Post on 10-Mar-2019
UNIVERSITI PUTRA MALAYSIA
HESHMATOLLAH ABDI
FK 2015 27
RESPONSE MODIFICATION FACTOR FOR STEEL AND REINFORCED CONCRETE STRUCTURES WITH VISCOUS DAMPERS
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RESPONSE MODIFICATION FACTOR FOR STEEL AND REINFORCED
CONCRETE STRUCTURES WITH VISCOUS DAMPERS
By
HESHMATOLLAH ABDI
Thesis Submitted to the School of Graduate Studies,
Universiti Putra Malaysia, in Fulfilment of the
Requirement for the Degree of
Master of Science
July 2015
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Abstract of thesis presented to the Senate of Universiti Putra Malaysia in fulfilment of
the requirement for the degree of Master of Science
RESPONSE MODIFICATION FACTOR FOR STEEL AND REINFORCED
CONCRETE STRUCTURES WITH VISCOUS DAMPERS
By
HESHMATOLLAH ABDI
July 2015
Chair: Farzad Hejazi, PhD
Faculty: Engineering
The response modification (R) factor serves a main function in the seismic design of
building structures nowadays and is considered to be one of the seismic design
parameters in the process of equivalent static analysis. In the last two decades, the
application of damper systems as earthquake energy dissipation systems in structures has
increased. However, an extensive review of the related literature indicates that the effect
of the viscous damper on the response modification factor of steel and reinforced
concrete structures has not been investigated. Framed by this context, the current study
investigates the effect of implementing a viscous damper device in steel and reinforced
concrete structures on the response modification factor.
In this research, steel and reinforced concrete structures with numerous stories were
considered to evaluate the value of the response modification factor, which was
formulated based on the following three aspects: strength, ductility, and redundancy
factors. Structural frames were designed according to the UBC 1994 and IBC 2012
codes, and non-linear static analysis was conducted with the guidance of previous
studies, such as the Applied Technology Council (ATC) 19 and ATC 40.
Nonlinear static analysis was performed using a finite element software, which
considered structural models equipped with viscous damper devices in different
arrangements. The bilinear approximation of the actual push-over curve was used to
evaluate the required parameters, such as the base shear at yield point (𝑉𝑦), roof
displacement relationship at yield point (𝛥𝑦), and maximum displacement (𝑉𝑚).
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Results showed that the response modification factor of steel and reinforced concrete
structures equipped with viscous dampers is higher than that of structures without
viscous dampers.
To verify the numerical analysis and formulation, experimental tests were conducted for
the steel and reinforced concrete models, as well as the ARCS3D used for the reinforced
concrete models. According to the experimental results and comparisons for the
proposed response modification factor, using energy dissipation systems has an effective
influence on the response modification factor and leads to a response modification factor
with a higher value.
Based on the analytical results for all the different cases, the equations proposed for
determining the response modification factor of the steel and reinforced concrete
structures were furnished by viscous dampers according to the value of the damping
coefficient and number of stories.
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Abstrak tesis yang dikemukakan kepada Senat Universiti Putra Malaysia
Sebagai memenuhi keperluan untuk ijazah Master Sains
BALAS FACTOR PENGUBAHSUAJAN BAGI STEEL DAN STRUKTUR
KONKRIT BERTETULANG DENGAN PEREDAM LIKAT
Oleh
HESHMATOLLAH ABDI
Julai 2015
Pengerusi: Farzad Hejazi, PhD
Fakulti: Kejuruteraan
Response modification factor adalah ciri utama dalam rekabentuk seismic struktur
bangunan masa kini dan ia adalah salah satu parameter bagi proses setara analisa static.
Walaupun telah dua(2) dekad, sistem penebat diguna sebagai system pengagihan tenaga
gempabumi dalam struktur banguhan, namun melalui semakan literature berkaitan nya ,
didapati kesan penebatan kepada rmf dalam struktur keluli dan konkrit bertetulang tidak
diberi kajian sewajarnya.Oleh itu, disini, usaha dibuat untuk melihat kesan penebatan
kepada response modification factor dalam struktur keluli dan konkrit bertetulang.
Dalam kajian ini, Struktur keluli, struktur konkrit bertetulang pelbagai aras di nilai untuk
menentu angka response modification factor yang didasarkan kepada tiga aspek iaitu
kekuatan, kemuluran , kelebihan. Rekabentuk struktur adalah menurut UBC 1994, UBC
2012 dan analisa statik tak linear dilaksana dengan panduan kajian terdahulu ATC 19 dan
ATC 40.
Analisa statik tak-linear melalui pengisian unsure terhingga di gunakan menilai model
struktur yang di pasang alat penebat. Beberapa susunan penebat pelbagai nilai di
gunakan. Penghampiran bilinear lengkok daya dorong tarik digunakan semasa menilai
parameter yang diperlukan saperti keterikan dasar pada titik alahan (Vy), sesaran atap
berkait dengan titik alahan (Δy) dan anjakan maksima (Vm).
Keputusan kajian memdedahkan response modification factor bagi struktur keluli dan
struktur konkrit bertetulang yang di pasang bersama system pengagihan tenaga adalah
lebihtinggi di bandingkanresponse modification factor di struktur tanpa penebat viscous.
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Bagi pengesahan formulasi persamaan dan keputusan analisa numerical, ujikaji
dilaksanakan atas kerangka keluli dan kerangka konkrit bertetulang. Dari hasil ujian ,
response modification factor bagi system debgab agihantenaga adalah lebih tinggi dan
response modification factor dipengaruhi oleh system agihan tenaga.
Berdasar keputusan analitika kes yang pelbagai, persamaan yang di cadang untuk menilai
response modification factor bagi kerangka keluli dan kerangka viscous bergantung pada
pengkali penebat dan bilangan aras.
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ACKNOWLEDGMENTS
Praise and thanks Almighty God for giving me the wisdom, health, and strength to fulfil
this degree successfully.
I would like to express my deepest gratitude and appreciation to my supervisor, Dr.
Farzad Hejazi for his Kind supervision, encouragement, immense assistance, and
valuable comments and advice throughout my research.
Also, I wish to extend my sincere gratitude to Professor Dr. Mohd.Saleh Jaafar and Dr.
Izian Binti Abd Karim for their kind supervision, invaluable guidance and suggestion,
and support to all stages of this research.
Besides, I would like to thanks Professor Dr.Azmi Ibrahim for his warm supervision and
cooperation.
My special thanks go to all my friends, colleagues, and the staff of structural laboratory
of Civil Engineering Department and Institute of Advanced Technology (Institut
Teknologi Maju, ITMA) of UPM for their assistance.
Finally, I give my heartfelt and special thanks to my family, especially my siblings for
their patience, encouragement, as well as their financial and moral supports.
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I certify that a Thesis Examination Committee has met on (date of viva voce) to
conduct the final examination of (HESHMATOLLAH ABDI) on his (or her) thesis
entitled(“Response modification factor for steel and reinforced concrete structures
equipped with viscous damper”) in accordance with the Universities and University
Colleges Act 1971 and the Constitution of the Universiti Putra Malaysia [P.U.(A) 106]
15 March 1998. The Committee recommends that the student be awarded the relevant
degree.
Members of the Thesis Examination Committee were as follows:
..........................................................., PhD
Professor
Faculty of Engineering
Universiti Putra Malaysia
(Chairman)
..........................................................., PhD
Professor
Faculty of Engineering
Universiti Putra Malaysia
(Internal Examiner)
............................................................, PhD
Professor
Faculty of Engineering
Universiti Putra Malaysia
(Internal Examiner)
............................................................, PhD
Professor
Faculty of Engineering
Universiti
(External Examiner)
__________________________________
(Insert name of current Deputy Dean)
(E.g. XXXX XXXX, PhD)
Professor andDeputy Dean
School of Graduate Studies
Universiti Putra Malaysia
Date:
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This thesis was submitted to the Senate of Universiti Putra Malaysia and has been
accepted as fulfilment of the requirement for the degree of Master of Science. The
members of the Supervisory Committee were as follows:
Farzad Hejazi,, PhD
Senior Lecturer
Faculty of Engineering
Universiti Putra Malaysia
(Chairman)
Mohd.Saleh Jaafar,, PhD
Professor, Ir
Faculty of Engineering
Universiti Putra Malaysia
(Member)
Izian Binti Abd Karim, PhD
Senior Lecturer
Faculty of Engineering
Universiti Putra Malaysia
(Member)
Azmi Ibrahim PhD
Professor
Faculty of Engineering
Universiti Teknologi Mara
(Member)
_____________________________
BUJANG KIM HUAT, PhD
Professor and Dean
School of Graduate Studies
Universiti Putra Malaysia
Date:
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Declaration by graduate student
I hereby confirm that:
this thesis is my original work;
quotations, illustrations and citations have been duly referenced;
this thesis has not been submitted previously or concurrently for any other degree
at any other institutions;
intellectual property from the thesis and copyright of thesis are fully-owned by
Universiti Putra Malaysia, as according to the Universiti Putra Malaysia
(Research) Rules 2012;
written permission must be obtained from supervisor and the office of Deputy
Vice-Chancellor (Research and Innovation) before thesis is published (in the form
of written, printed or in electronic form) including books, journals, modules,
proceedings, popular writings, seminar papers, manuscripts, posters, reports,
lecture notes, learning modules or any other materials as stated in the Universiti
Putra Malaysia (Research) Rules 2012;
there is no plagiarism or data falsification/fabrication in the thesis, and scholarly
integrity is upheld as according to the Universiti Putra Malaysia (Graduate
Studies) Rules 2003 (Revision 2012-2013) and the Universiti Putra Malaysia
(Research) Rules 2012. The thesis has undergone plagiarism detection software.
Signature: ________________________ Date: __________________
Name and Matric No.: _________________________________________
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Declaration by Members of Supervisory Committee
This is to confirm that:
the research conducted and the writing of this thesis was under our supervision;
supervision responsibilities as stated in the Universiti Putra Malaysia (Graduate
Studies) Rules 2003 (Revision 2012-2013) are adhered to.
Signature:
Name of Chairman of
Supervisory
Committee:
Signature:
Name of Member of
Supervisory
Committee:
Signature:
Name of Member of
Supervisory
Committee:
Signature:
Name of Member of
Supervisory
Committee:
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TABLE OF CONTENTS
Page
ABSTRACT i
ABSTRAK iii
ACKNOWLEDGEMENTS v
APPROVAL vi
DECLARATION viii
LIST OF TABLES xvi
LIST OF FIGURES xvii
CHAPTER
1 INTRODUCTION 1
1.1 General 1
1.2 Background and Earlier work 3
1.3 Statement of the Problem 6
1.4 Identified Gaps 6
1.5 Objectives 6
1.6 Scope and Limitations of the Work 7
1.7 Layout of the Thesis 8
2 REVIEW OF LITERATURE 9
2.1 Introduction 9
2.2 Response Modification Factor 10
2.2.1 Overstrength Factor 21
2.2.2 Ductility Reduction Factor 23
2.2.3 Redundancy Factor 26
2.3 Application of dampers in structures 28
2.4 Damping Factor 29 2.5 Discussion 31
3 METHODOLOGY AND MATERIAL 33
3.1 Introduction 33
3.2 Equivalent Lateral Load Analysis 34
3.2.1 Gravity Load Analysis 36
3.3 Response Modification Factor 37
3.3.1 Key Components of the R factor 38
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Miranda and Bertero’s Method 43
Krawinkler and Nassar’s Method 43
Newmark and Hall’s Method 44
3.3.2 Components of the Response Modification Factor Based on
ATC 19 46
3.3.3 Effect of the R Factor on the Design 48
3.3.4 Force-Displacement Response of Buildings 49
3.3.5 Response Modification Factor Procedure 50
3.3.6 Determination of the Approximate Fundamental Period of
Structure (second) 53
3.4 Non-linear Static Analysis 54
3.4.1 Process of Non-linear Static Analysis 56
3.4.2 Capacity Curve of the Structures 56
3.5 Sample Analysis 59
3.6 Application of the Viscous Damper Device in Structures 60
3.6.1 Damper Properties Due to Retrofitting in the Soft Story 63
3.6.2 Damper Properties for Steel and Reinforced Concrete
Structures 63
3.7 Damping Factor 64
3.8 Proposed technique 65
3.9 Structural Design 68
3.9.1 Steel Frame Design Due to Retrofitting in the Soft Story 68
3.9.2 Steel Frame and Reinforced Concrete Frame Design 72 3.10 Discussion 74 3.11 Concluding Remarks 74
4 EVALUATION OF THE RESPONSE MODIFICATION FACTOR
FOR STEEL STRUCTURES RETROFITED BY VISCOUS DAMPER
DEVICE 75 4.1 Introduction 75
4.2 Structural design 75
4.3 Results of Analysis 76
4.4 Development of formulation for R factor by consider for damping
effect 83
4.5 Conclusion 85
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5 EVALUATION OF THE RESPONSE MODIFICATION FACTOR
FOR STEEL AND REINFORCED CONCRETE STRUCTURES
EQUIPPED WITH DAMPER DEVICES 86
5.1 Introduction 86
5.2 Structural Models 87
5.3 Damper Model 87
5.4 Steel Structures 88
5.4.1 Pushover Curve Analysis and Description 88
5.4.2 Value of the R Factor of Steel Structures according to
Different Damping Coefficient 95
5.4.3 Development of a Proper Formula for the R Factor 97
5.5 Reinforced Concrete Structures 102
5.5.1 Pushover Curve Analysis and Description 103
5.5.2 Value of the R factor for Reinforced Concrete Structures
according to Different Damping Coefficients 110
5.5.3 Development of the Proper Formula for the R Factor 110
5.6 Discussion 116 5.7 Conclusion Remarks 116
6 EXPERIMENTAL RESULTS AND VERIFICATION 117
6.1 Introduction 117 6.2 Steel Frame 117
6.2.1 Comparison of the Results and Verification 120
6.2.2 Location of Strain Gauges in Steel Frame Models 124
6.2.3 Strain Results from Bare Frame 125
6.2.4 Strain Results from the Frame Equipped with Damper Type 1
126
6.2.5 Strain Results from the Frame Equipped with Damper Type 2
127
6.3 Verification of the Response Modification Factor for the RC Frame
128
6.3.1 Location of the Strain Gauges in the RC Frame Models 133
6.3.2 Strain Results from Bare Frame 135
6.3.3 Strain Results from the Frame Equipped with Damper Type 1
136
6.3.4 Strain Results from the Frame Equipped with Damper Type 2
137
6.3.5 Comparison of Strain Results 139
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6.4 Conclusion 140
7 CONCLUSIONS AND RECOMMENDATIONS 141
7.1 General Conclusion 141 7.2 Specific Conclusion 141
7.2.1 Proposed Response Modification Factor for the Steel
Structures Retrofitted with Viscous Damper Device at the Soft
Story 141 7.2.2 Proposed Response Modification Factor for the Steel and
Reinforced Concrete Structures Equipped with Viscous
Damper Device 142 7.3 Suggestion for Future Research 142
REFERENCES 143 APPENDICES 153 BIODATA OF STUDENT 180
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LIST OF TABLES
Table Page
2-1 𝑅 ∗ &𝑇 ∗ values proposed by Riddell et al. (1989) 12 2-2 The evaluated response modification factor based on FEMA provisions 13 2-3 Experimental and numerical R factor parameters for models unit frames 21 2-4 α &β coefficients proposed by authors Lai & Biggs 23 2-5 𝑅 ∗ &𝑇 ∗ values proposed by authors Riddell, Hidalgo and Cruz 24 2-6 α ,a & b coefficients per strain –hardening ratio 24 2-7 Various coefficients according to structures post- yield behaviour 25 2-8 Bs & B1 values derived by Ramirez 30 2-9 Comparison of proposed factors in some US codes 31 3-1 Values of site coefficient 𝐹𝑎𝑎 (IBC, 2012) 35 3-2 Values of site coefficient𝐹𝑣𝑎 (IBC, 2012) 35 3-3 Seismic Zone Factor Z (IBC, 2012) 36 3-4 Seismic coefficient 𝐶𝑎 (IBC, 2012) 36 3-5 Seismic coefficient 𝐶𝑣 (IBC, 2012) 36 3-6 Gravity Loads 36 3-7 Sample Frame Analysis Quantities 37 3-8 Values of approximate period parameters 𝐶𝑡 54 3-9 Analysis data for 4 stories steel structures 60 3-10 Fluid viscous dampers properties Taylor (2006) 64 4-1 Sample frame analysis quantities 76 4-2 Response modification factor for three-story steel buildings retrofitted at soft story
, level 77 4-3 Response modification factor for five-story steel buildings retrofitted at soft story
, level 78 4-4 Response modification factor for ten-story steel buildings retrofitted at soft story
. level 80 4-5 Response modification factor in percentage for three, five and ten story steel
....... buildings retrofitted at soft story l 81 4-6 Value of N based on the percentage of bay equipped with damper 84 5-1 Sample Frame Analysis Quantities 87 5-2 Value of N based on the percentage of bay equipped with damper 97 5-3 Value of N based on the percentage of bay equipped with damper 99 5-4 Value of N based on the percentage of bay equipped with damper 100 5-5 Value of N based on the percentage of bay equipped with damper 100 5-6 Value of N based on the percentage of bay equipped with damper 101 5-7 Value of N based on the percentage of bay equipped with damper 101 5-8 Value of N based on the percentage of bay equipped with damper 102 5-9 Value of N based on the percentage of bay equipped with damper 102 5-10 Value of N based on the percentage of bay equipped with damper 111 5-11 Value of N based on the percentage of bay equipped with damper 112 5-12 Value of N based on the percentage of bay equipped with Damper 113 5-13 Value of N based on the percentage of bay equipped with damper 114 5-14 Value of N based on the percentage of bay equipped with damper 114 5-15 Value of N based on the percentage of bay equipped with damper 115
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5-16 Value of N based on the percentage of bay equipped with damper 115 5-17 Value of N based on the percentage of bay equipped with damper 115 6-1 Experimental Steel Member properties 118 6-2 Dampers properties . 118 6-3 Response modification factor for experimental test 121 6-4 Response modification factor for numerical analysis 121 6-5 R factor calculation for steel frames 123 6-6 Increasing trend of damped frames compared with bare frame 123 6-7 location & details of strain gauges 124 6-8 Reinforcement specification for RC elements 128 6-9 Response modification factor obtained from SAP2000 RC frames 129 6-10 R factor calculation for RC frames 129 6-11 Response modification obtained from ARCS3D for RC frames 130 6-12 Response modification factor for experimental RC frames 132 6-13 Increasing trend of damped frames compared with bare frame 133 9-1 Response Modification Factors proposed in NEHRP (2003) 153 9-2 Response Modification Factors proposed in NEHRP (2003) 154 9-3 Response Modification Factors proposed in 156 9-4 Importance factor (UBC, 1997) 159 9-5 Numerical Coefficient (UBC, 1997) 160 9-6 R and Ω0 factors for nonbuilding structures (UBC, 1997) 161 9-7 Soil profile types (IBC, 2012) 161 9-8 Near source factor 𝑁𝑎1 (IBC, 2012) 162 9-9 Near source factor 𝑁𝑣1 (IBC, 2012) 162 9-10 Seismic design category based on short period (0.2 second) response accelerations
, (IBC, 2012) 162 9-11 Seismic design category based on 1- second period response acceleration (IBC,
....... 2012) 162 10-1 Proposed response modification factor when C = 0.2568533 163 10-2 Proposed response modification factor when C = 0.2568533 163 10-3 Proposed response modification factor when C = 0.2568533 164 10-4 Proposed response modification factor when C = 0.2568533 164 10-5 Proposed response modification factor when C = 0.2568533 165 10-6 Proposed response modification factor when C = 2.0598211 165 10-7 Proposed response modification factor when C = 2.0598211 166 10-8 Proposed response modification factor when C = 2.0598211 166 10-9 Proposed response modification factor when C = 2.0598211 167 10-10 Proposed response modification factor when C = 2.0598211 167 10-11 Proposed response modification factor when C = 8.4060888 168 10-12 Proposed response modification factor when C = 8.4060888 168 10-13 Proposed response modification factor for C = 8.4060888 169 10-14 Proposed response modification factor when C = 8.4060888 169 10-15 Proposed response modification factor when C = 8.4060888 170 10-16 Proposed response modification factor when C = 0.2568533 171 10-17 Proposed response modification factor when C = 0.2568533 171 10-18 Proposed response modification factor when C = 0.2568533 172 10-19 Proposed response modification factor when C = 0.2568533 172 10-20 Proposed response modification factor when C = 0.2568533 173
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10-21 Proposed response modification factor when C = 2.0598211 173 10-22 Proposed response modification factor when C = 2.0598211 174 10-23 Proposed response modification factor when C = 2.0598211 174 10-24 Proposed response modification factor when C = 2.0598211 175 10-25 Proposed response modification factor when C = 2.0598211 175 10-26 Proposed response modification factor when C = 8.4060888 176 10-27 Proposed response modification factor when C = 8.4060888 176 10-28 Proposed response modification factor when C = 8.4060888 177 10-29 Proposed response modification factor when C = 8.4060888 177 10-30 Proposed response modification factor when C = 8.4060888 178
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LIST OF FIGURES
Figure Page
1-1 𝑅µ − 𝑇 − µ Curves (Newmark & Hall, 1982) 4 2-1 Pushover Curves according to Mondal et al. (2013) study 15 2-2 Experimental and numerical pushover response curve for the unbraced and
, braced model unit frames 16 2-3 The effect of number of storey on the R value of X-braced frames 16 2-4 Pushover curve for SCBF and OCBF frames 17 2-5 Comparison of incremental dynamic and static pushover roof displacement base ,
, Shear curve, 5 story T-SMRFs 17 2-6 Dynamic multimodal pushover curves compared with a standard pushover curve
, for a bridge where higher modes are significant 18 2-7 Dynamic multimodal pushover curves compared with a standard pushover curve
, for a bridge where the first mode is dominant 18 2-8 Response spectrum of selected ground motions 19 2-9 Horizontal capacity curve of MSB-braced frames (brace-induced column actions
, by SRSS accumulation approach) 20 2-10 Plots of Proposed Ductility Reduction Factors 26 2-11 Redundancy in Moment Resisting Frames 27 3-1 Overall schematic view of the method of the study 34 3-2 MDOF modification factors 44 3-3 Redundancy factor 46 3-4 Single degree of freedom system 48 3-5 Sample elastic pseudo-acceleration spectra for 5% damping 48 3-6 Use of R factors to reduce elastic spectral demands to the design force level
, Republished courtesy of the ATC; originally published in ATC-19 49 3-7 Sample base shear force versus roof displacement relationship 50 3-8 Response Modification Factor procedure based on ATC 19 51 3-9 Response Modification Factor procedure based on ATC 19 52 3-10 Pushover analysis strategy 54 3-11 lateral load patterns 55 3-1 General Structure Response 57 3-13 General Structure Response in compare With Damper 58 3-14 Demand Curve (ATC-40) 58 3-15 Pushover analysis for 4 stories steel structures 59 3-16 Taylor Fluid Damper (Taylor 2006) 61 3-17 Viscous Damper Installation 61 3-18 Los Angeles City Hall Damper Installation 62 3-19 Hsien Dien Hospital Damper Installation 62 3-20 San Francisco Civic Centre Damper Installation 62 3-21 Hotel Woodland-Installation of Damper 63 3-22 Flow chart of proposed technique 67 3-23 Structural arrangement of buildings in plan 68 3-24 (a) Example of structure (b) Example of parking 69 3-25 Frame Types 70 3-26 Various considered structures with different damper assignments 71
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3-27 Story & % of bay equipped with damper device 73 4-1 Pushover curve for three-story steel buildings retrofitted at soft story level 76 4-2 Response modification factor of three-story steel buildings retrofitted at soft story
, level 77 4-3 Pushover curve for five-story steel buildings retrofitted at soft story level 78 4-4 Response modification factor of five-story steel buildings retrofitted at soft story
, level 79 4-5 Pushover curve for ten-story steel buildings retrofitted at soft story level 79 4-6 Response modification factor of 10-story steel buildings retrofitted at soft story
, level 80 4-7 Pushover curve analysis 82 4-8 Compression response modification factor for all models 82 4-9 Percentage of damper effect on R in comparison to structures 83 4-10 Effect of damper device on R in percentage 83 4-11 𝑅𝑑 based on the percentage of bays equipped with damper device 84 5-1 Pushover analysis for 4 stories steel structures (C = 0.2568533) 90 5-2 Pushover analysis for 8 stories steel structures (C = 0.2568533) 90 5-3 Pushover analysis for 12 stories steel structures (C = 0.2568533) 90 5-4 Pushover analysis for 16 stories steel structures (C = 0.2568533) 91 5-5 Pushover analysis for 20 stories steel structures (C = 0.2568533) 91 5-6 Pushover analysis for 4 stories steel structures (C = 2.0598211) 92 5-7 Pushover analysis for 8 stories steel structures (C = 2.0598211) 92 5-8 Pushover analysis for 12 stories steel structures (C = 2.0598211) 92 5-9 Pushover analysis for 16 stories steel structures (C = 2.0598211) 93 5-10 Pushover analysis for 20 stories steel structures (C = 2.0598211) 93 5-11 Pushover analysis for 4 stories steel structures (C = 8.4060888) 94 5-12 Pushover analysis for 8 stories steel structures (C = 8.4060888) 94 5-13 Pushover analysis for 12 stories steel structures (C = 8.4060888) 94 5-14 Pushover analysis for 16 stories steel structures (C = 8.4060888) 95 5-15 Pushover analysis for 20 stories steel structures (C = 8.4060888) 95 5-16 Pushover analysis for 4 stories Reinforced Concrete structures 104 5-17 Pushover analysis for 8 stories Reinforced Concrete structures 104 5-18 Pushover analysis for 12 stories Reinforced Concrete structures 105 5-19 Pushover analysis for 16 stories Reinforced Concrete structures 105 5-20 Pushover analysis for 20 stories Reinforced Concrete structures 105 5-21 Pushover analysis for 4 stories Reinforced Concrete structures 106 5-22 Pushover analysis for 8 stories Reinforced Concrete structures 106 5-23 Pushover analysis for 12 stories Reinforced Concrete structures 107 5-24 Pushover analysis for 16 stories s Reinforced Concrete tructures 107 5-25 Pushover analysis for 20 stories Reinforced Concrete structures 107 5-26 Pushover analysis for 4 stories Reinforced Concrete structures 108 5-27 Pushover analysis for 8 stories Reinforced Concrete structures 108 5-28 Pushover analysis for 12 stories Reinforced Concrete structures 109 5-29 Pushover analysis for 16 stories Reinforced Concrete structures 109 5-30 Pushover analysis for 20 stories Reinforced Concrete structures 109 6-1 Assembly of experimental test 119 6-2 Steel frame without damper 119 6-3 Steel frame with damper type 1 119
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6-4 Steel frame with damper type 2 120 6-5 Pushover analysis for experimental steel frames 120 6-6 Pushover analysis for numerical steel frames 121 6-7 Pushover analysis for numerical and experiment analysis 122 6-8 Position of attached strain gauges 124 6-9 Strain results for steel bare frame 125 6-10 Experimental test for steel bare frame 125 6-11 Strain result for damper type 1 126 6-12 Experimental test for steel frame with damper type 1 126 6-13 Strain result for frame with damper type 2 127 6-14 Experimental test for steel frame with damper type 2 127 6-15 Reinforced concrete sections 128 6-16 Pushover analysis for numerical RC frames with SAP2000 129 6-17 Pushover analysis obtained from ARCS3D software for RC frames 130 6-18 Plastic hinge formation for RC frame in ARCS3D 130 6-19 RC frame without damper 131 6-20 RC frame with damper type 1 131 6-21 RC frame with damper type 2 132 6-22 Pushover analysis for experimental RC frames 132 6-23 Position of attached strain gauges for RC frames (Concrete) 134 6-24 Position of attached strain gauges for RC frames (Steel bar) 134 6-25 Strain results for RC bare frame (Steel bars) 135 6-26 Strain results for RC bare frame (Concrete surface) 135 6-27 Experimental test for RC bare frame 136 6-28 Strain results for RC frame with damper type 1 (Steel bars) 136 6-29 Strain results for RC frame with damper type 1 (Concrete surface) 137 6-30 Experimental test for RC frame with damper type 1 137 6-31 Strain results for RC frame with damper type 2 (Steel bars) 138 6-32 Strain results for RC frame with damper type 2 (Concrete surface) 138 6-33 Experimental test for RC frame with damper type 2 138 6-34 RC Strain results for G1 (Concrete surface) 139 6-35 Strain results for G8 (Concrete surface) 139 6-36 Strain results for G10 (Concrete surface) 139 6-37 Strain results for G1 (Steel bars) 140 6-38 Strain results for G3 (Steel bars) 140 9-1 Example of frame member label 158
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CHAPTER 1
INTRODUCTION
1.1 General
There are numerous natural hazards in the world but earthquake is a most destructive
natural hazards that can result in severe social and economic impact. Earthquake
engineering is a branch of engineering that is concerned with the estimation of
earthquake impacts. It has become a group involving seismologists, structural
engineer, architects, information technologists, geotechnical engineers, social scientists
and urban planners. The earthquake engineering society has been reassessing their
procedures since the past few years, in the wake of destructive earthquakes which
caused wide-ranging damages such as loss of life and property. These procedures
involve assessment of seismic force demands on the structure and then developing
design procedures for the structure to withstand the applied actions.
Due to economic and architectural constraints, engineers are compelled to design
structural systems which are cost effective and good-looking while adequately safe and
strong to satisfy inhabitants who will live and work in there. Scarce resources of
materials, man & machine power and time, especially in active seismicity areas;
mandate the basic objective of structural design as to design buildings with capability
to withstand due to strong ground shaking without collapse, but potentially with some
significant structural damage. At the present time structural design philosophy residing
in codes, emphasizes that complete safety and without damage, even in an earthquake
with a reasonable possibility of occurrence, not possible to be achieved. However,
letting some structural and non-structural damage, a high level of life safety can be
economically achieve in structural design by applying inelastic energy dissipation
system.
According to seismic codes, usually the design lateral strength is lower than the lateral
strength that structures required to stay in the elastic range. Maintaining the structure
inelastic range means that all structural and nonstructural members, subjected to lateral
motion, are assured to return to the initial state with no permanent deformations and
damages. In many cases preserving this state is far from being feasible and rational. On
the other hand, going beyond the elastic frontier in an earthquake event may lead to
yielding and cracking in members which can bring catastrophic results unless these
inelastic actions are limited to a certain degree. At this point utilizing inelastic behavior
definitely lowers the overall construction costs by reducing member sizes thus reducing
material amounts and construction time also providing ease of operability and erection.
Finding the balance in between is the major concern of a designer who is searching for
the optimum design by means of seizing the members and making use of different
structural systems.
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To utilize inelastic behavior in design, first of all, effects of earthquake induced motion
of the structure must be examined. Current engineering practice is capable of making
close approximations of the structural properties and properly put them into operation
of computer aided finite element analysis (formulation of the problem into a set of
mathematical equations). Such as the mass, stiffness and damping properties moreover
gravity loading conditions may be modelled. On the contrary the earthquake
characteristics are unique. The ground motion is unpredictable and irregular in
direction, magnitude and duration. Therefore past ground motion records serve as a
starting point to form a basic understanding of the characteristics of the excitation such
as the displacements, velocities, and accelerations. Structural engineering took
advantage of these records by various schemes. Subjecting a model directly to a given
motion record as known as Time History Analysis, may provide an insight to what will
actually happen during an excitation. In the process of structural design an iterative
progression takes place; this kind of simulation may be carried on for linear and non-
linear models with different records but such an approach needs huge computational
effort and time.
Consequently the Response Spectrum Method is preferred in routine application. The
most simplified and striped method for seismic design is the Equivalent Lateral (Static)
Load analysis which is easy to employ and the variables (relatively less in number) are
defined in the codes.
Plastic design for steel and ultimate strength design for reinforced concrete members
are based on inelastic performance of materials. For both design methodologies
statistical studies played an important role in defining load factors since members shall
not be designed for the working loads. However the overall inelastic behavior is
another matter which is also studied by numerous researchers up to present date.
Equivalent Lateral Load and Response Spectrum Analysis methods are the most used
methods to evaluate earthquake resistance and design of structures since they are
actually based on elastic static analysis. However, these are not universal analytical
tools to allow for the perfect consideration of very complicated building behavior
subjected to earthquake ground motions. A new procedure which called Performance
Based Design is rising now, which implementing the inelastic static analysis
(pushover) natively in design process, stepping ahead of above mentioned elastic
procedures which are most of the time leading to poor approximations of overall
behavior. The main approximation lies in the concept of Response Modification
Factors. This value approach to assign discrete modification factors for structural
systems may be very practical when it comes down to routine practice in engineering
but simplicity brings higher uncertainty.
To judge the nonlinear performance of building structures when earthquake happen,
Response modification factor will be used as seismic design parameters and since
seismic design codes try to reduce loads. Damages due to earthquake are a worry to
professionals, government officials, and the public. Nevertheless, we can neither
predict the incidence of an earthquake nor accurately, estimate its amplitude,
frequency contents, and duration. Also the structural capacity such as material
strength always cannot be exactly determined. Brittleness data are necessary for
seismic risk assessment studies to estimate earthquake-induced loss of life and
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property damage, also to estimate economic and to develop an emergency plan
that can be helpful. On the other hand, to design the new building structures,
nonlinear structural response should be obtained more or less by using Response
Modification Factor (Seya et al. 1992).
The structures should be designed in a way that they have resistant enough against
severe earthquakes. In other words, a structure not only should dissipate a behavior, but
also it should be able to control the deformation and transfer the force to foundation
through enough lateral stiffness in ground motions.
Earthquake loads that loaded to structural buildings are normally more than that they
are designed for. This kind of reduction in design load by seismic codes is throughout
the application of response modification factor (R-factor). During earthquakes,
structural building typically behaves elastically and then inelastic analysis is essential
for design. Inelastic dynamic analysis is slow and construal of its results need high
level of experience. Recently Pushover analysis has being used to estimate inelastic
response of structures.
Nowadays most of seismic design codes consist of the nonlinear response of a structure
implicitly through a ‘response reduction modification factor’ (R). R factor helps
designers to apply linear elastic force according to design while counting for nonlinear
behavior and deformation limits.
The purpose of this research is to evaluate the Response Modification Factors of
structures equipped with and without damper device and finalize the final formulation
for evaluation of Response Modification Factor for structures equipped with viscous
damper devices. In this study past observations and studies are reviewed. The response
modification factor(R) simply represents the ratio of the maximum lateral force. Since,
the response modification factor depends on overstrength, ductility and redundancy
factor.
According to this research value of ductility, overstrength and finally response
modification factor have been evaluated for steel structures and reinforced concrete
structures. Results illustrate that the value of response modification factor for structures
equipped with damper device is higher in compare when there is no damper device in
structures. It establish that the factors such as number of damper (percentage of bay
equipped with damper device), damping coefficient and even height of structure has
effect on value of R factor and finally formulation finalized.
1.2 Background and Earlier work
To design earthquake loads resisting element, force reduction factor will be needed.
Response Modification Factor proposed for the first time in ATC 3-06 (1978) that were
selected according to observed performance of buildings during past earthquakes also
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on the estimation of overstrength and damping, etc. (ATC-19, 1995). Response
Modification Factor consider as factors such as: overstrength, ductility and redundancy
factor base on ATC-19 (1995) and ATC-34 (1995).
In the procedure to estimate the seismic force of structural building, R factor acts as an
important part. As mentioned, Response Modification Factor consider base on ductility
(µ), over-strength (Ω) and redundancy (ρ), since the dynamic response of structural
activates these factors to reduce elastic force into inelastic loads beyond the elastic
range.
To consider the overly behavior of any structural building when it is subjected to a
particular one direction lateral loads, load Vs displacement curve will be used. When
parameters such as ductility (µ), over-strength (Ω) and redundancy (ρ) evaluated during
the loading procedures then the R factor can be developed and estimated. The response
modification factor will be estimated as:
𝑅 = 𝑅µ . 𝑅Ω . 𝑅𝜌 (1.1)
The ductility factor (𝑅µ) can be intended from the evaluation of the translation ductility
ratio. The relationship between the maximum elastic load (𝑉𝑢𝑒) and maximum inelastic
load (𝑉𝑢) can define the 𝑅µ factor, in same structural building under inelastic behavior.
The essential studies about Response Modification Factor due to ductility have been
done by Newmark and Hall (1982). Based on their study, ductility (𝑅µ) is sensitive to
the natural period (T) of the structure and even there are five period of different range
which𝑅µ can be found according to different value. 𝑅µ-µ-T for numerous ductility
ratios and periods illustrates in Figure 1-1.
Figure 1-1. 𝑹µ − 𝑻 − µ Curves (Newmark & Hall, 1982)
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According to International Building Code (IBC, 2000), to evaluate the design seismic
forces of structures which have been reduced, to evaluate the deflection amplification
factor (𝐶𝑑), to convert elastic lateral displacements to total lateral displacements,
Response Modification Coefficient (R) will be applied even including effect of
inelastic deformations. The values of R and 𝐶𝑑 arranged in the IBC (IBC, 2000) are
based on technical justification, observations of the performance of different structural
systems in previous strong earthquakes and on tradition (NEHRP, 2000). The
coefficient R is proposed to explanation for energy dissipation through the soil-
foundation system, over-strength and ductility (NEHRP, 2000).
Numerous researches have been performed on the selection of Response Modification
Factors (R) for the seismic design of structures. For example, Miranda presents a
review of different investigations on the coefficient R, which is described as a strength
reduction factor (Rµ). The study of Miranda suggests that the factor (Rµ) is mostly a
function of the displacement ductility (µ), the natural period of the structure (T) and the
soil conditions.
The structures should be designed in a way that they have resistant enough against
server earthquakes and they should also provide comfort and peace of mind of residents
who live there against weaker earthquakes. In other words, a structure not only should
dissipate a considerable amount of imported energy by ductile behavior, also it should
be able to control the deformations and transfer the force to foundation through enough
lateral stiffness in ground motions. The final capacity of dissipated energy in every
structure depends upon various factors such as: structures seismic parameters,
characteristic of earthquake records, the environment condition of construction and
place of structural building. Response modification factor is reflection of energy
dissipation within the boundary of plastic with respect to the lake of overturning and
big deformation in structure. Height of structure is a one of various parameters which is
effective on the response modification factor (Abdollahzadeh et al, 2011).
Design a structural building to stay elastic is uneconomical and not easy to legitimatize
for a rare earthquake type loading. Instead, it is an ordinary design principle to accept
some seismic damage in a building which it does not guide to the fall down of the
structure. The collapse will be avoided if the structural components are designed in a
ductile manner which is expected to resist the excessive forces.
Damping in structural building is provided by inherent damping which is comes from
structures and by supplementary damping that is by adding energy dissipation devices
to structures. In building codes to consider for the effect of supplemental damping on
the force and displacement response of buildings the damping reduction factor has been
accepted. Researcher such as; Newmark and Hall (1982), Wu and Hanson (1989),
Hanson et al. (1993) have done research on this effect.
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1.3 Statement of the Problem
The equivalent lateral force method is a well-known approach in structural engineering
because of the simplicity and reliability of calculating the lateral forces induced by an
earthquake. In the mentioned scheme, the response modification factor (R) is one of the
controversial issues to choose for a different structural system. Furthermore, the
application of a supplementary energy dissipation system, such as the viscous damper,
attracts much interest among engineers, experts, and researchers. A review of the
literature indicates that the effect of the viscous damper on overstrength, ductility, and
response modification factor is not available and that no information exists on the
evaluation of the R factor of steel and reinforced concrete structure equipped with a
viscous damper device. In addition, no report exists on the effect of the damping
coefficient and height of the structure on the R factor when a structure is equipped with
viscous dampers. Therefore, developing a new formula for evaluating the R factor is
vital for structures equipped with a viscous damper device, given the effect of the
number of dampers and damping coefficient in formulation.
1.4 Identified Gaps
i. No investigation exists on the procedure of performing the equivalent static
analysis of steel and reinforced concrete structures equipped with a viscous
damper device.
ii. No study exists on the evaluation of the R factor of steel and reinforced
concrete structures equipped with a viscous damper device.
iii. No procedure exists for the evaluation of the R factor for structures equipped
with a viscous damper device.
iv. No information exists on the effect of different parameters on the response
modification factors of steel and RC structures equipped with a viscous
damper device.
v. No investigation exists on the effect of the number of dampers, different
damping coefficients, and height of structures on the R factor.
1.5 Objectives
The general objective of this study is to evaluate the R factor of steel and reinforced
concrete structures equipped with viscous damper device.
Therefore specific objectives of this study are defined as:
i. To propose a computation algorithm for performing equivalent static analysis
on steel and reinforced concrete structures equipped with a viscous damper
device.
ii. To develop a new process of evaluating the ductility (µ), overstrength (Ω), and
response modification factor of steel and reinforced concrete structures
equipped with a damper device.
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iii. To evaluate the effect of the number of dampers, damping coefficient, and
height of structures of steel and reinforced concrete-framed buildings on the R
factor.
1.6 Scope and Limitations of the Work
To achieve the said objectives, the following steps have been conducted in the present
study:
The main aim of this study is to investigate the performance of steel structures and
reinforced concrete structures designed according to the UBC 1994 and IBC 2012
codes, with non-linear static analysis conducted to evaluate their lateral load carrying
capacity. Another aim is to assess the pertinent response modification factors based on
the literal definition given by past studies and to finalize their formulation.
A 5-bay structural system is created in both directions for the 4-, 8-, 12-, 16-, and 20-
story configurations of 5 different framing systems according to the number of the
damper device in each floor and 3 different values of the damping coefficient (C). A
total of 150 different structural models are analyzed to evaluate the R factors.
The resultant base shear is normalized by the equivalent lateral load proposed by the
code. The design sections are chosen from a European section list and dampers from
Taylor Devices are used in this research.
Pushover analysis is performed according to the Applied Technology Council (ATC)
19 (1995) prescriptions. Ultimate capacity pushover analysis is performed until the
system becomes an unstable mechanism. Brief information and modeling property data
are presented in every section to explain the benefits.
Some of the design conditions for the framing systems are predetermined, such as
seismic zone, soil group, building importance, and gravity loading. These values are
kept constant for all design cases.
The method of analysis for the response modification factor is implemented by
considering the effect of a viscous damper on the R factor.
Equivalent static analysis is selected for steel and reinforced concrete frame buildings
equipped with earthquake an energy dissipation system (viscous damper). Pushover
analysis is conducted to determined the overstrength and ductility reduction factors.
The response modification factors are evaluated in accordance to the different damping
coefficients, number of dampers, and height of structures.
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To conduct this research, a new formulation for the response modification factors is
proposed in the range of different damping coefficients.
1.7 Layout of the Thesis
The thesis has been divided into 7 chapters and the brief description about each chapter
is described as below:
Chapter 1 highlighted the importance and the definition for the present investigation
along with the objective and scope of the study.
The review of works related to response modification factor, application of R factor,
nonlinear static analysis covered in Chapter 2.
Chapter 3 present the methodology of the thesis. The modelling of structural frames,
different viscous dampers, pushover analysis and method of analysis for response
modification factor illustrated.
The effect of viscous damper on response modification factor base on proposes value
of R factor presented in Chapter 4 and 5. The final formulation for steel structures and
reinforced concrete structures equipped with viscous damper illustrated in this chapter.
Chapter 6 present the verification of response modification factor for steel and
reinforced concrete frames.
Major conclusion observed from the study carried out in this thesis presented in
Chapter 7.
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