Experimental Research on Mechanical Properties of Semi-Grouting Sleeve Connection After Being Subjected to High Temperature

LI Mingtao

doi:10.13204/j.gyjzG22010612

Volume 52 Issue 7

Oct. 2022

Turn off MathJax

Article Contents

Article Navigation > INDUSTRIAL CONSTRUCTION > 2022 > 52(7): 106-112,71

LI Mingtao. Experimental Research on Mechanical Properties of Semi-Grouting Sleeve Connection After Being Subjected to High Temperature[J]. INDUSTRIAL CONSTRUCTION, 2022, 52(7): 106-112,71. doi: 10.13204/j.gyjzG22010612

Citation:

LI Mingtao. Experimental Research on Mechanical Properties of Semi-Grouting Sleeve Connection After Being Subjected to High Temperature[J]. INDUSTRIAL CONSTRUCTION, 2022, 52(7): 106-112,71. doi: 10.13204/j.gyjzG22010612

Citation:

PDF( 7742 KB)

Experimental Research on Mechanical Properties of Semi-Grouting Sleeve Connection After Being Subjected to High Temperature

doi: 10.13204/j.gyjzG22010612

LI Mingtao

China Railway First Survey and Design Institute Group Co., Ltd., Xi'an 710043, China

Received Date: 2022-01-06
Available Online: 2022-10-28

Abstract

Abstract

The compressive strength of grout after high temperature was studied, and the formula for calculating the compressive strength of grout after being subjected to high temperature was derived. In order to study the mechanical properties of semi-grouting sleeve connection after of high temperature, the pull-out test of semi-grouting sleeve connection after being subjected to high temperature was designed with temperature, anchorage length and protective layer thickness as variables. The test results showed that the failure mode of specimens changed with the increase of temperature, and the failure mode changed gradually from steel bar fracture failure to steel bar pull-out failure. Increasing anchorage length could effectively improve the mechanical properties of semi-grouting sleeve connections. At 600℃, the ultimate load and ultimate displacement losses of specimens with anchor length of 120 mm were 6% and 46% respectively, which were far smaller than those of specimens with anchor length of 100 mm. The existence of protective layer was beneficial to improve the bearing capacity and ductility of semi-grouting sleeve connections. Based on the test results, the bearing capacity formula of semi-grouting sleeve connection after being subjected to high temperature was deduced, and the predicted values were in good agreement with the test values.
- grout,
- semi-grouting sleeve connection,
- high temperature,
- anchorage length,
- protective layer thickness

FullText(HTML)

References(17)

References

[1]	MARAVEAS C, TSAVDARIDIS K D, NADJAI A. Fire resistance of unprotected ultra shallow floor beams (USFB):a numerical investigation[J]. Fire Technology, 2017, 53(2):609-627.
[2]	SHAKYA A M, KODUR V. Response of precast prestressed concrete hollowcore slabs under fire conditions[J]. Engineering Structures, 2015, 87(15):126-138.
[3]	KODUR V, SHAKYA A M. Modeling the response of precast, prestressed concrete hollow-core slabs exposed to fire[J]. PCI Journal, 2014, 59(3):78-94.
[4]	郑永乾,庄金平. 高强混凝土墙耐火性能的有限元分析[J]. 福建工程学院学报, 2009, 7(3):210-215.
[5]	韩林海. 钢管混凝土柱耐火性能和抗火设计的特点[J]. 安全与环境学报, 2001, 1(4):36-40.
[6]	顾海松,王新堂,徐金灿. 开孔薄壁钢梁-轻骨料混凝土装配式组合楼板受火试验研究[J]. 建筑结构学报, 2016, 37(5):48-56.
[7]	王新堂,任鹏飞,王万祯. 薄壁钢梁-陶粒混凝土装配式组合楼板受火后受力性能研究[J]. 建筑结构学报, 2017, 38(4):70-80.
[8]	刘激扬,黄益良,倪照鹏,等.装配式钢桁架组合楼盖耐火性能试验研究[J]. 消防科学与技术, 2014, 33(11):1264-1267.
[9]	吴刚,冯德成. 装配式混凝土框架节点基本性能研究进展[J]. 建筑结构学报, 2018, 39(2):1-16.
[10]	陈建伟,王占文,鞠士龙,等. 半灌浆套筒钢筋偏心连接受拉性能试验研究与数值模拟[J]. 建筑结构学报, 2020, 41(增刊2):160-171.
[11]	王占文,陈建伟,鞠士龙,等. 二次补浆对钢筋套筒灌浆连接性能影响试验研究[J]. 建筑结构, 2020, 50(22):45-50.
[12]	中华人民共和国住房和城乡建设部. 钢筋机械连接技术规程:JGJ 107-2016[S]. 北京:中国建筑工业出版社, 2016.
[13]	中华人民共和国住房和城乡建设部. 水泥基灌浆材料应用技术规范:GB/T 50448-2015[S]. 北京:中国建筑工业出版社, 2015.
[14]	余琼,袁炜航,尤高帅. 带肋钢筋与灌浆料粘结性能试验研究及有限元分析[J]. 结构工程师, 2016, 32(6):113-122.
[15]	肖建庄,黄均亮,赵勇. 高温后高性能混凝土和细晶粒钢筋间粘结性能[J]. 同济大学学报(自然科学版), 2009, 37(10):1296-1301.
[16]	李卫, 过镇海. 高温下混凝土的强度和变形性能试验研究[J]. 建筑结构学报, 1993, 14(1):8-16.
[17]	王振东.混凝土及砌体结构[M].北京:中国建筑工业出版社,2002.