钢管混凝土排柱剪力墙非线性性能分析
|
摘要
本文研究一种新型的结构“钢管混凝土排柱剪力墙”,即将混凝土填充于钢管内,再将钢管混凝土柱均匀排布到混凝土墙里,与混凝土墙体组合为一体。这种结构已经在广东博物馆新馆结构中应用,但国内对它的研究还鲜见文献。
本文回顾了国内钢-混凝土混合结构在高层中的应用,总结了钢管剪力墙的研究现状。利用ABAQUS软件对钢管混凝土排柱剪力墙进行了有限元数值模拟计算,考虑轴压比,混凝土强度等级,高宽比对钢管混凝土排柱剪力墙受力性能的影响,并一一与普通钢筋混凝土剪力墙作比较。分析了各工况条件下钢管混凝土排柱剪力墙与普通混凝土剪力墙在单调荷载作用下的荷载-位移曲线,在循环荷载作用下的滞回性能。
研究结果表明:在相同的含钢率下,钢管混凝土排柱剪力墙的承载能力比普通钢筋混凝土剪力墙大的多。轴压比对钢管混凝土排柱剪力墙的极限承载力影响不明显,随着轴压比的增大,延性先增大后降低。随着混凝土强度等级在一定范围内的提高,组合墙体的承载力提高。高宽比的减小,可以极大的提高宽比为2.0体的稳定性,进而提高其承载力。普通钢筋混凝土墙体一般从角部迅速破坏,钢管混凝土排柱剪力墙的破坏始于非约束区墙体,因此建议实际施工中应加强非约束区受力钢筋的作用。钢管混凝土排柱剪力墙的耗能能力大于钢筋混凝土剪力墙的耗能能力。由于混凝土是脆性材料,混凝土总是先于钢管屈服前破坏,虽然钢管不能充分的发挥其应有的作用,但是混凝土破碎后,依旧可以由钢管承担压力与水平作用力,有力的延缓了结构整体破坏的时间,所以应加强钢筋对混凝土的约束作用。
A new structure is proposed, concrete-filled steel tube shear wall. With theconcrete filling in tubes, concrete filled steel tube columns are even arranged in theshear wall. The application is obvious in the Guangdong province museum. But theresearch is very little.
It is introduced about the composite shear walls in High-Rise Building andanalyzed the existing related research. Grounded on the theoretical analysis, we makeuse of ABAQUS to conduct the finite element analysis of the concrete-filled steel tubeshear wall. For considering the behavior influence of the concrete-filled steel tubeshear wall by becoming type of axial load ratio、concrete grades, the ratio of height tothickNess,it is compared with the reinforced concrete shear wall. It is analyzed thatthe Curves of Reaction Force and Displacement under the uniaxial compress, theHysteresis Curves of the composite structure under cyclic loading with different loadsconditions.
The main conclusions are:with the increase of the axial compression ratio,theultimate load of the composite wall has little influence; while the ductility increases atfirst then decreases within a certain range. With increasing of the concrete grades,there are significant effects on bearing capacity. With the decreasing of the ratio ofheight to thickNess, the shear wall is more stable. And the capacity is large, too. Dueto the damage behavior, it is destroyed from the corner of the reinforced concrete shearwall, while the damage of the concrete-filled steel tube shear wall stars from the notrestraint. Therefore we advise that it is a must to strengthen the main reinforcement inthe not restraint. Energy dissipation capacity of the concrete-filled steel tube shearwall is more superior than the reinforced concrete shear wall.Because concrete isbrittle material, concrete is always yield before the destruction of the steel tube,although the tube can not play its due role fully. Otherwise the steel tube can still beundertaken the upper pressure and horizontal forces when the concrete is crushing.Dueto this property, it is delayed the overall damage to structure. In consequence, it shouldbe to strengthen reinforced concrete constraints.
本文回顾了国内钢-混凝土混合结构在高层中的应用,总结了钢管剪力墙的研究现状。利用ABAQUS软件对钢管混凝土排柱剪力墙进行了有限元数值模拟计算,考虑轴压比,混凝土强度等级,高宽比对钢管混凝土排柱剪力墙受力性能的影响,并一一与普通钢筋混凝土剪力墙作比较。分析了各工况条件下钢管混凝土排柱剪力墙与普通混凝土剪力墙在单调荷载作用下的荷载-位移曲线,在循环荷载作用下的滞回性能。
研究结果表明:在相同的含钢率下,钢管混凝土排柱剪力墙的承载能力比普通钢筋混凝土剪力墙大的多。轴压比对钢管混凝土排柱剪力墙的极限承载力影响不明显,随着轴压比的增大,延性先增大后降低。随着混凝土强度等级在一定范围内的提高,组合墙体的承载力提高。高宽比的减小,可以极大的提高宽比为2.0体的稳定性,进而提高其承载力。普通钢筋混凝土墙体一般从角部迅速破坏,钢管混凝土排柱剪力墙的破坏始于非约束区墙体,因此建议实际施工中应加强非约束区受力钢筋的作用。钢管混凝土排柱剪力墙的耗能能力大于钢筋混凝土剪力墙的耗能能力。由于混凝土是脆性材料,混凝土总是先于钢管屈服前破坏,虽然钢管不能充分的发挥其应有的作用,但是混凝土破碎后,依旧可以由钢管承担压力与水平作用力,有力的延缓了结构整体破坏的时间,所以应加强钢筋对混凝土的约束作用。
A new structure is proposed, concrete-filled steel tube shear wall. With theconcrete filling in tubes, concrete filled steel tube columns are even arranged in theshear wall. The application is obvious in the Guangdong province museum. But theresearch is very little.
It is introduced about the composite shear walls in High-Rise Building andanalyzed the existing related research. Grounded on the theoretical analysis, we makeuse of ABAQUS to conduct the finite element analysis of the concrete-filled steel tubeshear wall. For considering the behavior influence of the concrete-filled steel tubeshear wall by becoming type of axial load ratio、concrete grades, the ratio of height tothickNess,it is compared with the reinforced concrete shear wall. It is analyzed thatthe Curves of Reaction Force and Displacement under the uniaxial compress, theHysteresis Curves of the composite structure under cyclic loading with different loadsconditions.
The main conclusions are:with the increase of the axial compression ratio,theultimate load of the composite wall has little influence; while the ductility increases atfirst then decreases within a certain range. With increasing of the concrete grades,there are significant effects on bearing capacity. With the decreasing of the ratio ofheight to thickNess, the shear wall is more stable. And the capacity is large, too. Dueto the damage behavior, it is destroyed from the corner of the reinforced concrete shearwall, while the damage of the concrete-filled steel tube shear wall stars from the notrestraint. Therefore we advise that it is a must to strengthen the main reinforcement inthe not restraint. Energy dissipation capacity of the concrete-filled steel tube shearwall is more superior than the reinforced concrete shear wall.Because concrete isbrittle material, concrete is always yield before the destruction of the steel tube,although the tube can not play its due role fully. Otherwise the steel tube can still beundertaken the upper pressure and horizontal forces when the concrete is crushing.Dueto this property, it is delayed the overall damage to structure. In consequence, it shouldbe to strengthen reinforced concrete constraints.
引文
[1]廖飞宇,陶忠,韩林海.钢-混凝土组合剪力墙抗震性能研究简述[J].地震工程与工程振动,2006,26(5):129-135.
[2]汪大绥,周建龙.我国高层建筑钢-混凝土混合结构发展与展望[J].建筑结构学报,2010,31(6):62-70.
[3]王华林,陈星,李娜.中山古镇灯都商厦体形复杂超高层结构设计关键技术[J].建筑结构,2011,41(5):33-37.
[4]徐朔明,任咏芳.上海环球金融中心结构设计简析[J].建筑钢结构进展,2003,5(4):14-20.
[5]叶可明,范庆国.上海金茂大厦施工技术[J].中国工程科学,2000,2(10):42-49.
[6]丁浩民,巢斯,赵昕等.上海中心大厦结构分析中若干关键问题[J].建筑结构学报2010,31(6):122-131.
[7]高琳,周定,王云丹等.广州新电视塔基础设计[J].建筑结构,2011,41(1):103-106.
[8]陆建新.深圳京基金融中心简介[J].施工技术,2010,39(8):136-140.
[9]苏广洪葛洪军.广州珠江新城西塔斜交钢管混凝土柱施工技术,2009,38(12):1-4.
[10]钢骨混凝土结构技术规程[M].冶金工业出版社,2007.
[11]王连广钢与混凝土组合结构理论与计算[M].科学出版社,2005.
[12] Driver Robert G,Kulak Geoffrey L,Kenned D J Laurie,eta.1Cyclictest offour-story steel plateshearwall[J]. Journal ofStructural Engineering,1998,124(2):l12-120.
[13] Abolhassan Astaneh—Ash,QiuhongZhao.Cyclic behavior ofsteel shearwallsystems.Annual StabilityConference[C].Seattle:Structural Stabil.ity ResearchCouncil,2002.
[14]王敏,曹万林,张建伟,等.不同轴压比下钢管混凝土边框组合剪力墙抗震性能研究[J].世界地震工程,2008,24(2):34.38.
[15]王敏,曹万林,张建伟,等.钢管混凝土边框高强混凝土组合剪力墙抗震性能研究[J].世界地震工程,2008,28(2):92.97.
[16]曹万林,王敏,王绍合,等.矩形钢管混凝土边框组合剪力墙及筒体结构抗震研究[J].工程力学,2008,25(S1):66.78.
[17]曹万林,杨亚彬,张建伟等.圆钢管混凝土边框内藏桁架剪力墙抗震性能[J].东南大学学报(自然科学版),2009,39(6):208-212.
[18]廖飞宇,陶忠.带不同类型边框柱的剪力墙力学性能试验[J].工业建筑,2007,37(12):31-34.
[19]梁兴文,杨鹏辉,崔晓玲等.带端柱高强混凝土剪力墙抗震性能试验研究[J].建筑结构学报,2010,31(1):23-32.
[20]李娜,王华林,陈星.广东省博物馆新馆节点设计及新技术运用[J].建筑结构,2007,37(9):52-56.
[21]赖鸿立,焦柯,陈星.钢管混凝土排柱剪力墙抗震性能分析[C].第二十届全国高层建筑结构学术会议论文集,2008:826-831.
[22]李亚娥,徐利华.内置钢管混凝土排柱剪力墙框筒结构的抗震性能分析[J].甘肃科学学报.2010,22(2),:87-90.
[23]李惠,徐强,吴波.钢管混凝土耗能低剪力墙[J].哈尔滨建筑大学学报,2000,33(2):18-23.
[24] Fei-Yu Liao,Lin-Hai Han and Zhong Tao.钢管混凝土圆柱和钢筋混凝土剪力墙组合结构的抗震性能研究[J].钢结构,2009,24(9):84
[25] Kwan A K H,Dai H,Cheung Y K.Non-Linear Seismic Response of ReinforcedConcrete Slit Shear Walls[J].Journal of Sound and Vibration1999,226(4):70l-718.
[26]蒋欢军,吕西林.沿竖向耗能剪力墙的低周反复荷载试验研究[J].工程力学增刊,1997:649-654.
[27]戴航,陈贵.带水平短缝墙及低剪力墙的动力反应和耗能分析[J].东南大学学报,1992,22(5):58-65.
[28]王志惠,曹万林,张建伟等.高轴压比下内藏桁架组合中高剪力墙抗震性能试验研究[J].地震工程与工程振动,2007,25(3):60-66.
[29] P.john and P.E.Cook.Composite construction methods[M].A Wily-intersciencePublication,1977.
[30] P. KNowles. Composite steel and concrete construction[M].Buttecworth,1973.
[31]赵鸿铁.钢与混凝土组合结构[M].北京;科学出版社,2001.
[32]马怀忠,王天贤.钢-混凝土组合结构[M].北京:中国建材工业出版社,2006.
[33]石亦平,周玉蓉等。ABAQUS有限元分析实例详解[M].北京:机械工业出版社,2006.
[34]庄茁,张帆,岑松等.ABAQUS菲线性有限元分析与实例[M].北京:科学出版社,2005.
[35]曾攀.有限元分析及其应用[M].北京:清华大学出版社,2004.
[36]曹金凤,石亦平.ABAQUS有限元分析常见问题解答[M].北京:机械工业出版社,2009.
[37]王金昌,陈页开.ABAQUS在土木工程中的应用[M].杭州:浙江大学出版社,2006.
[38] GB50010-2010,混凝土结构设计规范[S]..中国建筑工业出版社,2010:174-176.
[39] Popovics S. A numerical appoarch to the complete stress-strain curves forconcrete[J].Cement Concrete Res,1973,3(5):583—599.
[40] Maner J B,Priestly J N,Park R.Theoretical stress-strain model for confinedconcrete[J].Journal of Structural Engineering,1988,114(8):1804-1826.
[41] Tang J,Hino S,Kuroda I,et a1.Modeling of stress-strain relation-ships for steeland concrete in concrete filled circular steel tubular columns[J].Steel ConstrEng,JSSC1996,3(11):35-46.
[42] Sugupta D P G,Mendis P A. Design of hish strength-concrete-filled tubecolumn[A].Proceedings of the Fifth East—Asia—Pacific Concrete on StructuralEngineering and Construction;Griffith University,Australia,1995:427-432.
[43]韩林海.钢管混凝土结构[M],北京:科学出版社,2000.
[44]卢明齐.钢管混凝土结构三维非线性有限元分析和设计理论的研究[D](博士学位论文).天津:天津大学,2005.
[45]孙修礼,梁书亭,段友利.钢管混凝土框架骨架曲线研究[J].地震工程与工程振动,2007,27(1):99-103.
[2]汪大绥,周建龙.我国高层建筑钢-混凝土混合结构发展与展望[J].建筑结构学报,2010,31(6):62-70.
[3]王华林,陈星,李娜.中山古镇灯都商厦体形复杂超高层结构设计关键技术[J].建筑结构,2011,41(5):33-37.
[4]徐朔明,任咏芳.上海环球金融中心结构设计简析[J].建筑钢结构进展,2003,5(4):14-20.
[5]叶可明,范庆国.上海金茂大厦施工技术[J].中国工程科学,2000,2(10):42-49.
[6]丁浩民,巢斯,赵昕等.上海中心大厦结构分析中若干关键问题[J].建筑结构学报2010,31(6):122-131.
[7]高琳,周定,王云丹等.广州新电视塔基础设计[J].建筑结构,2011,41(1):103-106.
[8]陆建新.深圳京基金融中心简介[J].施工技术,2010,39(8):136-140.
[9]苏广洪葛洪军.广州珠江新城西塔斜交钢管混凝土柱施工技术,2009,38(12):1-4.
[10]钢骨混凝土结构技术规程[M].冶金工业出版社,2007.
[11]王连广钢与混凝土组合结构理论与计算[M].科学出版社,2005.
[12] Driver Robert G,Kulak Geoffrey L,Kenned D J Laurie,eta.1Cyclictest offour-story steel plateshearwall[J]. Journal ofStructural Engineering,1998,124(2):l12-120.
[13] Abolhassan Astaneh—Ash,QiuhongZhao.Cyclic behavior ofsteel shearwallsystems.Annual StabilityConference[C].Seattle:Structural Stabil.ity ResearchCouncil,2002.
[14]王敏,曹万林,张建伟,等.不同轴压比下钢管混凝土边框组合剪力墙抗震性能研究[J].世界地震工程,2008,24(2):34.38.
[15]王敏,曹万林,张建伟,等.钢管混凝土边框高强混凝土组合剪力墙抗震性能研究[J].世界地震工程,2008,28(2):92.97.
[16]曹万林,王敏,王绍合,等.矩形钢管混凝土边框组合剪力墙及筒体结构抗震研究[J].工程力学,2008,25(S1):66.78.
[17]曹万林,杨亚彬,张建伟等.圆钢管混凝土边框内藏桁架剪力墙抗震性能[J].东南大学学报(自然科学版),2009,39(6):208-212.
[18]廖飞宇,陶忠.带不同类型边框柱的剪力墙力学性能试验[J].工业建筑,2007,37(12):31-34.
[19]梁兴文,杨鹏辉,崔晓玲等.带端柱高强混凝土剪力墙抗震性能试验研究[J].建筑结构学报,2010,31(1):23-32.
[20]李娜,王华林,陈星.广东省博物馆新馆节点设计及新技术运用[J].建筑结构,2007,37(9):52-56.
[21]赖鸿立,焦柯,陈星.钢管混凝土排柱剪力墙抗震性能分析[C].第二十届全国高层建筑结构学术会议论文集,2008:826-831.
[22]李亚娥,徐利华.内置钢管混凝土排柱剪力墙框筒结构的抗震性能分析[J].甘肃科学学报.2010,22(2),:87-90.
[23]李惠,徐强,吴波.钢管混凝土耗能低剪力墙[J].哈尔滨建筑大学学报,2000,33(2):18-23.
[24] Fei-Yu Liao,Lin-Hai Han and Zhong Tao.钢管混凝土圆柱和钢筋混凝土剪力墙组合结构的抗震性能研究[J].钢结构,2009,24(9):84
[25] Kwan A K H,Dai H,Cheung Y K.Non-Linear Seismic Response of ReinforcedConcrete Slit Shear Walls[J].Journal of Sound and Vibration1999,226(4):70l-718.
[26]蒋欢军,吕西林.沿竖向耗能剪力墙的低周反复荷载试验研究[J].工程力学增刊,1997:649-654.
[27]戴航,陈贵.带水平短缝墙及低剪力墙的动力反应和耗能分析[J].东南大学学报,1992,22(5):58-65.
[28]王志惠,曹万林,张建伟等.高轴压比下内藏桁架组合中高剪力墙抗震性能试验研究[J].地震工程与工程振动,2007,25(3):60-66.
[29] P.john and P.E.Cook.Composite construction methods[M].A Wily-intersciencePublication,1977.
[30] P. KNowles. Composite steel and concrete construction[M].Buttecworth,1973.
[31]赵鸿铁.钢与混凝土组合结构[M].北京;科学出版社,2001.
[32]马怀忠,王天贤.钢-混凝土组合结构[M].北京:中国建材工业出版社,2006.
[33]石亦平,周玉蓉等。ABAQUS有限元分析实例详解[M].北京:机械工业出版社,2006.
[34]庄茁,张帆,岑松等.ABAQUS菲线性有限元分析与实例[M].北京:科学出版社,2005.
[35]曾攀.有限元分析及其应用[M].北京:清华大学出版社,2004.
[36]曹金凤,石亦平.ABAQUS有限元分析常见问题解答[M].北京:机械工业出版社,2009.
[37]王金昌,陈页开.ABAQUS在土木工程中的应用[M].杭州:浙江大学出版社,2006.
[38] GB50010-2010,混凝土结构设计规范[S]..中国建筑工业出版社,2010:174-176.
[39] Popovics S. A numerical appoarch to the complete stress-strain curves forconcrete[J].Cement Concrete Res,1973,3(5):583—599.
[40] Maner J B,Priestly J N,Park R.Theoretical stress-strain model for confinedconcrete[J].Journal of Structural Engineering,1988,114(8):1804-1826.
[41] Tang J,Hino S,Kuroda I,et a1.Modeling of stress-strain relation-ships for steeland concrete in concrete filled circular steel tubular columns[J].Steel ConstrEng,JSSC1996,3(11):35-46.
[42] Sugupta D P G,Mendis P A. Design of hish strength-concrete-filled tubecolumn[A].Proceedings of the Fifth East—Asia—Pacific Concrete on StructuralEngineering and Construction;Griffith University,Australia,1995:427-432.
[43]韩林海.钢管混凝土结构[M],北京:科学出版社,2000.
[44]卢明齐.钢管混凝土结构三维非线性有限元分析和设计理论的研究[D](博士学位论文).天津:天津大学,2005.
[45]孙修礼,梁书亭,段友利.钢管混凝土框架骨架曲线研究[J].地震工程与工程振动,2007,27(1):99-103.