Investigation for Base Shear and Roof Displacement for Multi-Storey Building with Different Location of Shear Wall Using STAAD Pro

Similar documents
INTERNATIONAL JOURNAL OF CIVIL AND STRUCTURAL ENGINEERING Volume 2, No 2, 2011

STUDIES ON LOCATION OF SHEAR WALL IN BUILDINGS FOR STRUCTURAL STABILITY

EFFECT OF PLACEMENT AND OPENINGS IN SHEAR WALL ON THE DISPLACEMENT AT VARIOUS LEVELS IN A BUILDING SUBJECTED TO EARTHQUAKE LOADS

International Journal of Advance Engineering and Research Development DYNAMICS ANALYSIS OF STRUCTURES SUBJECTED TO EARTHQUAKE LOAD

Assessment of location and optimum percentage of shear wall for typical plans

SEISMIC BEHAVIOUR OF RC BUILDING RESTING ON PLAIN AND SLOPING GROUND WITH BRACINGS AND SHEAR WALL

Analysis and Design of Multi-Storey Building Subjected to Lateral Forces

Analysis of G+12 Structures with different material of Shear wall using SAP2000

EARTHQUAKE ANALYSIS OF A G+12 STOREY BUILDING WITH AND WITHOUT INFILL FOR BHUJ AND KOYNA EARTHQUAKE FUNCTIONS

Seismic Retrofitting of Building with Soft Storey and Floating Column

SEISMIC ANALYSIS OF SIX STOREYED RC FRAMED BUILDING WITH BRACING SYSTEMS

IJSRD - International Journal for Scientific Research & Development Vol. 4, Issue 05, 2016 ISSN (online):

SEISMIC EVALUATION OF RC MULTISTOREY BUILDING OF ASYMMETRIC PLAN WITH VISCO-ELASTIC DAMPER

Comparative Study of Equivalent Static Analysis and Response spectrum analysis on Flat Slab Using Etabs

COMPARATIVE STUDY ON REGULAR & IRREGULAR STRUCTURES USING EQUIVALENT STATIC AND RESPONSE SPECTRUM METHODS

THE EFFECTS OF P-DELTA AND CONSTRUCTION SEQUENTIAL ANALYSIS OF RCC AND STEEL BUILDING WITH RESPECT TO LINEAR STATIC ANALYSIS

Seismic Analysis of Steel Frames with Different Bracings using ETSBS Software.

Analytical Study on Seismic Performance of Hybrid (DUAL) Structural System Subjected To Earthquake

PUSHOVER ANALYSIS OF BUILDING WITH INFILL WALL

Seismic Analysis and Design of Vertically Irregular RC Building Frames

Seismic Behavior of High Rise Building for Soft Soil in All Seismic Zones Shaik Fayaz 1 Mrs. B.Ajitha 2

SEISMIC BEHAVIOR OF MULTI-STORY STRUCTURE WITH DIFFERENT TYPES OF SLABS

RESPONSE STUDY OF MULTI-STORIED BUILDINGS WITH PLAN IRREGULARITY SUBJECTED TO EARTHQUAKE AND WIND LOADS USING LINEAR STATIC ANALYSIS

Earthquakes Analysis of High Rise Buildings with Shear Walls at the Center Core and Center of Each Side of the External Perimeter with Opening

Comparative analysis betweenstatic and Non Linear Dynamic analysis of irregular and regular building

Assessment of P-Delta Effect on High Rise Buildings

Earthquake Resistant Design of a Building Using Shear Wall

Seismic Base Isolation of RC Frame Structures With and Without Infill

Analysis of Various Steel Bracing Systems using Steel Sections for High Rise Structures

Seismic Behavior of Soft First Storey

Static and Dynamic Behavior of Reinforced Concrete Framed Building: A Comparative Study

Pushover Analysis of High Rise Reinforced Concrete Building with and without Infill walls

SEISMIC EVALUATION OF HIGH RISE STEEL STRUCTURES WITH AND WITHOUT BRACING

INTERNATIONAL JOURNAL OF PURE AND APPLIED RESEARCH IN ENGINEERING AND TECHNOLOGY

Comparative Study of the Static and Dynamic Analysis of Multi-Storey Irregular Building

Parametric Study of Dual Structural System using NLTH Analysis Ismaeel Mohammed 1 S. M. Hashmi 2

SEISMIC ANALYSIS ON MEZZANINE FLOORING SYSTEM

Comparative study of Performance of RCC Multi-Storey Building for Koyna and Bhuj Earthquakes

Effect of Edge Beam and Shear Wall on the Structural Behavior of Flat Plate Multistoried Building: A Computing Modeling for lateral load Analysis

Index terms Diagrid, Nonlinear Static Analysis, SAP 2000.

Comparative Study of Static and Dynamic Seismic Analysis of a Multistoried Building

DYNAMIC ANALYSIS OF STEEL TUBE STRUCTURE WITH BRACING SYSTEMS

Comparative Study of Different Codes in Seismic Assessment

IJSRD - International Journal for Scientific Research & Development Vol. 2, Issue 09, 2014 ISSN (online):

Project Title. Comparative Study of Shear wall in multistoried

Pushover analysis of RC frame structure using ETABS 9.7.1

Diaphragm Flexibility in Buildings with Shear Walls

ANALYSIS OF SEISMIC BEHAVIOUR OF RCC AND COMPOSITE STRUCTURE WITH BUCKLING RESTRAINED BRACES

A COMPARATIVE STUDIES ON ELEVATED WATER TANK DUE TO DYNAMIC LOADING

PUSHOVER ANALYSIS FOR THE RC STRUCTURES WITH DIFFERENT ECCENTRICITY

Volume 1. HOW TO MAKE A DREAM HOUSE EARTHQUAKE RESISTANT Contents

Comparative Study on Dynamic Analysis of Irregular Building with Shear Walls

NON-LINEAR STATIC PUSHOVER ANALYSIS FOR MULTI-STORED BUILDING BY USING ETABS

Comparative Study of R.C.C and Steel Concrete Composite Structures

SEISMIC BEHAVIOR OF RC BUILDING FRAME WITH STEEL BRACING SYSTEM USING VARIOUS ARRANGEMENTS

Effect of Column Discontinuity on Base Shear and Displacement of Structure

Stability Analysis of Rigid Steel Frames With and Without Bracing Systems under the Effect of Seismic and Wind Loads

THE STUDY ON BEHAVIOUR OF OUTRIGGERS FOR TALL BUILDINGS SUBJECTED TO LATERAL LOAD

Comparative Study of Elastic Analysis and P-Δ Effect in Elevated Water Tank for Seismic Loads

NONLINEAR STATIC ANALYSIS OF R.C.C. FRAMES (Software Implementation ETABS 9.7)

DESIGN CRITERIA. Allowable Stress Design (ASD) AISC-1999.

DIAGRID STRUCTURAL SYSTEM: STRATEGIES TO REDUCE LATERAL FORCES ON HIGH-RISE BUILDINGS

PERFORMANCE- BASED SEISMIC DESIGN OF A BUILDING

Effect of Column Shortening on the Behavior of Tubular Structures

EVALUATION OF NONLINEAR STATIC PROCEDURES FOR SEISMIC DESIGN OF BUILDINGS

EARTHQUAKE ANALYSIS OF RCC BUILDINGS ON HILLY AREAS WITH VARYING SLOPES

ANALYSIS AND DESIGN OF COMMERCIAL BUILDING USING ETABS

ANALYTICAL INVESTIGATION ON THE PERFORMANCE OF TUBE-IN-TUBE STRUCTURES SUBJECTED TO LATERAL LOADS

IJSRD - International Journal for Scientific Research & Development Vol. 4, Issue 10, 2016 ISSN (online):

COMPARATIVE STUDY ON DESIGN RESULTS OF A MULTI-STORIED BUILDING USING STAAD PRO AND ETABS FOR REGULAR AND IRREGULAR PLAN CONFIGURATION

High Performance and Efficiency of Joints in Precast Members

SSRG International Journal of Civil Engineering (SSRG-IJCE) volume 4 Issue 7 July 2017

Seismic Analysis of High-Rise Building using Response Spectrum Method Pratik Bawankar 1

Effect of Torsion Consideration in Analysis of Multi Storey frame

COMPARATIVE STUDY OF SEISMIC FORCES BASED ON STATIC AND DYNAMIC ANALYSIS AS PER IS:

Analysis of Reinforced Concrete Building with Different Arrangement of Concrete and Steel Bracing system

Performance Based Seismic Design of Reinforced Concrete Building

EffectiveofSeismicLoadonBehaviorofRectangularShearWallinRCFramestructure

MULTI-STOREY BUILDINGS - II

ANALYSIS AND DESIGN OF RAFT FONDATION

IJSRD - International Journal for Scientific Research & Development Vol. 2, Issue 07, 2014 ISSN (online):

STUDY ON TIME HISTORY ANALYSIS METHOD USING STAAD PRO FOR MULTISTORYED BUILDING

CE 549 Building Design Project Spring Semester 2010

[Mohammed* et al., 5(8): August, 2016] ISSN: IC Value: 3.00 Impact Factor: 4.116

ANALYSIS OF MULTISTORIED BUILDING WITH AND WITHOUT FLOATING COLUMN USING ETABS

EARTHQUAKE DESIGN CONSIDERATIONS OF BUILDINGS. By Ir. Heng Tang Hai

DESIGN AND COMPARISON OF A RESIDENTIAL BUILDING (G+10) FOR SEISMIC FORCES USING THE CODES: IS1893, EURO CODE8, ASCE 7-10 AND BRITISH CODE

BLAST ANALYSIS AND BLAST RESISTANT DESIGN OF R.C.C RESIDENTIAL BUILDING

A Study on Construction of RC Shear Walls for Multi-Storied Residential Building

COMPARATIVE STUDY ON 3D RC FRAME STRUCTURE WITH AND WITHOUT FLOATING COLUMNS FOR STIFFNESS IRREGULARITIES SUBJECTED TO SEISMIC LOADING

COMPARATIVE STUDY ON RCC AND CFT MULTI-STOREYED BUILDINGS

SEISMIC RETROFITTING OF DORMITORY BUILDINGS WITH SOFT STOREY AND FLOATING COLUMNS

BEHAVIOURAL STUDIES OF FLOATING COLUMN ON FRAMED STRUCTURE

Seismic Analysis And Design of a Commercial Buildings (G+5)

CE 549 Building Design Project Spring Semester 2013

Dr. K. R. C. Reddy 1, Sandip A. Tupat 2 1,2

Wind analysis of multistoried structure with T shape and L Shape geometry

Consideration of torsional irregularity in Modal Response Spectrum Analysis

Seismic Analysis of Truss Bridges with Tall Piers

Available at ISSN

Transcription:

Investigation for Base Shear and Roof Displacement for Multi-Storey Building with Different Location of Shear Wall Using STAAD Pro SD Charkha Civil Dept Associate Professor Babasaheb Naik College Of Engineering Pusad Pusad Dist Yavatmal Aliya W Khan (PG Student Structural Engg) Babasaheb Naik College Of Engineering Pusad Pusad Dist Yavalmal Abstract Shear wall systems are one of the most commonly used lateral load resisting in high rise building Shear wall has high in plane stiffness and strength which can be used to simultaneously resist large horizontal loads and support gravity loads Incorporation of shear wall has become inevitable in multi-storey building to resist lateral forces It is very necessary to determine effective, efficient and ideal location of shear wall In this paper, study of 25 storey building in zone V is presented with some preliminary investigation which is analyzed by changing various position of shear wall with for determining parameters like bending moment,base shear and roof displacement This analysis is done by using standard package STAAD Pro Keywords- Shear Wall, Lateral Loading,, Displacements, Forces, Moments ***** I INTRODUCTION RC multi-storey buildings are adequate for resisting both the vertical and horizontal load When such building is designed without shear wall, beam and column sizes are quite heavy and there is lot of congestion at these joint and it is difficult to place and vibrate concrete at these places and displacement is quite heavy which induces heavy forces in member Shear wall may become imperative from the point of view of economy and control of lateral deflection In RC multi-storey building lift well or shear wall are usual requirement Centre of mass and stiffness of the building is ideal for a structure However, on many occasions the design has to be based on the off centre position of lift and stair case wall with respect to centre of mass which results into an excessive forces in most of the structural members, unwanted torsional moment and deflection II STRUCTURAL DATA Building consists of 7 bays of 75M in X- direction and 5 bays of 65M in Y- direction Table 1: Shows the Structural Data of Building Zone V Height of storey 335 m Number of storeys 25 600mm from base to storey Level 10 Shear wall thickness Grade of concrete and steel Depth of slab 400 mm from storey level 10 to 20 230 mm from storey level 20 to 25 M20 and Fe 415 175 mm Size of beam in longitudinal and transverse direction Size of Column 400 x 600 mm 850 x 850 mm From Base to Storey level 13 750 x 750 mm From Storey level 13 to 16 650 x 650 mm From Storey level 16 to 19 550 x 550 mm From Storey level 19 to 22 450 x 450 mm From Storey Level 22 to 25 Column around periphery 600 x 600 mm III GRAVITY LOADING A Gravity loading consists of dead load due to structural self-weight Abbreviations and Acronyms i Live load is considered as 3 KN per Square meter IV LATERAL LOADING Lateral loading consist of earthquake loading which has been calculated by program and it has been applied to the mass centre of the building ii Period Calculation: Users defined iii Response Reduction factor (R): 5 V RESULTS AND DISCUSSION Results obtained from the analysis are recorded in tabular form for the five cases of the building separately for comparison of base shear and displacement A 5084

i Case no 1 When Shear wall (Lift core) is placed at Table 5: Case No 02 Deflection at Roof when Shear Wall centre of building (Lift Core) at Second Position ii Case no 2 When Shear wall (Lift core) is displaced combination In mm in mm 75m from the centroid in X-direction iii Case no 3 When Shear wall (Lift core) is displaced 15 m from the centroid in X-direction iv Case No 4 When shear wall (Lift core is displaced 225m from the centroid X direction 12(DL+LL+EQx) 83521 0 12(DL+LL+EQz) 1692 74605 15DL+15EQx 108621 0 15DL+15EQz 44783 13613 Table 6: Case No 03 Base Shear when Shear Wall (Lift Core) Placed at Third Position In X 396111 In Z 304655 Table 7: Case No 03 Deflection at Roof when Shear Wall Plan of the Building (a) Table 2: Case No 01 Deflection at Roof when Shear Wall (Lift Core) at Centre 12(DL+LL+EQx) 6575 000 12(DL+LL+EQz) 0051 74873 15(DL+EQx) 83629 000 15(DL+EQz) 000 94858 Table 3: Case No 01 Base Shear when Shear Wall (Lift Core) at Centre In X 428412 In Z 386619 Table 4: Case No 02 Base Shear when Shear Wall (Lift Core) Placed at Second Position In X 367722 In Z 330344 12(DL+LL+EQx) 56118 0 12(DL+LL+EQz) -16753 68851 15DL+15EQx 75777 000 15DL+15EQz 31587 138509 Table 8: Case No 04 Base Shear when Shear Wall (Lift Core) Placed at Fourth Position In X 369209 In Z 316854 Table 9: Case No 04 Deflection at Roof when Shear Wall (Lift core) at Fourth Position Load Deflection in mm Deflection in mm combination X direction Z direction 12(DL+LL+EQx) 69709 000 12(DL+LL+EQz) -4762 57613 09DL+15EQx 92575 000 09DL+15EQz 39092 138788 B] i Case no 1 When Shear wall (Lift core) is placed at centre of building & Shear wall ( I type) is placed at corner of building in Y direction ii Case no 2 When Shear wall (Lift core) is displaced 75m from the centroid in X-direction & Shear wall 5085

( I type) is placed at corner of building in Y direction Core) at Second Position iii Case no 3 When Shear wall (Lift core) is displaced 15 m from the centroid in X-direction & Shear wall ( I type) is placed at corner of building in Y direction iv Case no 4 When Shear wall (Lift core) is displaced 225 from the centroid in X-direction & Shear wall (I type) is placed at corner of building in Y In X 504358 In Z 531302 Table 14: Case No 03 Base Shear when Shear Wall (Lift Core) Placed at Third Position In X 504358 In Z 531302 Table 15: Case No 03 Deflection at Roof when Shear Wall 12(DL+LL+EQ) 56636 0 12(DL+LL+EQ) -18763 82439 Plan of Building (b) Table 10: Case No 01 Deflection at Roof when Shear Wall (Lift Core) at Centre 12(DL+LL+EQx) 64925 000 12(DL+LL+EQz) 0919 70265 15(DL+EQx) 84009 000 15(DL+EQz) 000 89530 Table 11: Case No 01 Base Shear when Shear Wall (Lift Core) at Centre In X 435334 In Z 404594 Table 12: Case No 02 Deflection at Roof when Shear Wall (Lift Core) Placed at Second Position Load Deflection (mm) Deflection (mm) combination X direction Z direction 12(DL+LL+EQx) 11492 000 12(DL+LL+EQz) 2979 108453 15DL+15EQx 148944 000 15DL+15EQz 16579 142952 Table 13: Case No 02 Base shear when Shear Wall (Lift 15DL+15EQ 76263 0 15DL+15EQ 038 124982 Table 16: Case No 04 Deflection at roof when Shear Wall (Lift Core) Placed at Fourth Position Load combination Deflection In mm (X direction) Deflection In mm (Z direction) 12(DL+LL+EQx) 67812 0 12(DL+LL+EQz) 7498 89402 15DL+15EQx 87451 0 15DL+15EQz 4892 112459 Table 17: Case No 04 Base Shear when Shear Wall ) Lift core at fourth position In X 398759 In Z 386611 C] i Case no 1 When Shear wall (Lift core) is placed at centre of building & Shear wall ( L type) is placed at corner of building ii Case no 2 When Shear wall (Lift core) is displaced 75m from the centroid in X-direction & Shear wall ( L type) is placed at corner of building iii Case no 3 When Shear wall (Lift core) is 15 m from the centroid in X-direction & Shear wall ( L type) is placed at corner of building 5086

iv Case no 4 When Shear wall (Lift core) is displaced 225 Table 22: Case No 03 Base Shear when Shear Wall (Lift Core) from the centroid in X-direction & Shear wall (L type) is Placed at Third Position placed at corner of building In X 488368 In Z 461701 Table 23: Case No 03 Deflection at Roof when Shear Wall Plan of the Building (c) Table 18: Case No 01 Deflection at Roof when Shear Wall (Lift Core) at Centre 12(DL+LL+EQx) 59133 000 12(DL+LL+EQz) 1296 6547 15(DL+EQx) 74600 000 15(DL+EQz) 000 86845 Table 19: Case No 01 Base Shear when Shear Wall (Lift Core) at Centre In X 492558 In Z 525858 Table 20: Case No 02 Base Shear when Shear Wall (Lift Core) Placed at Second Position 12(DL+LL+EQx) 64199 0 12(DL+LL+EQz) -2782 73212 15DL+15EQx 81854 0 15DL+15EQz 13303 91711 Table 24: Case No 04 Deflection at Roof when Shear Wall (Lift Core) Placed at Fourth Position 12(DL+LL+EQx) 59721 0 12(DL+LL+EQz) -2474 70906 15DL+15EQx 75763 0 15DL+15EQz 4877 93015 Table 25: Case No 04 Base Shear when Shear Wall Lift core at fourth position In X 504741 In Z 464717 In X 670605 In Z 573671 Table 21: Case No 02 Deflection at Roof when Shear Wall (Lift Core) at Second Position combination In mm in mm 12(DL+LL+EQx) 62109 000 12(DL+LL+EQz) -21 68837 15DL+15EQx 81683 000 15DL+15EQz 3884 89456 D] i Case no 1 When Shear wall (Lift core) is placed at centre of building & Shear wall ( I type) is placed at corner of building in X direction ii Case no 2 When Shear wall (Lift core) is displaced 75m from the centroid in X-direction & Shear wall ( I type) is placed at corner of building in X direction iii Case no 3 When Shear wall (Lift core) is displaced 15 m from the centroid in X-direction & Shear wall ( I type) is placed at corner of building in x direction iv Case no 4 When Shear wall (Lift core) is displaced 225 from the centroid in X-direction & Shear wall (I type) is placed at corner of building in x direction 5087

Table 31: Case No 03 Deflection at Roof when Shear Wall 12(DL+LL+EQx) 71403 0 12(DL+LL+EQz) -0523 8188 Plan of the Building (d) Table 26: Case No 01 Deflection at Roof when Shear Wall (Lift Core) at Centre 12(DL+LL+EQx) 62499 000 12(DL+LL+EQz) 0051 78932 15(DL+EQx) 79199 000 15(DL+EQz) 0025 99249 Table 27: Case No 01 Base Shear when Shear Wall (Lift Core) at Centre In X 482528 In Z 417378 Table 28: Case No 02 Base Shear when Shear Wall (Lift Core) Placed at Second Position In X 430027 In Z 395986 Table 29: Case No 02 Deflection at Roof when Shear Wall (Lift Core) at Second Position combination In mm in mm 12(DL+LL+EQx) 70952 000 12(DL+LL+EQz) -3177 90634 15DL+15EQx 88373 000 15DL+15EQz 6287 113306 Table 30: Case No 03 Base Shear when Shear Wall (Lift Core) Placed at Third Position In X 431414 In Z 373120 15DL+15EQx 89974 0 15DL+15EQz 17643 115841 Table 32: Case No 04 Deflection at Roof when Shear Wall (Lift Core) Placed at Fourth Position 12(DL+LL+EQx) 62728 0 12(DL+LL+EQz) -0434 74278 15DL+15EQx 78827 0 15DL+15EQz 17079 121367 Table 33: Case No 04 Base Shear when Shear Wall Lift core at fourth position In X 448155 In Z 372012 CONCLUSION Study has been carried out on 16 models with different locations of shear wall From the above observations and study, following conclusion has been drawn 1 For all load Combinations From it is observed that the roof displacement is minimum for model no 5 2 For all load Combinations it is observed that the roof displacement is maximum for plan of building (b) 3 There is reduction in roof displacement in member in plan of building (c) due to occurrence of lateral forces 4 Lower roof displacement helps in reduction of P- Effect 5 Response quantity like storey drift, torsional irregularity etc should be calculated from actual displacement of each mode considered during analysis 6 The response quantity from each mode should be combined using modal combination to get the maximum magnitude of that response quantity 5088

7 Storey Drift will not be calculated corresponding to [2] M Ashraf, Z A Siddiqui, M A Javed Configuration of multistorey response spectrum load cases building subjected to lateral forces,, Asian journal of 8 Response Spectrum computes joint displacements that civil engineering,vol 9,no5, pp 525-535, 2008 represents maximum magnitude of the response quantity [3] Romy Mohammad C Prabha (2011), Dynamic analysis of rcc that is likely to occur during seismic loading building with shear wall, International Journal of earth Science 9 Multistory building subjected to lateral loads by changing & Engineering, ISSN 0974-5904, Volume-4 pp662 shear wall location using Software STAAD Pro gives [4] SV Venkatesh & H Sharda Bai (2011), Effect of Internal & External Shear wall on performance of building frame subjected lower displacement, base shear and base moment value as to lateral load, International Journal of earth Science & compare to other software Engineering, ISSN 0974-5904, Volume-6 pp571-576 10 Using STAADPro Structure becomes more rigid and [5] Comparative study of strength of RC Shear wall on different hence it gives concrete quantity more location on multi- storied Residential building by Varsha REFERENCES [1] Anshuman, Dipendu Bhunia, Bhavin Ramjiyani, Solution of shear wall in multi-storey building, International journal of civil and structural engineering, Volume 2, no2, 2011 Harne Civil Engineering department, ISSN 2278-3652 -4 (2014) pp391-400 @ Research India Publications Volume Fig a): Roof displacement (in mm) Vs model no for seismic forces in x- direction & seismic forces in z- direction 5089

2024 © businessdocbox.com Privacy Policy | Terms of Service | Feedback