OALib Journal期刊
ISSN: 2333-9721
费用：99美元

投递稿件

查看量	下载量

相关文章
更多...

- 2018

钢管与其核心自应力自密实高强混凝土的粘结性能 Experimental study on bond behavior of self-stressing and self-compacting high strength concrete filled steel tube

周鹏华,徐礼华,谷雨珊,吴敏,许明耀,黄乐

Keywords: 钢管混凝土柱,自应力自密实高强混凝土,粘结性能

Full-Text Cite this paper Add to My Lib

Abstract:

采用自应力自密实混凝土,可以提高钢管内混凝土的密实度,补偿混凝土的收缩,从而保证钢管与混凝土更好地共同工作.为研究钢管与其核心自应力自密实高强混凝土的粘结性能,考虑自应力值、混凝土强度、界面长度3个影响因素,设计制作23根试件,进行推出试验和理论分析.研究结果表明:与钢管自密实混凝土相比,当自应力值为3、5MPa时,对应的抗剪粘结强度可提高19%和85%;混凝土强度的提高也可增强界面抗剪粘结强度,但高强混凝土的脆性导致构件的荷载-滑移曲线在粘结极限荷载之后下降较快;抗剪粘结强度随界面长度的增加而下降,且近似呈线性关系下降;基于试验结果建立钢管自应力自密实高强混凝土界面抗剪粘结强度计算公式,可供工程应用参考

References

[1]	Okamura H.Self-compacting high-performance concrete[J].Concrete International,1997,19(7):50-54.
[2]	薛立红,蔡绍怀.钢管混凝土柱组合界面的粘结强度(下)[J].建筑科学,1996b,12(4):19-23.Xue Lihong,Cai Shaohuai.Bond strength at the interface of concrete-filled steel tube columns[J].Building Science,1996b,12(4):19-23.
[3]	薛立红,蔡绍怀.荷载偏心率对钢管混凝土柱组合界面粘结强度的影响[J].建筑科学,1997,13(2):22-25.Xue Lihong,Cai Shaohuai.The influence of load eccentricity on bond strength at the interface of concretefilled steel tube columns[J].Building Science,1997,13(2):22-25.
[4]	Park R,Paulay T.Reinforced Concrete Structures[M].New Zealand,1975.
[5]	Virdi K S,Dowling P J.Bond strength in concrete filled steel tubes[C]//IABSE Proceeding,P-33/80,1980:125-139.
[6]	Virdi K S,Dowling P J.Bond strength in concrete filled steel tubes[R].CESLIC Report CCII,Department of Civil Engineering,Imperial College,London,1975.
[7]	Roeder C W,Cameron B,Brown C B.Composite action in concrete filled tubes[J].Journal of Structural Engineering,ASCE,1999,125(5):477-484.
[8]	GB/T 2975-1998钢及钢产品力学性能试验取样位置及试样制备[S].GB/T 2975-1998Steel and Steel Products-Location and Preparation of Test Pieces for Mechanical Testing[S].
[9]	Caliskan,Sinan.Aggregate/mortar interface:Influence of silica fume at the micro-and macro-level[J].Cement and Concrete Composites,2003,25(4):557-564.
[10]	薛立红,蔡绍怀.钢管混凝土柱组合界面的粘结强度(上)[J].建筑科学,1996a,12(3):22-28.Xue Lihong,Cai Shaohuai.Bond strength at the interface of concrete-filled steel tube columns[J].Building Science,1996a,12(3):22-28.
[11]	Morishita Yo,Tomii M,Yoshimura K.Experimental studies on bond strength in concrete filled circular steel tubular columns subjected to axial loads[J].Transactions of Japan Concrete Institute,1979b,(I):359-366.
[12]	Khalil H S.Push-out strength of concrete-filled steel hollow sections[J].Structural Engineer,1993,71(13):230-233.
[13]	Khalil H S.Resistance of concrete-filled steel tubes to push-out force[J].Structural Engineer,1993,71(13):234-243.
[14]	杨玉喜,刘学全.硅灰在混凝土中的作用[J].黑龙江交通科技,2007,30(6):51-55.Yang Yuxi,Liu Xuequan.The effect of silica fume in the concrete[J].Communications Science and Technology Heilongjiang,2007,30(6):51-55.
[15]	徐磊.钢管自应力免振混凝土轴压柱设计理论研究[D].大连:大连理工大学,2005.Xu Lei.Research on the design theory for self-stressing and self-compacting concrete filled steel tube column under axial load[D].Dalian:Dalian University of Technology,2005.
[16]	袁启涛,唐玉超,罗作球,等.微珠在C50,C55商品混凝土中的应用研究[J].混凝土与水泥制品,2014,7:21-24.Yuan Qitao,Tang Yuchao,Luo Zuoqiu,et al.Study on the beads used in C50,C55commodity concrete[J].China Concrete and Cement Products,2014,7:21-24.
[17]	康希良,赵鸿铁,薛建阳,等.钢管混凝土套箍机理及组合弹性模量的理论分析[J].工程力学,2007,24(11):121-125.Kang Xiliang,Zhao Hongtie,Xue Jianyang,et al.Theoretic analysis for hooping mechanism and composite elastic modulus of CFST members[J].Engineering Mechanics,2007,24(11):121-125.
[18]	蔡绍怀.现代钢管混凝土结构[M].北京:人民交通出版社,2007.Cai Shaohuai.Modern Steel Tube Confined Concrete Structures[M]. Beijing:China Communications Press,2007.

Full-Text

Contact Us

service@oalib.com

QQ:3279437679

WhatsApp +8615387084133