بررسی رفتار دیوار برشی فولادی متشکل از دو ورق تخت و یک ورق موجدار با فولاد LYP
محورهای موضوعی : آنالیز سازه - زلزله
لیلا حسین زاده
1
,
بهنام بابایی
2
1 - گروه مهندسی عمران، واحد تبریز، دانشگاه آزاد اسلامی، تبریز، ایران
2 - گروه مهندسی عمران، واحد تبریز، دانشگاه آزاد اسلامی، تبریز، ایران
کلید واژه: دیوار برشی فولادی, فولاد با حد تسلیم پایین , سختي, مقاومت, جذب انرژي,
چکیده مقاله :
دیوار برشی فولادی، سیستم مقاوم در برابر بارهای جانبی است که در دهههای اخیر مورد توجه قرار گرفته است. دیوارهای برشی فولادی به دو صورت دیوارهای سختشده و سخت نشده کاربرد دارند. هرچند رفتار پس کمانشی دیوار برشی فولادی باعث باربری پس از کمانش میشود، اما همواره این کمانش ورق مطلوب نیست. یکی از راهحلهای مفید جهت از بین بردن کمانش جانبی، استفاده از دیوارهای با ورق موجدار است. در این تحقیق رفتار دیوار برشی فولاد متشکل از دو ورق تخت و یک ورق موجدار در دو حالت فولاد معمولی (A36) و فولادی با حد تسلیم پایین(LYP) مطالعه شد. استفاده از فولاد با حد تسلیم پایین، عملکرد لرزهای سیستم دیوار برشی فولادی را بهبود بخشید. با در نظر گرفتن تغییرات ضخامت ورقها و نسبت ابعادیهای مختلف، فولاد LYP، مقادیر سختی، مقاومت و جذب انرژی را حدود 74%، 51% و 36% افزایش داد. میزان تاثیر افزایش ضخامت ورق در پارامتر سختی برای پانل برشی با فولاد A36 بیشتر از فولاد LYP است. افزایش ضخامت ورقها، سختی، مقاومت نهایی و جذب انرژی سیستم را برای فولاد A36 به ترتیب حدود 45%، 35% و 44% و برای فولاد LYP حدود35%، 62% و 53% افزایش داد و همنین افزایش نسبت ابعادی سختی، مقاومت و جذب انرژی سیستم را برای فولاد A36 به ترتیب 51%، 36% و 38% و برای فولاد LYP به ترتیب 52%، 46% و 49% افزایش داد.
The steel shear wall is a lateral load resistant system that has received attention in recent decades. Steel shear walls are used in two ways: hardened and unhardened walls. Although the post-buckling behavior of the steel shear wall causes the post-buckling loading but this plate buckling is not always desirable. One of the useful solutions to prevent lateral buckling is the use of walls with corrugated plates. In this research, the behavior of a steel shear walls consisting of two flat plates and one corrugated plate was studied in two states of conventional structural steel (A36) and low yield point steel(LYP). The use of low yield strength steel improved the seismic performance of the steel shear wall system. Taking into account the changes in the thickness of the plate and different aspect ratio, LYP steel increased the values of stiffness, ultimate strength, and energy absorption by about 74%, 51% and 36%. The effect of increasing the plate thickness on the stiffness parameter for infill panel with A36 steel is more than that of LYP steel. Increasing the thickness of the plates increased the stiffness, ultimate strength, and energy absorption of the system for A36 steel by about 45%, 35%, and 44%, and for LYP steel by about 35%, 62%, and 53%, and also increase in the dimensional ratio of stiffness, strength and increased the energy absorption of the system for A36 steel by 51%, 36% and 38% respectively and for LYP steel by 52%, 46% and 49% respectively.
]1[ صبوری، سعید، سیستمهای مقاوم در برابر بارهای جانبی مقدمهای بر دیوارهای برشی فولادی، نشر انگیزه، چاپ اول، 1380.
[2] Elgaaly, M, Caccese, V, Post-buckling Behavior of Steel-Plate Shear Walls under Cyclic Loads588-605., ASCE, Journal of Structural Eng., 1993; 119(2):
[3] Xue, M, Lu, Le-Wu, Monotonic and Cyclic Behavior of Infilled Steel Shear Panels, Proceedings of the 17th Czech and Slovak International Conference on Steel Structures and Bridges, Bratislava, Slovakia, 1994.
[4] Alinia, M.M, Dastfan, M, Cyclic behavior, deformability and rigidity of stiffened steel shear panels, Journal of Constructional Steel Research, 2006; 63: 554-563.
[5] Sabouri-Ghomi, S, Sajjadi, R, Experimental and theoretical studies of steel shear wall with and without stiffeners, Journal of Constructional Steel Research,2012; 75: 152-159.
[6] Alavi, E, Nateghi, F, Experimental study on diagonally stiffened steel plate shear walls with central perforation, Journal of Constructional Steel Research, 2013; 89: 9-20.
[7] Shojaeifar, H, Maleki, A, Lotfollahi-Yaghin, M.A, Improving the seismic resistance of structure using FRP/steel shear walls, International Journal of Engineering, 2020; 33(1): 55-67.
[8] Khaloo, A, Ghamari, A, Foroutani, M, On the design of stiffened steel plate shear wall with diagonal stiffeners considering the crack effect, Structures, 2021; 31: 828-841. https://doi.org/10.1016/j.istruc.2021.02.027.
[9] Ebadi-Jamkhaneh, M, Kontoni, D-P N, Numerical finite element investigation of thin steel shear walls retrofitted with CFRP layers under reversed cyclic loading Journal of Building Pathology and Rehabilitation, 2022; 62(7): 1-10. https://doi.org/10.1007/s41024-022-00200-2.
[10] Maleki, A, Donchev, T, Hadavinia, H, Limbachiya, M, Improving the seismic resistance of structure using FRP/steel shear walls, The 6th International Conference on FRP Composites in Civil Engineering, 1 January, 2012.
[11] Bergman, S, Reissner, H, Neuere probleme aus der flugzeugstatik–über die knickung von wellblechstreifen bei schubbeanspruchung, Zeitschrift für Flugzeugtechnik und Motorluftschiffahrt. 1929; 20(18): 475-81.
[12] Elgaaly M, Hamilton RW, Seshadri A, Shear strength of beam with corrugated webs, ASCE, Journal of Structural Engineering, 1996; 122(4): 390–398.
[13] Elgaaly M, Seshadri, A, Steel Built-up Girders with Trapezoidally Corrugated Webs, AISC,
Engineering Journal, 1998; 35(1): 1–11. https://doi.org/10.62913/engj.v35i1.694
[14] Bergfelt, A, Leiva, L, Shear buckling of trapezoidally corrugated girders webs, Chalmers University of Technology Publ.s., 1986; 49. https://doi.org/10.5169/seals-38283
[15] Abbas, HH, Sause, R, Driver R, Shear strength and stability of high performance steel corrugated web girders, Proceedings - Annual Stability Conference, Structural Stability Research Council, 2002; 361–87.
[16] Hosseinzadeh, L, Mofid, M, Aziminejad, A, Emami, F, Elastic interactive buckling strength of corrugated steel shear wall under pure shear force, The Structural Design of Tall and Special Buildings, 2017; 26(8), e1357.
[17] Stojadinovic, B, Tipping, S, Structural Testing if Corrugated Sheet Steel Shear Walls, Nineteenth International Specialty Conference on Cold-Formed Steel Structures, St. Louis, Missouri, U.S.A, October 14, 2008.
[18] Emami, F, Mofid, M, On the hysteretic behavior of trapezoidally corrugated steel plate shear walls, The Structural Design of Tall and Special Buildings, 2012; 23 (2): 94–104.
[19] Emami, F, Mofid, M, Vafai, A, Experimental study on cyclic behavior of trapezoidally corrugated steel plate shear walls, Eng. Struct., 2013; 48: 750–762.
[20] Bahrebar, M, Zaman Kabir, M, Zirakian, T,
Hajsadeghi, M, Structural performance assessment
of trapezoidally-corrugated and centrally-perforated
steel plate shear walls, Journal of Constructional Steel Research, 2016; 122: 584-594.
[21] Hosseinzadeh, L, Mofid, M, Emami, F, Experimental investigation on the behavior of corrugated steel shear wall subjected to the different angle of trapezoidal plate, The Structural Design of Tall and Special Buildings, 2017; 26(17), e1390.
[22] Hosseinzadeh, L, Ghamari, A, Investigation of the effect of trapezoidal infill plate angle on the behavior of the corrugated steel shear walls – An experimental and numerical study, Steel Construction, 2023; 17(1): 43-52.
https://doi.org/10.1002/stco.202200048.
[23] C. Dou, Y. Pi, W. Gao, Shear resistance and post-buckling behavior of corrugated panels in steel plate shear walls,Thin-Walled Structures, 2018; 131: 816–826.
[24] Tong, J, Guo, Y, Zuo, J, Goa, J, Ultimate shear resistance and post-ultimate behavior of double corrugated-plate shear walls. Journal of Constructional Steel Research, 2020; 165: 105895. https://doi.org/10.1016/j.jcsr.2019.105895.
[25] Tong, J, Guo, Y, Zuo, J, Goa, J, Experimental and numerical study on shear resistant behavior of double-corrugated-plate shear walls, Thin-Walled Structures, 2020; 147: 106485. https://doi.org/10.1016/j.tws.2019.106485
[26] Broujerdian, V, Ghamari, A, Abbaszadeh, A, Introducing an efficient compound section for steel shear wall using flat and corrugated plates, Structures, 2021; 33: 2855-2871. https://doi.org/10.1016/j.istruc.2021.06.027
[27] Nakashima, M, Strain-Hardening Behavior of Shear Panels Made of Low-Yield Steel. I: Test, Journal of Structural Engineering, ASCE, 1995; 121: 1742-1749.
[28] Tadeh Zirakian, a, Jian Zhang, b, Structural performance of unstiffened low yield point steel plate shear walls, Journal of Constructional Steel Research, 2015; 112 :40-50.
[29] Gorji Azandariani M, Gholhaki M, Kafi M, Experimental and numerical investigation of low-yield-strength (LYS) steel plate shear walls under cyclic loading, Eng Struct, 2020; 203:109866.
[30] Hosseinzadeh, L, Kontoni, D-P N, Babaei, B, Investigation of the Behavior of Steel Plate Shear Walls Considering Double Corrugated Low-Yield-Point Steel Infill Plate, International Journal of Civil Engineering, 2023; 138. https://doi.org/10.1007/s40999-023-00855-z
[31] AC 154, Cyclic racking shear tests for metal-sheathed shear walls with steel framing, ICC Evaluation Service, INC., 2008. www.icc-es.org