- Open Access
- Authors : B.R Shilpa, Joshan Acharya, Jayandra Rawal, Susheel Kumar, Javed Osta
- Paper ID : IJERTCONV10IS10023
- Volume & Issue : ACME – 2022 (Volume 10 – Issue 10)
- Published (First Online): 13-08-2022
- ISSN (Online) : 2278-0181
- Publisher Name : IJERT
- License: This work is licensed under a Creative Commons Attribution 4.0 International License
Dynamic Analysis of Adjacent RCC Buildings for Pounding Effect
1B.R Shilpa, 2Joshan Acharya, 3Jayandra Rawal, 4Susheel Kumar, 5Javed Osta
1Assistant Professor, 2,3,4,5UG Students, Department of Civil Engineering,
RR Institute of Technology, Bangalore, India
AbstractCollision of two adjacent buildings which are of different dynamic characteristics and having insufficient separation gap between the buildings is called seismic pounding. In present day scenario buildings are constructed very close each other in urban areas for the complete usage of limited land space. During earthquakes the buildings closely spaced have a chance of pounding on the adjacent building block. This study covers the effect of providing insufficient gap element between the two adjacent RCC buildings. A modal of two buildings close to each other one being G+7 storey and other being G+4 storey was considered. Model analysis and Response spectrum analysis is carried out for both buildings. The parameters like displacement and drifts were considered for the analysis by using Etabs and plotted them on graph to know the effect of pounding on adjacent buildings.
Keywords Seismic pounding, Gap elements, Response spectrum Analysis, Displacement and Storeydrifts.
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INTRODUCTION
Pounding is one of the main causes of severe building damages in earthquake. Pounding effect refers to the collision of adjacent buildings during earthquake. It occurs when the distance between two buildings are lesser to face the relative motion during earthquake. When the seismic vibration occurs on the adjacent buildings, the load transfer from high rise building to the lower building and the lower storey building should not be constructed in such a way that to carry the transferred load. Its results in pounding between buildings which are narrow spaced, which causes severe damage. Investigation have shown that pounding damage was observed in Mexico (1985), Canada(1988),Kobe(1995),Nepal(2015)of earthquakes can be seen. The prevention measures to avoid the seismic pounding between the adjacent buildings are RC Shear Wall, Steel Cross Bracing, Dampers, sufficient separation gap between the adjacent buildings.
Fig1.1: 2015 Nepal Earthquake.Damages due to pounding effect
1.1 GAP ELEMENT
Gap element it is the link elements it is a compression memberor element which is required to access the force of pounding and to stimulate the effect of pounding the main purpose of the link or gap element is to transmit the force through the link only when contact occurs and the gap is closed.
Therefore, the stiffness of the gap element is found as below.
K= (AxEx102)/L
Where, K= stiffness of the gap elementA= W x tE= Youngs Modulust = Slab Thickness
W= Average Element Width
Fig: Shows the plan of the 2 colliding floors and the connecting gap element.
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LITERATURE REVIEW
In this study, the pounding effect is analyzed. on the two adjacent buildings (G+7) and (G+4) The g taken of 50mm, 80mm, 100mm, 140mm is used the two adjacent buildings are analyzed for various cases equal floor level and different storey height, equal floor level and equal storey height and Setback of 3m with equal floor and different storey height. And Response spectrum analysis to carried out for both 3D buildings. Displacement and storey drifts are compared with all the gap on each case and Conclusions are arrived on their aspects of the study.
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OBJECTIVES OF THE STUDY
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To study the 3D buildings by considering seismic pounding effect during earthquake with different gap element.
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50 mm b) 80 mm c) 110 mm d) 140 mm
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To study the seismic behaviour by analyzing the displacement value and storey drifts value.
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Graph will be plotted for various gap and conditions and giving an idea how pounding will affect the 3D Building
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METHODOLOGY
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To carry out the proposed work 2 buildings models
are considered (G+7&G+4).
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Etabs is used to create 3D model and run all investigation models.
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Model analysis is carriedoutfor both the buildings for (dead load, FF, l ive load, FF, EQ-X & EQ-Y)
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Response spectrum analysis is carried out for both seven &four storey buildings.
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Displacement and storey drifts obtained and plotted them on graph to see the pounding effect between the adjacent buildings
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DEFINING THE MATERIAL PROPERTIES
Beam Sections (mm)
Column Sections (mm)
230X450
300X400
450X550
600X600
550X650
700X700
Slab Sections
All Slabs are 150mm Thick
Wall Loads :
For 3m Storey Height For 3.2m Storey Height
14.72KN/m2
13.8 KN/m2
Live Load
3.0 KN/m2
Live Load on Roof
1.5 KN/m2
Floor Finish
1.2 KN/m2
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: Load Configurations:
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Seismic Factors
Specifications
Zone
V
Zone Factor
0.36
Importance factor (I)
1
Soil Type
III
Response reduction factor (R)
3
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Geometric & section properties
G+7
G+4
Number of Bays in X Direction
3
3
Spacing of Bays in X Direction (m)
5
5
Number of Bays in Y Direction
5
5
Spacing of Bays in Y Direction (m)
3
3
Storey Height (m)
3.2
3
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MODELLING DIAGRAMS FROM ETABS Case1: Adjacent Buildings at equal floor level with different storey height
Fig 6.1: PLAN
Fig 6.2: ELEVATION
Fig 6.3: 3D Model of Case1
Case 2: Adjacent Buildings at equal floor level and storey height
Fig 6.4: PLAN
Fig 6.5: ELEVATION
Fig 6.6: 3D Model of case 2
Case 3: Adjacent Buildings with a setback of 3m withequal floor level with and storeyheight.
Fig 6.7: PLAN
Fig 6.8: 3D Model of Case 3
7: RESULTS AND DISCUSSIONS
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Overall Maximum Displacement for 7 and
4 storey building for case 1 provided with 50, 80,110,140 mm gap element.
Building
Story
Maximum Displacements(mm)
Gap Element
G+7
7F
43.4
50mm
G+4
4F
11.8
50mm
G+7
7F
56.4
80mm
G+4
4F
15.2
80mm
G+7
7F
107.3
110mm
G+4
4F
27.9
110mm
G+7
7F
107.2
140mm
G+4
4F
27.9
140mm
Table 7A: Overall maximum storey displacements considering case 1
B.
Overall Maximum Displacement for 4 storey buildings for case 2 provided with 50, 80,110,140mm gap element.
Building
Story
Maximum Displacements(mm)
Gap Element
G+4
4F
32.4
50mm
G+4
4F
50.5
80 mm
G+4
4F
74.3
110mm
G+4
4F
73.7
140mm
Table 7B: Overall maximum storey displacements considering case 2
Fig 7B : Overall maximum storey displacementgraph considering case 2
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Overall Maximum Displacement for 4 and 7 storey buildings for case 3 provided with 50, 80,110,140
mm gap element
Building
Story
Maximum Displacements(mm)
Gap Element(m m)
G+7
7F
43.3
50mm
G+4
4F
11.8
50mm
G+7
7F
56.5
80mm
G+4
4F
15.2
80mm
G+7
7F
107.1
110mm
G+4
4F
27.9
110mm
G+7
7F
107
140mm
G+4
4F
27.9
140mm
Table 7C: Overall maximum Storey displacement considering case 3
Fig7C. Storey displacement graph for 7 and 4 storey building
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Maximum Displacement for 7 storey consideringall the cases
Building
Cases
Storey
Maximum Displacement(mm)
Gap elementsmm
G+7
Case1
7F
43.4
50
G+7
Case1
7F
56.4
80
G+7
Case1
7F
107.3
110
G+7
Case1
7F
107.2
140
Table 7D: Maximum Storey displacement consideringall the cases (7 storey)
Fig7D: Maximum Storey displacement graph consideringall the cases (storey7)
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Maximum Displacement for 4 storey considering allthe cases
Building
Cases
Storey
Maximum Displacem ent(mm)
Gap Element(m m)
G+4
Case 2
4F
32.4
50
G+4
Case 2
4F
50.5
80
G+4
Case 2
4F
74.3
110
G+4
Case 2
4F
73.7
140
Table 7E: Maximum Storey displacementconsidering all the cases (4 storey)
Fig7E: Maximum Storey displacement graphconsidering all the cases (4 storey)
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Overall Maximum storey drifts for 7 and 4 storey buildings for case 1 provided with 50,80,110,140 mm gap element.
Building
Cases
Storey
Maximum Storey Drifts
Gap Element (mm)
G+7
Case1
1F
0.002459
50
G+4
Case1
1F
0.001019
50
G+7
Case1
1F
0.003288
80
G+4
Case1
1F
0.00132
80
G+7
Case1
1F
0.006017
110
G+4
Case1
1F
0.002476
110
G+7
Case1
1F
0.006014
140
G+4
Case1
1F
0.002475
140
Table 7F: Overall Maximum Storey driftsconsidering case 1
Fig7F: Overall maximum Storey drifts graphconsidering case 1
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Overall Maximum storey drifts for 4 storey buildings for case 2 provided with 50, 80,110,140mm gap element.
Building
Cases
Storey
Maximum Storey Drifts
Gap Element (mm)
G+4
Case 2
1F
0.002757
50
G+4
Case 2
1F
0.004284
80
G+4
Case 2
1F
0.006381
110
G+4
Case 2
1F
0.00638
140
Table 7G: Overall Maximum Storey drifts considering case 2
Fig7G: Overall Maximum Storey drifts graph
considering case 2
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Overall Maximum storey drifts for 4 and 7 storey buildings for case 3 provided with 50, 80,110,140 mm
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gap element
Building
Cases
Storey
Maximum Storey Drifts
Gap Element
G+7
Case 3
1F
0.002476
50
G+4
Case 3
1F
0.001023
50
G+7
Case 3
1F
0.004727
80
G+4
Case 3
1F
0.00184
80
G+7
Case 3
1F
0.005999
110
G+4
Case 3
1F
0.002489
110
G+7
Case 3
1F
0.006003
140
G+4
Case 3
1F
0.002489
140
Table 7I: Maximum storey drift considering all the cases (7storey building)
Table 7H : Overall Story drift considering case 3
Fig 7H: Storey drifts graph considering case 3
I . Maximum Storey drifts considering all the cases for 7 storey budlinig.
Fig7I:maximum storey drifts considering all thecases (7 storey building)
J. Maximum Storey drifts considering all the cases for 4 storey building
Building
Cases
Storey
Maximu m Storey Drifts(m m)
Gap Element (mm)
G+4
Case 2
1F
0.002757
50
G+4
Case 2
1F
0.004284
80
G+4
Case 2
1F
0.006381
110
G+4
Case 2
1F
0.00638
140
Table 7J: Maximum storey drift considering all the cases(4 storey building)
Fig 7J: Overall maximum storey drifts considering all the cases (4 storey building)
Buildi ng
Cases
Storey
Maximum Storey Drifts
Gap Element
G+7
Case 3
1F
0.002476
50
G+7
Case 3
1F
0.004727
80
G+7
Case 3
1F
0.005999
110
G+7
Case 3
1F
0.006003
140
+
8: CONCLUSION
Based on analysis carried out on the seismic pounding effect inthe buildings the following conclusions are:
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The displacements value are less at lower storey building and gradually increasing at higher storey building.
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The storey drifts value are less at higher storeys building and gradually increasing at lower and intermediate storeys.
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With the buildings provided with the gapelement of 50, 80,110,140mm here the displacement as well as Storey drift is found to be gradually increasing for 50mm and 80mm gap element but with gap element of 110 and 140mm the displacement and the storey drift values are found to be constant i.e.., if the gap element size is further increased the displacement and the storey drift values becomes constant.
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The displacement is found to be maximum at the higher storey i.e. seventh storey for Case 1 and fourth storey for Case 2 on comparison with all the cases respectively.
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The drift is found to be maximum at the lower storey i.e., first floor for Case 1 and fourth storey for Case 2 on comparison with all the cases respectively.
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Therefore, the effect of the gap distance between adjacent buildings on their pounding behavior was found to be highly significant.
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FUTURE SCOPE
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This study can further be extended for ta buildings
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Seismic pounding effect can be studied forvarying spacing of buildings.
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Time history analysis can be applied to study seismic pounding effect
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REFERENCES
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