Seismic Performance of Steel Reinforced Ultra High-strength Concrete Columns 被引量：1

Seismic Performance of Steel Reinforced Ultra High-strength Concrete Columns

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摘要 The seismic performance of steel reinforced ultra-high-strength concrete columns(SRSHC) with various shear-span ratios(λ) were studied through a series of experiments.The concrete compressive cube strength value of experimental specimens ranged from 92.9 MPa to 108.1 MPa.The main experimental variables affecting seismic performance of specimens were axial load ratio and stirrup reinforcement ratio.The columns(λ=2.75) subjected to low cyclic reversed lateral loads failed mainly in the flexural-shear mode failure and columns(λ≤2.0) subjected to low cyclic reversed lateral loads failed mainly in the shear mode failure.Shear force-displacement hysteretic curves and skeleton curves were drawn.Coefficient of the specimen displacement ductility was calculated.Experimental results indicate that ductility decreases with axial pressure ratio increasing,and increases with stirrup reinforcement ratio increasing.Limit values of axial pressure ratio and minimum stirrup reinforcement ratio of columns are proposed to satisfy definite ductility requirement.The suggested values provide a reference for engineering application and for the amendment of the current Chinese design code of steel reinforced concrete composite structures. The seismic performance of steel reinforced ultra-high-strength concrete columns（SRSHC） with various shear-span ratios（λ） were studied through a series of experiments.The concrete compressive cube strength value of experimental specimens ranged from 92.9 MPa to 108.1 MPa.The main experimental variables affecting seismic performance of specimens were axial load ratio and stirrup reinforcement ratio.The columns（λ=2.75） subjected to low cyclic reversed lateral loads failed mainly in the flexural-shear mode failure and columns（λ≤2.0） subjected to low cyclic reversed lateral loads failed mainly in the shear mode failure.Shear force-displacement hysteretic curves and skeleton curves were drawn.Coefficient of the specimen displacement ductility was calculated.Experimental results indicate that ductility decreases with axial pressure ratio increasing,and increases with stirrup reinforcement ratio increasing.Limit values of axial pressure ratio and minimum stirrup reinforcement ratio of columns are proposed to satisfy definite ductility requirement.The suggested values provide a reference for engineering application and for the amendment of the current Chinese design code of steel reinforced concrete composite structures.

作者贾金青

机构地区 Inst.of Structural Eng.

出处《四川大学学报（工程科学版）》 EI CAS CSCD 北大核心 2009年第3期216-222,230,共8页 Journal of Sichuan University (Engineering Science Edition)

基金国家自然科学基金资助项目(50878037) 教育部创新团队资助项目(IRT0518)

关键词建筑结构建筑物抗震设计混凝土结构 steel reinforced ultra high-strength concrete columns axial load ratio stirrup reinforcement ratio shear-span ratio seismic performance

分类号 TU37 [建筑科学—结构工程] TU352 [建筑科学—结构工程]

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参考文献13

1Chen Chengchih, Lin Nanjiao. Analytical model for predicting axial capacity and behavior of concrete encased steel composite stub columns [ J ]. Journal of Constructional Steel Research, 2006, 62:424 - 433.
2Roeder C W. Overview of hybrid and composite systems for seismic design in the United States [ J]. Engineering Structures, 1998, 20(4 - 6): 355 - 363.
3Morino S. Recent developments in hybrid structures in Japan-research, design and construction [ J ]. Engineering Structures, 1998, 20(4 - 6):336 - 346.
4Weng C C , Yen S I. Comparisons of concrete-encased composite column strength provisions of ACI code and AISC specification [J]. Engineering Structures, 2002, 24:59 - 72.
5erome FHajjar. Composite steel and concrete structural systems for seismic engineering [ J ]. Journal of Constructional Steel Research, 2002,58:703 - 723.
6Thermou G E , Elnashai A S , Plumier A , et al. Seismic design and performance of composite frames [ J]. Journal of Constructional Steel Research, 2004, 60:31 - 57.
7Construction Ministry of China. Technical specification for steel reinforced concrete composite structures JGJ 138 - 2001 [ M ]. Beijing: China Architecture & Building Press, 2002.
8Metallurgy Ministry of China. Design specification for steel reinforced concrete structures YB 9082 -97 [ M]. Beijing: China Metallurgy Industry Press, 1998.
9Construction Ministry of China. Code for design of concrete structures GB 50010 - 2002 [ M ]. Beijing: China Architecture & Building Press, 2002.
10贾金青,徐世.钢骨高强混凝土短柱轴压力系数限值的试验研究[J].建筑结构学报,2003,24(1):14-18. 被引量：26

二级参考文献25

1黄煜镔,钱觉时.高强及超高强混凝土的脆性与强度尺寸效应[J].工业建筑,2005,35(1):15-17. 被引量：25
2胡庆昌.1995年1月17日日本阪神大地震中神户市房屋结构震害简介[J].建筑结构学报,1995,16(3):10-12. 被引量：26
3王清湘,赵国藩,林立岩.高强混凝土柱延性的试验研究[J].建筑结构学报,1995,16(4):22-31. 被引量：78
4贾金青,姜睿,厚童.钢骨超高强混凝土框架柱抗震性能的试验研究[J].土木工程学报,2006,39(8):14-18. 被引量：29
5.CECS104:99.高强混凝土结构技术规程[S].,..
6.YB9082- 97.钢骨混凝土结构设计规程[S].,..
7短柱专题组.劲性钢筋混凝土短柱受力性能及计算方法[M].北京：中国建筑工业出版社,1994..
8唐陞韡,余安东.短柱极限承载能力的研究[J].建筑结构学报,1997,18(2):20-28. 被引量：6
9梅村魁.劲性钢筋混凝土结构的抗震设计[M].中国建筑科学研究院译.北京,1988
10中华人民共和国行业标准.YB9082-97钢骨混凝土结构设计规程[S],1997

共引文献32

1刘界鹏,张小冬,张素梅.圆钢管约束钢骨高强混凝土短柱轴压力学性能[J].建筑结构学报,2009,30(S2):242-248. 被引量：9
2李俊华,赵鸿铁,薛建阳.型钢高强混凝土柱延性的试验研究[J].西安建筑科技大学学报（自然科学版）,2004,36(4):383-386. 被引量：19
3王连广,贾连光,张海霞.钢骨高强混凝土边节点抗震性能试验研究[J].工程力学,2005,22(1):182-186. 被引量：13
4张志伟,郭子雄.型钢混凝土柱位移延性系数研究[J].西安建筑科技大学学报（自然科学版）,2006,38(4):528-532. 被引量：7
5贾金青,姜睿,厚童.钢骨超高强混凝土框架柱抗震性能的试验研究[J].土木工程学报,2006,39(8):14-18. 被引量：29
6贾金青,姜睿,徐世烺,孙根勤,厚童.超高强混凝土短柱抗震性能的试验研究[J].地震工程与工程振动,2006,26(6):120-126. 被引量：9
7张盛东,曲恒绪.型钢混凝土柱轴压比限值研究[J].结构工程师,2007,23(2):26-31. 被引量：1
8李俊华,薛建阳,王新堂,赵鸿铁.型钢高强混凝土柱轴压比限值的试验研究[J].世界地震工程,2007,23(2):154-160. 被引量：3
9姜睿,徐世烺,贾金青.高轴压比PVA纤维超高强混凝土短柱延性的试验研究[J].土木工程学报,2007,40(8):54-60. 被引量：25
10陈才华,王翠坤,孙慧中.型钢混凝土压弯构件抗震性能试验研究[J].工程抗震与加固改造,2007,29(4):68-72. 被引量：9

同被引文献10

1BASU A K. Computation of failure loads of composite col- umns[ J ]. The Institution of Civil Engineers, 1998,36 (6) : 645-651.
2FAUCON P, ADENOT F, JAQUINOT J F, et al. Long- term behaviour of cement pastes used for nuclear waste dis- posal: Review of physico-chemical mechanisms of water degrada-tion[ J ]. Cement and Concrete Research, 1998,28 (6) : 847-857.
3中国人民共和国国家标准.混凝土结构设计规范(GB50010-2010)[S].北京:中华人民共和国住房和城乡建设部,2010.
4中国人民共和国行业标准.公路钢筋混凝土及预应力混凝土桥涵设计规范(JTGD62-2004)[S].北京:中华人民共和国交通部,2004.
5RASHID M A, MANSUR M A. Reinforced high-strength concrete beams in flexure [ J ]. ACI Structural Journal, 2005,102 ( 3 ) : 462 -471.
6王钧,邬丹,郑文忠.预应力H型钢混凝土简支梁正截面受力性能试验[J].哈尔滨工业大学学报,2009,41(6):22-27. 被引量：35
7佘伟,张云升,张文华,李欣.较好韧性的超高强混凝土的制备及性能[J].建筑材料学报,2010,13(3):310-314. 被引量：9
8陆春华,金伟良,延永东.正常使用状态下HRB500钢筋混凝土梁受弯性能试验[J].江苏大学学报（自然科学版）,2011,32(3):350-354. 被引量：14
9姜睿,贾金青,郑苗子,闫长旺,孟祥波.超高强混凝土短柱受剪强度的试验研究[J].建筑结构学报,2008,29(S1):15-19. 被引量：2
10段书凯,刘光远.混沌神经网络在分离叠加模式和信息恢复中的应用[J].西南师范大学学报（自然科学版）,2003,28(2):218-221. 被引量：6

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1孟刚,贾金青,王吉忠.预应力超高强混凝土简支梁抗弯性能分析[J].哈尔滨工程大学学报,2013,34(5):575-580. 被引量：14

二级引证文献14

1秦丽辉,李岩,王宗林,AL-DULAIMI A F N.BFRP加固损伤混凝土梁挠度计算方法[J].交通运输工程学报,2014,14(6):17-26. 被引量：6
2孟刚,贾金青,高军程,叶浩.预应力钢骨超高强混凝土梁裂缝宽度试验与计算[J].华南理工大学学报（自然科学版）,2014,42(10):102-109. 被引量：2
3项贻强,张翔,赵荐,廖小辉,李少骏.退役预应力混凝土梁受弯全过程分析及试验研究[J].桥梁建设,2015,45(5):30-35. 被引量：10
4戎贤,李强,刘平.高强钢筋部分预应力混凝土梁变形性能的试验研究[J].建筑科学,2016,32(1):37-42. 被引量：1
5张健新,戎贤,刘平.配置600MPa钢筋的有黏结部分预应力混凝土梁变形性能试验研究[J].工业建筑,2016,46(4):65-68. 被引量：6
6李强,戎贤.配置HRB600非预应力钢筋的有粘结预应力混凝土梁受弯试验研究[J].建筑科学,2016,32(11):59-65. 被引量：1
7贾金青,刘伟,涂兵雄.钢骨超高强混凝土框架边节点抗震性能试验研究[J].哈尔滨工程大学学报,2017,38(2):160-167. 被引量：2
8李艳艳,李泽高,李强.配置600MPa钢筋有粘结部分预应力混凝土梁抗弯性能研究[J].建筑结构,2017,47(6):50-54. 被引量：3
9王钧,李婷,任靖豪.大直径高强钢绞线预应力混凝土梁受力性能[J].建筑科学与工程学报,2017,34(2):103-110. 被引量：3
10杨丙文,黎雅乐.钢筋对超高强度混凝土梁受力性能的影响[J].特种结构,2017,34(2):71-74. 被引量：2

1Yan Changwang,Jia Jinqing.Seismic performance of steel reinforced ultra high-strength concrete composite frame joints[J].Earthquake Engineering and Engineering Vibration,2010,9(3):439-448. 被引量：5
2Yuping Sun,Takashi Takeuchi,Yingmin Li.Characteristics of seismic performance of building structures located in mountainous areas[J].西部人居环境学刊,2015,30(A01):17-23.
3Babak Omidvar Alireza Sadeghian Mehdi Nojavan.The Role of Architectural Considerations in Seismic Performance of Buildings： A Case Study in Iran[J].Journal of Civil Engineering and Architecture,2014,8(3):268-275.
4刘劲松,裘涛.Experimental Study on Seismic Performance of Tall Building with Steel Transfer Trusses Located at a Higher Level[J].Journal of Shanghai Jiaotong university(Science),2008,13(2):181-183.
5Tomisawa Koichi,Miura Seiichi.Verification of Seismic Performance of Pile Foundation in Composite Ground through Experimental and Numerical Methods[J].Journal of Civil Engineering and Architecture,2013,7(6):656-669.
6丁红岩,郭耀华,梁玉国,张浦阳.Experimental Research on Seismic Performance of Storey-Adding Frame Structures[J].Transactions of Tianjin University,2016,22(1):43-49.
7Sanjaya Kumar Patro,Ravi Sinha.Seismic Performance of Dry-Friction Devices in Shear-Frame Buildings[J].Journal of Civil Engineering and Architecture,2010,4(12):1-19.
8魏标,戴公连,文颖,夏烨.Seismic performance of isolation system of rolling friction with springs[J].Journal of Central South University,2014,21(4):1518-1525.
9Z.Saneei Nia,A.Mazroi,M.Ghassemieh,H.Pezeshki.Seismic performance and comparison of three different I beam to box column joints[J].Earthquake Engineering and Engineering Vibration,2014,13(4):717-729. 被引量：2
10Feng Yuan,Wu Xiaobin,Xiong Yaoqing,Li Congchun,Yang Wen.Seismic performance analysis and design suggestion for frame buildings with cast-in-place staircases[J].Earthquake Engineering and Engineering Vibration,2013,12(2):209-219. 被引量：2

四川大学学报（工程科学版）

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