Enhancing The Sesmic Performance Of Building Using Dampers

Enhancing The Sesmic Performance Of Building Using Dampers

Namrata S Naragundkar Department of Civil Engineering Jain Institute of Technology, Davanagere Karnataka, India
Bhuvan S Somanna Department of Civil Engineering Jain Institute of Technology, Davanagere Karnataka, India	Anoop A N Department of Civil Engineering Jain Institute of Technology, Davanagere Karnataka, India
Baskar A Department of Civil Engineering Jain Institute of Technology, Davanagere Karnataka, India	Keshav Murthy N D Department of Civil Engineering Jain Institute of Technology, Davanagere Karnataka, India

Abstract India is developing country, nowadays our Indian population is increasing day by day. According to some sources our Indian population is reached nearly 142.86 crores, this rapid increase in population forced engineers to adopt for high rise building. Damage caused by lateral load is needed to be control. There are so many methods to control the damage of building by lateral loads: we are adopting one of method, providing the different types of loads in the building. In present study, we have used conventional building with 15mx18m along the direction. We carried out the linear analysis by using E-TABS software, then comparing the result of displacement, storey drift, between the bare building.

Keyword Fluid viscous dampers, Displacement, Storey Drift, E-TABS etc.

1. INTRODUCTION

   The increase in population by which land deficit occurs and to overcome that, high-rise buildings are opted. These type of high-rise buildings are prone to structural failures mainly on application of lateral loads such as wind, seismic forces etc. Geographical statistics of India show that almost 54% of the land is vulnerable to earthquakes. Calamities like earthquakes are the most dangerous by means of the damage and chaos caused to the structural components and they cannot be controlled. These natural calamities caused property damage and interruptions in development of the normal lifecycle. Since its a global concern, most of the analysis should be carried out and provided with the results to prep the structure in order to attain time period.‌‌‌

   Fig COMMERCIAL BUILDING

   1. LOADS TO BE CONSIDERED

      1. Dead load

         A dead load is nothing but the self- weight of its structural element. It is mainly considered for its density of materials.

      2. Live load

         Live loads are imposed loads that are temporary and of a short duration, are moving loads.

      3. Wind load

         The effect of wind load is not considered as the structure satisfies the following requirements as per the national building code of 1970.

         1. The building or a part of a building of which h does not exceed twice the effective width.

         2. A wing of such a building, if it does not project more than twice its own width.

      4. Seismic load

         Seismic load is the basic concept of earthquake engineering, which means the application of an earthquakes generated agitation to a shape.

2. OBJECTIVES OF STUDY

   The main objectives of this study are summarized in few points as follows:

   484

   • Conventional building and building incorporated with dampers.

   • To evaluate the dampers i n d i f fe re n t of seismic performance.

3. MODELING AND ANALYSIS

ETABS is analysis software. ETABS is expanded as extended three dimensional analysis of building systems. All the necessary tools, like create, modify, analyse and optimize etc., which are required for structural engineers are provided by this software.

1. MODELS CONSIDERD FOR ANALYSIS

   Fig 1: View of slab, beam &column

   Fig 2: View of slab, beam &column

2. PROCEDURE FOR USING E-TABS

   Step 1: Model Initialization Step 2: Custom grid settings Step 3: Defining the materials

   Step 4: Defining frame properties Step 5: Defining slab properties Step 6: Draw beams and column Step 7: Defining load patterns Step 8: Assigning shell loads Step 10: Analyse/Check model

   Figure 4: Rendered view

   Results lateral displacement along for the different load combinations with Conventional dampers are expressed table.

   485

   Table 5.1: Maximum storey displacement in X- direction.

   40
   35
   30
   25
   20
   15
   10
   5

   Story	Elevation(m)	Without Dampers in mm	With Dampers in mm
   Story12	36	177.881	106.847
   Story11	33	167.289	94.171
   Story10	30	154.739	81.462
   Story9	27	140.527	68.861
   Story8	24	124.953	56.55
   Story7	21	108.304	44.743
   Story6	18	90.853	33.684
   Story5	15	72.878	23.646
   Story4	12	54.703	14.924
   Story3	9	36.808	7.841
   Story2	6	20.076	2.74
   Story1	3	6.385	0
   Base	0	0	0

   Displacement in X Direction

   0

   -50 0 50 100 150 200

   DISPLACEMENT

   Without Damper Without Damper

   Fig 5.2: Maximum storey along Y- direction.

   Story1

   Story	Elevation(m)	Without Dampers in mm	With Dampers in mm
   Story12	36	181.804	107.912
   Story11	33	170.891	95.059
   Story10	30	157.989	82.186
   Story9	27	143.399	69.435
   Story8	24	127.425	56.99
   Story7	21	110.36	45.066
   Story6	18	92.488	33.909
   Story5	15	74.098	23.79
   Story4	12	55.529	15.007
   Story3	9	37.282	7.879
   Story2	6	20.273	2.752
   3	6.421	0
   Base	0	0	0

   Displacement in Y

   4
   3
   3
   2
   2
   1
   1
   5

   0

   -5 0 5 10 15 20

   DISPLACEME

   Without Without

   486

3. STOREY DRIFT

   Table 3: Maximum drift in X direction.

   Story	Elevation(m)	Without Dampers in mm	With Dampers in mm
   Story12	36	0.003531	0.004225
   Story11	33	0.004183	0.004236
   Story10	30	0.004737	0.0042
   Story9	27	0.005191	0.004104
   Story8	24	0.00555	0.003936
   Story7	21	0.005817	0.003686
   Story6	18	0.005992	0.003346
   Story5	15	0.006058	0.002907
   Story4	12	0.005965	0.002361
   Story3	9	0.005577	0.0017
   Story2	6	0.004563	0.000913
   Story1	3	0.002128	0
   Base	0	0	0

   Table 5.4 Maximum drift in Y- direction.

   Story	Elevation(m)	Without Dampers in mm	With Dampers in mm
   Story12	36	0.003638	0.004284
   Story11	33	0.004301	0.004291
   Story10	30	0.004864	0.00425
   Story9	27	0.005325	0.004148
   Story8	24	0.005688	0.003975
   Story7	21	0.005957	0.003719
   Story6	18	0.00613	0.003373
   Story5	15	0.00619	0.002928
   Story4	12	0.006082	0.002376
   Story3	9	0.00567	0.001709
   Story2	6	0.004617	0.000917
   Story1	3	0.00214	0
   Base	0	0	0

   487

   CONCLUSION

   • The displacement in X direction the conventional / bare or without dampers in building shows that 39.93% lesser than with dampers in building.

   • The displacement in Y Direction the conventional / bare or without dampers in building shows that 40.63% lesser than with dampers in building.

   • The story drift in X Direction the conventional / bare or without dampers in building shows that 44.15% lesser than with dampers in building.

   • The story drift in Y Direction the conventional / bare or without dampers in building shows that 52.69% lesser than with dampers in building.

   • From the overall result the displacement and story drift are minimum in with dampers building as compared to the without damper building.

   • Compared to the building connected with dampers the story displacement is increases with increase in stiffness of the buildings.

   • The story drift will decrease as the flexibility decreases in building, due to dampers connected to the building.

SCOPE OF FUTURE STUDY

Within the limited scope of the present work, the broad conclusion drawn from this work have been reported. However, further study can be undertaken in the following areas.

• Irregular plan buildings are considered for analysis that can be further extended to vertical irregular plan of building.

• Dampers provided at the corners only, further study also may be undertaken by providing different location

• fixed base structure, further study may also be undertaken by considering of soil structure interaction.

• The study is further being extended to progressive collapse mechanism.

REFERENCES

[1]. Wakale Yogesh Namdev , Moon Manish Yewnath , Thool Suhas Ashok ,Bodkhe Akash Machhindra, A.A. Waghmare (2022), Analysis And Design Of High Rise Building Using ETABS Software. Volume:04/Issue:05. International Research Journal of

Modernization in Engineering Technology and Science.

[2]. Darshan K M, Dr. H R Srinivas, Mary Bhagya Jyothi J (2021), Entitled Comparitive Analysis Of Highrise Buildings With And Without Dampers In Zone V Using E. Volume:03/Issue:11. International Research Journal of Modernization in Engineering

Technology and Science.

[3]. Rohan Haridas Pore, Arohan Anandrao Jadhav, Sakharam Ekanath Dhat, Amit Bandu Pardeshi (2020), A Literature review of MR Damper – Design and Analysis. Volume 8, Issue 6.

[4]. Apoorva S, Ajay K R, Bhavyashree R, Lokesh M, Prithvirani (2020), Seismic

Analysis of High-Rise Building G+24 Using ETABS. Volume:07, Issue:08. International Research Journal of Engineering and Technology (IRJET).

[5]. DR. K. Chandrasekhar Reddy & G.Lalith Kumar (2019),

Seismic Analysis of

High- Rise Buildings (G+30) by Using ETABS. Volume 5, Issue 03. International Journal of Technical Innovation in Modern Engineering & Science (IJTIMES).

[6]. Nikhil Shedbale , Prof. P. V. Muley (2017), Viscoelastic Materials used in

Viscoelastic Dampers . Volume:04, Issue:07. International Research Journal of Engineering and Technology (IRJET).

[7]. Ankit Jain, Dr. R. S. Talikoti (2016), Performance of High-Rise Structure with Dampers at Different Location. Volume:05, Issue:07. International Journal of Engineering Research & Technology (IJERT).

[8]. Sagar Dhok, Prof. P. V. Muley, Dr. T. N. Boob, Prof. P. R. Barbude (2016), Review on applicability of combinations of Damper for Steel Frame Structure. Volume: 03 Issue:

07. International Research Journal of Engineering and Technology (IRJET)

488