DOI : 10.17577/IJERTV9IS060173
- Open Access
- Authors : Akansha Dwivedi , B.S Tyagi
- Paper ID : IJERTV9IS060173
- Volume & Issue : Volume 09, Issue 06 (June 2020)
- Published (First Online): 11-06-2020
- ISSN (Online) : 2278-0181
- Publisher Name : IJERT
- License:
This work is licensed under a Creative Commons Attribution 4.0 International License
Seismic Analysis of Building with and Without Shear Wall for Building with RCC and Composite Column
1Akansha Dwivedi
1Post Graduate Student in Structural Engineering, Department of Civil Engineering,
Radha Govind Engineering College, Meerut, UP ,India
2 B.S Tyagi
2 Professor, Department of Civil Engineering,
Radha Govind Engineering College, Meerut, UP, India
Abstract – Shear wall is a structural element which is provided for resisting horizontal forces (like wind force, earthquake force, etc) parallel to the plane of the wall and for supporting gravity loads simultaneously. These are basically flexural members which are generally provided in high rise buildings to avoid the total collapse of the building exposed to seismic forces. For seismic design of buildings, RC structural walls or shear walls are major earthquake resisting members which offer lateral load resistance by providing an efficient bracing system.
The response of the buildings is dominated by the properties of seismic shear walls and so it becomes important to evaluate the seismic response of the shear walls appropriately. In this study, the effect of presence of shear walls in RCC and composite structures in being analysed on basis of storey displacement, storey drift, stiffness, lateral force and base shear for G+19 buildings. Effectiveness of shear wall is being studied with the help of four different models. Model 1 is RCC building without shear wall, Model 2 is RCC building with shear wall, Model 3 is building with composite columns having no shear wall and Model 4 is building with composite columns in presence of shear wall. The earthquake load is applied to a building in zone IV and the analysis is done using both static analysis method and response spectrum analysis method.
Keywords: ETAB 2017, RCC buildings, Building with steel- concrete composite columns, Seismic analysis, Shear wall.
-
INTRODUCTION
In recent time, a lot of effort is given to develop the structural control devices so that seismic impact in buildings can be reduced. One such practice is introduction of shear wall in the buildings. Shear walls are one of the best means to provide earthquake resistance in multi- storied building. Behaviour of building under earthquake load depends on how the weight, stiffness and strength are distributed in the horizontal and lateral direction. Shear walls are used in the building to reduce the effect of earthquake by improving the seismic response of buildings. It becomes important to ensure adequate lateral stiffness to resist lateral load. For high- rise buildings, beam and column sizes are very heavy and requirement of steel is large because of which there is a lot of congestion at the joints and making it difficult to vibrate concrete at the joints and also the displacement is quite heavy.
In India most of the buildings are low rise. So, RCC members are used widely as it is easy to construct and
is economical. However with the growth of population there is increasing growth in high-rise buildings in metropolis. It is observed that the use of composite members over RCC members is much more effective and economical in high rise buildings. When a steel component like I-beam is attached to a concrete component like floor slab or bridge deck, a composite member is formed. In composite structures the high strength of the concrete in compression and high strength of the steel in tension are utilized in combination. Thus steel- concrete composite construction makes use of compressive strength of concrete and tensile strength of steel together to give more economical and effective structure. Such an advanced system is gaining recognition in high rise buildings.
In this paper effectiveness of shear wall in RCC building and building with composite columns have been studied with the help of four different models using Etabs in zone IV . The analysis is done by response spectrum analysis method and static analysis method. The models considered for the analysis are as follows:
Model 1 is RCC building without shear wall, Model 2 is RCC building with shear wall,
Model 3 is building with composite columns having no shear wall and
Model 4 is building with composite columns in presence of shear wall.
-
BUILDING MODELING
For the analysis 20 storey building has been considered having a height of 3m for each story including the ground storey. The structure modelled in symmetrical about both the axis. The modelling has been done in accordance to IS 456 and IS 1893 .The buildings has the fixed support at the base. The buildings are modelled using software ETAB for zone IV. Centre to centre distance between the two consecutive columns are 4m, the columns provided is square as they resist earthquake loading better. The study is carried out for the same building plan with and without shear wall for both RCC columns and composite columns by making four different models. Equivalent static method and response spectrum method have been used for the analysis and analysis has been done considering the parameters like storey displacement, storey drift, stiffness , lateral force and base shear .
Table 1: Building description
Building storey
G+19
Total height of building
60 m
Height of each storey
3.0 m
Beam size
350mm x700mm
Column size
600 mm X 600 mm
Shear wall thickness
250 mm
Slab thickness
225 mm
Thickness of external walls
230m
Thickness of internal walls
115
Live load
3 KN/m2
Floor finish
2 KN/m2
Grade of Concrete
M30
Grade of reinforcing Steel
HYSD 415
Grade of Steel
Fe250
Density of Concrete
25 KN/m3
Zone
IV
Importance factor
1.2
Soil condition
Medium soil
Response reduction factor
5.0
Damping ratio
5%
Fig 1: Plan view of building without shear wall Fig 2: Elevation view of building without shear wall
Fig 3: Plan view of building with shear Fig 4: Elevation view of building with shear wall
-
RESULTS AND DISCUSSIONS Equivalent static method and response spectrum method is used to analyse the results of all four models. Loads are calculated and distributed as per IS 1893:2016 and results obtained is compared as per following parameters.
-
STATIC ANALYSIS OF G+19 BUILDINGS
-
Lateral Displacement- From the observed results it was found that building with composite column in presence of shear wall showed minimum displacement. Also it is observed that the building on introduction of shear wall reduced displacement in the building substantially.
Table 2: Storey displacement
STOREY
RCC
(mm)
RCC WITH SHEAR WALL
(mm)
COMPOSITE
(mm)
COMPOSITE WITH SHEAR WALL
(mm)
1
6.562
1.427
4.123
1.154
2
17.534
4.305
12.168
3.458
3
29.419
8.29
21.505
6.599
4
41.539
13.165
31.266
10.43
5
53.728
18.744
41.146
14.814
6
65.909
24.868
51.019
19.637
7
78.016
31.398
60.809
24.794
8
89.979
38.211
70.457
30.192
9
101.723
45.199
79.902
35.748
10
113.168
52.261
89.078
41.386
11
124.227
59.311
97.917
47.037
12
134.808
66.271
106.344
52.638
13
144.813
73.071
114.28
58.137
14
154.139
79.655
121.64
63.486
15
162.678
85.977
128.336
68.647
16
170.318
92.002
134.274
73.591
17
176.943
97.714
139.363
78.302
18
182.435
103.115
143.517
82.774
19
186.693
108.234
146.69
87.029
20
189.744
113.06
148.965
91.014
Displacement (mm)
200
150
100
50
0
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20
RCC RCC WITH SHEAR WALL
COMPOSITE COMPOSITE WITH SHEAR WALL
Fig 5: Comparison of storey displacement
-
Storey Drift-Decrease in storey drift was observed in presence of shear wall in both building with RCC column as well as building with Composite column. Maximum drift was observed in RCC building without shear wall.
Table 3: Storey drift
STOREY
RCC
(mm)
RCC WITH SHEAR WALL
(mm)
COMPOSITE
(mm)
COMPOSITE WITH SHEAR WALL
(mm)
1
6.562
1.427
4.123
1.154
2
10.972
2.879
8.045
2.304
3
11.885
3.985
9.337
3.141
4
12.12
4.875
9.761
3.83
5
12.189
5.579
9.88
4.385
6
12.181
6.124
9.872
4.823
7
12.107
6.53
9.791
5.157
8
11.963
6.814
9.648
5.398
9
11.744
6.987
9.444
5.556
10
11.445
7.063
9.176
5.638
11
11.059
7.05
8.839
5.651
12
10.581
6.959
8.427
5.602
13
10.005
6.801
7.936
5.499
14
9.326
6.584
7.36
5.349
15
8.539
6.321
6.696
5.161
16
7.64
6.025
5.939
4.944
17
6.624
5.712
5.089
4.511
18
5.492
4.702
4.154
3.673
19
4.258
3.719
3.172
2.855
20
3.051
2.64
2.276
1.984
Drift(mm)
14
12
10
8
6
4
2
0
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20
RCC RCC WITH SHEAR WALL
COMPOSITE COMPOSITE WITH SHEAR WALL
Fig 6: Storey drift
-
Stiffness- It is observed that building with composite column having shear wall has maximum stiffness and RCC building without shear wall shows minimum stiffness as evident from the graph below.
Table 4: Stiffness
STOREY
RCC
(KN/m)
RCC WITH SHEAR WALL
(KN/m)
COMPOSITE
(KN/m)
COMPOSITE WITH SHEAR WALL
(KN/m)
Base
0
0
0
0
1
1268830
6058615.79
2062814.746
7645668.716
2
758607.9
3000926.082
1056867.359
3827626.858
3
699311.8
2164984.441
909335.751
2803316.998
4
683496.6
1764036.19
867034.373
2291679.015
5
675719.4
1532494.518
851613.092
1990302.456
6
670043.4
1383341.694
844533.12
1793098.3
7
665269
1280102.383
840342.895
1654623.847
8
661009
1204476.322
837254.968
1551727.315
9
657014.2
1146030.216
834587.182
1471074.498
10
653038.4
1098099.278
831982.827
1404090.936
11
648797.8
1055899.696
829154.648
1344609.27
12
643937.4
1015525.479
825782.217
1287617.095
13
637982.4
973324.746
821441.032
1228487.908
14
630252.7
925436.317
815506.837
1162426.33
15
619704
867387.251
806971.279
1084005.722
16
604599.5
793723.815
794013.26
986762.678
17
581758.1
697717.153
772848.449
862871.81
18
544364.9
571451.642
734022.261
703273.343
19
474687.1
405781.908
649120.953
497137.915
20
308690.8
197581.503
419907.19
242734.859
STIFFNESS
STIFFNESS
1 3 5 7 9 11 13 15 17 19 21
1 3 5 7 9 11 13 15 17 19 21
9000000
8000000
7000000
6000000
5000000
4000000
3000000
2000000
1000000
0
9000000
8000000
7000000
6000000
5000000
4000000
3000000
2000000
1000000
0
RCC
RCC
RCC WITH SHEAR
WALL COMPOSITE
COMPOSITE WITH SHEAR WALL
RCC WITH SHEAR
WALL COMPOSITE
COMPOSITE WITH SHEAR WALL
stiffness
stiffness
Fig 7: Comparison of stiffness
Fig 9: Representation of base shear for different models
-
-
RESPONSE SPECTRUM ANALYSIS OF G+19 BUILDINGS
-
Lateral displacement- It is observed that displacement is reduced substantially in presence of shear wall. Building with composite column in presence of shear wall showed minimum displacement while the RCC building without shear wall showed maximum displacement.
Table 6: Lateral displacement by response spectrum
STOREY
RCC
(mm)
RCC WITH SHEAR WALL
(mm)
COMPOSITE
(mm)
COMPOSITE WITH SHEAR WALL
(mm)
1
4.295
0.835
2.682
0.678
2
11.3
2.413
7.815
1.947
3
18.614
4.509
13.597
3.601
4
25.759
6.984
19.422
5.546
5
32.64
9.725
25.084
7.699
6
39.241
12.64
30.519
9.993
7
45.563
15.659
35.711
12.376
8
51.605
18.726
40.653
14.805
9
57.358
21.798
45.341
17.25
10
62.811
24.844
49.767
19.686
11
67.948
27.842
53.918
22.095
12
72.752
30.774
57.781
24.464
13
77.205
33.627
61.341
26.782
14
81.289
36.393
64.584
29.042
15
84.985
39.062
67.495
31.235
16
88.27
41.63
70.056
33.356
17
91.115
44.092
72.244
35.399
18
93.486
46.45
74.034
37.362
19
95.346
48.713
75.414
39.251
20
96.714
50.871
76.423
41.038
Displacement (mm)
Displacement (mm)
120
100
80
60
40
20
0
120
100
80
60
40
20
0
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20
RCC
COMPOSITE
RCC WITH SHEAR WALL
COMPOSITE WITH SHEAR WALL
RCC
COMPOSITE
RCC WITH SHEAR WALL
COMPOSITE WITH SHEAR WALL
Fig 10: Comparison of displacement by response spectrum method
-
Lateral drift- There is decrease in drift in building with composite column than building with RCC column. Building with composite column in presence of shear wall showed minimum drift among all the four models
Table 6: Lateral drift by response spectrum
STOREY
RCC
(mm)
RCC WITH SHEAR WALL
(mm)
COMPOSITE
(mm)
COMPOSITE WITH SHEAR WALL
(mm)
1
4.295
0.835
2.682
0.678
2
7.015
1.581
5.136
1.271
3
7.355
2.103
5.801
1.66
4
7.243
2.49
5.874
1.956
5
7.059
2.766
5.764
2.173
6
6.87
2.957
5.605
2.327
7
6.683
3.082
5.435
2.433
8
6.483
3.158
5.259
2.501
9
6.269
3.197
5.07
2.543
10
6.033
3.209
4.865
2.564
11
5.777
3.202
4.641
2.569
12
5.505
3.177
4.404
2.561
13
5.214
3.137
4.155
2.539
14
4.904
3.081
3.891
2.503
15
4.567
3.007
3.606
2.452
16
4.18
2.913
3.28
2.383
17
3.717
2.801
2.891
2.297
18
3.146
2.673
2.42
2.097
19
2.436
2.141
1.865
1.592
20
1.665
1.286
1.304
0.95
Drift (mm)
Drift (mm)
8
7
6
5
4
3
2
1
0
8
7
6
5
4
3
2
1
0
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20
RCC
COMPOSITE
RCC WITH SHEAR WALL
COMPOSITE WITH SHEAR WALL
RCC
COMPOSITE
RCC WITH SHEAR WALL
COMPOSITE WITH SHEAR WALL
Fig 11: Comparison of drift by response spectrum method
4. Stiffness- It is observed that building with composite column having shear wall has maximum stiffness and RCC building without shear wall shows minimum stiffness as evident from the graph below.
Table 7: Lateral drift by response spectrum
STOREY
RCC
(KN/m)
RCC WITH SHEAR WALL
(KN/m)
COMPOSITE
(KN/m)
COMPOSITE WITH SHEAR WALL
(KN/m)
Base
0
0
0
0
1
1292503
6903487.031
2114177.636
8671133.005
2
774342.8
3580772.778
1084590.899
4557050.78
3
714501.7
2603232.877
931641.314
3380857.809
4
697616.7
2100287.83
885008.033
2744738.727
5
690112.3
1790395.946
868738.96
2341520.377
6
684098.4
1576977.717
860705.989
2056837.42
7
679372.2
1422627.942
857024.369
1845012.295
8
674405.3
1307964.745
853859.368
1683578.05
9
670043.8
1223756.894
851149.968
1562652.152
10
665350.3
1163540.138
848342.788
1475294.03
11
660542.6
1122271.362
844653.719
1415875.442
12
656247
1096152.405
841706.512
1378940.327
13
651791.5
1079304.053
839213.043
1355954.249
14
647886.4
1065735.302
837528.542
1337481.054
15
645048.4
1049062.173
838233.66
1313068.196
16
641406.4
1018441.574
839112.705
1268493.341
17
635356.8
960059.353
836997.76
1186967.922
18
622575.9
855676.38
826986.996
1046213.631
19
580528.6
670223.997
776934.689
806723.924
20
412496.8
361815.448
546004.379
430153.909
STIFFNESS
STIFFNESS
10000000
10000000
RCC
RCC
8000000
6000000
4000000
RCC WITH SHEAR
WALL
COMPOSITE
8000000
6000000
4000000
RCC WITH SHEAR
WALL
COMPOSITE
2000000
COMPOSITE WITH
0 SHEAR WALL
1 3 5 7 9 11 13 15 17 19 21
2000000
COMPOSITE WITH
0 SHEAR WALL
1 3 5 7 9 11 13 15 17 19 21
stiffness
stiffness
Fig 12: Comparison of stiffness by response spectrum method
-
-
CONCLUSION
-
From all the above analysis, it is observed that for high rise building of 20 storey, building with composite column is more efficient. It is observed that displacement and drift is reduced substantially and stiffness of the building increases in presence of shear walls. Hence it is concluded that composite column building with shear wall counter seismic force more as compared to other models.
-
In case of RCC framed structure the lateral displacement is very high. It is observed that in presence of shear wall the displacement at top reduces by approx 40% in case of static analysis and 47% in case of response spectrum analysis in both RCC and composite column buildings. Also the building with composite column reduces the displacement by approx 20% as compared to RCC building.
-
Hence the composite column building in presence of shear wall counters the seismic effect more efficiently.
-
Storey-drift is the relative displacement, it means the drift of one level relative to the level below. It is observed that the drift at top is reduced by 13% in presence of shear wall in case of static analysis and 23% in case of response spectrum analysis.
-
Building with composite columns reduces the drift by approx 25% compared to RCC column buildings.
-
The stiffness of the building is more in case of composite column compared to RCC column building. The shear wall in the building makes the building increases the stiffness of the building.
-
-
REFERENCE
-
IS 1893 (part 1): (2002), Criteria for Earthquake Resistant Design of Structures Part 1 General Provisions and Buildings, Bureau of Indian Standards.
-
IS: 11384, code of practice for composite construction in structural steel and concrete, Bureau of Indian Standards, New Delhi, 1985
-
CSI Computers and Structures INC. Introductory Tutorial for Etabs: Linear and Nonlinear Static and Dynamic Analysis and Design of Three-Dimensional Structures 2017
-
B.C. Punmia, A.K. Jain, 2006, R.C.C Designs, Laxmi Publications New Delhi.
-
IS-456 2000 plain and reinforced concrete code of practice.
-
Panchal D.R., and Marathe P.M., Comparative study of R.C.C, Steel and Composite (G+30) Building Institute Of Technology, Nirma University, Ahmadabad, 2011.
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Prof. Charantimath, S.S., Prof. Cholekar, Swapnil B, and Birje, Manjunath M. (2014) Comparative Study on Structural Parameter of R.C.C and Composite Building IISTE, ISSN 2224-5790 (Paper) ISSN 2225-0514, 6(6) 98-109
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Kiran Tidke, Rahul Patil and Dr. G.R. Gandhe, Seismic Analysis of Building with and Without Shear Wall, International Journal of Innovative Research in Science, Engineering and Technology (JIRSET). Vol.3, pp.17852-17858, October 2016.
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N. Venkata Sairam Kumar, R. Surendra Babu and L. Usha Kranti, Shear walls A review, International Journal of Innovative Research in Science
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S.G. Satpute and D.B. Kulkarni, Comparative study of reinforced concrete shear wall analysis in multi-storeyed building with openings by nonlinear methods,International Journal of Structural and Civil Engineering Research (IJSCER). Vol.2, pp. 183-193, August 2013.