients for sheeted roofs, both covered and sloping were modified; seismic load provisions were deleted (separate code having been prepared) and metric system of weights and measurements was adopted. With the increased adoption of this standard, a number of comments were received on provision of live loads adopted for different occupancies. Subsequently the Committee recommended the formulation of this standard in the following five parts, during the second revision of IS 875 in 1987: Par t 1
Dead loads
Part 2
Imp Imposed loa load ds
Par t 3
Wind loads
Par t 4
Snow loads
Part Part 5
Speci Special al loa loads ds and and loa load d comb combina inatio tions ns
This standard (Part 3) deals with wind loads to be considered when designing buildings, structures and components thereof. In this current revision, the Committee recommends the following modifications/inclusions by taking into account the recent improvements that have been made in the wind engineering descriptive, descriptive, through R & D efforts nationally and internationally: a)
Aerodynamic Aerodynamic roughness roughness heights heights for individual individual terrain terrain categories categories have have been been explicitly explicitly included, included, and are used to derive turbulence intensity and mean hourly wind speed profiles.
b)
The previous previous classific classification ation of structures structures into into B and C classes classes has been been deleted deleted and accordingly accordingly the modification factor, k 2 is renamed as terrain roughness and height factor.
c)
The The va values of of k 2 factor corresponding to previous class A type structure only, are retained in this standard.
d)
An additional additional modificati modification on factor, factor, termed as importanc importancee factor has has been included included for cyclonic cyclonic regions. regions.
e)
Simple empirical empirical express expressions ions have have been suggest suggested ed for height height variations variations of of hourly mean mean wind speed speed and also turbulence intensity in different terrains. (Continued on Continued on third cover )
IS 875 (Part 3) : 2015
Indian Standard
DESIGN LOADS (OTHER THAN EARTHQUAKE) FOR BUILDINGS BUILDINGS AND STRUCTURE STRUCTURES S — CODE OF PRA PRACTIC CTICE E
( Third Revision ) 1 SCOPE
specific requirements as specified in the respective Codes shall be adopted in conjunction with the provisions of this Code as far as they are applicable. Some of the Indian Standards available for the design of special structures are:
1.1 This standard (Part 3) specifies wind forces and their effects (static and dynamic) that should be taken into account when designing buildings, structures and components thereof.
IS No. 4998 : 2015
vary randomly both in time and space 1.2 Wind speeds vary and hence assessment of wind loads and response predictions are very important in the design of several buildings and structures. A large majority of structures met with in practice do not however, suffer wind induced oscillations and generally do not require to be examined for the dynamic effects of wind. For such normal, short and heavy structures, estimation of loads using static wind analysis has proved to be satisfactory. The details of this method involving important wind characteristics such as the basic wind speeds, terrain categories, modification factors, wind pressure and force coefficients, etc, are given in 6 and 7.
6533 (Par (Partt 1) : 1989 1989 (Par (Partt 2) 2) : 198 1989 9 5613 (Part 2/ Sec 1) :1985
802 802 (Pa (Part rt 1/ Sec Sec 1) : 201* 201*
1.3 Nevertheless, there are various types of structures or their components such as some tall buildings, chimneys, latticed towers, cooling towers, transmission towers, towers, guyed masts, communication towers, long span bridges, partially or completely solid faced antenna dish, etc, which require investigation of wind induced oscillations. The influence of dynamic velocity fluctuations on the along wind loads (drag loads) for these structures shall be determined using Gust Factor Method, included in 10. 10. A method for calculation of across wind response of tall buildings and towers is included in 10.3. 10.3.
11504 : 1985
1473 14732 2 : 2000 2000
1.4 This standard also applies to buildings or other structures during erection/construction and the same shall be considered carefully during various stages of erection/construction. In locations where the strongest winds and icing may occur simultaneously, loads on structural members, cables and ropes shall be calculated by assuming an ice covering based on climatic and local experience.
Title Cr it it er er ia ia fo fo r de si sig n of re rei nf nf or or ce ce d concrete chimneys : Part 1 Assessment of loads ( third revision) (under print ) C o d e o f p r a c t i c e f o r d es i g n a n d construction of steel chimneys Mech Mechan anic ical al aspe aspect ctss Stru Struct ctur ural al asp aspec ects ts C o de de o f p r a ct ct i ce ce f o r d e si si g n, n, instal installat lation ion and maint maintena enance nce of overhead power power lines : Part 2 Lines above 11 kV, kV, and up to and including in cluding 220 kV, Section 1 Design Code Code of prac practi tice ce for for use use of stru struct ctur ural al stee steell in in over overhe head ad trans transmi miss ssio ion n lin linee towers: Part 1 Materials, Loads and permissible stresses, Section 1 Materials and Loads ( fourth revision revision) (under print ) Criter Criteria ia for for struc structur tural al desig design n of reinforced concrete natural draught cooling towers Guid Guidel elin ines es for the the eva evalu luat atio ion n of of the the response of occupants of fixed structures, especially buildings and off-shore structures, to lowfrequency horizontal motion (0.063 to 1 Hz)
NOTES 1 This standard does not apply to buildings or structures with unconventional shapes, unusual locations, and abnormal environmental conditions that have not been covered in this Code. Special investigations are necessary in such cases to establish wind loads and their effects. Wind tunnel studies may also be required in such situations. 2 In the case of tall structures with unsymmetrical geometry, the designs may have to be checked for tor sional effects effects due to wind pressure.
1. 5 In the design of special structures, such as chimneys, overhead transmission line towers, etc, 1
IS 875 (Part 3) : 2015 2 REFE REFERE RENC NCES ES
force normal normal to the the surfa surface; ce; F = force
The following standard contains provisions, which through reference in this text, constitute provisions of this standard. At the time of publication, the edition indicated was valid. All standards are subject to revision, and parties to agreements based on this standard are encouraged to investigate the possibility of applying the most recent edition of the standard indicated.
naturall frequency frequency of the building/ building/ f a = first mode natura structure in along wind direction in Hz;
IS No. 15498 : 2004
naturall frequency frequency of the building/ building/ f c = first mode natura structure in across wind direction in Hz; vortex shedding shedding frequenc frequency; y; f s = vortex normal al forc force; e; F n = norm transve verse rse force force;; F t = trans frictiona onall force force;; F' = fricti
Title G ui ui de de li li ne ne s f or or i mp mp ro ro vi vi ng ng t he he cyclonic resistance of low rise houses and other buildings/structures
gust fact factor or;; G = gust factorr for resonan resonantt respons response; e; gR = peak facto factor for upwind upwind veloc velocity ity fluctuati fluctuations; ons; gv = peak factor
3 NOTA NOTATI TION ONS S
height of structu structure re above above mean mean ground ground level; level; h = height
3.1 The following notations shall be followed unless otherwise specified in relevant clauses. Notations have been defined in the text at their first appearance. A few of the notations have more than one definition, having been used for denoting different variables:
height of develop development ment of of a velocity velocity profi profile le hx = height at a distance x down wind from a change in terrain category; height factor factor for for resonant resonant resp response onse;; H s = height height above above mean mean groun ground d level level on the the H = height topography feature;
surface area area of a struct structure ure or part of of a A = surface structure;
turbulen lence ce inten intensit sity; y; I = turbu
effectiv tivee fronta frontall area; area; Ae = effec
turbulencee intens intensity ity at heigh heightt h in terrain I h,i = turbulenc category i;
effective ive frontal frontal area area of the the building building at Az = the effect height z;
turbulence intensity intensity at height height z in terrain I z,i = turbulence category i;
breadth of a struc structure ture or or structur structural al member member b = breadth normal to the wind stream in the horizontal plane;
interfer ferenc encee facto factor; r; IF = inter shape power power expon exponent; ent; k = mode shape
backgroun ound d fact factor; or; Bs = backgr
wind speed speed modifi modifica catio tion n factor factors; s; k 1, k 2, = wind k 3, k 4
drag coeff coeffici icient ent;; C d = drag force coeff coeffici icient ent;; C fd' = force
k 2,i = hourly hourly mean mean wind wind spee speed d factor; factor;
normall force force coeffi coefficie cient; nt; C fn = norma
coefficient nt multiplic multiplication ation factor factor for K = force coefficie individual members of finite length;
transverse se force force coeff coefficie icient; nt; C ft = transver frictional al drag coeffici coefficient; ent; C f ' = friction
area averag averaging ing fac factor tor;; K a = area
pressure ure coef coeffic ficien ient; t; C p = press
combinati ation on factor factor;; K c = combin
external pressure pressure coeffici coefficient; ent; C pe = external
directionali nality ty factor; factor; K d = wind directio
internal pressure pressure coeffici coefficient; ent; C pi = internal
length of the membe memberr or larger larger horizon horizontal tal l = length dimensio dimension n of a building building;;
cross-wind nd force force spectrum spectrum coeffi coefficien cient; t; C fs = cross-wi Cf, z = drag force coefficient coefficient of the the building building corresponding to the area Az;
actual length length of upwind upwind slope; slope; L = actual effectivee length length of of upwind upwind slope slope;; Le = effectiv
coefficien ient, t, which which depen depends ds on s, used in the C = coeffic evaluation of k 3 factor;
integral turbulence turbulence length scale at the height height Lh = integral h;
depth of a structu structure re or struct structural ural membe memberr d = depth parallel to wind stream in the horizontal plane;
average mass mass per unit unit height height of the struct structure; ure; m0 = average design peak peak along along wind wind base base bending bending M a = design moment;
wake widt width; h; d w = wake
design peak peak across across wind wind base bendin bending g M c = design moment;
diameterr of cylin cylinder der or spher sphere; e; D = diamete wind ene energy rgy factor factor;; E = wind
effectivee reduce reduced d freque frequency; ncy; N = effectiv
Fz = along along wind load load on the buildi building/s ng/struc tructure ture at at any height z;
design wind wind pre press ssure ure;; pd = design 2
IS 875 (Part 3) : 2015
design wind wind press pressure ure at at height height z; pz = design
4 TE TERM RMIN INOL OLOG OGY Y
si g n h ou ou r l y m ea ea n w in in d p r es es s ur ur e pd = d e si corresponding to V z,d ;
For the purpose of this standard, the following definitions shall apply.
external al press pressure ure;; pe = extern
4.1 Angle Angle of Atta Attack ck — An angle between the direction of wind and a reference axis of the structure.
internal al press pressure ure;; pi = intern roughnesss factor factor which which is is twice twice the r = roughnes longitudinal turbulence intensity at height h;
4.2 4.2 Brea Breadt dth h — It means horizontal dimension of the building measured normal to the direction of wind.
Reynolds lds number number;; Re = Reyno el o n a b u i l d in in g / st st r uc uc t u re re f o r t h e s = l e v el evaluation of along wind load effects;
NOTE — Breadth and depth are dimensions measured in relation to the direction of wind, whereas length and width are dimensions related to the plan.
factor, which which depen depends ds on H and and X , used for s0 = factor, the evaluation of k 3 factor;
4.3 4.3 Depth — It means the horizontal dimension of the building measured in the direction of the wind.
strouh uhal al numb number er;; S t = stro
4.4 Devel Develop oped ed Height Height — It is the height of upward penetration of the velocity profile in a new terrain. At large fetch lengths, such penetration reaches the gradient height, above which the wind speed may be taken to be constant. At lesser fetch lengths, a velocity profile of a smaller height but similar to that of the fully developed profile of that terrain category has to be taken, with the additional provision that the v elocity at the top of this shorter shorter profile equal to that of the unpenetrated earlier velocity profile at that height.
size reduc reductio tion n factor factor;; S = size regional basic basic wind wind speed; speed; V b = regional design wind wind speed speed at height height z; V z = design design hourl hourly y mean mean wind wind speed speed;; V d = design V d,z = design design hourly hourly mean mean wind wind speed speed at height height z; V z,H = hourly hourly mean mean wind wind speed speed at height height z; lesser horizon horizontal tal dimens dimension ion of a building, building, w = lesser or a str struc uctu tura rall memb member er;;
4.5 Effectiv Effectivee Fronta Frontall Area Area — The projected area of the structure normal to the direction of wind.
width in multimulti-bay bay build building; ing; w' = bay width accelera leration tion at at the top of the build building/ ing/ ˆ = peak acce x structure in along wind direction, in m/s2;
4.6 Element Element of of Su Surfac rfacee Area Area — The area of surface over which the pressure coefficient is taken to be constant.
distance down down wind wind from a change change in terrain terrain x = distance category;
4 . 7 F o rc rc e C o ef ef f i ci ci e nt nt — A non-dimensional coefficient such that the total wind force on a body is the product of the force coefficient, the dynamic pressure of the incident design wind speed and the reference area over which the force is required.
distance from the the summit summit or crest crest of of X = distance topography feature relative to the effective length, Le; accelera leration tion at at the top of the build building/ ing/ ˆ = peak acce y structure in across wind direction;
NOTE — When the force is in the direction of the incident wind, the non-dimensional coefficient will be called as ‘drag coefficient’. coefficient’. When the force is perpendicular to the direction of incident wind, the non-dimensional coefficient will be cal led as ‘lift coefficient’.
height or dista distance nce above above the the ground; ground; z = a height aerodynamicc roughnes roughnesss height height for ith z0,i = aerodynami terrain; effectivee height height of the topograph topography y feature; feature; Z = effectiv
4.8 Ground Ground Roughne Roughness ss — The nature of the earth’s surface as influenced by small scale obstructio ns such as trees and buildings (as distinct from topography) is called ground roughness.
α = inclinat inclination ion of the roof to the the horizonta horizontal; l; β = d a m pi pi n g c o ef ef f i ci ci e nt nt o f t h e b u i ld ld i n g/ g/ structure;
4.9 Gus t — A positive or negative departure of wind speed from its mean value, lasting for not more than, say, 2 min over a specified interval of time.
η = shiel shieldin ding g factor factor;; φ = factor factor to account account for for the second second order order turbulence intensity;
4.10 4.10 Peak Peak Gu Gust st — A peak gust or peak gust speed is the wind speed associated with the maximum amplitude.
Φ = soli solidi dity ty rat ratio io;; Φe = effective effective solidit solidity y ratio; ratio; ε = average average height height of the the surface surface roughnes roughness; s;
4.11 4.11 Fetc Fetch h Leng Length th — It is the distance measured along the wind from a boundary at which a change in the type of terrain occurs. When the changes in terrain types are encountered (such as, the boundary of a town
θs = upwind upwind slope slope of the topograp topography hy feature feature in in the wind direction; and θ = wind angle angle from from a given given axis. axis. 3
IS 875 (Part 3) : 2015 or city, forest, etc), the wind profile changes in character but such changes are gradual and start at ground level, spreading or penetrating upwards with increasing fetch length.
4.21 Terrain Category — It means the characteristics of the surface irregularities of an area which arise from natural or constructed features. The categories are numbered in increasing order of roughness.
4.12 4.12 Gradie Gradient nt Height Height — It is the height above the mean ground level at which the gradient wind blows as a result of balance among pressure gradient force, coriolis force and centrifugal force. For the purpose of this Code, the gradient height is taken as the height above the mean ground level, above which the variation vari ation of wind speed with height need not be considered.
4.22 Topography — Topography — The nature of the earth’s surface as influenced by the hill and valley configurations. 4.23 Velocity Velocity Profile — Profile — The variation of the horizontal component of the atmospheric wind speed at different heights above the mean ground level is termed as velocity profile. 5 GENER ENERAL AL
4.13 High Rise Rise Building Building (Tall (Tall Building) Building) — A building with a height more than or equal to 50 m or having a height to smaller dimension more than 6.
5.1 Wind is air in motion relative to the surface of the earth. The primary cause of wind is traced to earth’s rotation and differences in terrestrial radiation. The radiation effects are primarily responsible for convection either upwards or downwards. The wind generally blows horizontal to the ground at high wind speeds. Since vertical components of atmospheric motion are relatively small, the term ‘wind’ denotes almost exclusively the horizontal wind; vertical winds are always identified as such. The wind speeds are assessed with the aid of anemometers or anemographs which are installed at meteorological observatories at heights generally varying from 10 to 30 m above ground.
4.14 4.14 Low Low Rise Rise Buildi Building ng — A building having its height less than 20 m. — The mean ground level 4.15 4.15 Mean Mean Groun Ground d Level Level — is the average horizontal plane of the area enclosed by the boundaries of the structure. 4.16 Pressur Pressuree Coeff Coefficien icientt — It is the ratio of the difference between the pressure acting at a point on the surface and the static pressure of the incident wind to the design wind pressure, where the static and design wind pressures are determined at the height of the point considered after taking into account the geographical location, terrain conditions and shielding effect. The pressure coefficient is also equal to [1–( V p / V Vz )2], where V p is the actual wind speed at any point on the structure at a height corresponding to that of V z.
5.2 5. 2 Very strong winds (more than 80 kmph) are generally associated with cyclonic storms, thunderstorms, dust storms or vigorous monsoons. A feature of the cyclonic storms over the Indian area is that they rapidly weaken after crossing the coasts and move as depressions/lows inland. The influence of a severe storm after striking the coast does not; in general exceed about 60 km, though sometimes, it may extend even up to 120 km. Very short duration hurricanes of very high wind speeds called Kal Baisaki or Norwester s occur fairly frequently during summer months over North East India.
NOTE — Positive sign of the pressure coefficient indicates pressure acting towards the surface and negative sign indicates pressure acting away from the surface.
4.17 4.17 Retur Return n Period Period — It is the number of years, reciprocal of which gives the probability of extreme wind exceeding a given wind speed in anyone year. 4.18 4.18 Shiel Shieldin ding g Effect Effect — — Shielding effect or shielding refers to the condition where wind has to pass along some structure(s) or structural element(s) located on the upstream wind side, before meeting the structure or structural element under consideration. A factor called ‘shielding factor’ is used to account for such effects in estimating the force on the shielded shiel ded structures.
5.3 The wind speeds recorded at any locality are extremely variable and in addition to steady wind at any time, there are effects of gusts which may last for a few seconds. These gusts cause increase in air pressure but their effect on stability of the building may not be so important; often, gusts affect only part of the building and the increased local pressures may be more than balanced by a momentary reduction in the pressure elsewhere. Because of the inertia of the building, short period gusts may not cause any appreciable increase in stress in main components of the building although the walls, roof sheeting and individual cladding units (glass panels) and their supporting members such as purlins, sheeting rails and glazing bars may be more seriously affected. Gusts can also be extremely important for design of structures with high slenderness
4.19 4.19 Suct Suctio ion n — It means pressure less than the atmospheric (static) pressure and is taken to act away from the surface. — It is equal to the effective area 4.20 Solidit Solidity y Ratio Ratio — (projected area of all the individual elements) of a frame normal to the wind direction divided by the area enclosed by the boundary of the frame normal to the wind direction. NOTE — Solidity ratio is to be calculated for individual frames.
4
IS 875 (Part 3) : 2015 ratios.
6.3 Design Design Wind Wind Speed Speed (V z)
5.4 The liability of a building to high wind pressures depends not only upon the geographical location and proximity of other obstructions ob structions to air flow but also upon the characteristics of the structure itself.
The basic wind speed ( V b) for any site shall be obtained from Fig. 1 and shall be modified to include the following effects to get design wind speed, V z at any height z, for the chosen structure:
5.5 The effect of wind on the structure as a whole is determined by the combined action of external and internal pressures acting upon it. In all cases, the calculated wind loads act normal to the surface to which they apply.
a)
Risk le level,
b)
Terrain errain rough roughnes nesss and height height of structu structure, re,
c)
Loca Locall topo topogr grap aph hy, and and
d)
Importan Importance ce fact factor or for for the cyclon cyclonic ic regio region. n.
It can be mathematically expressed as follows:
5.6 The stability calculations as a whole shall be done considering the combined effect, as well as separate effects of imposed loads and wind loads on vertical surfaces, roofs and other part of the building above general roof level.
V z = V b k 1 k 2 k 3 k 4
where V z
= design design wind speed speed at at height height z, in m/s;
k 1
= probability factor (risk coefficient) ( see 6.3.1); 6.3.1);
k 2
= terrain terrain roughnes roughnesss and height height factor factor (see 6.3.2); 6.3.2);
6 WIND WIND SPEE SPEED D
k 3
= topo topogra graph phy y fac factor tor (see 6.3.3); 6.3.3); and
6.1 Nature of Wind in in Atmospher Atmospheree
k 4
= importanc importancee factor factor for the the cyclonic cyclonic region region (see 6.3.4). 6.3.4).
5.7 Buildings shall also be designed with due attention to the effects of wind on the comfort of people inside and outside the buildings.
In general, wind speed in the atmospheric boundary layer increases with height from zero at ground level to maximum at a height called the gradient height. There is usually a slight change in direction (Ekman effect) but this is ignored in this standard. The variation with height depends primarily on the terrain conditions. However, the wind speed at any height never remains constant and it has been found convenient to resolve its instantaneous magnitude into an average or mean value and a fluctuating component around this average value. The average value depends on the average time employed in analyzing the meteorological data and this averaging time varies from few seconds to several minutes. The magnitude of fluctuating component of the wind speed which is called gust, depends on the averaging time. In general, smaller the averaging interval, more is the magnitude of the gust speed.
NOTE — Wind speed may be taken as constant up to a height of 10 m. However, pressures for buildings less than 10 m high may be reduced by 20 percent for evaluating stability and design of the framing.
6.3.1 Risk Coefficient (k 1 Factor) — Figure 1 gives basic wind speeds for terrain Category 2 as applicable at 10 m above ground level based on 50 years mean return period. The suggested life period to be assumed in design and the corresponding k 1 factors for different class of structures for the purpose of design are given in Table 1. In the design of buildings and str uctures, a regional basic wind speed having a mean return peri od of 50 years shall be used except as specified in the note of Table 1. 6.3.2 Terrain, Height Factor (k 2 Factor) 6.3.2.1 Terrain Selection of terrain categories shall be made with due regard to the effect of obstructions which constitute the ground surface roughness. The terrain category used in the design of a structure may vary depending on the direction of wind under consideration. Wherever Wherever sufficient meteorological information is available about the nature of wind direction, the orientation of any building or structure may be suitably planned.
6.2 BASIC BASIC WIND WIND SPEED SPEED Figure 1 gives basic wind speed map of India, as applicable to 10 m height above mean ground level for different zones of the country. Basic wind speed is based on peak gust velocity averaged over a short time interval of about 3 s and corresponds to mean heights above ground level in an open terrain (Category 2). Basic wind speeds presented in Fig. 1 have been worked out for a 50 year return period. Basic wind speed for some important cities/towns is also given in Annex A.
Terrain in which a specific structure stands shall be assessed as being one of the following terrain categories: a)
5
Category 1 — Exposed open terrain with few or no obstructions and in which the average
IS 875 (Part 3) : 2015
FIG. 1 B ASIC W IND S PEED
( BASED ON 50-YEARS R ETURN P ERIOD ) IN M / S (B
height of any object surrounding the structure is less than 1.5 m. The equivalent aerodynamic roughness height, ( z0,1) for this terrain is 0.002 m. Typically this category represents open sea-coasts and flat plains without trees.
b)
6
Category 2 — Open terrain with well scattered obstructions having heights generally between 1.5 m and 10 m. The equivalent aerodynamic roughness height, ( z 0,2 ) for this terrain is 0.02 0.02 m.
IS 875 (Part 3) : 2015
This is the criterion for measurement of regional basic wind speeds and represents airfields, open park lands and undeveloped sparsely built-up outskirts of towns and suburbs. Open land adjacent to sea coast may also be classified as Category 2 due to roughness of large sea waves at high winds. c)
buildings/structures up to 10 m in height with or without a few isolated tall structures. The equivalent aerodynamic roughness height, ( z z0,3) for this terrain is 0.2 m. This category represents well wooded areas, and shrubs, towns and industrial areas full or partially developed.
Category 3 — Terrain with numerous closely spaced obstructions having the size of
It is likely that the, next higher category than this will not exist in most design situations
Table 1 Risk Coefficients for Different Classes of Structures in Different Wind Speed Zones (Clause 6.3.1 ) Sl No.
Class of Structure
(1) i) ii)
iii)
iv)
k1 Factor
Mean Probable Design Life of Structure in Years
for Basic Wind Speed m/s
33
39
44
47
50
55
(2)
(3)
(4)
(5)
(6)
(7)
(8)
(9)
All general buildings and structures Temporary sheds, structures such as those used during construction operations (for example, formwork and false work), structures during during construction stages and boundary walls Buildings and structures presenting a low degree of hazard to life and property in the event of failure, such as isolated towers in wooded areas, farm buildings other than residential buildings Important buildings and structures such as hospitals communication buildings/towers, buildings/towers, power plant structures
50 5
1.0 0.82
1.0 0.76
1.0 0.73
1.0 0.71
1.0 0.70
1.0 0.67
25
0.94
0.92
0.91
0.90
0.90
0.89
100
1.05
1.06
1.07
1.07
1.08
1.08
NOTE — The factor k 1 is based on statistical concepts which take into account the degree of reliability required and period of time in years during which these will be exposed to wind, that is, life of the structure. Whatever wind speed is adopted for design purposes, there is always a probability (however (however small) that it may exceed in a storm of exceptional violence; more the period of years over which there is exposure to the wind, more is the probability. Larger return periods ranging from 100 to 1 000 years (implying lower risk level) in association with larger periods of exposure may have to be selected for exceptionally important structures, such as, nuclear power reactors and satellite communication towers. towers. Equation given below may be used in such cases to estimate k 1 factors for different different periods of exposure and chosen probability of exceedance (risk level). The probability level of 0.63 is normally considered sufficient for design of buildings and structures against wind effects and the values of k 1 corresponding corresponding to this risk level are given above.
k 1
=
X N ,P X 50,0.63
=
1 A − B ln − ln (1 − P N ) N A + 4B
where probable le design design life life of structu structure re in years years;; N = mean probab risk leve levell in in N consecutive consecutive years (probability that the design wind speed is exceeded at least once in N successive years), PN = risk nominal value = 0.63; extreme wind wind speed speed for for given given values values of N and and PN; and X N,P = extreme extreme me wind wind spee speed d for for N = = 50 years and PN = 0.63 X 50,0.63 = extre A and B have the following values for different basic wind speed zones:
Zone m/ s
A* m/ s
B* m/s
33
23.1 (8 3.2)
2.6 (9.2 )
39
23.3 (8 4.0)
3.9 (14.0)
44
24.4 (8 8.0)
5.0 (18.0)
47
24.4 (8 8.0)
5.7 (20.5)
50
24.7 (8 8.8)
6.3 (22.8)
55
25.2 (9 0.8)
7.6 (27.3)
* Values of A and B, in kmph, are given in bracket.
7
IS 875 (Part 3) : 2015 and that selection of a more severe category will be deliberate. d)
gradually to height ( hx) which increases with the fetch or upwind distance ( x).
Category 4 — Terrain with numerous large high closely spaced obstructions. The equivalent aerodynamic roughness height, ( z0,4) for this terrain is 2.0 m.
a)
This category represents large city centers, generally with obstructions above 25 m and well developed industrial complexes.
Fetch Fetch and and devel developed oped height height relation relationshi ship p — The relation between the developed height (hx) and the fetch ( x) for wind-flow over each of the four terrain categories may be taken as given in Table 3.
b) For structure structuress of of height heightss more more than the developed height ( hx) in Table 3, the velocity profile may be determined in accordance with the following:
6.3.2.2 Variation of wind speed with height in different terrains (k 2 factor) Table 2 gives multiplying multipl ying factors ( k 2) by which the basic wind speed given in Fig. 1 shall be multiplied to o btain the wind speed at different heights, in each terrain category.
1)
The less less or lea least st roug rough h terra terrain, in, or
2)
The meth method od des descri cribe bed d in Anne Annex x B.
Table 3 Fetch and Developed Height Relationship ( Clause 6.3.2.4 ) Sl No.
Table 2 Factors to Obtain Design Wind Speed Variation with Height in Different Terrains
Fetch ( x x) km
(1)
(2)
Terrain Category 1 (3)
i) ii) iii) iv) v) vi) vii) viii)
0.2 0.5 1 2 5 10 20 50
12 20 25 35 60 80 120 180
(Clause 6.3.2.2) Sl Height No. z
Terrain and Height Multiplier ( k2)
m
Terrain Category 1
(1)
(2)
(3)
(4)
(5)
(6)
i) ii) iii) iv) v) vi) vii) viii) ix) x) xi) xii) xiii) xiv)
10 15 20 30 50 100 150 200 250 300 350 400 450 500
1.05 1.09 1.12 1.15 1.20 1.26 1.30 1.32 1.34 1.35 1.35 1.35 1.35 1.35
1.00 1.05 1.07 1.12 1.17 1.24 1.28 1.30 1.32 1.34 1.35 1.35 1.35 1.35
0.91 0.97 1.01 1.06 1.12 1.20 1.24 1.27 1.29 1.31 1.32 1.34 1.35 1.35
0.80 0.80 0.80 0.97 1.10 1.20 1.24 1.27 1.28 1.30 1.31 1.32 1.33 1.34
Terrain Terrain Terrain Category 2 Category 3 Category 4
Developed Height, hx m Terrain Terrain Terrain Category 2 Category 3 Category 4 (4) (5) (6) 20 30 45 65 100 140 200 300
35 35 80 110 170 250 350 400
60 95 130 190 300 450 500 500
6.3.3 Topography (k 3 Factor) The basic wind speed V b given in Fig. 1 takes into account the general level of site above sea level. This does not allow for local topographic features such as hills, valleys, cliffs, escarpments, or ridges which can significantly affect wind speed in their vicinity. The effect of topography is to accelerate wind near the summits of hills or crests of cliffs, escarpments or ridges and decelerate the wind in valleys or near the foot of cliffs, steep escarpments, or ridges.
NOTE — For intermediate values of height z height z in in a given terrain category, use linear interpolation.
6.3.3.1 The 6.3.3.1 The effect of topography shall be significant a t a site when the upwind slope ( θ) is more than about 3°, and below that, the value of k 3 may be taken to be equal to 1.0. The value of k 3 is confined in the range of 1.0 to 1.36 for slopes more than 3°. A method of evaluating the value of k 3 for values more than 1.0 is given in Annex C. It may be noted that the value of k 3 varies with height above ground level, at a maximum near the ground, and reducing to 1.0 at higher levels.
6.3.2.3 Terrain categories in relation to the direction of wind The terrain category used in the design of a structure may vary depending on the direction of wind under consideration. Where sufficient meteorological information is available, the basic wind speed may be varied for specific wind direction. 6.3.2.4 Changes in terrain categories
R egion (k 4) 6.3.4 Importance Factor for Cyclonic Region
The velocity profile for a given terrain category does not develop to full height immediately with the commencement of that terrain category but develop
The east coast of India is relatively more vulnerable for occurrences of severe cyclones. On the west coast, Gujarat is vulnerable for severe cyclones. Studies of 8
IS 875 (Part 3) : 2015
wind speed and damage to buildings and structures point to the fact that the th e speeds given in the basic wind speed map are often exceeded during the cyclones. The effect of cyclonic storms is largely felt in a belt of approximately 60 km width at the coast. In order to ensure better safety of structures in this region (60 km wide on the east coast as well as on the Gujarat Coast), the following values of k 4 (as recommended in IS 15498) are stipulated as applicable according to the importance of the structure:
6.6 Off Shore Shore Wind Wind Velocit Velocity y
Cyclonic storms form far a way from the sea coast and gradually reduce in speed as they approach the sea coast. Cyclonic storms generally extend up to about 60 km inland after striking the coast. Their effect on land is already reflected in basic wind speeds specified in Fig. 1. The influ ence of wind speed off the coast up to a distance of about 200 km may be taken as 1.15 times the value on the nearest coast in the absence of any definite wind data. The factor 1.15 shall be used in addition to k 4.
k 4
Stru Struccture turess of pos post-cy t-cycl clon onee impo import rtaance nce for for 1.30 1.30 emergency services (such as cyclone shelters, hospitals, schools, communication towers, etc)
7 WIND PRESSURES PRESSURES AND FORCES ON BUILDINGS/STRUCTURES
Industrial structures
1.15
7.1 7.1 Gene Genera rall
All other structures
1.00
The wind load on a building shall be calculated for:
6.4 Hourly Hourly Mean Mean Wind Wind Spee Speed d
The hourly mean wind speed at height z, for different terrains can be obtained as V z,H
= k 2,iV b
a)
Buil Buildi ding ng as a whol whole, e,
b)
Individua Individuall structu structural ral elements elements as roofs and walls, and
c)
Individu Individual al claddin cladding g units units including including glazing glazing and their fixings.
where
7.2 Design Design Wind Wind Pressu Pressure re
hourly mean wind wind speed speed factor factor for terrai terrain n k 2,i = hourly category 1
The wind pressure at any height above mean ground level shall be obtained by the following relationship between wind pressure and wind speed:
z ln = 0.1423 ln ( z0,i )0.0706 z0,i
pz = 0.6 V z2
The design hourly mean wind speed at height z can be obtained as:
where pz
V z,d = V z,H k1k3 k4
design wind speed speed at at height height z, in m/s. V z = design The design wind pressure pd can be obtained as,
= V b k1 k 2,i k3 k4
pd
6.5 Turbul Turbulenc encee Intensi Intensity ty
directional onality ity factor, factor, K d = wind directi averaging ng facto factor, r, and K a = area averagi combinat ation ion factor factor (see 7.3.3.13). K c = combin
a) Terrain category 1
The value of pd, however shall not be taken as less than 0.70 pz.
z .3507 7 − 0.05 0.0535l 35lo og10 I z ,1 = 0.350 z0,1
c)
1 The coefficient 0.6 (in SI units) in the above formula depends on a number of factors and mainly on the atmospheric pressure and air temperature. The value chosen corresponds to the average Indian a tmospheric tmospheric conditions.
1
= I z,1 + ( I z,4 − I z,1 )
7 Terrain category 3
I z,3
d)
NOTES
Terrain category 2 I z,2
2 K d should be taken as 1.0 when considering local pressure coefficients.
3
= I z,1 + ( I z,4 − I z,1 )
7.2.1 Wind Directionality Factor, K d
z = 0.466 − 0.135 8 log10 z0,4
Considering the randomness in the directionality of wind and recognizing the fact that pressure or force coefficients are determined for specific wind directions, it is specified that for buildings, solid signs, open signs,
7 Terrain category 4
I z ,4
= K d K a K c pz
where
The turbulence intensity variations with height for different terrains can be obtained using the relations given below:
b)
= wind wind press pressure ure at at height height z, in N/m2; and
9
IS 875 (Part 3) : 2015 lattice frameworks, and trussed towers (triangular, square, rectangular) a factor of 0.90 may be used on the design wind pressure. For circular or near-circular forms this factor may be taken as 1.0.
Average values of pressure coefficients are given for critical wind directions in one or more quadrants. In order to determine the maximum wind load on the building, the total load should be calculated for each of the critical directions shown from all quadrants. Where considerable variation of pressure occurs over a surface, it has been sub-divided and mean pressure coefficients given for each of its several parts.
For the cyclone affected regions also the factor K d shall be taken as 1.0. 7.2.2 Area Averaging Averaging Factor, Factor, K a Pressure coefficients given in 7.3 7.3 are a result of averaging the measured pressure values over a given area. As the area becomes larger, the correlation of measured values decrease and vice-versa . The decrease in pressures due to larger areas may be taken into account as given in Table 4.
In addition, areas of high local suction (negative pressure concentration) frequently occurring near the edges of walls and roofs are separately shown. Coefficients for the local effects should only be used for calculation of forces on these local areas affecting roof sheeting, glass panels, and individual cladding units including their fixtures. They should not be used for calculating force on entire structural elements such as roof, walls or structure as a whole.
Table 4 Area Averaging Factor ( K K a) (Clause 7.2.2)
NOTES 1 The pressure coefficients given in different tables have been obtained mainly from measurements on models in wind tunnels, and the great majority of data available has been obtained in conditions of relatively smooth flow. Where sufficient field data exists as in the case of rectangular buildings, values have been obtained to allow for turbulent flow.
2 In recent years, wall glazing and cladding design has been a source of major concern. Although of less consequence than the collapse of main structures, damage to glass can be hazardous and cause considerable financial losses.
7.2.2.1 Tributary area a)
Overall structure — For evaluating loads on frames the tributary area shall be taken as the centre to centre distances between frames multiplied by the individual panel dimension in the other direction together with overall pressure coefficients.
3 For pressure coefficients for structures not covered here, reference may be made to specialist literature on the subject or advice may be sought from specialists in the subject.
7.3.1 Wind Load on Individual Members When calculating the wind load on individual structural elements such as roofs and walls, and individual cladding units and their fittings, it is essential to take account of the pressure difference between opposite faces of such elements or units. For clad structures, it is, therefore, necessary to know the internal pressure as well as the external pressure. Then the wind load, F , acting in a direction normal t o the individual structural element or cladding unit is:
b) Ind I nd i vi du al el em en ts — For beam type elements, purlins, etc, the tributary area shall be taken as effective span multiplied by spacing. The effective span is the actual span for mid span and cantilever load effects; and half the sum of adjacent spans for support moments and reactions. For plate type elements, the area of individual plates between supports is taken as the tributary area.
F = (C pe – C pi) A pd
For glass cladding, individual pane area of glass is the tributary area.
where
7.3 Pressur Pressuree Coefficien Coefficients ts
internall pressur pressuree coeffic coefficien ient, t, C pi = interna
The pressure coefficients are always given for a particular surface or part of the surface of a building. The wind load acting normal to a surface is obtained by multiplying the area of that surface or its appropriate portion by the pressure coefficient ( C p) and the design wind pressure at the height of the surface from the ground. The average values of these pressure coefficients coefficients for some building shapes are given in 7.3.2 and 7.3.3. 7.3.3.
A
= surface area of structural element or cladding unit, and
pd
= desi design gn wind wind pres pressu sure re.
externall pressure pressure coeff coeffici icient, ent, C pe = externa
NOTES 1 If the surface design pressure varies with height, the surface areas of the structural element may be sub-divided so that the specified pressures are taken over appropriate areas. 2 Positive wind load indicates the force acting towards the structural element and negative away from it.
10
IS 875 (Part 3) : 2015 7.3.2 Internal Pressure Coefficients
of clad buildings of rectangular plan shall be as given in Table 5. In addition, local pressure concentration coefficients are also given.
Internal air pressure in a building depends upon the degree of permeability of cladding to the flow of air. The internal air pressure may be positive or negative depending on the direction of flow of air in relation to openings in the buildings.
7.3.3.2 Pitched, hipped and mono slope roofs of clad buildings The average external pressure coefficients and pressure concentration coefficients for pitched roofs of rectangular clad building shall be as given in Table 6. Where no pressure concentration coefficients are given, the average coefficients shall apply. The pressure coefficients on the under-side of any overhanging roof shall be taken in accordance with 7.3.3.5. 7.3.3.5.
7.3.2.1 In the case of buildings where the claddings permit the flow of air with openings not more than about 5 percent of the wall area but where there are no large openings, it is necessary to consider the possibility of the internal pressure being po sitive or negative. Two Two design conditions shall be examined, one with an internal pressure coefficient of +0.2 and another with an internal pressure coefficient of –0.2.
For mono slope roofs of rectangular clad buildings, the average pressure coefficient and pressure concentration coefficient coefficient for mono slope (lean-to) roofs of rectangular clad buildings shall be as given in Table able 7.
The internal pressure coefficient is algebraically added to the external pressure coefficient and the analysis which indicates greater distress of the member shall be adopted. In most situations a simple inspection of the sign of external pressure will at once indicate the proper sign of the internal pressure coefficient to be taken for design.
NOTES 1 The pressure concentration shall be assumed to act outward (suction pressure) at the ridges, eaves, cornices and 90° corners of roofs. 2 The pressure concentration shall not be included with the net external pressure when computing overall load.
NOTE — The term normal permeability relates to the flow of air commonly afforded by claddings not only through open windows and doors, but also through the slits round the closed windows and doors and through chimneys, ventilators and through the joints between roof coverings, the total open area being less than 5 percent of area of the walls having the openings.
3 For hipped roofs, pressure coefficients (including local values) may be taken on all the four slopes, as appropriate from Table 6, and be reduced by 20 percent for the hip slope.
7.3.3.3 Canopy roofs with (1/4 < h /w < 1 and 1 < L / w < 3)
7.3.2.2 Buildings with medium and large openings
The pressure coefficients are given in Tables 8 and 9 separately for mono-pit mon o-pitch ch and double pitch canopy roofs such as open-air parking garages, shelter areas, outdoor areas, railway platforms, stadia and theatres. The coefficients take into account of the combined effect of the wind exerted on and under the roof for all wind directions; the resultant is to be taken normal to the canopy. Where the local coefficients overlap, the greater gr eater of the two given values should be taken. However, the effect of partial closures of one side and or both sides, such as those due to trains, buses and stored materials shall be foreseen and taken into account.
Buildings with medium and large openings may also exhibit either positive or negative internal pressure depending upon the direction of wind. Buildings with medium openings between about 5 and 20 percent of wall area shall be examined for an internal pressure coefficient of +0.5 and later with an internal pressure coefficient of –0.5, and the analysis which produces greater distress of the member shall be adopted. Buildings with large openings, that is, openings l arger than 20 percent of the wall area shall be examined once with an internal pressure coefficient of +0.7 and a gain with an internal pressure coefficient of –0.7, and the analysis which produces greater distress of the member shall be adopted.
The solidity ratio f is equal to the area of obstructions under the canopy divided by the gross area under the canopy, both areas normal to the wind direction. f = 0 represents a canopy with no obstructions underneath. f = 1 represents the canopy fully blocked with contents to the downwind eaves. Values of C p for intermediate solidities may be linearly interpolated between these two extremes, and apply upwind of the position of maximum blockage block age only. For downwind downwind of the position positio n of maximum blockage, the coefficients for f = f = 0 may be used.
Buildings with one open side or opening exceeding 20 percent of wall area may be assumed to be subjected to internal positive pressure or suction similar to those of buildings with large openings. A few examples of buildings with one side openings are shown in Fig. 2 indicating values of internal pr essure coefficients with respect to the direction of wind. 7.3.3 External Pressure Pressure Coefficients 7.3.3.1 Walls
In addition to the forces due to t he pressures normal to the canopy, there will be horizontal loads on the canopy
The average external pressure coefficient for the walls 11
IS 875 (Part 3) : 2015
FIG. 2 B UILDINGS W ITH ONE S IDE O PENINGS
12
IS 875 (Part 3) : 2015 Table 5 External Pressure Coefficients (Cpe) for Walls Walls of Rectangular Clad Buildings (Clause 7.3.3.1)
NOTE h is the height to eaves or parapet, l is the greater horizontal dimensions of a building and w is the lesser horizontal dimensions of a building.
13
IS 875 (Part 3) : 2015 Table 6 External Pressure Coefficients (Cpe) for Pitched Roofs of Rectangular Recta ngular Clad Buildings (Clause 7.3.3.2)
NOTE 1 h is the height to eaves or parapet and w is the lesser horizontal dimension of a building. 2 Where no local coefficients are given, the overall coefficient apply. 3 For hipped roofs the local coefficient for the hip ridge may be conservatively taken as the the appropriate ridge value. 4 w and l are dimensions between the walls excluding overhangs. overhangs.
14
IS 875 (Part 3) : 2015 Table 7 External Pressure Coefficients (Cpe) for Monoslope Roofs of Rectangular Clad Buildings
h w
<2
(Clause 7.3.3.2)
* Applied to length w/2 from wind-ward end.
** Applies to remainder
NOTE 1 h is the height of eaves at lower side, is the greater horizontal dimensions of a building and w is the lesser horizontal dimension of a building. 2 I and and w are overall length and width including overhangs.
15
IS 875 (Part 3) : 2015 due to the wind pressure on any fascia and to friction over the surface of the canopy. For any wind direction, only the greater of these two forces need to be taken into account. Fascia loads should be calculated on the area of the surface facing the wind, using a force coefficient of 1.3. Frictional drag should be calculated 7.4.1. using the coefficients given in 7.4.1.
provided that the clearance between the tank and the ground is not less than the diameter of the cylinder. h is height of a vertical cylinder or length of a horizontal cylinder. Where there is a free flow of air around both ends, h is to be taken as half the length when calculating calcula ting h/D ratio. In the calculation of resultant load on the periphery of the cylinder, the value of C pi shall be taken into account. For open ended cylinders, C pi shall be taken as follows:
NOTE — Tables 10 to 15 may be used to get internal and external pressure coefficients for pitches and troughed free roofs for some specific cases for which aspect ratios and roof slopes have been specified. However, while using Tables 10 to 15 any significant departure from it should be investigated carefully. No increase shall be made for local effects except as indicated.
a)
b)
– 0.5, where h / D is less than 0.3.
7.3.3.4 Pitched and saw-tooth roofs multi-span buildings
7.3.3.8 Roofs Roo fs and bottom bot tomss of cylindr cyl indr ical elevated eleva ted structures
For pitched and saw-tooth roofs of multi-span buildings, the external average pressure coefficients shall be as given in Tables 16 and 17 respectively provided that all the spans shall be equal and the height to the eaves shall not exceed the span.
The external pressure coefficients for roofs and bottoms of cylindrical elevated structures shall be as given in Table 20. Alternately, the pressure distribution given in Fig. 3 can be used together with the force coefficients given in Table 25 for the cylindrical portion.
Pressure coefficients on overhangs from roofs 7.3.3.5 Pressure
The pressure coefficients on the top over-hanging portion of the roofs shall be taken to be the same as that of the nearest top portion of the non-overhanging portion of the roofs. The pressure coefficients for the underside surface of the over-hanging portions shall be taken as follows and shall be taken as positive if the overhanging portion is on the windward side:
7.3.3.9 Combined roofs The average external pressure coefficients for combined roofs are shown in Table 21. 7.3.3.10 Roofs with skylight
a)
1.25, 1.25, if the the ove overhan rhangin ging g slopes slopes, downw downward ards; s;
The average external pressure coefficients for roofs with skylight are shown in Table 22.
b)
1.00, 1.00, if the overhan overhanging ging is hori horizon zontal tal;; and
7.3.3.11 Grandstands
c)
0.75, 0.75, if the overhan overhanging ging slopes slopes upwards upwards.
The pressure coefficients on the roof (top and bottom) and rear wall of a typical grandstand roof which is open on three sides are given in Table 23. The pressure coefficients are valid for a particular ratio of dimensions dimensi ons as specified in Table Table 21 but may be used for deviations up to 20 percent. In general, the maximum wind load occurs when the wind is blowing into the open front of the stand, causing positive pressure under the roof and negative pressure on the roof.
For overhanging portions on sides other than windward side, the average pressure coefficients on adjoining walls may be used. 7.3.3.6 Curved roofs For curved roofs the external pressure coefficients coefficients shall be as given in Table 18. Allowance for local effects shall be made in accordance with Table 6. Two Two values of C 2 have been given for elevated curved roofs. Both the load cases have to be analyzed, and critical load effects are to be considered in design.
7.3.3.12 Spheres The external pressure coefficients for spheres shall be as given in Table 24.
7.3.3.7 Cylindrical structures
7.3.3.13 Frames
For the purpose of calculating the wind pressure distribution around a cylindrical structure of circular cross-section, the value of external pressure coefficients given in Table 19 may be used, provided that the Reynolds number is more than 10 000. They ma y be used for wind blowing normal to the axis of cylinders having axis normal to the ground plane (that is, chimneys and silos) and cylinders having their axis parallel to the ground plane (that is, horizontal tanks),
When taking wind loads on frames of clad buildings it is reasonable to assume that the pressures or suctions inside and outside the structure shall not be fully correlated. Therefore when taking the combined effect of wind loads on the frame, a reduction factor of building envelope envelope when K c = 0.90 may be used over the building roof is subjected to pressure and internal pressure is suction, or vice-versa. 16
IS 875 (Part 3) : 2015 Table 8 Pressure Pressure Coefficients for Monoslope Free Roofs (Clause 7.3.3.3)
NOTES 1 For monopitch canopies the centre of pressure should be taken to act at 0.3 w from the windward edge. 2 W and L are overall width and length including overhangs,
17
IS 875 (Part 3) : 2015 Table 9 Pressure Coef ficients for Free Standing Double Sloped Roofs (Clause 7.3.3.3)
NOTES 1 Each slope of a duopitch canopy should be able to withstand forces using both the maximum and the minimum coefficients, coefficients, and the whole canopy should be able to support forces using one slope at the maximum coefficient with the other slope at the minimum coefficient. For duoptich canopies the centre of pressure should be taken to act at the centre of each slope. 2 W and L and L are are overall width and length including overhangs
18
IS 875 (Part 3) : 2015 Table 10 Pressure Coefficients (Top (Top and Bottom) for Pitched Roofs, Roof Slope α = 30° (Clause 7.3.3.3)
19
IS 875 (Part 3) : 2015 Table 11 Pressure Coefficients (Top (Top and Bottom) for Pitched Roofs, Roof α = 30° with effects of Train or Stored Material (Clause 7.3.3.3)
20
IS 875 (Part 3) : 2015 Table 12 Pressure Pressure Coefficients (Top and Bottom) for Pitched Roofs, α = 10° (Clause 7.3.3.3)
21
IS 875 (Part 3) : 2015 Table 13 Pressure Coefficients (Top (Top and Bottom) for Pitched Free Roofs, α = 10° with effects of Train or Stored Materials (Clause 7.3.3.3)
22
IS 875 (Part 3) : 2015 Table 14 Pressure Coefficients for Troughed Free Roofs, α = 10° (Clause 7.3.3.3)
23
IS 875 (Part 3) : 2015 Table 15 Pressure Coefficients (Top and Bottom) for Troughed Free Roofs, α = 10° with Effects of Train Train or Stored Materials (Clause 7.3.3.3)
24
IS 875 (Part 3) : 2015 Table 16 External Pressure Coefficients (Cpe) for Pitched Roofs of Multispan Buildings (All Spans Equal) with h < w' (Clause 7.3.3.4)
Frictional drag : When wind angle θ = 0°, horizontal forces due to frictional drag are allowed for in the above values, and When wind angle θ = 90°, allow for frictional drag in accordance with 7.4.1 NOTE — Evidence on these buidings is fragmentary and any departure from the cases given should be investigated separately.
25
IS 875 (Part 3) : 2015 Table 17 External Pressure Coefficients (C pe) for Saw Tooth Roofs of Multispan Buildings (All Spans Equal) with h < w’ (Clause 7.3.3.4)
Frictional drag : When wing angle θ = 0°, horizontal forces due to frictional drag are allowed for in the above values, and When wind angle θ = 90°, allow for frictional drag in accordance with 7.4.1. 7.4.1. NOTE — Evidence on these buidings is fragmentary and any departure from the cases given should be investigated separately.
26
IS 875 (Part 3) : 2015 Table 18 External Pressure Coefficients (C pe) for Curved Roofs (Clause 7.3.3.6)
NOTE — When the wind is blowing normal to gable ends, C pe may be taken as equal to –0.7 for the full width of the roof over a length of l /2 /2 fr om the ga ble en ds an d – 0.5 for th e r emaining portion.
27
IS 875 (Part 3) : 2015 Table 19 External Pressure Coefficients Around Cylindrical Structures (Clause 7.3.3.7)
28
IS 875 (Part 3) : 2015
F IG. 3 EXTERNAL PRESSURE C OEFFICIENTS ON THE U PPER R OOF S URFACE STANDING ON THE G ROUND
29
OF C YCLINDRICAL S TRUCTURES
IS 875 (Part 3) : 2015 Table 20 External Pressure Coefficients for Roofs and Bottoms of Cylindrical Structures (Clause 7.3.3.8)
30
IS 875 (Part 3) : 2015 Table 21 External Pressure Pressure Coefficients (Cpe) for Combined Roofs (Clause 7.3.3.9)
31
IS 875 (Part 3) : 2015 Table 22 External Pressure Coefficients (Cpe) for Roofs with a Sky Light (Clause 7.3.3.10)
NOTES
7.4 Force Coefficients
1 The value of the force coefficient differs for the wind acting on different faces of a building or structure. In order to determine the critical load, the total wind load should be calculated for each wind direction. 2 If surface design pressure varies with height, the surface area of the building/structure may be sub-divided so that specified pressures are taken over appropriate areas. 3 In tapered buildings/structures, the force coefficients shall be applied after sub-dividing the building/structure into suitable number of strips and the load on each strip calculated individually, taking the area of each strip as Ae.
The value of force coefficients ( C f ) apply to a building or structure as a whole, and when multiplied by the effective frontal area Ae of the building or structure and design wind pressure, pd gives the total wind load (F ) on that particular building or structure. F = C f Ae pd
where F is the force acting in a direction specified in the respective tables and C f is the force coefficient for the building.
4 For force coefficients for structures not covered above reference may be made specialist literature on the subject or advice may be sought from specialist in the subject.
32
IS 875 (Part 3) : 2015 Table 23 Pressure Pressure Coefficients at Top Top and Bottom Bott om Roof of Grand Stands Sta nds Open Three Three Sides (Roof Angle Upto Upto 5°) (Clause 7.3.3.11)
33
IS 875 (Part 3) : 2015 Table 24 External Pressure Distribution Coefficients Around Spherical Structures (Clause 7.3.3.12)
7.4.1 Frictional Drag
b)
In certain buildings of special shape, a force due to frictional drag shall be taken into account in addition to those loads specified in 7.3. 7.3. For rectangular clad buildings, this addition is necessary only where the ratio d/h or d / b is more than 4. The fr ictional drag force, F', in the direction of the wind is given by the following formulae:
If h > b, F' = C f ' ( (d – 4b) bpd + C f ' ( (d – 4b) 2h pd
The first term in each case gives the drag on the roof and the second on the walls. The value of C f ’ has the following value:
≤ b, F' = C f ' ( (d – 4h) bpd + C f ' ( (d – 4b) 2h pd , and 34
1)
C f ' = 0.01 for smooth surfaces without corrugations or ribs across the wind dir ection,
2)
C f ' = 0.02 for surfaces with corrugations across the wind direction, and
3)
C f ' = 0.04 for surfaces with ribs across the wind direction.
IS 875 (Part 3) : 2015 NOTE — Structures that are in the supercritical flow regime, because of their size and design wind velocity , may need further calculation to ensure that the greatest loads do not occur at some wind speed below the maximum when the flow will be sub critical. The coefficients are for buildings without projections, except where otherwise shown.
For other buildings, the frictional drag has been indicated, where necessary, in the tables of pressure coefficients and force coefficients. 7.4.2 Force Coefficients for Clad Buildings 7.4.2.1 Clad buildings of uniform section
In Table 25, V d b is used as an indication of the airflow regime.
The overall force coefficients for rectangular clad buildings of uniform section with flat roo fs in uniform flow shall be as given in Fig. 4 and for other clad buildings of uniform section (without projections, except where otherwise shown) shall be as given in Table 25.
FIG . 4 F ORCE COEFFICIENT
7.4.2.2 Buildings of circular shapes Force coefficients for buildings of circular cross-section shapes shall be as given in Table 25. However more precise estimation of force coefficients for circular shapes of infinite length can be obtained from Fig. 5
FOR RECTANGULAR C LAD B UILDING IN U NIFORM F LOW
35
IS 875 (Part 3) : 2015 Table 25 Force Coefficients C f for Clad Buildings of Uniform Section (Acting in the Direction of Wind) (Clause 7.4.2.2)
36
IS 875 (Part 3) : 2015 Table 25 — (Continued )
37
IS 875 (Part 3) : 2015 Table 25 — (Concluded )
7.4.3 Force Coefficients for Unclad Buildings
taking into account the average height of surface roughness ε . When the length is finite the values obtained from Fig. 5 shall be reduced by the multiplication factor K ( ( see Table 28 and Annex D).
7.4.3.1 7.4.3.1 This section applies to permanently unclad buildings and to frameworks of buildings while temporarily unclad. In the case of buildings whose surfaces are well-rounded, such as those with elliptic, circular or oval cross-sections, the total force can be more at a wind speed much less than maximum due to transition in the nature of boundary layer on them. Although this phenomenon is well known in the case of circular cylinders, the same phenomenon exists in the case of many other well-rounded structures, and this possibility must be checked.
7.4.2.3 Free standing walls and hoardings Force coefficients coefficients for free standing walls and hoardings shall be as given in Table Table 26. To allow for oblique winds, the design shall also be checked for net pressure normal to t he surface varying linearly from a maximum of 1.7 C f at the windward edge to 0.44 C f at the leeward edge.
7.4.3.2 Individual members
The wind load on appurtenances and supports for hoardings shall be accounted for separately by using the appropriate net pressure coefficients. Allowance shall be made for shielding effects of one element on another.
a) The force coefficient given in Table 29 refers to members of infinite length. For members of finite length, the coefficients should be multiplied by a factor that depends on the ratio l / / b where l is the length of K that the member and b is the width across the direction of wind. Table 28 gives the required values of K . The following special cases must be noted while estimating K .
7.4.2.4. 7.4.2.4. Solid circular shapes mounted on a surface The force coefficients for solid circular shapes mounted on a surface shall be as given in Table 27. 38
IS 875 (Part 3) : 2015
FIG . 5 V ARIATION
OF
C f 1
2
WITH R e >
3 × 10 4
FOR C IRCULAR S ECTIONS
D
Table 26 Force Coefficients for Low Walls or Hoardings (< 15m High) (Clause 7.4.2.2)
39
IS 875 (Part 3) : 2015 1)
2)
when when any any member member abuts abuts on to to a plat platee or wall wall in such a way that free flow of air around th at end of the member is prevented, then the ratio of l/b shall be doubled for the purpose of determining K ; and
b) Flat-sided members — Force coefficients for wind normal to the longitudinal axis of flat-sided structural members shall be as given in Table 29.
w h en en b ot ot h en en d s o f a m e mb mb e r a r e s o obstructed, the ratio shall be taken as infinity for the purpose of determining K .
Table 27 Force Coefficients for Solid Shapes Mounted on a Surface (Clause 7.4.2.4)
Table 28 Reduction Factor K for Individual Members [(Clauses 7.4.2.2, 7.4.3.2(a)] Sl No.
l/b or l/D
2
5
10
20
40
50
100
(1)
(2)
(3)
(4)
(5)
(6)
(7)
(8)
(9)
(10)
0.58
0.62
0.68
0.74
0.82
0.87
0.98
1.00
0.80
0.80
0.82
0.90
0.98
0.99
1.00
1.00
0.62
0.66
0.69
0.81
0.87
0.90
0.95
1.00
i) ii)
Circular cylinder, cylinder, subcritical flow Circular cylinder, supercritical flow ( D D 6m2 /s)
iii)
For plate perpendicular to wind (b 6m2 /s)
40
IS 875 (Part 3) : 2015
h t g n e L e t i n i f n I f o s r e b m e M l a r u t c ] ) b u r t ( 2 S . . l 3 a 4 . u 7 d i e v s i u d l a n I C r [ o f f C s t n e i c i f f e o C e c r o F 9 2 e l b a T
41
IS 875 (Part 3) : 2015 Normal force,
/ b F n = (C fn pd K) /
where
Transverse force,
F t = (C ft pd K) / b
coefficie icient nt for the supercrit supercritical ical circula circularr C f super = force coeff members as given in Table Table 31 or Annex D,
c) Circular sections — Force coefficients for members of circular section shall be as given in Table 25 see also Annex D. d) Force coefficie coefficients nts for wires and cables shall shall be as given in Table 30 according to the diameter ( D), the design wind speed ( V d) and the surface roughness.
C f sub
= force coefficient coefficient for subcritical subcritical circular members as given in Table Table 31or Annex D,
C f flat
= force coeffici coefficient ent for the flat flat sided sided members members as given in Table 31,
effectivee area of of subcritical subcritical circu circular lar Acirc sub = effectiv members,
7.4.3.3 Single frames Force coefficients for a single frame having either,
Aflat
= effectiv effectivee area area of flat-side flat-sided d members, members,
Asub
= Acirc sub + Aflat, and = (Area of of the frame in a supercritical supercritical flow)/ flow)/ Ae
a)
all all fla flatt sid sided ed membe members rs;; or or
γ
b)
all circ circula ularr member memberss in which which all all the the member memberss of the frame have either:
7.4.3.4 Multiple frame buildings
1) 2)
D V d less than 6 m2 /s, or
This section applies to structures having two or more parallel frames where the windward frames may have a shielding effect upon the fr ames to leeward side. The windward frame and any unshielded parts of other 7.4.3.3, frames shall be calculated in accordance with 7.4.3.3, but the wind load on the parts of frames that are sheltered should be multiplied by a shielding factor which is dependent upon the solidity ratio of the windward frame, the types of members comprising the frame and the spac-ing ratio of the frames. The values of the shielding factors are given in Table 32.
2
D V d more than or equal to 6 m /s,
shall be as given in Table 31 according to the type of the member, the diameter (D), the design hourly mean wind wind spee speed d ( V d ) and and the the soli solidit dity y rat ratio io (Φ). Force coefficients for a single frame not complying with the above requirements shall be calculated as follows: Cf Cf super (1 )
Acir sub Asub
A C fsub (1 ) flat C f flat Asub
Table 30 Force Coefficients for Wires and Cables (L/D = 100) [Clause 7.4.3.2(d)]
Table 31 Force Coefficients for Single Frames (Clause 7.4.3.3)
42
V d
V d
IS 875 (Part 3) : 2015 Table 32 Shielding Factor H for for Multiple Frames (Clause 7.4.3.4) Effective Solidity Ratio e
(1)
Frame Spacing Ratio
< 0.5
1.0
2.0
4.0
> 8.0
(2)
(3)
(4)
(5)
(6)
1.0 1.0 1.0 1.0 1.0 1.0 0.9 0.8 0.6
1.0 1.0 1.0 1.0 1.0 1.0 0.9 0.8
1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0
0 1.0 1.0 0.1 0.9 1.0 0.2 0.8 0.9 0.3 0.7 0.8 0.4 0.6 0.7 0.5 0.5 0.6 0.7 0.3 0.6 1.0 0.3 0.6 NOTE — Linear interpolation between the values is permitted.
Where there are more than two frames of similar geometry and spacing, the wind load on the third and subsequent frames should be taken as equal to that on the second frame. The loads on the various frames shall be added to obtain total load on the structure.
7.4.3.5 Lattice towers a)
a) The frame spacing ratio is equal to the centre to centre distance between the frames, beams or girders divided by the least overall dimension of the frames, beam or girder measured in a direction normal to the direction of wind. For triangular framed structures or rectangular framed structures diagonal to the wind, the spacing ratio should be calculated from the mean distance between the frames in the direction of the wind. b) Effective solidity ratio, for Φ e = Φ for Φ e
Force Force coeff coeffici icient ent for for lattic latticee towers towers of of square square or equilateral triangle section with flat-sided members for wind blowing against any face shall be as given in Table 33.
b) For squar squaree lattic latticee towers towers with with flatflat-sid sided ed members the maximum load, which occurs when the wind blows into a corner, shall be taken as 1.2 times the load for the wind blowing against a face.
Φ e:
c)
For equil equilatera aterall triangl trianglee lattic latticee towers towers with flatflatsided members, the load may be assumed to be constant for any inclination of wind to a face.
d)
Force Force coeff coeffici icient entss for lattic latticee towers towers of of square square section with circular members, all in the same flow regime, may be as given in Table 34.
e)
Force Force coeff coefficie icients nts for for lattic latticee towers towers of of equilateral-triangle section with circular members all in the same flow regime may be as given in Table 35.
flat-sided members.
is to be obtained from Fig. 6 for members of circular cross-sections.
7.4.3.6 Tower Tower appurtenances The wind loading on tower appurtenances, such as ladders, conduits, lights, elevators, etc, shall be calculated using appropriate net pressure coefficients Table 33 Overall Force Coefficients for Towers Composed of Flat Sided Members [Clause 7.4.3.5(a)] Sl No.
FIG . 6 EFFECTIVE S OLIDITY R ATIO , SECTION M EMBERS
FOR C IRCULAR
43
Solidity Ratio
Force Coefficient
Square Towers
Equilateral Triangular Towers
(1)
(2)
(3)
(4)
i) ii) iii) iv) v)
< 0.1 0.2 0.3 0.4 0.5
3.8 3.3 2.8 2.3 2.1
3.1 2.7 2.3 1.9 1.5
IS 875 (Part 3) : 2015 Table 34 Overall Force Coefficients for Square Towers Towers Composed of Circular Members [(Clause 7.4.3.5 (d)] Sl No.
Solidity Ratio of Front Face
Force Coefficient
Subcritical Flow ( D D < 6 m2 /s)
Supercritical Flow ( D D 6 m2 /s)
Onto Face
Onto Corner
Onto Face
Onto Corner
(1)
(2)
(3)
(4)
(5)
(6)
i) ii) iii) iv) v) vi)
< 0.05 0.1 0.2 0.3 0.4 0.5
2.4 2.2 1.9 1.7 1.6 1.4
2.5 2.3 2.1 1.9 1.9 1.9
1.1 1.2 1.3 1.4 1.4 1.4
1.2 1.3 1.6 1.6 1.6 1.6
for these elements. Allowance may be made for shielding effect from other elements.
Since the values of IF can vary considerably based on building geometry and location , the given values values of IF are a kind of median values and are meant only for preliminary design estimates. The designer is advised that for assigning values of IF for final design particularly for tall buildings, specialist literature be consulted or a wind tunnel study carried out.
8 INTERF INTERFERE ERENCE NCE EFFEC EFFECTS TS 8.1 8.1 Gene Genera rall Wind interference is caused by modification in the wind characteristics produced by the obstruction caused by an object or a structure in the path of the wind. If such wind strikes another structure, the wind pressures usually get enhanced, though there can also be some shielding effect between two very closely spaced buildings/structures. The actual phenomenon is too complex to justify generalization of the wind forces/ pressures produced due to interference which can on ly be ascertained by detailed wind tunnel/CFD studies. However, some guidance can be provided for the purpose of preliminary prelimi nary design. design . To To account for the effect of interference, a wind interference factor (IF) has been introduced as a multiplying factor to be applied to the design wind pressure/force. Interfer ence effects can be more significant for tall buildings. The interference factor is defined as the ratio between the enhanced pressure/force in the grouped configuration to the corresponding pressure/force in isolated configuration.
8.2 Roof Roof of Low-Rise Low-Rise Build Building ingss Maximum increase in wind force on the roof due to interference from similar buildings in case of closely spaced low-rise buildings with flat roofs may be up to 25 percent for c/c distance ( x x) between the buildings of 5 times the dimension (b) of the interfering building normal to the direction of wind ( see Fig. 7). Interference effect beyond 20b may be considered to be negligible. For intermediate spacing linear interpolation may be used. 8.3 Tall Buildings Based on studies on tall rectangular buildings, Fig. 8 gives various zones of interference. The interference factor (IF), which needs to be considered as a multiplication factor for wind loads corresponding to
Table 35 Overall Force Coefficients for Equilateral Triangular Towers Towers Composed of Circular Members [Clause 7.4.3.5(e)] Sl No.
Solidity Ratio of Front Face
Force Coefficient
Subcritical Flow ( D D < 6 m2 /s)
Supercritical Flow ( D D 6 m2 /s) All wind Directions (4)
(1)
(2)
All wind Directions (3)
i)
< 0.05
1.8
0.8
ii)
0.1
1.7
0.8
iii) iv)
0.2 0.3
1.6 1.5
1.1 1.1
v) vi)
0.4 0.5
1.5 1.4
1.1 1.2
44
IS 875 (Part 3) : 2015 isolated building, may be assumed as follows, for preliminary estimate of the wind loads under interference caused by another interfering tall building of same or more height located at different zones Z1 to Z4 as shown in Fig. 8:
Zone IF
Z1
Z2
Z3
Z4
1.35
1.25
1.15
1.07
In general, the following guidelines may be used for examining the problems of wind-induced oscillations. a)
Buildin Buildings gs and and closed closed structu structures res with a height height to minimum lateral dimension ratio of more than about 5.0, or
b)
Buildi Buildings ngs and and struc structur tures es whose whose natu natural ral frequency in the first mode is less than 1.0 Hz.
Any building or structure which satisfies either of the above two criteria shall be examined for dynamic effects of wind.
The interference effect due to buildings of height less than one-third of the height of the building under consideration may be considered to be negligible while for interference from a building of intermediate height, linear interpolation may be used between one-third and full height.
NOTES
9 DYNAMIC YNAMIC EFFECT EFFECTS S
1 The fundamental time period (T) may either be established by experimental experimental observations on similar buildings or calculated by any rational method of analysis. In the absence of such data, T may be determined as follows for multi-storied buildings:
9.1 9.1 Gene Genera rall
a) For moment resistant frames without bracings or shear walls resisting the lateral loads, T = = 0.1 n
Flexible slender structures and structural elements shall be investigated to ascertain the importance of wind induced oscillations or excitations in along wind and across wind directions.
FIG. 7 L OW-RISE B UILDINGS
where n = number of storeys including basement storeys; and b) for all others
IN TANDEM C AUSING I NTERFERENCE E FFECT
FIG . 8 INTERFERENCE Z ONES
FOR T ALL R ECTANGULAR B UILDINGS OF S AME OR G REATER H EIGHT (C LAUSE 7.3)
45
IS 875 (Part 3) : 2015 T =
7 Buildings and structures that may be subjected to significant wind excited oscillations. It is to be noted that wind induced oscillations may occur at wind speeds lower than the design wind speed.
0.09 H d
where H = total height of the main structures of the building, in m; and
8 Analytical methods for the evaluation o f response of dynamic structures to wind loading can be found in the special publications.
d = maximum base dimension of building in meters in a direction parallel to the applied wind force.
9 In assessing wind loads due to such dynamic phenomenon as galloping, flutter and ovalli ng, in the absence of the required information either in the special publicat ions or other literature, expert advice should be sought including experiments on models in boundary layer wind tunnels.
2 If preliminary studies indicate that wind-induced oscillations are likely to be significant, investigations should be pursued with the aid of analytical methods or if necessary, by means of wind tunnel tests on models. 3 Across-wind motions may be due to lateral gustiness of the wind. unsteady wake flow (for example, vortex shedding), negative aerodynamic damping or due to a combination of these effects. These cross-wind motions may become critical in the design of tall buildings/structures.
9.2 Motion Motion due to to Vortex Vortex Shedding Shedding 9.2.1 Slender Structures
4 Motions in the direction of wind (known also as buffeting) are caused by fluctuating wind force associated with gust. The excitation depends on gust energy available at the resonant frequency.
For a structure, the vortex shedding frequency f s shall be determined by the following formula:
5 The eddies shed from an upstream body may intensify motion in the direction of the wind and may also affect cross-wind motion.
f s
=
St V z,H b
6 The designer should also be aware of the following three forms of wind-induced motion which are characterized by increasing amplitude of oscillation with the increase of wind speed.
where
i) Gallopin Galloping g — Galloping Galloping is transverse transverse oscillation oscillationss of some structures due to the development of aerodynamic forces which are in phase with the motion. It is characterized by the progressively increasing amplitude of transverse vibration with increase of wind speed. The cross-sections cross-sections which are particularly prone to this type of excitation include the following: following:
V z,H = hourly hourly mean mean wind wind speed speed at height height z, and
S t
= breadth breadth of a structu structure re or structur structural al member member normal to the wind direction in the horizontal plane
b
a)
1) All structures structures with non-circular cross-sections, cross-sections, such as triangular, square, polygons, as well as angl es, crosses, and T sections.
S t
2) Twisted cables and cables with ice encrustations.
= Stro Strouh uhal al numb number er,
Circular structures — For structures of circular in cross-section:
= 0.20 fo fo r D V z,H less than 6 m2 /s, and = 0.25 for D V z,H more than or equal to 6 m2 /s.
ii) Flutter — Flutter Flutter is unstable oscillator oscillatory y motion of a structure due to coupling between aerodynamic force and elastic deformation of the structure. Perhaps the most common form is oscillatory motion due to combined bending and torsion. Although oscillatory motion in each degree of freedom may be damped, instability can set in due to energy transfer from one mode of oscillation to another and the structure is seen to execute sustained or divergent oscillations with a type of motion which is a combination of the individual modes of vibration. Such energy transfer takes place when the natural frequencies of modes taken individually are close to each other (ratio being typically less than 2.0). Flutter can set in at wind speeds much less than those required for exciting the individual modes of motion. Long span suspension bridge decks or any member of a structure with large values of d/t (where d is the length of the member and t is its dimension parallel to wind stream) are prone to low speed flutter. Wind tunnel testing is required to determine critical flutter speeds and the likely structural response. Other types of flutter are single degree of freedom stall flutter, torsional flutter, etc.
1 Significant cross wind motions may be produced by vortex shedding if the natural frequency of the structure or structural element is equal to the frequency of the vortex shedding within the range of expected wind speeds. In such cases, further analysis should be carried out on the basis of special publications.
iii) Ovalling — Thin walled structures with open ends at one or both ends such as oil storage tanks and natural draught cooling towers in which the ratio of the diameter or minimum lateral dimension to the wall thickness is of the order of 100 or more are prone to ovalling oscillations. These oscillations are characterized by periodic radial deformation of the hollow structure.
4 The formulae given in 8.2.1 (a) is valid for infinitely long cylindrical structures. The value of S t decreases slowly as the ratio of length to maximum transverse width decreases, the reduction being up to about half the value, if the structure is only three times higher than its width. Vortex shedding need not be considered if the ratio of length to maximum transverse dimension is less than 2.0.
b) Rectangular structures — For structures of rectangular cross-section: S t = 0.10 NOTES
2 Unlined welded steel chimney stacks and similar structures structures are prone to excitations by vortex shedding. 3 Intensification of the effects of periodic vortex shedding has been reported in cases where two or more similar structures are located in close proximity, for example at less than 20b apart, where b is the dimension of the structure normal to the wind.
46
IS 875 (Part 3) : 2015 10 DYNAMI DYNAMIC C WIND WIND RESPON RESPONSE SE
V z,d = design design hourly hourly mean mean wind speed speed at at height height z, in m/s (see 6.4 )
10.1 10.1 Gene Genera rall
drag force coeffi coefficien cientt of the building building/ / C f,z = the drag structure corresponding to the area Az
Tall buildings which are ‘wind sensitive’ shall be designed for dynamic wind loads. Hourly mean wind speed is used as a reference wind speed to be used in dynamic wind analysis. For calculation of along wind loads and response (bending moments, shear forces, or tip deflections) the Gust Factor (GF) method is used as specified in 10.2 . The across wind design peak base overturning moment and tip deflection shall be calculated using 10.3 .
G
= 1+ r
2 2 H s gR SE 2 gv Bs (1 + g ) + β
where r
= roughness roughness factor factor which is is twice twice the longitudinal turbulence intensity, I h, i (see 6.5),
gv
= peak factor factor for upwind upwind veloci velocity ty fluctuat fluctuation ion,
10.2 Along Along Wind Wind Respons Responsee
For calculation of along-wind load effects at a level s on a building/structure, the design hourly mean wind pressure at height z shall be multiplied by the Gust Factor (GF). This factor is dependent on both the overall height h and the level s under consideration (see Fig. 9). For calculation of base bending moment and deflection at the top of the building/structure s should be taken as zero.
= 3.0 for for categor category y 1 and 2 terrain terrains, s, and and = 4.0 for for catego category ry 3 and and 4 terrai terrains, ns, Bs
The design peak along wind base bending moment, ( M a) shall be obtained by summing the moments resulting from design peak along wind loads acting at different heights, z, along the height of the building/ structure and can be obtained from, M a =
= Gust Gust Factor Factor and is given given by. by.
= background background factor factor indicat indicating ing the the measure measure of slowly varying component of fluctuating wind load caused by the lower frequency wind speed variations =
1
1 +
0.26 ( h − s ) Lh
2
+ 0.46bsh2
where
∑ F z Z
F z = C f,z Az pd G
breadth of the building/stru building/structure cture bsh = average breadth between heights s and h
where
Lh
design peak peak along along wind load load on the buildi building/ ng/ F z = design structure at any height z
= measure measure of effective effective turbulence turbulence length length scale scale at the height, h, in m 0.25
h for terrain category 1 to 3 10 0.25 h = 70 for terrain category 4 10 = 85
Az = the effecti effective ve frontal frontal area area of the the building/ building/ structure at any height z, in m2 design hourly hourly mean mean wind wind press pressure ure pd = design corresponding to V z,d and obtained as
φ
2 0.6 V z,d (N/m2)
= factor factor to accoun accountt for the seco second nd order order turbulence intensity
Level at which action effects are calculated h
s z
NOTE — 0 < s < h, and s < z < h
FIG . 9 N OTATIONS FOR HEIGHTS 47
IS 875 (Part 3) : 2015
=
10.2.1 Peak Acceleration in Along Wind Direction
gv I h ,i Bs
The peak acceleration at the top of the building/ ˆ in m/s2) is given structure in along wind direction ( x by the following equation:
2
turbulencee intens intensity ity at at height height h in terrain I h,i = turbulenc category i height factor factor for reson resonance ance respons responsee H s = height
s = 1+ h S
SE 2 ˆ = ( 2π fa ) x gR r x
β
2
where
=
1
3.5 fa h 4 fa b0 h 1 + V 1 + V h ,d h, d
For computing the peak acceleration in the along wind direction, a mean wind speed at the height of the building/structure, V h corresponding to a 5 year mean return period shall be used. A reduced value of 0.011 is also suggested for the structural damping, β for reinforced concrete structures.
where the building/s building/structur tructuree b0h = average breadth of the between 0 and h. E
= spectru spectrum m of turbulenc turbulencee in the approac approaching hing wind stream =
10.3 Across Across Wind Wind Respon Response se
This section gives method for determining equivalent static wind load and base overturning moment in the across wind direction for tall enclosed buildings and towers of rectangular cross-section. Calculation of across wind response is not required for lattice towers.
π N
(1 + 70.8 N ) 2
5
6
where
The across wind design peak base bending moment M c for enclosed buildings and towers shall be determined as follows:
effective reduced reduced frequenc frequency y N = effective = f a
= mean deflec deflection tion at at the positio position n where where the acceleration is required. Other notations are same as given in 10.2.
x
= size size reducti reduction on facto factorr given given by: by:
f a Lh V h,d
M c
= f i r s t m o d e n a t u r al al f r e qu qu e n c y o f t h e building/structure in along wind direction, in Hz
where
V h,d = design design hourly hourly mean mean wind speed speed at heigh height, t, h
gh
= a pea peak k fac facto tor, r,
in m/s (see 6.4 )
β
=
= damping damping coeffici coefficient ent of the building building/st /struct ructure ure (see Table 36)
Pa;
2 ln ln ( 3 60 6 00 f a )
Table 36 Suggested Values of Structural Damping Coefficients Coefficients
b
= the breadt breadth h of the struc structure ture norma normall to the wind, in m;
h
= the heigh heightt of the the struct structure, ure, in in m;
k
= a m o d e sh sh a p e p o w er er e x p on on e nt nt f o r representation of the fundamental mode shape as represented by:
(Clause 10.2) Sl No.
Kind of Structure
(1)
(2)
Damping Coefficient,
z ψ( z z)= h
β
(3)
i)
Welded steel structures
0.010
ii)
Bolted steel steel structures
0.020
iii)
Prestressed concrete structures
structures/RCC structures/RCC
2 ln ln ( 36 00 f c ) in cross wind direction;
hourly mean wind wind pressu pressure re at height height h, in in ph = hourly
factor for resonant resonant res respons ponsee gR = peak factor =
πC = 0.5gh ph bh 2 (1.06 − 0.06 k ) fs β
f c
k
= first mode natura naturall frequency frequency of the building/ building/ structure in across across wind wind direction, direction, in Hz.
The across wind load distribution on the building/ structure can be obtained from M c using linear
0.016
48
IS 875 (Part 3) : 2015
distribution of loads as given below: F z,c =
= 0.5 k = c)
3 Mc z h2 h
d) lattice lattice tower tower decrea decreasin sing g in stiff stiffnes nesss with with height, or a tower with a large mass at the top, k = = 2.3
where F z,c = across wind load per unit height at height z. 10.3.1 Peak Acceleration in Across Wind Direction
C fs = across wind force spectrum coefficient generalized for a linear mode. ( see Fig. 10 and Fig. 11).
The peak acceleration at the top of the building/ structure in across-wind direction ( y ˆ in m/s2) with approximately constant mass per unit height shall be determined as follows: g pb ˆ = 1.5 h h ( 0.76 + 0.24k ) y m0
πCfs β
β
10.4 Combinatio Combination n of Along Wind Wind and Across Across Wind Wind Load Effects
Typical values of the mode shape power exponent, k are as follows: unif unifor orm m cant cantil ilev ever er, k = = 1.5
b)
slender slender framed framed struc structure ture (moment (moment resi resistin sting), g),
= damping damping coeffici coefficient ent of the building/ building/stru structur cturee (see Table 36).
average mass mass per unit height height of the m0 = the average structure in, kg/m.
a)
buildi building ng with with a centr central al core core and moment moment resisting façade, k = = 1.0
The along wind and across wind loads have to be applied simultaneously on the building/structure during design.
Legend: — Turbulence Intensity of 0.12 at 2/ 3 h
FIG . 10 V ALUES OF
- - Turbulence Intensity of 0.20 at 2/3 h
THE C ROSS W IND F ORCE S PECTRUM C OEFFICIENT FOR S QUARE S ECTION BUILDINGS
49
IS 875 (Part 3) : 2015
FIG . 11 V ALUES
OF THE C ROSS WIND F ORCE S PECTRUM C OEFFICIENT FOR 2:1 AND
1 : 2 RECTANGULAR S ECTION B UILDINGS
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IS 875 (Part 3) : 2015
ANNEX A
(Clause 6.2) BASIC WIND SPEED AT 10 m HEIGHT FOR SOME IMPORTANT CITIES / TOWNS City/Town
Basic wind Speed m/s
City/Town
Basic wind Speed m/s
Ag r a
47
Kanpur
47
Ahmedabad
39
Kohima
44
Ajmer
47
Kolkata
50
A l mo r a
47
Kozhikode
39
Amritsar
47
Kurnool
39
Asansol
47
Lakshadweep
39
Aurangabad
39
Lucknow
47
Bahraich
47
Ludhiana
47
Bengaluru
33
Madurai
39
Barauni
47
Mandi
39
Bareilly
47
Mangalore
39
Bhatinda
47
Moradabad
47
Bhilai
39
M u mb ai
44
Bhopal
39
Mysore
33
Bhubaneshwar
50
Nagpur
44
Bhuj
50
Nainital
47
Bikaner
47
Nasik
39
Bokaro
47
Nellore
50
Chandigarh
47
Panjim
39
Chennai
50
Patiala
47
Coimbatore
39
Patna
47
Cuttack
50
Puducherry
50
Darbhanga
55
Port Blair
44
Darjeeling
47
Pune
39
Dehradun
47
Raipur
39
Delhi
47
Rajkot
39
Durgapur
47
Ranchi
39
Gangtok
47
Roorkee
39
Guwahati
50
Rourkela
39
Gaya
39
Shimla
39
Gorakhpur
47
Srinagar
39
Hyderabad
44
S u r at
44
Imphal
47
Tiruchirappalli
47
Jabalpur
47
Trivandrum
39
Jaipur
47
Udaipur
47
Jamshedpur
47
Vadodara
44
Jhansi
47
Var anasi
47
Jodhpur
47
Vijayawada
50
Vishakapatnam
50
51
IS 875 (Part 3) : 2015
ANNEX B
[Clause 6.3.2.4 (b)(ii)] CHANGES IN TERRAIN CATEGORIES B-1 LO LOW W TO HIGH HIGH TERRAIN TERRAIN CATEGO CATEGORY RY NUMBER
follows:
In cases of transition from a low terrain category number (corresponding to a low terrain roughness) to a higher terrain category number (corresponding to a rougher terrain), the velocity profile over the rougher terrain shall be determined as follows: a)
B el el ow ow h ei ei gh gh t h x, the velocities shall be determined in relation to the rougher terrain; and
b)
A bo bo ve ve h ei ei gh gh t h x, the velocities shall be determined in relation to the less rough (more distant) terrain.
a)
A b o ve h ei ei g ht ht hx , the velocities shall be determined in accordance with the rougher (more distant) terrain; and
b)
Below he height hx, the velocity shall be taken as the lesser of the following: 1)
that determi determined ned in acco accordan rdance ce with the less rough terrain, and
2)
the the vel veloc ocit ity y at heig height ht hx as determined in relation to the rougher terrain NOTE — Examples of determination of velocity profiles in the vicinity of a change in terrain category are shown in Figs.12a and 12b.
B-3 MORE THAN ONE ONE CATEGOR CATEGORY Y B-2 HIGH TO TO LOW TERRAIN TERRAIN CATEGOR CATEGORY Y NUMBER
Terrain changes involving more than one category shall B-2. be treated in similar way to that described in B-1 and B-2.
In cases of transition from a more rough to a less rough terrain, the velocity profile shall be determined as
FIG. 12 V ELOCITY P ROFILES
NOTE — Examples involving three terrain categories are shown in Fig. 12c.
IN THE VICINITY OF A C HANGE IN T ERRAIN C ATEGORY
52
IS 875 (Part 3) : 2015
FIG. 12 V ELOCITY P ROFILES
IN THE VICINITY OF A C HANGE IN T ERRAIN C ATEGORY
53
IS 875 (Part 3) : 2015
ANNEX C
(Clause 6.3.3.1) EFFECT OF A CLIFF OR ESCARPMENT ON EQUIVALENT HEIGHT ABOVE GROUND ( k3 FACTOR) the local topography to the site is significant in terms of wind flow. In such cases, the average value of the terrain upwind of the site for a distance of 5 km should be taken as the base level from wind to assess the height, Z, and the upwind slope θ, of the feature.
C-1 The influence of the topographic feature is considered to extend 1.5 L e upwind and 2.5 L e downwind of the summit of crest of the feature where Le is the effective horizontal length of the hill de pending on slope as indicated below (see Fig. 13). Sl Slope
Le
3° < θs ≤ 17°
L
θs > 17°
C-2 TOPOGRA TOPOGRAPHY PHY FA FACTOR, CTOR, k3 The topography factor k 3 is given by the following: k 3
Z / 0. 3
where C has the following values:
where L
Slope
= actual actual length length of the the upwind upwind slope slope in the the wind wind direction,
Z
= effectiv effectivee height height of the the topograph topography y feature, feature, and
θs
= upwind upwind slope slope in the wind direc directio tion. n.
= 1 + C s0
3° < θs ≤ 17 17°
θs > 17°
C
1.2 ( Z / L) 0.36
and s0 is a factor derived in accordance with C-2.1 appropriate to the height, H above above mean ground level and the distance, x, from the summit or crest relative to the effective length, Le
In case, the zone in downwind side of the crest of the feature is relatively flat ( θ s < 3°) for a distance exceeding Le, then the feature should be treated as an escarpment. Otherwise the feature should be treated as a hill or ridge. Examples of typical features are given in Fig. 13.
C-2.1 The factor, s0 should be determined from: a)
Fig. 14 for cliffs cliffs and escarpm escarpment ents, s, and
b)
Fig. Fig. 15 15 for for ridg ridges es and and hills hills.
NOTE – Where the downwind slope of a hill or ridge is more than 3°, there will be large regions of reduced accelerations or even shelter and it is not possible to give general design rules to cater for these circumstances. Values of s 0 from Fig. 15 may be used as upper bound values.
NOTES 1 No difference is made, in evaluating k 3 between a three dimensional hill and two dimensional ridge. 2 In undulating terrain, it is often not possible to decide whether
54
IS 875 (Part 3) : 2015
FIG . 13 TOPOGRAPHICAL D IMENSIONS
FIG. 14 F ACTOR
FIG . 15 FACTOR
S FOR R IDGE AND H ILL
S FOR C LIFF AND E SCARPMENT
55
IS 875 (Part 3) : 2015
ANNEX D
(Clauses 7.4.2.2, 7.4.3.2 and 7.4.3.3) 7.4.3.3) WIND FORCE ON CIRCULAR SECTIONS D-1 The wind force on any object is given by:
= C f Ae pd F = where force coeffi coeffici cient ent, C f = force effective area area of the the object object normal normal to the the Ae = effective wind direction, and pd
= design design pres pressure sure of the the wind. wind.
For most shapes, the force coefficient remains approximately constant over the whole range of wind speeds likely to be encountered. However, for objects of circular cross-section, it varies considerably.
F IG . 16 W AKE
For a circular section, the force coefficient depends on the way in which the wind flows around it and is dependent upon the velocity and kinematic viscosity of the wind and diameter of the section. The force coefficient is usually quoted against a non-dimensional parameter, called the Reynolds number, which takes into account of the velocity and viscosity of the flowing medium (in this case the wind), and the member diameter.
F IG. 17 W AKE
Reynolds number, Re = DV d / v
= diame diamete terr of the the memb member er
The variation of C f with parameter D V d is shown in Fig. 5 for infinitely long circular cylinders having various values of relative surface r oughness (ε / D) when subjected to wind having an intensity and scale of turbulence typical of built-up urban areas. The curve for a smooth cylinder ( ε /D) = 1 × 10 –5 in a steady air stream, as found in a low-turbulence wind tunnel, is also shown for comparison.
design hourl hourly y mean mean wind wind speed speed V d = design
ν
IN SUPER C RITICAL F LOW
a critical value of Reynolds number followed by a gradual rise as Reynolds number is increased still further.
where D
IN S UB C RITICAL F LOW
= kinemati kinematicc viscosi viscosity ty of the air air which is is 1.46 –5 2 × 10 m /s at 15 °C an d st a nd ar d atmospheric pressure.
Since in most natural environments likely to be found in India, the kinematic viscosity of the air is fairly constant, it is convenient to use D V d as the parameter instead of Reynolds number and this has been done in this code.
It can be seen that the main effect of free-stream turbulence is to decrease the critical value of the parameter D V d . For subcritical flows, turbulence can produce a considerable reduction in C f below the steady air-stream values. For supercritical flows, this effect becomes significantly smaller.
The dependence of a circular section’s force coefficient coefficient on Reynolds number is due to the change in the wake developed behind the body. At a low Reynolds number, the wake is as shown in Fig. 16 and the force coefficient is typically 1.2. As Reynolds number is increased, the wake gradually changes to that shown in Fig. Fi g. 17; that is, the wake width dw decreases and the separation point denoted as sp, moves from front to the back of the body.
If the surface of the cylinder is deliberately roughened such as by incorporating flutes, riveted construction, etc, then the data given in Fig. 5 for appropriate value of ε / D > 0 shall be used. NOTE — In case of uncertainty regarding the value of ε to be used for small roughness, ε / D shall be taken as 0.001.
As a result, the force coefficient shows a rapid drop at
56
IS 875 (Part 3) : 2015
ANNEX E
(Foreword ) COMMITTEE COMPOSITION (Excluding Water Resources Development Division) Sectional Committee, CED 37 Org anization
Re presentative(s)
In personal capacity (80, ( 80, SRP Colony, Peravallur, Chennai 600 082) 082 )
DR N. LAKSHMANAN (Chairman )
Atomic Energ y Regulator y Boar d, Mumbai
SHRI L. R. BISHNOI SHRI A. D. ROSHAN ( Alternate) Alternate )
Bhar at Heavy Electricals Limited, New Delhi
SHRI S. S. M ANI
Central Bu ilding Resear ch Institute (CSIR), Ro or kee
DR A. K. P ANDEY DR RAJESH DEOLIYA ( Alternate) Alternate)
Central Electr icity A uthority, New Delhi
SHRI R. B. WALIMBE SHRI S. K. ROY CHOWDHURY ( Alternate) Alternate)
Cen tral Pub lic Wor ks Dep artment, New Delhi
SHRI A. K. GARG SHRI RAJESH KHARE ( Alternate) Alternate)
Central Water Commission, New Delhi
DIRECTOR C&M DD (E&N E) DIRECTOR C&MDD (N&W) ( Alternate) Alternate)
Engineer-in-Chief ’s Branc h (MES), NewDelh i
BRIG S ANDEEP RAWAT SHRI V. K. JATAV ( Alternate) Alternate )
Engineers India Limited, New Delhi
SHRI VINAY KUMAR SHRI SUDHIR CHATURVEDI ( Alternate) Alternate)
G a m m o n I n d i a L i m i te d , M u m b a i
SHRI S. W. DESHPANDE SHRI A VINASH Y. Y. MAHENDRAKAR ( Alternate) Alternate )
Indian In stitute of Tech nology Mad ras, C hennai
DR D EVDAS MENON DR A MEHER PRASAD ( Alternate) Alternate)
Indian I nstitute of Techno lo gy Kanpu r, Kanp ur
DR VINAY K. GUPTA
Indian Institute of Tec hnolog y Roo r kee, R oor kee
DR PREM KISHAN DR S.K.K AUSHIK ( Alternate) Alternate)
In dian Metro log ical Dep artment, New Delhi
SHRI K. RATNAM
M.N. Dastur & Company Lim ited, Kolkata
SHRI A . DAS GUPTA SHRI SATYAKI SEN ( Alternate) Alternate)
MEC ON Limited, R anchi
SHRI ONKAR SAHAY SHRI A. K. B EG ( Alternate) Alternate)
Mi ni ni st st ry ry o f S hi hip pi pin g, g, R oa oad Tr an an sp sp or ort & Hi gh gh wa way s, s, New De lh lh i
SHRI S. K. PURI SHRI SATISH KUMAR, SE (P-9) ( Alternate) Alternate)
Mun cipal Co rporation of Greater Mumbai, Mumbai
Deputy Municipal C ommissio ner (ENGG) City Engineer ( Alternate) Alternate)
Nati Nation onal al Buil Buildi ding ngss Con Const stru ruct ctio ion n Cor Corpo pora rati tion on Limi Limite ted, d, New New Del Delhi hi
SHRI R AKESH MARYA SHRI L. P. SINGH ( Alternate) Alternate)
Nati Nation onal al Coun Counci cill for for Ceme Cement nt and and Buil Buildi ding ng Mate Materi rial als, s, Ball Ballab abga garh rh
SHRI V. V. ARORA SHRI S. S HARMA ( Alternate) Alternate)
National The rmal Power C or por ation, Noida
SHRI H. KUNDU SHRI M ASOOM A LI ( Alternate) Alternate )
Researc h, De Designs & Stan dards Or Organization, Lu Lu cknow
Joint Di Directo r St Standards (B (B &S) JT Director Stnds (B&S) SB-I ( Alternate) Alternate)
RITES Limited , Gurgaon
SHRI ASHOK KUMAR MATHUR
Structu ral Engineering Research Centre (C SIR ), Chennai
DR S. SELVI RAJAN DR P. HARIKRISHNA ( Alternate) Alternate)
TC E Con sulting Eng in eers Limited, Mu mbai
SHRI A. P. MULL SHRI A. DUTTA ( Alternate) Alternate )
The Institutio n of Engineer s (India) Ltd, New Delhi
SHRI K. B. RAJORIA
57
IS 875 (Part 3) : 2015 In personal capacity, (P-121, (P-121, Sanjay Nagar, Ghaziabad 201 001) 001 )
SHRI S. K. A GARWAL
In personal capacity, (142 ( 142 Deshbandhu Apartments, New Delhi 110 019)
SHRI G. P. LAHIRI
In personal capacity, (61, (61, Civil Lines, Roorkee 247 667)
DR PREM KRISHNA
BIS Directorate General
Shri D. K. AGRAWAL, SCIENTIST ‘F’ and HEAD (CIVIL ENGG) [Representing Director General ( Ex-officio)] Ex-officio )]
Member Secretaries Shri S. CHATURVEDI SCIENTIST ‘F’ (CIVIL ENGG), BIS and Shri S. ARUN KUMAR SCIENTIST ‘C’ (CIVIL ENGG), BIS
58
(Continued from from second cover ) f)
Provisions Provisions to account account for for effects of directionality directionality, area averagin averaging g and correlation correlation of of pressures pressures on the design wind pressure have been included.
g)
Guidelines Guidelines to account account for the the wind induced induced interferenc interferencee for tall buildings buildings and low rise buildings buildings have have been included for use in preliminary design. It is however recommended to carry out detailed boundary layer wind tunnel tests/CFD (Computational Fluid Dynamics) studies for final design of important structures.
h)
In the Gust Factor Method for eva evaluating luating along wind response, response, equations equations have have been suggested suggested for background factor, size reduction factor, energy ratio and length scale of turbulence.
j)
A method for computing across wind response of tall buildings and lattice towers, which is in line with some of the international codes of practice, has been included.
The Committee observed that there has been a growing awareness among the consultants, academicians, academician s, researchers and practice engineers for design and construction of wind sensitive structures. In order to augment the available limited good quality meteorological wind data and structural response data, it is necessary to conduct full scale measurements in the field. Thus as emphasized in the previous revision, all individuals and organizations responsible for putting-up of tall structures are encouraged to provide instrumentation in their existing and new structures (transmission towers, chimneys, cooling towers, buildings, etc) at different elevations (at least at two levels) to continuously measure and monitor wind data. The instruments are required to collect data on wind direction, wind speed and structural response of the structure due to wind (with the help of accelerometer, strain gauges, etc). It is also the opinion of the Committee that such instrumentation i n tall structures shall not in any way affect or alter the functional behaviour of such structur es. The data so collected shall be very valuable in evolving evolving more accurate wind loading of structures. The Committee responsible for the formulation of this standard has taken into account the prevailing practice in regard to loading standards followed in this country by the various authorities and has also taken note of the developments in a number of other countries. In the formulation of this code, the following overseas standards have also been examined: a)
BS EN 1991-1-4:2005 1991-1-4:2005 Eurocode Eurocode 1: Actions on on structures structures — Part 1-4: 1-4: General General actions actions — Wind Wind actions actions
b)
Joint Australian/Ne Australian/New w Zealand Standard Standard AS/NZS AS/NZS 1170.2:2002 1170.2:2002 Structural Structural design design actions, actions, Part 2: Wind Wind actions
c)
ASCE 7-05 American American Standard Standard Building Building Code Requiremen Requirements ts for Minimum Minimum Design Design Loads Loads for Buildings Buildings and Other Structures.
d)
AIJ 2004 — Architecture Architecture Institute Institute of Japan Japan (AIJ) Recomme Recommendation ndationss for Loads Loads on Buildings. Buildings.
The composition of the Committee responsible for the formulation of this Code is given at Annex E. For the purpose of deciding whether a particular requirement of this standard is complied with, the final value observed or calculated, calculated, expressing the result of a test or analysis, analysis, shall be rounded off in accordance accordance with IS 2 : 1960 ‘Rules for rounding off numerical values (revised )’. )’. The number of significant places retained in the rounded off value should be the same as that of specified value in this standard.
Bureau of Indian Standards BIS is a statutory institution established under the Bureau of Indian Standards Act , 1986 to promote harmonious development of the activities of standardization, marking and quality certification of goods and attending to connected matters in the country. Copyright BIS has the copyright of all its publications. No part of these publications may be reproduced in any form without the prior permission in writing of BIS. This does not preclude the free use, in the course of implementing the standard, of necessary details, such as symbols and sizes, type or grade designations. Enquiries relating to copyright be addressed to the Director (Publications), BIS. Review of Indian Standards Amendments are issued to standards as the need arises on the basis of comments. Standards are also reviewed periodically; a standard along with amendments is reaffirmed when such review indicates that no changes are needed; if the review indicates that changes are needed, it is taken up for revision. Users of Indian Standards should ascertain that they are in possession of the latest amendments or edition by referring to the latest issue of ‘BIS Catalogue’ and ‘Standards : Monthly Additions’. This Indian Standard has been developed from Doc No.: CED 37 (7792).
Amendments Issued Since Publication Amend No.
Date of Issue
Text Affected
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IS 875 (Part 3) : 2015
Indian Standard
— 3
Design Loads (Other than Earthquake) for Buildings and Structures — Structures — Code of Practice Part 3 Wind Loads
( Thir Third d Rev Revis isio ion n)
ICS 91.100.10
© BIS 2015
B U RE A U O F I N DI A N ST A ND AR D S
110002 9 MANAK BHAVAN, 9 BAHADUR SHAH ZAFAR MARG NEW DELHI-110002 www.bis.org.in www.standardsbis.in
April 2015
Price Group 14
Structural Safety Sectional Committee, CED 37
FOREWORD This Indian Standard (Part 3) (Third Revision) was adopted by the Bureau of Indian Standards after the draft finalized by the Structural Safety Sectional Committee had been approved by the Civil Engineering Division Council. A building has to perform many functions satisfactorily. Amongst these functions are the utility of the building for the intended use and occupancy, structural safety, fire safety and compliance with hygienic, sanitation, ventilation and daylight standards. The design of the building is dependent upon the minimum requirements prescribed for each one of the above functions. The minimum requirements pertaining to the structural safety of buildings are being covered in loading codes by way of laying down minimum design loads, which have to be assumed for dead loads, imposed loads, wind loads and other external loads, the structure would be required to bear. Strict conformity to loading standards, it is hoped , will not only ensures the structur al safety of the buildings and structures which are being designed and constructed in the country and thereby reduce loss of life and property caused by unsafe structures, but also eliminates the wastage caused by assuming unnecessarily heavy loadings without proper assessment. This standard was first published in 1957 for the guidance of civil engineers, designers and architects associated with the planning and design of buildings. It included the provisions for the basic design loads (dead loads, live loads, wind loads and seismic loads) to be assumed in the design of t he buildings. In its first revision in 1964, the wind pressure provisions were modified on the basis of studies of wind phenomenon and its effect on structures, undertaken by the special Committee in consultation with the Indian Meteorological Department. In addition to this, new clauses on wind loads for butterfly type structures were included; wind pressure coefficients for sheeted roofs, both covered and sloping were modified; seismic load provisions were deleted (separate code having been prepared) and metric system of weights and measurements was adopted. With the increased adoption of this standard, a number of comments were received on provision of live loads adopted for different occupancies. Subsequently the Committee recommended the formulation of this standard in the following five parts, during the second revision of IS 875 in 1987: Par t 1
Dead loads
Part 2
Imp Imposed loa load ds
Par t 3
Wind loads
Par t 4
Snow loads
Part Part 5
Speci Special al loa loads ds and and loa load d comb combina inatio tions ns
This standard (Part 3) deals with wind loads to be considered when designing buildings, structures and components thereof. In this current revision, the Committee recommends the following modifications/inclusions by taking into account the recent improvements that have been made in the wind engineering descriptive, descriptive, through R & D efforts nationally and internationally: a)
Aerodynamic Aerodynamic roughness roughness heights heights for individual individual terrain terrain categories categories have have been been explicitly explicitly included, included, and are used to derive turbulence intensity and mean hourly wind speed profiles.
b)
The previous previous classific classification ation of structures structures into into B and C classes classes has been been deleted deleted and accordingly accordingly the modification factor, k 2 is renamed as terrain roughness and height factor.
c)
The The va values of of k 2 factor corresponding to previous class A type structure only, are retained in this standard.
d)
An additional additional modificati modification on factor, factor, termed as importanc importancee factor has has been included included for cyclonic cyclonic regions. regions.
e)
Simple empirical empirical express expressions ions have have been suggest suggested ed for height height variations variations of of hourly mean mean wind speed speed and also turbulence intensity in different terrains. (Continued on Continued on third cover )
IS 875 (Part 3) : 2015
Indian Standard
DESIGN LOADS (OTHER THAN EARTHQUAKE) FOR BUILDINGS BUILDINGS AND STRUCTURE STRUCTURES S — CODE OF PRA PRACTIC CTICE E
( Third Revision ) 1 SCOPE
specific requirements as specified in the respective Codes shall be adopted in conjunction with the provisions of this Code as far as they are applicable. Some of the Indian Standards available for the design of special structures are:
1.1 This standard (Part 3) specifies wind forces and their effects (static and dynamic) that should be taken into account when designing buildings, structures and components thereof.
IS No. 4998 : 2015
vary randomly both in time and space 1.2 Wind speeds vary and hence assessment of wind loads and response predictions are very important in the design of several buildings and structures. A large majority of structures met with in practice do not however, suffer wind induced oscillations and generally do not require to be examined for the dynamic effects of wind. For such normal, short and heavy structures, estimation of loads using static wind analysis has proved to be satisfactory. The details of this method involving important wind characteristics such as the basic wind speeds, terrain categories, modification factors, wind pressure and force coefficients, etc, are given in 6 and 7.
6533 (Par (Partt 1) : 1989 1989 (Par (Partt 2) 2) : 198 1989 9 5613 (Part 2/ Sec 1) :1985
802 802 (Pa (Part rt 1/ Sec Sec 1) : 201* 201*
1.3 Nevertheless, there are various types of structures or their components such as some tall buildings, chimneys, latticed towers, cooling towers, transmission towers, towers, guyed masts, communication towers, long span bridges, partially or completely solid faced antenna dish, etc, which require investigation of wind induced oscillations. The influence of dynamic velocity fluctuations on the along wind loads (drag loads) for these structures shall be determined using Gust Factor Method, included in 10. 10. A method for calculation of across wind response of tall buildings and towers is included in 10.3. 10.3.
11504 : 1985
1473 14732 2 : 2000 2000
1.4 This standard also applies to buildings or other structures during erection/construction and the same shall be considered carefully during various stages of erection/construction. In locations where the strongest winds and icing may occur simultaneously, loads on structural members, cables and ropes shall be calculated by assuming an ice covering based on climatic and local experience.
Title Cr it it er er ia ia fo fo r de si sig n of re rei nf nf or or ce ce d concrete chimneys : Part 1 Assessment of loads ( third revision) (under print ) C o d e o f p r a c t i c e f o r d es i g n a n d construction of steel chimneys Mech Mechan anic ical al aspe aspect ctss Stru Struct ctur ural al asp aspec ects ts C o de de o f p r a ct ct i ce ce f o r d e si si g n, n, instal installat lation ion and maint maintena enance nce of overhead power power lines : Part 2 Lines above 11 kV, kV, and up to and including in cluding 220 kV, Section 1 Design Code Code of prac practi tice ce for for use use of stru struct ctur ural al stee steell in in over overhe head ad trans transmi miss ssio ion n lin linee towers: Part 1 Materials, Loads and permissible stresses, Section 1 Materials and Loads ( fourth revision revision) (under print ) Criter Criteria ia for for struc structur tural al desig design n of reinforced concrete natural draught cooling towers Guid Guidel elin ines es for the the eva evalu luat atio ion n of of the the response of occupants of fixed structures, especially buildings and off-shore structures, to lowfrequency horizontal motion (0.063 to 1 Hz)
NOTES 1 This standard does not apply to buildings or structures with unconventional shapes, unusual locations, and abnormal environmental conditions that have not been covered in this Code. Special investigations are necessary in such cases to establish wind loads and their effects. Wind tunnel studies may also be required in such situations. 2 In the case of tall structures with unsymmetrical geometry, the designs may have to be checked for tor sional effects effects due to wind pressure.
1. 5 In the design of special structures, such as chimneys, overhead transmission line towers, etc, 1
IS 875 (Part 3) : 2015 2 REFE REFERE RENC NCES ES
force normal normal to the the surfa surface; ce; F = force
The following standard contains provisions, which through reference in this text, constitute provisions of this standard. At the time of publication, the edition indicated was valid. All standards are subject to revision, and parties to agreements based on this standard are encouraged to investigate the possibility of applying the most recent edition of the standard indicated.
naturall frequency frequency of the building/ building/ f a = first mode natura structure in along wind direction in Hz;
IS No. 15498 : 2004
naturall frequency frequency of the building/ building/ f c = first mode natura structure in across wind direction in Hz; vortex shedding shedding frequenc frequency; y; f s = vortex normal al forc force; e; F n = norm transve verse rse force force;; F t = trans frictiona onall force force;; F' = fricti
Title G ui ui de de li li ne ne s f or or i mp mp ro ro vi vi ng ng t he he cyclonic resistance of low rise houses and other buildings/structures
gust fact factor or;; G = gust factorr for resonan resonantt respons response; e; gR = peak facto factor for upwind upwind veloc velocity ity fluctuati fluctuations; ons; gv = peak factor
3 NOTA NOTATI TION ONS S
height of structu structure re above above mean mean ground ground level; level; h = height
3.1 The following notations shall be followed unless otherwise specified in relevant clauses. Notations have been defined in the text at their first appearance. A few of the notations have more than one definition, having been used for denoting different variables:
height of develop development ment of of a velocity velocity profi profile le hx = height at a distance x down wind from a change in terrain category; height factor factor for for resonant resonant resp response onse;; H s = height height above above mean mean groun ground d level level on the the H = height topography feature;
surface area area of a struct structure ure or part of of a A = surface structure;
turbulen lence ce inten intensit sity; y; I = turbu
effectiv tivee fronta frontall area; area; Ae = effec
turbulencee intens intensity ity at heigh heightt h in terrain I h,i = turbulenc category i;
effective ive frontal frontal area area of the the building building at Az = the effect height z;
turbulence intensity intensity at height height z in terrain I z,i = turbulence category i;
breadth of a struc structure ture or or structur structural al member member b = breadth normal to the wind stream in the horizontal plane;
interfer ferenc encee facto factor; r; IF = inter shape power power expon exponent; ent; k = mode shape
backgroun ound d fact factor; or; Bs = backgr
wind speed speed modifi modifica catio tion n factor factors; s; k 1, k 2, = wind k 3, k 4
drag coeff coeffici icient ent;; C d = drag force coeff coeffici icient ent;; C fd' = force
k 2,i = hourly hourly mean mean wind wind spee speed d factor; factor;
normall force force coeffi coefficie cient; nt; C fn = norma
coefficient nt multiplic multiplication ation factor factor for K = force coefficie individual members of finite length;
transverse se force force coeff coefficie icient; nt; C ft = transver frictional al drag coeffici coefficient; ent; C f ' = friction
area averag averaging ing fac factor tor;; K a = area
pressure ure coef coeffic ficien ient; t; C p = press
combinati ation on factor factor;; K c = combin
external pressure pressure coeffici coefficient; ent; C pe = external
directionali nality ty factor; factor; K d = wind directio
internal pressure pressure coeffici coefficient; ent; C pi = internal
length of the membe memberr or larger larger horizon horizontal tal l = length dimensio dimension n of a building building;;
cross-wind nd force force spectrum spectrum coeffi coefficien cient; t; C fs = cross-wi Cf, z = drag force coefficient coefficient of the the building building corresponding to the area Az;
actual length length of upwind upwind slope; slope; L = actual effectivee length length of of upwind upwind slope slope;; Le = effectiv
coefficien ient, t, which which depen depends ds on s, used in the C = coeffic evaluation of k 3 factor;
integral turbulence turbulence length scale at the height height Lh = integral h;
depth of a structu structure re or struct structural ural membe memberr d = depth parallel to wind stream in the horizontal plane;
average mass mass per unit unit height height of the struct structure; ure; m0 = average design peak peak along along wind wind base base bending bending M a = design moment;
wake widt width; h; d w = wake
design peak peak across across wind wind base bendin bending g M c = design moment;
diameterr of cylin cylinder der or spher sphere; e; D = diamete wind ene energy rgy factor factor;; E = wind
effectivee reduce reduced d freque frequency; ncy; N = effectiv
Fz = along along wind load load on the buildi building/s ng/struc tructure ture at at any height z;
design wind wind pre press ssure ure;; pd = design 2
IS 875 (Part 3) : 2015
design wind wind press pressure ure at at height height z; pz = design
4 TE TERM RMIN INOL OLOG OGY Y
si g n h ou ou r l y m ea ea n w in in d p r es es s ur ur e pd = d e si corresponding to V z,d ;
For the purpose of this standard, the following definitions shall apply.
external al press pressure ure;; pe = extern
4.1 Angle Angle of Atta Attack ck — An angle between the direction of wind and a reference axis of the structure.
internal al press pressure ure;; pi = intern roughnesss factor factor which which is is twice twice the r = roughnes longitudinal turbulence intensity at height h;
4.2 4.2 Brea Breadt dth h — It means horizontal dimension of the building measured normal to the direction of wind.
Reynolds lds number number;; Re = Reyno el o n a b u i l d in in g / st st r uc uc t u re re f o r t h e s = l e v el evaluation of along wind load effects;
NOTE — Breadth and depth are dimensions measured in relation to the direction of wind, whereas length and width are dimensions related to the plan.
factor, which which depen depends ds on H and and X , used for s0 = factor, the evaluation of k 3 factor;
4.3 4.3 Depth — It means the horizontal dimension of the building measured in the direction of the wind.
strouh uhal al numb number er;; S t = stro
4.4 Devel Develop oped ed Height Height — It is the height of upward penetration of the velocity profile in a new terrain. At large fetch lengths, such penetration reaches the gradient height, above which the wind speed may be taken to be constant. At lesser fetch lengths, a velocity profile of a smaller height but similar to that of the fully developed profile of that terrain category has to be taken, with the additional provision that the v elocity at the top of this shorter shorter profile equal to that of the unpenetrated earlier velocity profile at that height.
size reduc reductio tion n factor factor;; S = size regional basic basic wind wind speed; speed; V b = regional design wind wind speed speed at height height z; V z = design design hourl hourly y mean mean wind wind speed speed;; V d = design V d,z = design design hourly hourly mean mean wind wind speed speed at height height z; V z,H = hourly hourly mean mean wind wind speed speed at height height z; lesser horizon horizontal tal dimens dimension ion of a building, building, w = lesser or a str struc uctu tura rall memb member er;;
4.5 Effectiv Effectivee Fronta Frontall Area Area — The projected area of the structure normal to the direction of wind.
width in multimulti-bay bay build building; ing; w' = bay width accelera leration tion at at the top of the build building/ ing/ ˆ = peak acce x structure in along wind direction, in m/s2;
4.6 Element Element of of Su Surfac rfacee Area Area — The area of surface over which the pressure coefficient is taken to be constant.
distance down down wind wind from a change change in terrain terrain x = distance category;
4 . 7 F o rc rc e C o ef ef f i ci ci e nt nt — A non-dimensional coefficient such that the total wind force on a body is the product of the force coefficient, the dynamic pressure of the incident design wind speed and the reference area over which the force is required.
distance from the the summit summit or crest crest of of X = distance topography feature relative to the effective length, Le; accelera leration tion at at the top of the build building/ ing/ ˆ = peak acce y structure in across wind direction;
NOTE — When the force is in the direction of the incident wind, the non-dimensional coefficient will be called as ‘drag coefficient’. coefficient’. When the force is perpendicular to the direction of incident wind, the non-dimensional coefficient will be cal led as ‘lift coefficient’.
height or dista distance nce above above the the ground; ground; z = a height aerodynamicc roughnes roughnesss height height for ith z0,i = aerodynami terrain; effectivee height height of the topograph topography y feature; feature; Z = effectiv
4.8 Ground Ground Roughne Roughness ss — The nature of the earth’s surface as influenced by small scale obstructio ns such as trees and buildings (as distinct from topography) is called ground roughness.
α = inclinat inclination ion of the roof to the the horizonta horizontal; l; β = d a m pi pi n g c o ef ef f i ci ci e nt nt o f t h e b u i ld ld i n g/ g/ structure;
4.9 Gus t — A positive or negative departure of wind speed from its mean value, lasting for not more than, say, 2 min over a specified interval of time.
η = shiel shieldin ding g factor factor;; φ = factor factor to account account for for the second second order order turbulence intensity;
4.10 4.10 Peak Peak Gu Gust st — A peak gust or peak gust speed is the wind speed associated with the maximum amplitude.
Φ = soli solidi dity ty rat ratio io;; Φe = effective effective solidit solidity y ratio; ratio; ε = average average height height of the the surface surface roughnes roughness; s;
4.11 4.11 Fetc Fetch h Leng Length th — It is the distance measured along the wind from a boundary at which a change in the type of terrain occurs. When the changes in terrain types are encountered (such as, the boundary of a town
θs = upwind upwind slope slope of the topograp topography hy feature feature in in the wind direction; and θ = wind angle angle from from a given given axis. axis. 3
IS 875 (Part 3) : 2015 or city, forest, etc), the wind profile changes in character but such changes are gradual and start at ground level, spreading or penetrating upwards with increasing fetch length.
4.21 Terrain Category — It means the characteristics of the surface irregularities of an area which arise from natural or constructed features. The categories are numbered in increasing order of roughness.
4.12 4.12 Gradie Gradient nt Height Height — It is the height above the mean ground level at which the gradient wind blows as a result of balance among pressure gradient force, coriolis force and centrifugal force. For the purpose of this Code, the gradient height is taken as the height above the mean ground level, above which the variation vari ation of wind speed with height need not be considered.
4.22 Topography — Topography — The nature of the earth’s surface as influenced by the hill and valley configurations. 4.23 Velocity Velocity Profile — Profile — The variation of the horizontal component of the atmospheric wind speed at different heights above the mean ground level is termed as velocity profile. 5 GENER ENERAL AL
4.13 High Rise Rise Building Building (Tall (Tall Building) Building) — A building with a height more than or equal to 50 m or having a height to smaller dimension more than 6.
5.1 Wind is air in motion relative to the surface of the earth. The primary cause of wind is traced to earth’s rotation and differences in terrestrial radiation. The radiation effects are primarily responsible for convection either upwards or downwards. The wind generally blows horizontal to the ground at high wind speeds. Since vertical components of atmospheric motion are relatively small, the term ‘wind’ denotes almost exclusively the horizontal wind; vertical winds are always identified as such. The wind speeds are assessed with the aid of anemometers or anemographs which are installed at meteorological observatories at heights generally varying from 10 to 30 m above ground.
4.14 4.14 Low Low Rise Rise Buildi Building ng — A building having its height less than 20 m. — The mean ground level 4.15 4.15 Mean Mean Groun Ground d Level Level — is the average horizontal plane of the area enclosed by the boundaries of the structure. 4.16 Pressur Pressuree Coeff Coefficien icientt — It is the ratio of the difference between the pressure acting at a point on the surface and the static pressure of the incident wind to the design wind pressure, where the static and design wind pressures are determined at the height of the point considered after taking into account the geographical location, terrain conditions and shielding effect. The pressure coefficient is also equal to [1–( V p / V Vz )2], where V p is the actual wind speed at any point on the structure at a height corresponding to that of V z.
5.2 5. 2 Very strong winds (more than 80 kmph) are generally associated with cyclonic storms, thunderstorms, dust storms or vigorous monsoons. A feature of the cyclonic storms over the Indian area is that they rapidly weaken after crossing the coasts and move as depressions/lows inland. The influence of a severe storm after striking the coast does not; in general exceed about 60 km, though sometimes, it may extend even up to 120 km. Very short duration hurricanes of very high wind speeds called Kal Baisaki or Norwester s occur fairly frequently during summer months over North East India.
NOTE — Positive sign of the pressure coefficient indicates pressure acting towards the surface and negative sign indicates pressure acting away from the surface.
4.17 4.17 Retur Return n Period Period — It is the number of years, reciprocal of which gives the probability of extreme wind exceeding a given wind speed in anyone year. 4.18 4.18 Shiel Shieldin ding g Effect Effect — — Shielding effect or shielding refers to the condition where wind has to pass along some structure(s) or structural element(s) located on the upstream wind side, before meeting the structure or structural element under consideration. A factor called ‘shielding factor’ is used to account for such effects in estimating the force on the shielded shiel ded structures.
5.3 The wind speeds recorded at any locality are extremely variable and in addition to steady wind at any time, there are effects of gusts which may last for a few seconds. These gusts cause increase in air pressure but their effect on stability of the building may not be so important; often, gusts affect only part of the building and the increased local pressures may be more than balanced by a momentary reduction in the pressure elsewhere. Because of the inertia of the building, short period gusts may not cause any appreciable increase in stress in main components of the building although the walls, roof sheeting and individual cladding units (glass panels) and their supporting members such as purlins, sheeting rails and glazing bars may be more seriously affected. Gusts can also be extremely important for design of structures with high slenderness
4.19 4.19 Suct Suctio ion n — It means pressure less than the atmospheric (static) pressure and is taken to act away from the surface. — It is equal to the effective area 4.20 Solidit Solidity y Ratio Ratio — (projected area of all the individual elements) of a frame normal to the wind direction divided by the area enclosed by the boundary of the frame normal to the wind direction. NOTE — Solidity ratio is to be calculated for individual frames.
4
IS 875 (Part 3) : 2015 ratios.
6.3 Design Design Wind Wind Speed Speed (V z)
5.4 The liability of a building to high wind pressures depends not only upon the geographical location and proximity of other obstructions ob structions to air flow but also upon the characteristics of the structure itself.
The basic wind speed ( V b) for any site shall be obtained from Fig. 1 and shall be modified to include the following effects to get design wind speed, V z at any height z, for the chosen structure:
5.5 The effect of wind on the structure as a whole is determined by the combined action of external and internal pressures acting upon it. In all cases, the calculated wind loads act normal to the surface to which they apply.
a)
Risk le level,
b)
Terrain errain rough roughnes nesss and height height of structu structure, re,
c)
Loca Locall topo topogr grap aph hy, and and
d)
Importan Importance ce fact factor or for for the cyclon cyclonic ic regio region. n.
It can be mathematically expressed as follows:
5.6 The stability calculations as a whole shall be done considering the combined effect, as well as separate effects of imposed loads and wind loads on vertical surfaces, roofs and other part of the building above general roof level.
V z = V b k 1 k 2 k 3 k 4
where V z
= design design wind speed speed at at height height z, in m/s;
k 1
= probability factor (risk coefficient) ( see 6.3.1); 6.3.1);
k 2
= terrain terrain roughnes roughnesss and height height factor factor (see 6.3.2); 6.3.2);
6 WIND WIND SPEE SPEED D
k 3
= topo topogra graph phy y fac factor tor (see 6.3.3); 6.3.3); and
6.1 Nature of Wind in in Atmospher Atmospheree
k 4
= importanc importancee factor factor for the the cyclonic cyclonic region region (see 6.3.4). 6.3.4).
5.7 Buildings shall also be designed with due attention to the effects of wind on the comfort of people inside and outside the buildings.
In general, wind speed in the atmospheric boundary layer increases with height from zero at ground level to maximum at a height called the gradient height. There is usually a slight change in direction (Ekman effect) but this is ignored in this standard. The variation with height depends primarily on the terrain conditions. However, the wind speed at any height never remains constant and it has been found convenient to resolve its instantaneous magnitude into an average or mean value and a fluctuating component around this average value. The average value depends on the average time employed in analyzing the meteorological data and this averaging time varies from few seconds to several minutes. The magnitude of fluctuating component of the wind speed which is called gust, depends on the averaging time. In general, smaller the averaging interval, more is the magnitude of the gust speed.
NOTE — Wind speed may be taken as constant up to a height of 10 m. However, pressures for buildings less than 10 m high may be reduced by 20 percent for evaluating stability and design of the framing.
6.3.1 Risk Coefficient (k 1 Factor) — Figure 1 gives basic wind speeds for terrain Category 2 as applicable at 10 m above ground level based on 50 years mean return period. The suggested life period to be assumed in design and the corresponding k 1 factors for different class of structures for the purpose of design are given in Table 1. In the design of buildings and str uctures, a regional basic wind speed having a mean return peri od of 50 years shall be used except as specified in the note of Table 1. 6.3.2 Terrain, Height Factor (k 2 Factor) 6.3.2.1 Terrain Selection of terrain categories shall be made with due regard to the effect of obstructions which constitute the ground surface roughness. The terrain category used in the design of a structure may vary depending on the direction of wind under consideration. Wherever Wherever sufficient meteorological information is available about the nature of wind direction, the orientation of any building or structure may be suitably planned.
6.2 BASIC BASIC WIND WIND SPEED SPEED Figure 1 gives basic wind speed map of India, as applicable to 10 m height above mean ground level for different zones of the country. Basic wind speed is based on peak gust velocity averaged over a short time interval of about 3 s and corresponds to mean heights above ground level in an open terrain (Category 2). Basic wind speeds presented in Fig. 1 have been worked out for a 50 year return period. Basic wind speed for some important cities/towns is also given in Annex A.
Terrain in which a specific structure stands shall be assessed as being one of the following terrain categories: a)
5
Category 1 — Exposed open terrain with few or no obstructions and in which the average
IS 875 (Part 3) : 2015
FIG. 1 B ASIC W IND S PEED
( BASED ON 50-YEARS R ETURN P ERIOD ) IN M / S (B
height of any object surrounding the structure is less than 1.5 m. The equivalent aerodynamic roughness height, ( z0,1) for this terrain is 0.002 m. Typically this category represents open sea-coasts and flat plains without trees.
b)
6
Category 2 — Open terrain with well scattered obstructions having heights generally between 1.5 m and 10 m. The equivalent aerodynamic roughness height, ( z 0,2 ) for this terrain is 0.02 0.02 m.
IS 875 (Part 3) : 2015
This is the criterion for measurement of regional basic wind speeds and represents airfields, open park lands and undeveloped sparsely built-up outskirts of towns and suburbs. Open land adjacent to sea coast may also be classified as Category 2 due to roughness of large sea waves at high winds. c)
buildings/structures up to 10 m in height with or without a few isolated tall structures. The equivalent aerodynamic roughness height, ( z z0,3) for this terrain is 0.2 m. This category represents well wooded areas, and shrubs, towns and industrial areas full or partially developed.
Category 3 — Terrain with numerous closely spaced obstructions having the size of
It is likely that the, next higher category than this will not exist in most design situations
Table 1 Risk Coefficients for Different Classes of Structures in Different Wind Speed Zones (Clause 6.3.1 ) Sl No.
Class of Structure
(1) i) ii)
iii)
iv)
k1 Factor
Mean Probable Design Life of Structure in Years
for Basic Wind Speed m/s
33
39
44
47
50
55
(2)
(3)
(4)
(5)
(6)
(7)
(8)
(9)
All general buildings and structures Temporary sheds, structures such as those used during construction operations (for example, formwork and false work), structures during during construction stages and boundary walls Buildings and structures presenting a low degree of hazard to life and property in the event of failure, such as isolated towers in wooded areas, farm buildings other than residential buildings Important buildings and structures such as hospitals communication buildings/towers, buildings/towers, power plant structures
50 5
1.0 0.82
1.0 0.76
1.0 0.73
1.0 0.71
1.0 0.70
1.0 0.67
25
0.94
0.92
0.91
0.90
0.90
0.89
100
1.05
1.06
1.07
1.07
1.08
1.08
NOTE — The factor k 1 is based on statistical concepts which take into account the degree of reliability required and period of time in years during which these will be exposed to wind, that is, life of the structure. Whatever wind speed is adopted for design purposes, there is always a probability (however (however small) that it may exceed in a storm of exceptional violence; more the period of years over which there is exposure to the wind, more is the probability. Larger return periods ranging from 100 to 1 000 years (implying lower risk level) in association with larger periods of exposure may have to be selected for exceptionally important structures, such as, nuclear power reactors and satellite communication towers. towers. Equation given below may be used in such cases to estimate k 1 factors for different different periods of exposure and chosen probability of exceedance (risk level). The probability level of 0.63 is normally considered sufficient for design of buildings and structures against wind effects and the values of k 1 corresponding corresponding to this risk level are given above.
k 1
=
X N ,P X 50,0.63
=
1 A − B ln − ln (1 − P N ) N A + 4B
where probable le design design life life of structu structure re in years years;; N = mean probab risk leve levell in in N consecutive consecutive years (probability that the design wind speed is exceeded at least once in N successive years), PN = risk nominal value = 0.63; extreme wind wind speed speed for for given given values values of N and and PN; and X N,P = extreme extreme me wind wind spee speed d for for N = = 50 years and PN = 0.63 X 50,0.63 = extre A and B have the following values for different basic wind speed zones:
Zone m/ s
A* m/ s
B* m/s
33
23.1 (8 3.2)
2.6 (9.2 )
39
23.3 (8 4.0)
3.9 (14.0)
44
24.4 (8 8.0)
5.0 (18.0)
47
24.4 (8 8.0)
5.7 (20.5)
50
24.7 (8 8.8)
6.3 (22.8)
55
25.2 (9 0.8)
7.6 (27.3)
* Values of A and B, in kmph, are given in bracket.
7
IS 875 (Part 3) : 2015 and that selection of a more severe category will be deliberate. d)
gradually to height ( hx) which increases with the fetch or upwind distance ( x).
Category 4 — Terrain with numerous large high closely spaced obstructions. The equivalent aerodynamic roughness height, ( z0,4) for this terrain is 2.0 m.
a)
This category represents large city centers, generally with obstructions above 25 m and well developed industrial complexes.
Fetch Fetch and and devel developed oped height height relation relationshi ship p — The relation between the developed height (hx) and the fetch ( x) for wind-flow over each of the four terrain categories may be taken as given in Table 3.
b) For structure structuress of of height heightss more more than the developed height ( hx) in Table 3, the velocity profile may be determined in accordance with the following:
6.3.2.2 Variation of wind speed with height in different terrains (k 2 factor) Table 2 gives multiplying multipl ying factors ( k 2) by which the basic wind speed given in Fig. 1 shall be multiplied to o btain the wind speed at different heights, in each terrain category.
1)
The less less or lea least st roug rough h terra terrain, in, or
2)
The meth method od des descri cribe bed d in Anne Annex x B.
Table 3 Fetch and Developed Height Relationship ( Clause 6.3.2.4 ) Sl No.
Table 2 Factors to Obtain Design Wind Speed Variation with Height in Different Terrains
Fetch ( x x) km
(1)
(2)
Terrain Category 1 (3)
i) ii) iii) iv) v) vi) vii) viii)
0.2 0.5 1 2 5 10 20 50
12 20 25 35 60 80 120 180
(Clause 6.3.2.2) Sl Height No. z
Terrain and Height Multiplier ( k2)
m
Terrain Category 1
(1)
(2)
(3)
(4)
(5)
(6)
i) ii) iii) iv) v) vi) vii) viii) ix) x) xi) xii) xiii) xiv)
10 15 20 30 50 100 150 200 250 300 350 400 450 500
1.05 1.09 1.12 1.15 1.20 1.26 1.30 1.32 1.34 1.35 1.35 1.35 1.35 1.35
1.00 1.05 1.07 1.12 1.17 1.24 1.28 1.30 1.32 1.34 1.35 1.35 1.35 1.35
0.91 0.97 1.01 1.06 1.12 1.20 1.24 1.27 1.29 1.31 1.32 1.34 1.35 1.35
0.80 0.80 0.80 0.97 1.10 1.20 1.24 1.27 1.28 1.30 1.31 1.32 1.33 1.34
Terrain Terrain Terrain Category 2 Category 3 Category 4
Developed Height, hx m Terrain Terrain Terrain Category 2 Category 3 Category 4 (4) (5) (6) 20 30 45 65 100 140 200 300
35 35 80 110 170 250 350 400
60 95 130 190 300 450 500 500
6.3.3 Topography (k 3 Factor) The basic wind speed V b given in Fig. 1 takes into account the general level of site above sea level. This does not allow for local topographic features such as hills, valleys, cliffs, escarpments, or ridges which can significantly affect wind speed in their vicinity. The effect of topography is to accelerate wind near the summits of hills or crests of cliffs, escarpments or ridges and decelerate the wind in valleys or near the foot of cliffs, steep escarpments, or ridges.
NOTE — For intermediate values of height z height z in in a given terrain category, use linear interpolation.
6.3.3.1 The 6.3.3.1 The effect of topography shall be significant a t a site when the upwind slope ( θ) is more than about 3°, and below that, the value of k 3 may be taken to be equal to 1.0. The value of k 3 is confined in the range of 1.0 to 1.36 for slopes more than 3°. A method of evaluating the value of k 3 for values more than 1.0 is given in Annex C. It may be noted that the value of k 3 varies with height above ground level, at a maximum near the ground, and reducing to 1.0 at higher levels.
6.3.2.3 Terrain categories in relation to the direction of wind The terrain category used in the design of a structure may vary depending on the direction of wind under consideration. Where sufficient meteorological information is available, the basic wind speed may be varied for specific wind direction. 6.3.2.4 Changes in terrain categories
R egion (k 4) 6.3.4 Importance Factor for Cyclonic Region
The velocity profile for a given terrain category does not develop to full height immediately with the commencement of that terrain category but develop
The east coast of India is relatively more vulnerable for occurrences of severe cyclones. On the west coast, Gujarat is vulnerable for severe cyclones. Studies of 8
IS 875 (Part 3) : 2015
wind speed and damage to buildings and structures point to the fact that the th e speeds given in the basic wind speed map are often exceeded during the cyclones. The effect of cyclonic storms is largely felt in a belt of approximately 60 km width at the coast. In order to ensure better safety of structures in this region (60 km wide on the east coast as well as on the Gujarat Coast), the following values of k 4 (as recommended in IS 15498) are stipulated as applicable according to the importance of the structure:
6.6 Off Shore Shore Wind Wind Velocit Velocity y
Cyclonic storms form far a way from the sea coast and gradually reduce in speed as they approach the sea coast. Cyclonic storms generally extend up to about 60 km inland after striking the coast. Their effect on land is already reflected in basic wind speeds specified in Fig. 1. The influ ence of wind speed off the coast up to a distance of about 200 km may be taken as 1.15 times the value on the nearest coast in the absence of any definite wind data. The factor 1.15 shall be used in addition to k 4.
k 4
Stru Struccture turess of pos post-cy t-cycl clon onee impo import rtaance nce for for 1.30 1.30 emergency services (such as cyclone shelters, hospitals, schools, communication towers, etc)
7 WIND PRESSURES PRESSURES AND FORCES ON BUILDINGS/STRUCTURES
Industrial structures
1.15
7.1 7.1 Gene Genera rall
All other structures
1.00
The wind load on a building shall be calculated for:
6.4 Hourly Hourly Mean Mean Wind Wind Spee Speed d
The hourly mean wind speed at height z, for different terrains can be obtained as V z,H
= k 2,iV b
a)
Buil Buildi ding ng as a whol whole, e,
b)
Individua Individuall structu structural ral elements elements as roofs and walls, and
c)
Individu Individual al claddin cladding g units units including including glazing glazing and their fixings.
where
7.2 Design Design Wind Wind Pressu Pressure re
hourly mean wind wind speed speed factor factor for terrai terrain n k 2,i = hourly category 1
The wind pressure at any height above mean ground level shall be obtained by the following relationship between wind pressure and wind speed:
z ln = 0.1423 ln ( z0,i )0.0706 z0,i
pz = 0.6 V z2
The design hourly mean wind speed at height z can be obtained as:
where pz
V z,d = V z,H k1k3 k4
design wind speed speed at at height height z, in m/s. V z = design The design wind pressure pd can be obtained as,
= V b k1 k 2,i k3 k4
pd
6.5 Turbul Turbulenc encee Intensi Intensity ty
directional onality ity factor, factor, K d = wind directi averaging ng facto factor, r, and K a = area averagi combinat ation ion factor factor (see 7.3.3.13). K c = combin
a) Terrain category 1
The value of pd, however shall not be taken as less than 0.70 pz.
z .3507 7 − 0.05 0.0535l 35lo og10 I z ,1 = 0.350 z0,1
c)
1 The coefficient 0.6 (in SI units) in the above formula depends on a number of factors and mainly on the atmospheric pressure and air temperature. The value chosen corresponds to the average Indian a tmospheric tmospheric conditions.
1
= I z,1 + ( I z,4 − I z,1 )
7 Terrain category 3
I z,3
d)
NOTES
Terrain category 2 I z,2
2 K d should be taken as 1.0 when considering local pressure coefficients.
3
= I z,1 + ( I z,4 − I z,1 )
7.2.1 Wind Directionality Factor, K d
z = 0.466 − 0.135 8 log10 z0,4
Considering the randomness in the directionality of wind and recognizing the fact that pressure or force coefficients are determined for specific wind directions, it is specified that for buildings, solid signs, open signs,
7 Terrain category 4
I z ,4
= K d K a K c pz
where
The turbulence intensity variations with height for different terrains can be obtained using the relations given below:
b)
= wind wind press pressure ure at at height height z, in N/m2; and
9
IS 875 (Part 3) : 2015 lattice frameworks, and trussed towers (triangular, square, rectangular) a factor of 0.90 may be used on the design wind pressure. For circular or near-circular forms this factor may be taken as 1.0.
Average values of pressure coefficients are given for critical wind directions in one or more quadrants. In order to determine the maximum wind load on the building, the total load should be calculated for each of the critical directions shown from all quadrants. Where considerable variation of pressure occurs over a surface, it has been sub-divided and mean pressure coefficients given for each of its several parts.
For the cyclone affected regions also the factor K d shall be taken as 1.0. 7.2.2 Area Averaging Averaging Factor, Factor, K a Pressure coefficients given in 7.3 7.3 are a result of averaging the measured pressure values over a given area. As the area becomes larger, the correlation of measured values decrease and vice-versa . The decrease in pressures due to larger areas may be taken into account as given in Table 4.
In addition, areas of high local suction (negative pressure concentration) frequently occurring near the edges of walls and roofs are separately shown. Coefficients for the local effects should only be used for calculation of forces on these local areas affecting roof sheeting, glass panels, and individual cladding units including their fixtures. They should not be used for calculating force on entire structural elements such as roof, walls or structure as a whole.
Table 4 Area Averaging Factor ( K K a) (Clause 7.2.2)
NOTES 1 The pressure coefficients given in different tables have been obtained mainly from measurements on models in wind tunnels, and the great majority of data available has been obtained in conditions of relatively smooth flow. Where sufficient field data exists as in the case of rectangular buildings, values have been obtained to allow for turbulent flow.
2 In recent years, wall glazing and cladding design has been a source of major concern. Although of less consequence than the collapse of main structures, damage to glass can be hazardous and cause considerable financial losses.
7.2.2.1 Tributary area a)
Overall structure — For evaluating loads on frames the tributary area shall be taken as the centre to centre distances between frames multiplied by the individual panel dimension in the other direction together with overall pressure coefficients.
3 For pressure coefficients for structures not covered here, reference may be made to specialist literature on the subject or advice may be sought from specialists in the subject.
7.3.1 Wind Load on Individual Members When calculating the wind load on individual structural elements such as roofs and walls, and individual cladding units and their fittings, it is essential to take account of the pressure difference between opposite faces of such elements or units. For clad structures, it is, therefore, necessary to know the internal pressure as well as the external pressure. Then the wind load, F , acting in a direction normal t o the individual structural element or cladding unit is:
b) Ind I nd i vi du al el em en ts — For beam type elements, purlins, etc, the tributary area shall be taken as effective span multiplied by spacing. The effective span is the actual span for mid span and cantilever load effects; and half the sum of adjacent spans for support moments and reactions. For plate type elements, the area of individual plates between supports is taken as the tributary area.
F = (C pe – C pi) A pd
For glass cladding, individual pane area of glass is the tributary area.
where
7.3 Pressur Pressuree Coefficien Coefficients ts
internall pressur pressuree coeffic coefficien ient, t, C pi = interna
The pressure coefficients are always given for a particular surface or part of the surface of a building. The wind load acting normal to a surface is obtained by multiplying the area of that surface or its appropriate portion by the pressure coefficient ( C p) and the design wind pressure at the height of the surface from the ground. The average values of these pressure coefficients coefficients for some building shapes are given in 7.3.2 and 7.3.3. 7.3.3.
A
= surface area of structural element or cladding unit, and
pd
= desi design gn wind wind pres pressu sure re.
externall pressure pressure coeff coeffici icient, ent, C pe = externa
NOTES 1 If the surface design pressure varies with height, the surface areas of the structural element may be sub-divided so that the specified pressures are taken over appropriate areas. 2 Positive wind load indicates the force acting towards the structural element and negative away from it.
10
IS 875 (Part 3) : 2015 7.3.2 Internal Pressure Coefficients
of clad buildings of rectangular plan shall be as given in Table 5. In addition, local pressure concentration coefficients are also given.
Internal air pressure in a building depends upon the degree of permeability of cladding to the flow of air. The internal air pressure may be positive or negative depending on the direction of flow of air in relation to openings in the buildings.
7.3.3.2 Pitched, hipped and mono slope roofs of clad buildings The average external pressure coefficients and pressure concentration coefficients for pitched roofs of rectangular clad building shall be as given in Table 6. Where no pressure concentration coefficients are given, the average coefficients shall apply. The pressure coefficients on the under-side of any overhanging roof shall be taken in accordance with 7.3.3.5. 7.3.3.5.
7.3.2.1 In the case of buildings where the claddings permit the flow of air with openings not more than about 5 percent of the wall area but where there are no large openings, it is necessary to consider the possibility of the internal pressure being po sitive or negative. Two Two design conditions shall be examined, one with an internal pressure coefficient of +0.2 and another with an internal pressure coefficient of –0.2.
For mono slope roofs of rectangular clad buildings, the average pressure coefficient and pressure concentration coefficient coefficient for mono slope (lean-to) roofs of rectangular clad buildings shall be as given in Table able 7.
The internal pressure coefficient is algebraically added to the external pressure coefficient and the analysis which indicates greater distress of the member shall be adopted. In most situations a simple inspection of the sign of external pressure will at once indicate the proper sign of the internal pressure coefficient to be taken for design.
NOTES 1 The pressure concentration shall be assumed to act outward (suction pressure) at the ridges, eaves, cornices and 90° corners of roofs. 2 The pressure concentration shall not be included with the net external pressure when computing overall load.
NOTE — The term normal permeability relates to the flow of air commonly afforded by claddings not only through open windows and doors, but also through the slits round the closed windows and doors and through chimneys, ventilators and through the joints between roof coverings, the total open area being less than 5 percent of area of the walls having the openings.
3 For hipped roofs, pressure coefficients (including local values) may be taken on all the four slopes, as appropriate from Table 6, and be reduced by 20 percent for the hip slope.
7.3.3.3 Canopy roofs with (1/4 < h /w < 1 and 1 < L / w < 3)
7.3.2.2 Buildings with medium and large openings
The pressure coefficients are given in Tables 8 and 9 separately for mono-pit mon o-pitch ch and double pitch canopy roofs such as open-air parking garages, shelter areas, outdoor areas, railway platforms, stadia and theatres. The coefficients take into account of the combined effect of the wind exerted on and under the roof for all wind directions; the resultant is to be taken normal to the canopy. Where the local coefficients overlap, the greater gr eater of the two given values should be taken. However, the effect of partial closures of one side and or both sides, such as those due to trains, buses and stored materials shall be foreseen and taken into account.
Buildings with medium and large openings may also exhibit either positive or negative internal pressure depending upon the direction of wind. Buildings with medium openings between about 5 and 20 percent of wall area shall be examined for an internal pressure coefficient of +0.5 and later with an internal pressure coefficient of –0.5, and the analysis which produces greater distress of the member shall be adopted. Buildings with large openings, that is, openings l arger than 20 percent of the wall area shall be examined once with an internal pressure coefficient of +0.7 and a gain with an internal pressure coefficient of –0.7, and the analysis which produces greater distress of the member shall be adopted.
The solidity ratio f is equal to the area of obstructions under the canopy divided by the gross area under the canopy, both areas normal to the wind direction. f = 0 represents a canopy with no obstructions underneath. f = 1 represents the canopy fully blocked with contents to the downwind eaves. Values of C p for intermediate solidities may be linearly interpolated between these two extremes, and apply upwind of the position of maximum blockage block age only. For downwind downwind of the position positio n of maximum blockage, the coefficients for f = f = 0 may be used.
Buildings with one open side or opening exceeding 20 percent of wall area may be assumed to be subjected to internal positive pressure or suction similar to those of buildings with large openings. A few examples of buildings with one side openings are shown in Fig. 2 indicating values of internal pr essure coefficients with respect to the direction of wind. 7.3.3 External Pressure Pressure Coefficients 7.3.3.1 Walls
In addition to the forces due to t he pressures normal to the canopy, there will be horizontal loads on the canopy
The average external pressure coefficient for the walls 11
IS 875 (Part 3) : 2015
FIG. 2 B UILDINGS W ITH ONE S IDE O PENINGS
12
IS 875 (Part 3) : 2015 Table 5 External Pressure Coefficients (Cpe) for Walls Walls of Rectangular Clad Buildings (Clause 7.3.3.1)
NOTE h is the height to eaves or parapet, l is the greater horizontal dimensions of a building and w is the lesser horizontal dimensions of a building.
13
IS 875 (Part 3) : 2015 Table 6 External Pressure Coefficients (Cpe) for Pitched Roofs of Rectangular Recta ngular Clad Buildings (Clause 7.3.3.2)
NOTE 1 h is the height to eaves or parapet and w is the lesser horizontal dimension of a building. 2 Where no local coefficients are given, the overall coefficient apply. 3 For hipped roofs the local coefficient for the hip ridge may be conservatively taken as the the appropriate ridge value. 4 w and l are dimensions between the walls excluding overhangs. overhangs.
14
IS 875 (Part 3) : 2015 Table 7 External Pressure Coefficients (Cpe) for Monoslope Roofs of Rectangular Clad Buildings
h w
<2
(Clause 7.3.3.2)
* Applied to length w/2 from wind-ward end.
** Applies to remainder
NOTE 1 h is the height of eaves at lower side, is the greater horizontal dimensions of a building and w is the lesser horizontal dimension of a building. 2 I and and w are overall length and width including overhangs.
15
IS 875 (Part 3) : 2015 due to the wind pressure on any fascia and to friction over the surface of the canopy. For any wind direction, only the greater of these two forces need to be taken into account. Fascia loads should be calculated on the area of the surface facing the wind, using a force coefficient of 1.3. Frictional drag should be calculated 7.4.1. using the coefficients given in 7.4.1.
provided that the clearance between the tank and the ground is not less than the diameter of the cylinder. h is height of a vertical cylinder or length of a horizontal cylinder. Where there is a free flow of air around both ends, h is to be taken as half the length when calculating calcula ting h/D ratio. In the calculation of resultant load on the periphery of the cylinder, the value of C pi shall be taken into account. For open ended cylinders, C pi shall be taken as follows:
NOTE — Tables 10 to 15 may be used to get internal and external pressure coefficients for pitches and troughed free roofs for some specific cases for which aspect ratios and roof slopes have been specified. However, while using Tables 10 to 15 any significant departure from it should be investigated carefully. No increase shall be made for local effects except as indicated.
a)
b)
– 0.5, where h / D is less than 0.3.
7.3.3.4 Pitched and saw-tooth roofs multi-span buildings
7.3.3.8 Roofs Roo fs and bottom bot tomss of cylindr cyl indr ical elevated eleva ted structures
For pitched and saw-tooth roofs of multi-span buildings, the external average pressure coefficients shall be as given in Tables 16 and 17 respectively provided that all the spans shall be equal and the height to the eaves shall not exceed the span.
The external pressure coefficients for roofs and bottoms of cylindrical elevated structures shall be as given in Table 20. Alternately, the pressure distribution given in Fig. 3 can be used together with the force coefficients given in Table 25 for the cylindrical portion.
Pressure coefficients on overhangs from roofs 7.3.3.5 Pressure
The pressure coefficients on the top over-hanging portion of the roofs shall be taken to be the same as that of the nearest top portion of the non-overhanging portion of the roofs. The pressure coefficients for the underside surface of the over-hanging portions shall be taken as follows and shall be taken as positive if the overhanging portion is on the windward side:
7.3.3.9 Combined roofs The average external pressure coefficients for combined roofs are shown in Table 21. 7.3.3.10 Roofs with skylight
a)
1.25, 1.25, if the the ove overhan rhangin ging g slopes slopes, downw downward ards; s;
The average external pressure coefficients for roofs with skylight are shown in Table 22.
b)
1.00, 1.00, if the overhan overhanging ging is hori horizon zontal tal;; and
7.3.3.11 Grandstands
c)
0.75, 0.75, if the overhan overhanging ging slopes slopes upwards upwards.
The pressure coefficients on the roof (top and bottom) and rear wall of a typical grandstand roof which is open on three sides are given in Table 23. The pressure coefficients are valid for a particular ratio of dimensions dimensi ons as specified in Table Table 21 but may be used for deviations up to 20 percent. In general, the maximum wind load occurs when the wind is blowing into the open front of the stand, causing positive pressure under the roof and negative pressure on the roof.
For overhanging portions on sides other than windward side, the average pressure coefficients on adjoining walls may be used. 7.3.3.6 Curved roofs For curved roofs the external pressure coefficients coefficients shall be as given in Table 18. Allowance for local effects shall be made in accordance with Table 6. Two Two values of C 2 have been given for elevated curved roofs. Both the load cases have to be analyzed, and critical load effects are to be considered in design.
7.3.3.12 Spheres The external pressure coefficients for spheres shall be as given in Table 24.
7.3.3.7 Cylindrical structures
7.3.3.13 Frames
For the purpose of calculating the wind pressure distribution around a cylindrical structure of circular cross-section, the value of external pressure coefficients given in Table 19 may be used, provided that the Reynolds number is more than 10 000. They ma y be used for wind blowing normal to the axis of cylinders having axis normal to the ground plane (that is, chimneys and silos) and cylinders having their axis parallel to the ground plane (that is, horizontal tanks),
When taking wind loads on frames of clad buildings it is reasonable to assume that the pressures or suctions inside and outside the structure shall not be fully correlated. Therefore when taking the combined effect of wind loads on the frame, a reduction factor of building envelope envelope when K c = 0.90 may be used over the building roof is subjected to pressure and internal pressure is suction, or vice-versa. 16
IS 875 (Part 3) : 2015 Table 8 Pressure Pressure Coefficients for Monoslope Free Roofs (Clause 7.3.3.3)
NOTES 1 For monopitch canopies the centre of pressure should be taken to act at 0.3 w from the windward edge. 2 W and L are overall width and length including overhangs,
17
IS 875 (Part 3) : 2015 Table 9 Pressure Coef ficients for Free Standing Double Sloped Roofs (Clause 7.3.3.3)
NOTES 1 Each slope of a duopitch canopy should be able to withstand forces using both the maximum and the minimum coefficients, coefficients, and the whole canopy should be able to support forces using one slope at the maximum coefficient with the other slope at the minimum coefficient. For duoptich canopies the centre of pressure should be taken to act at the centre of each slope. 2 W and L and L are are overall width and length including overhangs
18
IS 875 (Part 3) : 2015 Table 10 Pressure Coefficients (Top (Top and Bottom) for Pitched Roofs, Roof Slope α = 30° (Clause 7.3.3.3)
19
IS 875 (Part 3) : 2015 Table 11 Pressure Coefficients (Top (Top and Bottom) for Pitched Roofs, Roof α = 30° with effects of Train or Stored Material (Clause 7.3.3.3)
20
IS 875 (Part 3) : 2015 Table 12 Pressure Pressure Coefficients (Top and Bottom) for Pitched Roofs, α = 10° (Clause 7.3.3.3)
21
IS 875 (Part 3) : 2015 Table 13 Pressure Coefficients (Top (Top and Bottom) for Pitched Free Roofs, α = 10° with effects of Train or Stored Materials (Clause 7.3.3.3)
22
IS 875 (Part 3) : 2015 Table 14 Pressure Coefficients for Troughed Free Roofs, α = 10° (Clause 7.3.3.3)
23
IS 875 (Part 3) : 2015 Table 15 Pressure Coefficients (Top and Bottom) for Troughed Free Roofs, α = 10° with Effects of Train Train or Stored Materials (Clause 7.3.3.3)
24
IS 875 (Part 3) : 2015 Table 16 External Pressure Coefficients (Cpe) for Pitched Roofs of Multispan Buildings (All Spans Equal) with h < w' (Clause 7.3.3.4)
Frictional drag : When wind angle θ = 0°, horizontal forces due to frictional drag are allowed for in the above values, and When wind angle θ = 90°, allow for frictional drag in accordance with 7.4.1 NOTE — Evidence on these buidings is fragmentary and any departure from the cases given should be investigated separately.
25
IS 875 (Part 3) : 2015 Table 17 External Pressure Coefficients (C pe) for Saw Tooth Roofs of Multispan Buildings (All Spans Equal) with h < w’ (Clause 7.3.3.4)
Frictional drag : When wing angle θ = 0°, horizontal forces due to frictional drag are allowed for in the above values, and When wind angle θ = 90°, allow for frictional drag in accordance with 7.4.1. 7.4.1. NOTE — Evidence on these buidings is fragmentary and any departure from the cases given should be investigated separately.
26
IS 875 (Part 3) : 2015 Table 18 External Pressure Coefficients (C pe) for Curved Roofs (Clause 7.3.3.6)
NOTE — When the wind is blowing normal to gable ends, C pe may be taken as equal to –0.7 for the full width of the roof over a length of l /2 /2 fr om the ga ble en ds an d – 0.5 for th e r emaining portion.
27
IS 875 (Part 3) : 2015 Table 19 External Pressure Coefficients Around Cylindrical Structures (Clause 7.3.3.7)
28
IS 875 (Part 3) : 2015
F IG. 3 EXTERNAL PRESSURE C OEFFICIENTS ON THE U PPER R OOF S URFACE STANDING ON THE G ROUND
29
OF C YCLINDRICAL S TRUCTURES
IS 875 (Part 3) : 2015 Table 20 External Pressure Coefficients for Roofs and Bottoms of Cylindrical Structures (Clause 7.3.3.8)
30
IS 875 (Part 3) : 2015 Table 21 External Pressure Pressure Coefficients (Cpe) for Combined Roofs (Clause 7.3.3.9)
31
IS 875 (Part 3) : 2015 Table 22 External Pressure Coefficients (Cpe) for Roofs with a Sky Light (Clause 7.3.3.10)
NOTES
7.4 Force Coefficients
1 The value of the force coefficient differs for the wind acting on different faces of a building or structure. In order to determine the critical load, the total wind load should be calculated for each wind direction. 2 If surface design pressure varies with height, the surface area of the building/structure may be sub-divided so that specified pressures are taken over appropriate areas. 3 In tapered buildings/structures, the force coefficients shall be applied after sub-dividing the building/structure into suitable number of strips and the load on each strip calculated individually, taking the area of each strip as Ae.
The value of force coefficients ( C f ) apply to a building or structure as a whole, and when multiplied by the effective frontal area Ae of the building or structure and design wind pressure, pd gives the total wind load (F ) on that particular building or structure. F = C f Ae pd
where F is the force acting in a direction specified in the respective tables and C f is the force coefficient for the building.
4 For force coefficients for structures not covered above reference may be made specialist literature on the subject or advice may be sought from specialist in the subject.
32
IS 875 (Part 3) : 2015 Table 23 Pressure Pressure Coefficients at Top Top and Bottom Bott om Roof of Grand Stands Sta nds Open Three Three Sides (Roof Angle Upto Upto 5°) (Clause 7.3.3.11)
33
IS 875 (Part 3) : 2015 Table 24 External Pressure Distribution Coefficients Around Spherical Structures (Clause 7.3.3.12)
7.4.1 Frictional Drag
b)
In certain buildings of special shape, a force due to frictional drag shall be taken into account in addition to those loads specified in 7.3. 7.3. For rectangular clad buildings, this addition is necessary only where the ratio d/h or d / b is more than 4. The fr ictional drag force, F', in the direction of the wind is given by the following formulae:
If h > b, F' = C f ' ( (d – 4b) bpd + C f ' ( (d – 4b) 2h pd
The first term in each case gives the drag on the roof and the second on the walls. The value of C f ’ has the following value:
≤ b, F' = C f ' ( (d – 4h) bpd + C f ' ( (d – 4b) 2h pd , and 34
1)
C f ' = 0.01 for smooth surfaces without corrugations or ribs across the wind dir ection,
2)
C f ' = 0.02 for surfaces with corrugations across the wind direction, and
3)
C f ' = 0.04 for surfaces with ribs across the wind direction.
IS 875 (Part 3) : 2015 NOTE — Structures that are in the supercritical flow regime, because of their size and design wind velocity , may need further calculation to ensure that the greatest loads do not occur at some wind speed below the maximum when the flow will be sub critical. The coefficients are for buildings without projections, except where otherwise shown.
For other buildings, the frictional drag has been indicated, where necessary, in the tables of pressure coefficients and force coefficients. 7.4.2 Force Coefficients for Clad Buildings 7.4.2.1 Clad buildings of uniform section
In Table 25, V d b is used as an indication of the airflow regime.
The overall force coefficients for rectangular clad buildings of uniform section with flat roo fs in uniform flow shall be as given in Fig. 4 and for other clad buildings of uniform section (without projections, except where otherwise shown) shall be as given in Table 25.
FIG . 4 F ORCE COEFFICIENT
7.4.2.2 Buildings of circular shapes Force coefficients for buildings of circular cross-section shapes shall be as given in Table 25. However more precise estimation of force coefficients for circular shapes of infinite length can be obtained from Fig. 5
FOR RECTANGULAR C LAD B UILDING IN U NIFORM F LOW
35
IS 875 (Part 3) : 2015 Table 25 Force Coefficients C f for Clad Buildings of Uniform Section (Acting in the Direction of Wind) (Clause 7.4.2.2)
36
IS 875 (Part 3) : 2015 Table 25 — (Continued )
37
IS 875 (Part 3) : 2015 Table 25 — (Concluded )
7.4.3 Force Coefficients for Unclad Buildings
taking into account the average height of surface roughness ε . When the length is finite the values obtained from Fig. 5 shall be reduced by the multiplication factor K ( ( see Table 28 and Annex D).
7.4.3.1 7.4.3.1 This section applies to permanently unclad buildings and to frameworks of buildings while temporarily unclad. In the case of buildings whose surfaces are well-rounded, such as those with elliptic, circular or oval cross-sections, the total force can be more at a wind speed much less than maximum due to transition in the nature of boundary layer on them. Although this phenomenon is well known in the case of circular cylinders, the same phenomenon exists in the case of many other well-rounded structures, and this possibility must be checked.
7.4.2.3 Free standing walls and hoardings Force coefficients coefficients for free standing walls and hoardings shall be as given in Table Table 26. To allow for oblique winds, the design shall also be checked for net pressure normal to t he surface varying linearly from a maximum of 1.7 C f at the windward edge to 0.44 C f at the leeward edge.
7.4.3.2 Individual members
The wind load on appurtenances and supports for hoardings shall be accounted for separately by using the appropriate net pressure coefficients. Allowance shall be made for shielding effects of one element on another.
a) The force coefficient given in Table 29 refers to members of infinite length. For members of finite length, the coefficients should be multiplied by a factor that depends on the ratio l / / b where l is the length of K that the member and b is the width across the direction of wind. Table 28 gives the required values of K . The following special cases must be noted while estimating K .
7.4.2.4. 7.4.2.4. Solid circular shapes mounted on a surface The force coefficients for solid circular shapes mounted on a surface shall be as given in Table 27. 38
IS 875 (Part 3) : 2015
FIG . 5 V ARIATION
OF
C f 1
2
WITH R e >
3 × 10 4
FOR C IRCULAR S ECTIONS
D
Table 26 Force Coefficients for Low Walls or Hoardings (< 15m High) (Clause 7.4.2.2)
39
IS 875 (Part 3) : 2015 1)
2)
when when any any member member abuts abuts on to to a plat platee or wall wall in such a way that free flow of air around th at end of the member is prevented, then the ratio of l/b shall be doubled for the purpose of determining K ; and
b) Flat-sided members — Force coefficients for wind normal to the longitudinal axis of flat-sided structural members shall be as given in Table 29.
w h en en b ot ot h en en d s o f a m e mb mb e r a r e s o obstructed, the ratio shall be taken as infinity for the purpose of determining K .
Table 27 Force Coefficients for Solid Shapes Mounted on a Surface (Clause 7.4.2.4)
Table 28 Reduction Factor K for Individual Members [(Clauses 7.4.2.2, 7.4.3.2(a)] Sl No.
l/b or l/D
2
5
10
20
40
50
100
(1)
(2)
(3)
(4)
(5)
(6)
(7)
(8)
(9)
(10)
0.58
0.62
0.68
0.74
0.82
0.87
0.98
1.00
0.80
0.80
0.82
0.90
0.98
0.99
1.00
1.00
0.62
0.66
0.69
0.81
0.87
0.90
0.95
1.00
i) ii)
Circular cylinder, cylinder, subcritical flow Circular cylinder, supercritical flow ( D D 6m2 /s)
iii)
For plate perpendicular to wind (b 6m2 /s)
40
IS 875 (Part 3) : 2015
h t g n e L e t i n i f n I f o s r e b m e M l a r u t c ] ) b u r t ( 2 S . . l 3 a 4 . u 7 d i e v s i u d l a n I C r [ o f f C s t n e i c i f f e o C e c r o F 9 2 e l b a T
41
IS 875 (Part 3) : 2015 Normal force,
/ b F n = (C fn pd K) /
where
Transverse force,
F t = (C ft pd K) / b
coefficie icient nt for the supercrit supercritical ical circula circularr C f super = force coeff members as given in Table Table 31 or Annex D,
c) Circular sections — Force coefficients for members of circular section shall be as given in Table 25 see also Annex D. d) Force coefficie coefficients nts for wires and cables shall shall be as given in Table 30 according to the diameter ( D), the design wind speed ( V d) and the surface roughness.
C f sub
= force coefficient coefficient for subcritical subcritical circular members as given in Table Table 31or Annex D,
C f flat
= force coeffici coefficient ent for the flat flat sided sided members members as given in Table 31,
effectivee area of of subcritical subcritical circu circular lar Acirc sub = effectiv members,
7.4.3.3 Single frames Force coefficients for a single frame having either,
Aflat
= effectiv effectivee area area of flat-side flat-sided d members, members,
Asub
= Acirc sub + Aflat, and = (Area of of the frame in a supercritical supercritical flow)/ flow)/ Ae
a)
all all fla flatt sid sided ed membe members rs;; or or
γ
b)
all circ circula ularr member memberss in which which all all the the member memberss of the frame have either:
7.4.3.4 Multiple frame buildings
1) 2)
D V d less than 6 m2 /s, or
This section applies to structures having two or more parallel frames where the windward frames may have a shielding effect upon the fr ames to leeward side. The windward frame and any unshielded parts of other 7.4.3.3, frames shall be calculated in accordance with 7.4.3.3, but the wind load on the parts of frames that are sheltered should be multiplied by a shielding factor which is dependent upon the solidity ratio of the windward frame, the types of members comprising the frame and the spac-ing ratio of the frames. The values of the shielding factors are given in Table 32.
2
D V d more than or equal to 6 m /s,
shall be as given in Table 31 according to the type of the member, the diameter (D), the design hourly mean wind wind spee speed d ( V d ) and and the the soli solidit dity y rat ratio io (Φ). Force coefficients for a single frame not complying with the above requirements shall be calculated as follows: Cf Cf super (1 )
Acir sub Asub
A C fsub (1 ) flat C f flat Asub
Table 30 Force Coefficients for Wires and Cables (L/D = 100) [Clause 7.4.3.2(d)]
Table 31 Force Coefficients for Single Frames (Clause 7.4.3.3)
42
V d
V d
IS 875 (Part 3) : 2015 Table 32 Shielding Factor H for for Multiple Frames (Clause 7.4.3.4) Effective Solidity Ratio e
(1)
Frame Spacing Ratio
< 0.5
1.0
2.0
4.0
> 8.0
(2)
(3)
(4)
(5)
(6)
1.0 1.0 1.0 1.0 1.0 1.0 0.9 0.8 0.6
1.0 1.0 1.0 1.0 1.0 1.0 0.9 0.8
1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0
0 1.0 1.0 0.1 0.9 1.0 0.2 0.8 0.9 0.3 0.7 0.8 0.4 0.6 0.7 0.5 0.5 0.6 0.7 0.3 0.6 1.0 0.3 0.6 NOTE — Linear interpolation between the values is permitted.
Where there are more than two frames of similar geometry and spacing, the wind load on the third and subsequent frames should be taken as equal to that on the second frame. The loads on the various frames shall be added to obtain total load on the structure.
7.4.3.5 Lattice towers a)
a) The frame spacing ratio is equal to the centre to centre distance between the frames, beams or girders divided by the least overall dimension of the frames, beam or girder measured in a direction normal to the direction of wind. For triangular framed structures or rectangular framed structures diagonal to the wind, the spacing ratio should be calculated from the mean distance between the frames in the direction of the wind. b) Effective solidity ratio, for Φ e = Φ for Φ e
Force Force coeff coeffici icient ent for for lattic latticee towers towers of of square square or equilateral triangle section with flat-sided members for wind blowing against any face shall be as given in Table 33.
b) For squar squaree lattic latticee towers towers with with flatflat-sid sided ed members the maximum load, which occurs when the wind blows into a corner, shall be taken as 1.2 times the load for the wind blowing against a face.
Φ e:
c)
For equil equilatera aterall triangl trianglee lattic latticee towers towers with flatflatsided members, the load may be assumed to be constant for any inclination of wind to a face.
d)
Force Force coeff coeffici icient entss for lattic latticee towers towers of of square square section with circular members, all in the same flow regime, may be as given in Table 34.
e)
Force Force coeff coefficie icients nts for for lattic latticee towers towers of of equilateral-triangle section with circular members all in the same flow regime may be as given in Table 35.
flat-sided members.
is to be obtained from Fig. 6 for members of circular cross-sections.
7.4.3.6 Tower Tower appurtenances The wind loading on tower appurtenances, such as ladders, conduits, lights, elevators, etc, shall be calculated using appropriate net pressure coefficients Table 33 Overall Force Coefficients for Towers Composed of Flat Sided Members [Clause 7.4.3.5(a)] Sl No.
FIG . 6 EFFECTIVE S OLIDITY R ATIO , SECTION M EMBERS
FOR C IRCULAR
43
Solidity Ratio
Force Coefficient
Square Towers
Equilateral Triangular Towers
(1)
(2)
(3)
(4)
i) ii) iii) iv) v)
< 0.1 0.2 0.3 0.4 0.5
3.8 3.3 2.8 2.3 2.1
3.1 2.7 2.3 1.9 1.5
IS 875 (Part 3) : 2015 Table 34 Overall Force Coefficients for Square Towers Towers Composed of Circular Members [(Clause 7.4.3.5 (d)] Sl No.
Solidity Ratio of Front Face
Force Coefficient
Subcritical Flow ( D D < 6 m2 /s)
Supercritical Flow ( D D 6 m2 /s)
Onto Face
Onto Corner
Onto Face
Onto Corner
(1)
(2)
(3)
(4)
(5)
(6)
i) ii) iii) iv) v) vi)
< 0.05 0.1 0.2 0.3 0.4 0.5
2.4 2.2 1.9 1.7 1.6 1.4
2.5 2.3 2.1 1.9 1.9 1.9
1.1 1.2 1.3 1.4 1.4 1.4
1.2 1.3 1.6 1.6 1.6 1.6
for these elements. Allowance may be made for shielding effect from other elements.
Since the values of IF can vary considerably based on building geometry and location , the given values values of IF are a kind of median values and are meant only for preliminary design estimates. The designer is advised that for assigning values of IF for final design particularly for tall buildings, specialist literature be consulted or a wind tunnel study carried out.
8 INTERF INTERFERE ERENCE NCE EFFEC EFFECTS TS 8.1 8.1 Gene Genera rall Wind interference is caused by modification in the wind characteristics produced by the obstruction caused by an object or a structure in the path of the wind. If such wind strikes another structure, the wind pressures usually get enhanced, though there can also be some shielding effect between two very closely spaced buildings/structures. The actual phenomenon is too complex to justify generalization of the wind forces/ pressures produced due to interference which can on ly be ascertained by detailed wind tunnel/CFD studies. However, some guidance can be provided for the purpose of preliminary prelimi nary design. design . To To account for the effect of interference, a wind interference factor (IF) has been introduced as a multiplying factor to be applied to the design wind pressure/force. Interfer ence effects can be more significant for tall buildings. The interference factor is defined as the ratio between the enhanced pressure/force in the grouped configuration to the corresponding pressure/force in isolated configuration.
8.2 Roof Roof of Low-Rise Low-Rise Build Building ingss Maximum increase in wind force on the roof due to interference from similar buildings in case of closely spaced low-rise buildings with flat roofs may be up to 25 percent for c/c distance ( x x) between the buildings of 5 times the dimension (b) of the interfering building normal to the direction of wind ( see Fig. 7). Interference effect beyond 20b may be considered to be negligible. For intermediate spacing linear interpolation may be used. 8.3 Tall Buildings Based on studies on tall rectangular buildings, Fig. 8 gives various zones of interference. The interference factor (IF), which needs to be considered as a multiplication factor for wind loads corresponding to
Table 35 Overall Force Coefficients for Equilateral Triangular Towers Towers Composed of Circular Members [Clause 7.4.3.5(e)] Sl No.
Solidity Ratio of Front Face
Force Coefficient
Subcritical Flow ( D D < 6 m2 /s)
Supercritical Flow ( D D 6 m2 /s) All wind Directions (4)
(1)
(2)
All wind Directions (3)
i)
< 0.05
1.8
0.8
ii)
0.1
1.7
0.8
iii) iv)
0.2 0.3
1.6 1.5
1.1 1.1
v) vi)
0.4 0.5
1.5 1.4
1.1 1.2
44
IS 875 (Part 3) : 2015 isolated building, may be assumed as follows, for preliminary estimate of the wind loads under interference caused by another interfering tall building of same or more height located at different zones Z1 to Z4 as shown in Fig. 8:
Zone IF
Z1
Z2
Z3
Z4
1.35
1.25
1.15
1.07
In general, the following guidelines may be used for examining the problems of wind-induced oscillations. a)
Buildin Buildings gs and and closed closed structu structures res with a height height to minimum lateral dimension ratio of more than about 5.0, or
b)
Buildi Buildings ngs and and struc structur tures es whose whose natu natural ral frequency in the first mode is less than 1.0 Hz.
Any building or structure which satisfies either of the above two criteria shall be examined for dynamic effects of wind.
The interference effect due to buildings of height less than one-third of the height of the building under consideration may be considered to be negligible while for interference from a building of intermediate height, linear interpolation may be used between one-third and full height.
NOTES
9 DYNAMIC YNAMIC EFFECT EFFECTS S
1 The fundamental time period (T) may either be established by experimental experimental observations on similar buildings or calculated by any rational method of analysis. In the absence of such data, T may be determined as follows for multi-storied buildings:
9.1 9.1 Gene Genera rall
a) For moment resistant frames without bracings or shear walls resisting the lateral loads, T = = 0.1 n
Flexible slender structures and structural elements shall be investigated to ascertain the importance of wind induced oscillations or excitations in along wind and across wind directions.
FIG. 7 L OW-RISE B UILDINGS
where n = number of storeys including basement storeys; and b) for all others
IN TANDEM C AUSING I NTERFERENCE E FFECT
FIG . 8 INTERFERENCE Z ONES
FOR T ALL R ECTANGULAR B UILDINGS OF S AME OR G REATER H EIGHT (C LAUSE 7.3)
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IS 875 (Part 3) : 2015 T =
7 Buildings and structures that may be subjected to significant wind excited oscillations. It is to be noted that wind induced oscillations may occur at wind speeds lower than the design wind speed.
0.09 H d
where H = total height of the main structures of the building, in m; and
8 Analytical methods for the evaluation o f response of dynamic structures to wind loading can be found in the special publications.
d = maximum base dimension of building in meters in a direction parallel to the applied wind force.
9 In assessing wind loads due to such dynamic phenomenon as galloping, flutter and ovalli ng, in the absence of the required information either in the special publicat ions or other literature, expert advice should be sought including experiments on models in boundary layer wind tunnels.
2 If preliminary studies indicate that wind-induced oscillations are likely to be significant, investigations should be pursued with the aid of analytical methods or if necessary, by means of wind tunnel tests on models. 3 Across-wind motions may be due to lateral gustiness of the wind. unsteady wake flow (for example, vortex shedding), negative aerodynamic damping or due to a combination of these effects. These cross-wind motions may become critical in the design of tall buildings/structures.
9.2 Motion Motion due to to Vortex Vortex Shedding Shedding 9.2.1 Slender Structures
4 Motions in the direction of wind (known also as buffeting) are caused by fluctuating wind force associated with gust. The excitation depends on gust energy available at the resonant frequency.
For a structure, the vortex shedding frequency f s shall be determined by the following formula:
5 The eddies shed from an upstream body may intensify motion in the direction of the wind and may also affect cross-wind motion.
f s
=
St V z,H b
6 The designer should also be aware of the following three forms of wind-induced motion which are characterized by increasing amplitude of oscillation with the increase of wind speed.
where
i) Gallopin Galloping g — Galloping Galloping is transverse transverse oscillation oscillationss of some structures due to the development of aerodynamic forces which are in phase with the motion. It is characterized by the progressively increasing amplitude of transverse vibration with increase of wind speed. The cross-sections cross-sections which are particularly prone to this type of excitation include the following: following:
V z,H = hourly hourly mean mean wind wind speed speed at height height z, and
S t
= breadth breadth of a structu structure re or structur structural al member member normal to the wind direction in the horizontal plane
b
a)
1) All structures structures with non-circular cross-sections, cross-sections, such as triangular, square, polygons, as well as angl es, crosses, and T sections.
S t
2) Twisted cables and cables with ice encrustations.
= Stro Strouh uhal al numb number er,
Circular structures — For structures of circular in cross-section:
= 0.20 fo fo r D V z,H less than 6 m2 /s, and = 0.25 for D V z,H more than or equal to 6 m2 /s.
ii) Flutter — Flutter Flutter is unstable oscillator oscillatory y motion of a structure due to coupling between aerodynamic force and elastic deformation of the structure. Perhaps the most common form is oscillatory motion due to combined bending and torsion. Although oscillatory motion in each degree of freedom may be damped, instability can set in due to energy transfer from one mode of oscillation to another and the structure is seen to execute sustained or divergent oscillations with a type of motion which is a combination of the individual modes of vibration. Such energy transfer takes place when the natural frequencies of modes taken individually are close to each other (ratio being typically less than 2.0). Flutter can set in at wind speeds much less than those required for exciting the individual modes of motion. Long span suspension bridge decks or any member of a structure with large values of d/t (where d is the length of the member and t is its dimension parallel to wind stream) are prone to low speed flutter. Wind tunnel testing is required to determine critical flutter speeds and the likely structural response. Other types of flutter are single degree of freedom stall flutter, torsional flutter, etc.
1 Significant cross wind motions may be produced by vortex shedding if the natural frequency of the structure or structural element is equal to the frequency of the vortex shedding within the range of expected wind speeds. In such cases, further analysis should be carried out on the basis of special publications.
iii) Ovalling — Thin walled structures with open ends at one or both ends such as oil storage tanks and natural draught cooling towers in which the ratio of the diameter or minimum lateral dimension to the wall thickness is of the order of 100 or more are prone to ovalling oscillations. These oscillations are characterized by periodic radial deformation of the hollow structure.
4 The formulae given in 8.2.1 (a) is valid for infinitely long cylindrical structures. The value of S t decreases slowly as the ratio of length to maximum transverse width decreases, the reduction being up to about half the value, if the structure is only three times higher than its width. Vortex shedding need not be considered if the ratio of length to maximum transverse dimension is less than 2.0.
b) Rectangular structures — For structures of rectangular cross-section: S t = 0.10 NOTES
2 Unlined welded steel chimney stacks and similar structures structures are prone to excitations by vortex shedding. 3 Intensification of the effects of periodic vortex shedding has been reported in cases where two or more similar structures are located in close proximity, for example at less than 20b apart, where b is the dimension of the structure normal to the wind.
46
IS 875 (Part 3) : 2015 10 DYNAMI DYNAMIC C WIND WIND RESPON RESPONSE SE
V z,d = design design hourly hourly mean mean wind speed speed at at height height z, in m/s (see 6.4 )
10.1 10.1 Gene Genera rall
drag force coeffi coefficien cientt of the building building/ / C f,z = the drag structure corresponding to the area Az
Tall buildings which are ‘wind sensitive’ shall be designed for dynamic wind loads. Hourly mean wind speed is used as a reference wind speed to be used in dynamic wind analysis. For calculation of along wind loads and response (bending moments, shear forces, or tip deflections) the Gust Factor (GF) method is used as specified in 10.2 . The across wind design peak base overturning moment and tip deflection shall be calculated using 10.3 .
G
= 1+ r
2 2 H s gR SE 2 gv Bs (1 + g ) + β
where r
= roughness roughness factor factor which is is twice twice the longitudinal turbulence intensity, I h, i (see 6.5),
gv
= peak factor factor for upwind upwind veloci velocity ty fluctuat fluctuation ion,
10.2 Along Along Wind Wind Respons Responsee
For calculation of along-wind load effects at a level s on a building/structure, the design hourly mean wind pressure at height z shall be multiplied by the Gust Factor (GF). This factor is dependent on both the overall height h and the level s under consideration (see Fig. 9). For calculation of base bending moment and deflection at the top of the building/structure s should be taken as zero.
= 3.0 for for categor category y 1 and 2 terrain terrains, s, and and = 4.0 for for catego category ry 3 and and 4 terrai terrains, ns, Bs
The design peak along wind base bending moment, ( M a) shall be obtained by summing the moments resulting from design peak along wind loads acting at different heights, z, along the height of the building/ structure and can be obtained from, M a =
= Gust Gust Factor Factor and is given given by. by.
= background background factor factor indicat indicating ing the the measure measure of slowly varying component of fluctuating wind load caused by the lower frequency wind speed variations =
1
1 +
0.26 ( h − s ) Lh
2
+ 0.46bsh2
where
∑ F z Z
F z = C f,z Az pd G
breadth of the building/stru building/structure cture bsh = average breadth between heights s and h
where
Lh
design peak peak along along wind load load on the buildi building/ ng/ F z = design structure at any height z
= measure measure of effective effective turbulence turbulence length length scale scale at the height, h, in m 0.25
h for terrain category 1 to 3 10 0.25 h = 70 for terrain category 4 10 = 85
Az = the effecti effective ve frontal frontal area area of the the building/ building/ structure at any height z, in m2 design hourly hourly mean mean wind wind press pressure ure pd = design corresponding to V z,d and obtained as
φ
2 0.6 V z,d (N/m2)
= factor factor to accoun accountt for the seco second nd order order turbulence intensity
Level at which action effects are calculated h
s z
NOTE — 0 < s < h, and s < z < h
FIG . 9 N OTATIONS FOR HEIGHTS 47
IS 875 (Part 3) : 2015
=
10.2.1 Peak Acceleration in Along Wind Direction
gv I h ,i Bs
The peak acceleration at the top of the building/ ˆ in m/s2) is given structure in along wind direction ( x by the following equation:
2
turbulencee intens intensity ity at at height height h in terrain I h,i = turbulenc category i height factor factor for reson resonance ance respons responsee H s = height
s = 1+ h S
SE 2 ˆ = ( 2π fa ) x gR r x
β
2
where
=
1
3.5 fa h 4 fa b0 h 1 + V 1 + V h ,d h, d
For computing the peak acceleration in the along wind direction, a mean wind speed at the height of the building/structure, V h corresponding to a 5 year mean return period shall be used. A reduced value of 0.011 is also suggested for the structural damping, β for reinforced concrete structures.
where the building/s building/structur tructuree b0h = average breadth of the between 0 and h. E
= spectru spectrum m of turbulenc turbulencee in the approac approaching hing wind stream =
10.3 Across Across Wind Wind Respon Response se
This section gives method for determining equivalent static wind load and base overturning moment in the across wind direction for tall enclosed buildings and towers of rectangular cross-section. Calculation of across wind response is not required for lattice towers.
π N
(1 + 70.8 N ) 2
5
6
where
The across wind design peak base bending moment M c for enclosed buildings and towers shall be determined as follows:
effective reduced reduced frequenc frequency y N = effective = f a
= mean deflec deflection tion at at the positio position n where where the acceleration is required. Other notations are same as given in 10.2.
x
= size size reducti reduction on facto factorr given given by: by:
f a Lh V h,d
M c
= f i r s t m o d e n a t u r al al f r e qu qu e n c y o f t h e building/structure in along wind direction, in Hz
where
V h,d = design design hourly hourly mean mean wind speed speed at heigh height, t, h
gh
= a pea peak k fac facto tor, r,
in m/s (see 6.4 )
β
=
= damping damping coeffici coefficient ent of the building building/st /struct ructure ure (see Table 36)
Pa;
2 ln ln ( 3 60 6 00 f a )
Table 36 Suggested Values of Structural Damping Coefficients Coefficients
b
= the breadt breadth h of the struc structure ture norma normall to the wind, in m;
h
= the heigh heightt of the the struct structure, ure, in in m;
k
= a m o d e sh sh a p e p o w er er e x p on on e nt nt f o r representation of the fundamental mode shape as represented by:
(Clause 10.2) Sl No.
Kind of Structure
(1)
(2)
Damping Coefficient,
z ψ( z z)= h
β
(3)
i)
Welded steel structures
0.010
ii)
Bolted steel steel structures
0.020
iii)
Prestressed concrete structures
structures/RCC structures/RCC
2 ln ln ( 36 00 f c ) in cross wind direction;
hourly mean wind wind pressu pressure re at height height h, in in ph = hourly
factor for resonant resonant res respons ponsee gR = peak factor =
πC = 0.5gh ph bh 2 (1.06 − 0.06 k ) fs β
f c
k
= first mode natura naturall frequency frequency of the building/ building/ structure in across across wind wind direction, direction, in Hz.
The across wind load distribution on the building/ structure can be obtained from M c using linear
0.016
48
IS 875 (Part 3) : 2015
distribution of loads as given below: F z,c =
= 0.5 k = c)
3 Mc z h2 h
d) lattice lattice tower tower decrea decreasin sing g in stiff stiffnes nesss with with height, or a tower with a large mass at the top, k = = 2.3
where F z,c = across wind load per unit height at height z. 10.3.1 Peak Acceleration in Across Wind Direction
C fs = across wind force spectrum coefficient generalized for a linear mode. ( see Fig. 10 and Fig. 11).
The peak acceleration at the top of the building/ structure in across-wind direction ( y ˆ in m/s2) with approximately constant mass per unit height shall be determined as follows: g pb ˆ = 1.5 h h ( 0.76 + 0.24k ) y m0
πCfs β
β
10.4 Combinatio Combination n of Along Wind Wind and Across Across Wind Wind Load Effects
Typical values of the mode shape power exponent, k are as follows: unif unifor orm m cant cantil ilev ever er, k = = 1.5
b)
slender slender framed framed struc structure ture (moment (moment resi resistin sting), g),
= damping damping coeffici coefficient ent of the building/ building/stru structur cturee (see Table 36).
average mass mass per unit height height of the m0 = the average structure in, kg/m.
a)
buildi building ng with with a centr central al core core and moment moment resisting façade, k = = 1.0
The along wind and across wind loads have to be applied simultaneously on the building/structure during design.
Legend: — Turbulence Intensity of 0.12 at 2/ 3 h
FIG . 10 V ALUES OF
- - Turbulence Intensity of 0.20 at 2/3 h
THE C ROSS W IND F ORCE S PECTRUM C OEFFICIENT FOR S QUARE S ECTION BUILDINGS
49
IS 875 (Part 3) : 2015
FIG . 11 V ALUES
OF THE C ROSS WIND F ORCE S PECTRUM C OEFFICIENT FOR 2:1 AND
1 : 2 RECTANGULAR S ECTION B UILDINGS
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IS 875 (Part 3) : 2015
ANNEX A
(Clause 6.2) BASIC WIND SPEED AT 10 m HEIGHT FOR SOME IMPORTANT CITIES / TOWNS City/Town
Basic wind Speed m/s
City/Town
Basic wind Speed m/s
Ag r a
47
Kanpur
47
Ahmedabad
39
Kohima
44
Ajmer
47
Kolkata
50
A l mo r a
47
Kozhikode
39
Amritsar
47
Kurnool
39
Asansol
47
Lakshadweep
39
Aurangabad
39
Lucknow
47
Bahraich
47
Ludhiana
47
Bengaluru
33
Madurai
39
Barauni
47
Mandi
39
Bareilly
47
Mangalore
39
Bhatinda
47
Moradabad
47
Bhilai
39
M u mb ai
44
Bhopal
39
Mysore
33
Bhubaneshwar
50
Nagpur
44
Bhuj
50
Nainital
47
Bikaner
47
Nasik
39
Bokaro
47
Nellore
50
Chandigarh
47
Panjim
39
Chennai
50
Patiala
47
Coimbatore
39
Patna
47
Cuttack
50
Puducherry
50
Darbhanga
55
Port Blair
44
Darjeeling
47
Pune
39
Dehradun
47
Raipur
39
Delhi
47
Rajkot
39
Durgapur
47
Ranchi
39
Gangtok
47
Roorkee
39
Guwahati
50
Rourkela
39
Gaya
39
Shimla
39
Gorakhpur
47
Srinagar
39
Hyderabad
44
S u r at
44
Imphal
47
Tiruchirappalli
47
Jabalpur
47
Trivandrum
39
Jaipur
47
Udaipur
47
Jamshedpur
47
Vadodara
44
Jhansi
47
Var anasi
47
Jodhpur
47
Vijayawada
50
Vishakapatnam
50
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IS 875 (Part 3) : 2015
ANNEX B
[Clause 6.3.2.4 (b)(ii)] CHANGES IN TERRAIN CATEGORIES B-1 LO LOW W TO HIGH HIGH TERRAIN TERRAIN CATEGO CATEGORY RY NUMBER
follows:
In cases of transition from a low terrain category number (corresponding to a low terrain roughness) to a higher terrain category number (corresponding to a rougher terrain), the velocity profile over the rougher terrain shall be determined as follows: a)
B el el ow ow h ei ei gh gh t h x, the velocities shall be determined in relation to the rougher terrain; and
b)
A bo bo ve ve h ei ei gh gh t h x, the velocities shall be determined in relation to the less rough (more distant) terrain.
a)
A b o ve h ei ei g ht ht hx , the velocities shall be determined in accordance with the rougher (more distant) terrain; and
b)
Below he height hx, the velocity shall be taken as the lesser of the following: 1)
that determi determined ned in acco accordan rdance ce with the less rough terrain, and
2)
the the vel veloc ocit ity y at heig height ht hx as determined in relation to the rougher terrain NOTE — Examples of determination of velocity profiles in the vicinity of a change in terrain category are shown in Figs.12a and 12b.
B-3 MORE THAN ONE ONE CATEGOR CATEGORY Y B-2 HIGH TO TO LOW TERRAIN TERRAIN CATEGOR CATEGORY Y NUMBER
Terrain changes involving more than one category shall B-2. be treated in similar way to that described in B-1 and B-2.
In cases of transition from a more rough to a less rough terrain, the velocity profile shall be determined as
FIG. 12 V ELOCITY P ROFILES
NOTE — Examples involving three terrain categories are shown in Fig. 12c.
IN THE VICINITY OF A C HANGE IN T ERRAIN C ATEGORY
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IS 875 (Part 3) : 2015
FIG. 12 V ELOCITY P ROFILES
IN THE VICINITY OF A C HANGE IN T ERRAIN C ATEGORY
53
IS 875 (Part 3) : 2015
ANNEX C
(Clause 6.3.3.1) EFFECT OF A CLIFF OR ESCARPMENT ON EQUIVALENT HEIGHT ABOVE GROUND ( k3 FACTOR) the local topography to the site is significant in terms of wind flow. In such cases, the average value of the terrain upwind of the site for a distance of 5 km should be taken as the base level from wind to assess the height, Z, and the upwind slope θ, of the feature.
C-1 The influence of the topographic feature is considered to extend 1.5 L e upwind and 2.5 L e downwind of the summit of crest of the feature where Le is the effective horizontal length of the hill de pending on slope as indicated below (see Fig. 13). Sl Slope
Le
3° < θs ≤ 17°
L
θs > 17°
C-2 TOPOGRA TOPOGRAPHY PHY FA FACTOR, CTOR, k3 The topography factor k 3 is given by the following: k 3
Z / 0. 3
where C has the following values:
where L
Slope
= actual actual length length of the the upwind upwind slope slope in the the wind wind direction,
Z
= effectiv effectivee height height of the the topograph topography y feature, feature, and
θs
= upwind upwind slope slope in the wind direc directio tion. n.
= 1 + C s0
3° < θs ≤ 17 17°
θs > 17°
C
1.2 ( Z / L) 0.36
and s0 is a factor derived in accordance with C-2.1 appropriate to the height, H above above mean ground level and the distance, x, from the summit or crest relative to the effective length, Le
In case, the zone in downwind side of the crest of the feature is relatively flat ( θ s < 3°) for a distance exceeding Le, then the feature should be treated as an escarpment. Otherwise the feature should be treated as a hill or ridge. Examples of typical features are given in Fig. 13.
C-2.1 The factor, s0 should be determined from: a)
Fig. 14 for cliffs cliffs and escarpm escarpment ents, s, and
b)
Fig. Fig. 15 15 for for ridg ridges es and and hills hills.
NOTE – Where the downwind slope of a hill or ridge is more than 3°, there will be large regions of reduced accelerations or even shelter and it is not possible to give general design rules to cater for these circumstances. Values of s 0 from Fig. 15 may be used as upper bound values.
NOTES 1 No difference is made, in evaluating k 3 between a three dimensional hill and two dimensional ridge. 2 In undulating terrain, it is often not possible to decide whether
54
IS 875 (Part 3) : 2015
FIG . 13 TOPOGRAPHICAL D IMENSIONS
FIG. 14 F ACTOR
FIG . 15 FACTOR
S FOR R IDGE AND H ILL
S FOR C LIFF AND E SCARPMENT
55
IS 875 (Part 3) : 2015
ANNEX D
(Clauses 7.4.2.2, 7.4.3.2 and 7.4.3.3) 7.4.3.3) WIND FORCE ON CIRCULAR SECTIONS D-1 The wind force on any object is given by:
= C f Ae pd F = where force coeffi coeffici cient ent, C f = force effective area area of the the object object normal normal to the the Ae = effective wind direction, and pd
= design design pres pressure sure of the the wind. wind.
For most shapes, the force coefficient remains approximately constant over the whole range of wind speeds likely to be encountered. However, for objects of circular cross-section, it varies considerably.
F IG . 16 W AKE
For a circular section, the force coefficient depends on the way in which the wind flows around it and is dependent upon the velocity and kinematic viscosity of the wind and diameter of the section. The force coefficient is usually quoted against a non-dimensional parameter, called the Reynolds number, which takes into account of the velocity and viscosity of the flowing medium (in this case the wind), and the member diameter.
F IG. 17 W AKE
Reynolds number, Re = DV d / v
= diame diamete terr of the the memb member er
The variation of C f with parameter D V d is shown in Fig. 5 for infinitely long circular cylinders having various values of relative surface r oughness (ε / D) when subjected to wind having an intensity and scale of turbulence typical of built-up urban areas. The curve for a smooth cylinder ( ε /D) = 1 × 10 –5 in a steady air stream, as found in a low-turbulence wind tunnel, is also shown for comparison.
design hourl hourly y mean mean wind wind speed speed V d = design
ν
IN SUPER C RITICAL F LOW
a critical value of Reynolds number followed by a gradual rise as Reynolds number is increased still further.
where D
IN S UB C RITICAL F LOW
= kinemati kinematicc viscosi viscosity ty of the air air which is is 1.46 –5 2 × 10 m /s at 15 °C an d st a nd ar d atmospheric pressure.
Since in most natural environments likely to be found in India, the kinematic viscosity of the air is fairly constant, it is convenient to use D V d as the parameter instead of Reynolds number and this has been done in this code.
It can be seen that the main effect of free-stream turbulence is to decrease the critical value of the parameter D V d . For subcritical flows, turbulence can produce a considerable reduction in C f below the steady air-stream values. For supercritical flows, this effect becomes significantly smaller.
The dependence of a circular section’s force coefficient coefficient on Reynolds number is due to the change in the wake developed behind the body. At a low Reynolds number, the wake is as shown in Fig. 16 and the force coefficient is typically 1.2. As Reynolds number is increased, the wake gradually changes to that shown in Fig. Fi g. 17; that is, the wake width dw decreases and the separation point denoted as sp, moves from front to the back of the body.
If the surface of the cylinder is deliberately roughened such as by incorporating flutes, riveted construction, etc, then the data given in Fig. 5 for appropriate value of ε / D > 0 shall be used. NOTE — In case of uncertainty regarding the value of ε to be used for small roughness, ε / D shall be taken as 0.001.
As a result, the force coefficient shows a rapid drop at
56
IS 875 (Part 3) : 2015
ANNEX E
(Foreword ) COMMITTEE COMPOSITION (Excluding Water Resources Development Division) Sectional Committee, CED 37 Org anization
Re presentative(s)
In personal capacity (80, ( 80, SRP Colony, Peravallur, Chennai 600 082) 082 )
DR N. LAKSHMANAN (Chairman )
Atomic Energ y Regulator y Boar d, Mumbai
SHRI L. R. BISHNOI SHRI A. D. ROSHAN ( Alternate) Alternate )
Bhar at Heavy Electricals Limited, New Delhi
SHRI S. S. M ANI
Central Bu ilding Resear ch Institute (CSIR), Ro or kee
DR A. K. P ANDEY DR RAJESH DEOLIYA ( Alternate) Alternate)
Central Electr icity A uthority, New Delhi
SHRI R. B. WALIMBE SHRI S. K. ROY CHOWDHURY ( Alternate) Alternate)
Cen tral Pub lic Wor ks Dep artment, New Delhi
SHRI A. K. GARG SHRI RAJESH KHARE ( Alternate) Alternate)
Central Water Commission, New Delhi
DIRECTOR C&M DD (E&N E) DIRECTOR C&MDD (N&W) ( Alternate) Alternate)
Engineer-in-Chief ’s Branc h (MES), NewDelh i
BRIG S ANDEEP RAWAT SHRI V. K. JATAV ( Alternate) Alternate )
Engineers India Limited, New Delhi
SHRI VINAY KUMAR SHRI SUDHIR CHATURVEDI ( Alternate) Alternate)
G a m m o n I n d i a L i m i te d , M u m b a i
SHRI S. W. DESHPANDE SHRI A VINASH Y. Y. MAHENDRAKAR ( Alternate) Alternate )
Indian In stitute of Tech nology Mad ras, C hennai
DR D EVDAS MENON DR A MEHER PRASAD ( Alternate) Alternate)
Indian I nstitute of Techno lo gy Kanpu r, Kanp ur
DR VINAY K. GUPTA
Indian Institute of Tec hnolog y Roo r kee, R oor kee
DR PREM KISHAN DR S.K.K AUSHIK ( Alternate) Alternate)
In dian Metro log ical Dep artment, New Delhi
SHRI K. RATNAM
M.N. Dastur & Company Lim ited, Kolkata
SHRI A . DAS GUPTA SHRI SATYAKI SEN ( Alternate) Alternate)
MEC ON Limited, R anchi
SHRI ONKAR SAHAY SHRI A. K. B EG ( Alternate) Alternate)
Mi ni ni st st ry ry o f S hi hip pi pin g, g, R oa oad Tr an an sp sp or ort & Hi gh gh wa way s, s, New De lh lh i
SHRI S. K. PURI SHRI SATISH KUMAR, SE (P-9) ( Alternate) Alternate)
Mun cipal Co rporation of Greater Mumbai, Mumbai
Deputy Municipal C ommissio ner (ENGG) City Engineer ( Alternate) Alternate)
Nati Nation onal al Buil Buildi ding ngss Con Const stru ruct ctio ion n Cor Corpo pora rati tion on Limi Limite ted, d, New New Del Delhi hi
SHRI R AKESH MARYA SHRI L. P. SINGH ( Alternate) Alternate)
Nati Nation onal al Coun Counci cill for for Ceme Cement nt and and Buil Buildi ding ng Mate Materi rial als, s, Ball Ballab abga garh rh
SHRI V. V. ARORA SHRI S. S HARMA ( Alternate) Alternate)
National The rmal Power C or por ation, Noida
SHRI H. KUNDU SHRI M ASOOM A LI ( Alternate) Alternate )
Researc h, De Designs & Stan dards Or Organization, Lu Lu cknow
Joint Di Directo r St Standards (B (B &S) JT Director Stnds (B&S) SB-I ( Alternate) Alternate)
RITES Limited , Gurgaon
SHRI ASHOK KUMAR MATHUR
Structu ral Engineering Research Centre (C SIR ), Chennai
DR S. SELVI RAJAN DR P. HARIKRISHNA ( Alternate) Alternate)
TC E Con sulting Eng in eers Limited, Mu mbai
SHRI A. P. MULL SHRI A. DUTTA ( Alternate) Alternate )
The Institutio n of Engineer s (India) Ltd, New Delhi
SHRI K. B. RAJORIA
57
IS 875 (Part 3) : 2015 In personal capacity, (P-121, (P-121, Sanjay Nagar, Ghaziabad 201 001) 001 )
SHRI S. K. A GARWAL
In personal capacity, (142 ( 142 Deshbandhu Apartments, New Delhi 110 019)
SHRI G. P. LAHIRI
In personal capacity, (61, (61, Civil Lines, Roorkee 247 667)
DR PREM KRISHNA
BIS Directorate General
Shri D. K. AGRAWAL, SCIENTIST ‘F’ and HEAD (CIVIL ENGG) [Representing Director General ( Ex-officio)] Ex-officio )]
Member Secretaries Shri S. CHATURVEDI SCIENTIST ‘F’ (CIVIL ENGG), BIS and Shri S. ARUN KUMAR SCIENTIST ‘C’ (CIVIL ENGG), BIS
58
(Continued from from second cover ) f)
Provisions Provisions to account account for for effects of directionality directionality, area averagin averaging g and correlation correlation of of pressures pressures on the design wind pressure have been included.
g)
Guidelines Guidelines to account account for the the wind induced induced interferenc interferencee for tall buildings buildings and low rise buildings buildings have have been included for use in preliminary design. It is however recommended to carry out detailed boundary layer wind tunnel tests/CFD (Computational Fluid Dynamics) studies for final design of important structures.
h)
In the Gust Factor Method for eva evaluating luating along wind response, response, equations equations have have been suggested suggested for background factor, size reduction factor, energy ratio and length scale of turbulence.
j)
A method for computing across wind response of tall buildings and lattice towers, which is in line with some of the international codes of practice, has been included.
The Committee observed that there has been a growing awareness among the consultants, academicians, academician s, researchers and practice engineers for design and construction of wind sensitive structures. In order to augment the available limited good quality meteorological wind data and structural response data, it is necessary to conduct full scale measurements in the field. Thus as emphasized in the previous revision, all individuals and organizations responsible for putting-up of tall structures are encouraged to provide instrumentation in their existing and new structures (transmission towers, chimneys, cooling towers, buildings, etc) at different elevations (at least at two levels) to continuously measure and monitor wind data. The instruments are required to collect data on wind direction, wind speed and structural response of the structure due to wind (with the help of accelerometer, strain gauges, etc). It is also the opinion of the Committee that such instrumentation i n tall structures shall not in any way affect or alter the functional behaviour of such structur es. The data so collected shall be very valuable in evolving evolving more accurate wind loading of structures. The Committee responsible for the formulation of this standard has taken into account the prevailing practice in regard to loading standards followed in this country by the various authorities and has also taken note of the developments in a number of other countries. In the formulation of this code, the following overseas standards have also been examined: a)
BS EN 1991-1-4:2005 1991-1-4:2005 Eurocode Eurocode 1: Actions on on structures structures — Part 1-4: 1-4: General General actions actions — Wind Wind actions actions
b)
Joint Australian/Ne Australian/New w Zealand Standard Standard AS/NZS AS/NZS 1170.2:2002 1170.2:2002 Structural Structural design design actions, actions, Part 2: Wind Wind actions
c)
ASCE 7-05 American American Standard Standard Building Building Code Requiremen Requirements ts for Minimum Minimum Design Design Loads Loads for Buildings Buildings and Other Structures.
d)
AIJ 2004 — Architecture Architecture Institute Institute of Japan Japan (AIJ) Recomme Recommendation ndationss for Loads Loads on Buildings. Buildings.
The composition of the Committee responsible for the formulation of this Code is given at Annex E. For the purpose of deciding whether a particular requirement of this standard is complied with, the final value observed or calculated, calculated, expressing the result of a test or analysis, analysis, shall be rounded off in accordance accordance with IS 2 : 1960 ‘Rules for rounding off numerical values (revised )’. )’. The number of significant places retained in the rounded off value should be the same as that of specified value in this standard.
Bureau of Indian Standards BIS is a statutory institution established under the Bureau of Indian Standards Act , 1986 to promote harmonious development of the activities of standardization, marking and quality certification of goods and attending to connected matters in the country. Copyright BIS has the copyright of all its publications. No part of these publications may be reproduced in any form without the prior permission in writing of BIS. This does not preclude the free use, in the course of implementing the standard, of necessary details, such as symbols and sizes, type or grade designations. Enquiries relating to copyright be addressed to the Director (Publications), BIS. Review of Indian Standards Amendments are issued to standards as the need arises on the basis of comments. Standards are also reviewed periodically; a standard along with amendments is reaffirmed when such review indicates that no changes are needed; if the review indicates that changes are needed, it is taken up for revision. Users of Indian Standards should ascertain that they are in possession of the latest amendments or edition by referring to the latest issue of ‘BIS Catalogue’ and ‘Standards : Monthly Additions’. This Indian Standard has been developed from Doc No.: CED 37 (7792).
Amendments Issued Since Publication Amend No.
Date of Issue
Text Affected
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