ارزیابی پاسخ لرزه‌ای قاب‌های بتن‌آرمه پس از آتش‌سوزی به روش اجزای محدود

نوع مقاله : پژوهشی اصیل (کامل)

نویسندگان
مرتضی کمالوند
علی معصومی
امیرحسن بریمانی
دانشگاه خوارزمی
10.22034/23.2.9
چکیده
با توجه به اهمیت برآورد ظرفیت لرزه‌ای باقی‌مانده سازه‌ها پس از وقوع آتش‌سوزی، در این مقاله مطالعه عددی برپایه روش اجزای محدود روی قاب‌های‌ بتن‌آرمه انجام شد. مراحل شبیه­سازی عددی شامل دو گام مجزا است. در گام اول، فرآیند توزیع دما در عناصر تشکیل­دهنده قاب‌ها حین قرار گرفتن در معرض آتش به‌وسیله تحلیل انتقال حرارت شبیه‌سازی گردید. در گام دوم با بهره‌گیری از ویژگی‌های مکانیکی باقی‌مانده مصالح براساس بیشینه حرارت تجربه شده در گام قبل، رفتار نمونه‌ها تحت بارگذاری جانبی افزایشی (پوش آور) مورد ارزیابی قرار گرفت. نمونه‌های آزمایشگاهی مورد استفاده برای درستی‌آزمایی مدل عددی پیشنهادی، شامل دو قاب با نسبت ظرفیت خمشی تیر به ستون متفاوت است که هر قاب در دو حالت شامل قاب در دمای محیط به عنوان نمونه شاهد و قاب پس از قرار گرفتن در کوره، در نظر گرفته شد. در مرحله تحلیل انتقال حرارت، علاوه­بر ارزیابی مدل­های حرارتی مواد و شرایط مرزی تعریف شده، حساسیت پاسخ‌ها به دو پارامتر تأثیرگذار بر توزیع حرارت شامل درصد رطوبت بتن و قابلیت جذب انرژی حرارتی سطح بتن ارزیابی شد. در گام تحلیل مقاومت لرزه­ای باقی‌مانده، با توجه به مدل­های مختلف موجود برای منحنی تنش-کرنش بتن حرارت دیده، پاسخ لرزه‌ای قاب بر پایه سه مدل متداول بررسی شد. مقایسه نتایج عددی با داده های آزمایشگاهی در گام اول نشان داد که مدل عددی بهخوبی تاریخچه دما-زمان در عناصر قاب‌ها را پیش­بینی می­کند و درصد رطوبت 5/1 و ضریب قابلیت جذب انرژی سطح بتن برابر با 7/0 موافقت بهتری با داده‌های آزمایشگاهی دارد. نتایج مرحله تحلیل عملکرد لرزه‌ای نشان داد که بر اثر آتش‌سوزی 21 درصد مقاومت و 30 درصد جذب انرژی نمونه با تیرضعیف-ستون قوی، کاهش می‌یابد، در حالی‌که در نمونه با تیرقوی-ستون ضعیف، این مشخصه‌ها به‌ترتیب 35 و 49 درصد است.

کلیدواژه‌ها

موضوعات

عنوان مقاله English

Evaluation of the Post-fire Seismic Response of Reinforced Concrete Frames by Finite Element Method

نویسندگان English

M. Kamalvand
A. Massumi
A. Barimani
Kharazmi University
چکیده English

Accidental fire can be a catastrophe for engineering constructions, especially in building structures. Among structures made of various engineering materials exposed to fire, the reinforced concrete (RC) structures show better performance against fire, due to lower relative thermal conductivity, higher specific heat capacity of concrete, and slower reduction of concrete mechanical characteristics compared with other types of the structure materials. However, in case of severe fire exposure, the RC structures may experience serious structural damage due to the explosive concrete spalling resulting in a high-temperature rise in the reinforcing rebars and relatively large deformation with very limited residual bearing capacity. Although the explosive spalling and significant loss of the cross-sectional area of RC structural elements is a sign of severe damage to these elements, the reduction of mechanical properties of the materials and the performance level of the structure due to chemical reactions such as C-S-H gel dehydration caused by penetration of high temperature in the interior layers of the element cross-section may not be easily visible and evaluated.

A building that has experienced a fire, cannot be exploited for immediate reuse, even when the fire is completely extinguished until load bearing capacity of its members is determined. Therefore, it is necessary to determine the residual capacity of structural elements through logical engineering methods to facilitate the re-operation or development of strengthening methods in the fired RC structures.

Due to the importance of recognizing the behavior and residual seismic capacity of the structures exposed to fire, in this paper, a numerical study based on the nonlinear finite element method has been performed on RC frames. In the first step of the research, the process of heat distribution in the frames located in the furnace based on the previous experimental study is simulated by heat transfer analysis. All three modes of heat transfer including convection, radiation, and conduction were considered in this analysis and the effect of moisture content and emissivity coefficient was evaluated. In the second step, using the residual mechanical properties of materials (reinforcing steel rebar and concrete) based on the maximum heat experienced in the previous step, the seismic behavior of RC frames is evaluated using the pushover analysis. The experimental RC specimens used to validate the proposed numerical model consist of two frames with various beam/column bending capacity ratios in two cases, at room temperature and after being exposed to fire. Due to the different relationships available to determine the residual compressive strength of concrete, the seismic response of the frame was investigated based on three common relations Shi, Lie, and Schneider. The results showed that the proposed numerical analysis method has good accuracy in both steps of analysis and different models for estimating the residual compressive strength, despite some differences, have the ability to predict the post-fire performance of RC frames. It was also shown that for the RC frame specimen with the strong beam-weak column, the ratio of reduced post-fire load bearing capacity and energy absorption is higher.

کلیدواژه‌ها English

Reinforced Concrete Frame
Nonlinear finite element analysis
heat transfer analysis
residual capacity
Seismic behavior
[1] Butry D. T., Chapman R. E., Huang A.L. & Thomas D. S. 2012 A life-cycle cost comparison of exit stairs and occupant evacuation elevators in tall buildings. Fire Technology, 48, 155 –72.
[2] Kodur V. K. R. & Agrawal A. 2016 An approach for evaluating residual capacity of reinforced concrete beams exposed to fire. Engineering Structures, 110, 293-306.
[3] Felicetti R., Gambarova P. G. & Meda A. 2009 Residual behavior of steel rebars and R/C sections after a fire. Construction and Building Materials, 23, 3546-3555.
[4] Xu Y. Y., Wu B., Wang R. H., Jiang M. & Luo Y. 2013 Experimental study on residual performance of reinforced concrete beams after fire. Journal of Building Structures, 34 (8), 20-29.
[5] Yao Y. & Hu X. X. 2015 Cooling behavior and residual strength of post-fire concrete filled steel tubular columns. Journal of Constructional Steel Research, 112, 282-292.
[6] He A. Liang Y. & Zhao O. 2020 Behaviour and residual compression resistances of circular high strength concrete-filled stainless-steel tube (HCFSST) stub columns after exposure to fire. Engineering Structures, 203, 109897.
[7] Hajiloo H. & Green M. 2018 Post-fire residual properties of GFRP reinforced concrete slabs: A holistic investigation. Composite Structures, 201, 398–413.
[8] Wang Y. et al. 2020 Residual properties of three-span continuous reinforced concrete slabs subjected to different compartment fires. Engineering Structures, 208, 110352.
[9] Jadooe A., Al-Mahaidi R. & Abdouka K. 2017 Experimental and numerical study of strengthening of heat-damaged RC beams using NSM CFRP strips. Construction and Building Materials, 154, 899-913.
[10] Kodur V. K. R & Agrawal A. 2016 An approach for evaluating residual capacity of reinforced concrete beams exposed to fire. Engineering Structures, 110, 293-306.
[11] Bai L. L. & Wang Z. Q. 2011 Residual bearing capacity of reinforced concrete member after exposure to high temperature. Advanced Materials Research, 368–373, 577–81.
[12] Ozbolt J., Bosnjak J., Periskic G. & Sharma A. 2014 3D numerical analysis of reinforced concrete beams exposed to elevated temperature. Engineering Structures, 58, 166–174.
[13] Kumar A. & Kumar V. 2003 Behavior of RCC beams after exposure to elevated temperatures. Journal of the Institution of Engineers (India), Civil Engineering Division, 84, 165–170.
[14] Massumi A., Sedighi k. & Zifan N. 2019 A novel nondestructive method to quantify fire-induced damage in RC structures based on their dynamic behavior, Materials and Structures, 52(132), 1-14.
[15] ASTM E119-11a. Standard methods of fire test of building construction and materials. West Conshohocken, 2011.
[16] Li L. Z., Liua X., Yu J. T., Lu Z. D., Su M. N., Liao J.H. & Xia M. 2019 Experimental study on seismic performance of post-fire reinforced concrete frames. Engineering Structures, 179, 161-173.
[17] Xiao J.Z., Li J. & Huang Z. F. 2008 Fire response of high-performance concrete frames and their post-fire seismic performance. ACI Structural Journal, 105(5), 531 –40.
[18] BSI (2002) BS EN 1991-1-2:2002, Eurocode 1: Actions on structures–Part 1-2: General actions-actions on structures exposed to fire. European Standard
[19] Purkiss J. A. 2007 Fire safety engineering design of structures. 2nd edition. Oxford: Butterworth-Heineman.
[20] BSI (2004) BS EN 1992-1-2:2004, Eurocode 2-Design of concrete structures-Part 1–2: General Rules-Structural fire design. Structural Fire Design. BSI, London, UK.
[21] BSI (2005) BS EN 1993-1-2:2005, Eurocode 2-Design of steel structures-Part 1–2: General Rules-Structural fire design. Structural Fire Design. BSI, London, UK.
[22] Lubliner J., Oliver J. & Onate E. 1989 Plastic-Damage Model for Concrete. Solids and Structures, 25(3), 299-329.
[23] Lee J. & Fenves G. L. 1998 Plastic-damage model for cyclic loading of concrete structures. Engineering Mechanics (ASCE), 124(8) ,892–900.
[24] Saenz L. P., Discussion of Paper by Desai P. & Krishnan S. 1964 Equation for stress-strain curve of concrete. Journal of ACI, 61(9), 1229-35.
[25] Bischoff P. H. & Paixao R. 2004 Tension stiffening and cracking of concrete reinforced with glass fiber reinforced polymer (GFRP) bars. Canadian Journal of Civil Engineering, 31(4), 579-588.
[26] Schneider U. 1985 Properties of materials at high temperatures concrete. Kassel, Germany: Gesamthochsch-Bibliothek.
[27] Shi X., Tan T. H., Kang H. T. & Guo Z. 2002 Concrete constitutive relationships under different stress-temperature paths. Structural Engineering, 1511-1518.
[28] Law A. & Gillie M. 2008 Load Induced Thermal Strains, Implications for Structural Behaviour. Singapore, China, SiF 2008 Organising Comittee.
[29] Lie T. T. & Kodur V. K. R. 1996 Thermal and mechanical properties of steel-fiber-reinforced concrete at elevated temperatures. Canadian Journal of Civil Engineering, 23, 511-517.
[30] Ritter W. 1899 Die bauweise hennebique (In German), Schweizerische Bauzeitung, 7(33) 59–61.
[31] Hognestad E. 1951 A study of combined bending and axial load in reinforced concrete members. Bulletin No.399, University of Illinois Engineering Experiment Station, Urbana, I.
[32] Schneider U. 1988 Concrete at high temperatures-a general review. Fire Safety Journal, 13, 55-68.
[33] Franssen J. M. 2004 Plastic analysis of concrete structures subjected to fire. Proc. of the Workshop on Fire Design of Concrete Structures, Milano, Italy, December 2004.
[34] Hu C. P., Xu Y. Y., Luo Y., Zheng Y. L. & Lin B. L. 2014 Experimental study on tensile strength of concrete after high temperature. Journal of Huaqiao University (Natural Science), 35(2), 196-201.
[35] Shen R., Feng L. Y & Rong K. 1991 Evaluation of rebar mechanical properties after high temperature (Fire Exposure). Sichuan Building Science, 02, 5-9.
[36] Tao Z. & Ghannam M. 2013 Heat transfer in concrete-filled carbon and stainless-steel tubes exposed to fire, Fire safety journal, 61, 1-11.
[37] Aulic A. 1973 Fire resistance of concrete-Filled steel columns, Byggmastaren 9, 8-12.
مهندسی عمران مدرس
دوره 23، شماره 2
خرداد و تیر 1402
صفحه 135-150