FRP约束橡胶混凝土的轴心受压承载力分析

doi:10.3969/j.issn.1671-7775.2021.05.018

摘要
图/表
参考文献(22)
相关文章 (6)

全文: PDF (1690 KB) HTML (1 KB)
输出: BibTeX | EndNote (RIS)

摘要为准确计算纤维增强聚合物（fibre reinforced polymer，FRP）约束橡胶混凝土的抗压强度，对相关文献的 FRP 约束橡胶混凝土抗压强度模型进行归纳与总结，并采用已发表相关文献的122个试验数据，对相关文献抗压强度模型的准确性进行评估，得到了影响FRP约束橡胶混凝土抗压强度模型准确性的关键参数，即混凝土粗、细骨料的橡胶颗粒体积替换率和FRP的种类.在评估结果的基础上，通过考虑橡胶颗粒替换率系数和FRP种类，建立了抗压强度模型.新建立的抗压强度模型预测值与试验值更为接近，误差评估指标值仅为0.09.

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	曹玉贵1
	李龙龙1
	谯理格2

关键词 ：橡胶混凝土, FRP约束, 轴心受压, 抗压强度, 模型评估

Abstract：To accurately calculate the compressive strength of fibre reinforced polymer (FRP) confined rubber concrete, the existing compressive strength models of FRP confined rubber concrete of related literature were analyzed. The 122 test data collected from literature were used to evaluate the accuracy of the existing model. The evaluation results show that rubber particle volume replacement rate of concrete coarse and fine aggregates and the FRP type have significant effect on the compressive strength of FRP confined rubber concrete. Based on the evaluation results, a new compressive strength model with considering rubber particle replacement rate coefficient and FRP type was established. The predicted value of the new compressive strength model is relatively close to the test value, and the error evaluation index value is 0.09.

Key words： rubber concrete FRP confinement axial compression compressive strength model evaluation

收稿日期: 2020-08-09

基金资助:国家自然科学基金资助项目(51808419)；湖北省自然科学基金资助项目(2019CFB217)；武汉理工大学自主创新基金资助项目 (2019IVA089)

作者简介: 曹玉贵(1984—),男，山东安丘人,博士,副研究员(caoyugui@163.com)，主要从事FRP约束混凝土结构的研究. 李龙龙(1995—),男，甘肃庆阳人，硕士研究生(623564153@qq.com),主要从事FRP约束橡胶混凝土结构的研究.

引用本文:

曹玉贵1，李龙龙1，谯理格2. FRP约束橡胶混凝土的轴心受压承载力分析[J]. 江苏大学学报（自然科学版）, 2021, 42(5): 616-620. CAO Yugui1， LI Longlong1， QIAO Lige2. Analysis of axial compressive bearing capacity of FRP confined rubber concrete[J]. Journal of Jiangsu University(Natural Science Eidtion) , 2021, 42(5): 616-620.

链接本文:

http://zzs.ujs.edu.cn/xbzkb/CN/10.3969/j.issn.1671-7775.2021.05.018 或 http://zzs.ujs.edu.cn/xbzkb/CN/Y2021/V42/I5/616

［1］	CHAN C W，YU T，ZHANG S S，et al. Compressive behaviour of FRP-confined rubber concrete[J]. Construction and Building Materials，2019，211： 416-426.
［2］	DAN V B, ELGHAZOULI A Y. Behaviour of confined rubberised concrete members under combined loading conditions[J]. Magazine of Concrete Research, doi：10.1680/jmacr.19.00121.
［3］	BOMPA D V，ELGHAZOULI A Y. Stress-strain response and practical design expressions for FRP-confined recycled tyre rubber concrete[J]. Construction and Building Materials，2020，237：117633.
［4］	陈克凡，乔宏霞，王鹏辉，等. 温度循环退化模型的橡胶混凝土可靠寿命预估[J]. 华中科技大学学报(自然科学版)，2020，48(2)：42-46.
	CHEN K F，QIAO H X，WANG P H，et al. Reliable life prediction of rubber concrete based on temperature cycle degradation model[J]. Journal of Huazhong University of Science and Technology(Natural Science Edition)，2020，48(2)：42-46. (in Chinese)
［5］	吕晶，周天华，杜强，等. 掺橡胶颗粒轻集料混凝土力学性能的试验研究[J]. 硅酸盐通报，2015，34(8)：2077-2082.
	LYU J，ZHOU T H，DU Q，et al. Mechanical properties of lightweight aggregate concrete contained rubber particles[J]. Bulletin of the Chinese Ceramic Society，2015，34(8)：2077-2082. (in Chinese)
［6］	YOUSSF O，MILLS J E，HASSANLI R. Assessment of the mechanical performance of crumb rubber concrete[J]. Construction and Building Materials，2016，125：175-183.
［7］	李悦，吴玉生，王敏，等. 橡胶集料混凝土物理力学性能研究[J]. 武汉理工大学学报，2008，30(1)：55-57.
	LI Y，WU Y S，WANG M，et al. Physical and mechanical properties of rubber concrete[J]. Journal of Wuhan University of Technology，2008，30(1)：55-57. (in Chinese)
［8］	CAO Y G，LIU M Y，WU Y F. Effect of low strain rate on the axial behavior of concrete in CFRP- confined circular cylinders[J]. Construction and Building Mate-rials，2020，255：119351.
［9］	CAO Y G，LIU M Y，ZHANG Y，et al. Effect of strain rates on the stress-strain behavior of FRP-confined pre-damaged concrete[J]. Materials, 2020，13(5)：13051078.
[10]	LI G Q, PANG S S, IBEKWE S I. FRP tube encased rubberized concrete cylinders[J]. Materials and Structures, 2011, 44(1): 233-243.
[11]	TUFAIL R F，FENG X，ZAHID M. Behavior of unconfined and CFRP confined rubberized concrete[J]. International Journal of Low-Carbon Technologies，2020，15(1)：65-83.
[12]	YOUSSF O，ELGAWADY M A，MILLS J E. Static cyclic behaviour of FRP-confined crumb rubber concrete co-lumns[J]. Engineering Structures，2016，113: 371-387.
[13]	YOUSSF O，HASSANLI R，MILLS J E. Mechanical performance of FRP-confined and unconfined crumb rubber concrete containing high rubber content[J]. Journal of Building Engineering，2017，11：115-126.
[14]	YOUSSF O，ELGAWADY M A， MILLS J E，et al. An experimental investigation of crumb rubber concrete confined by fibre reinforced polymer tubes[J]. Construction and Building Materials，2014，53(4)：522-532.
[15]	GHOLAMPOUR A，POUR A F，HASSANLI R，et al. Behavior of actively confined rubberized concrete under cyclic axial compression[J]. Journal of Structural Engineering，2019，145(11)：04019131.
[16]	RAFFOUL S，ESCOLANO-MARGARIT D，GARCIA R，et al. Constitutive model for rubberized concrete passively confined with FRP Laminates[J]. Journal of Compo-sites for Construction，2019，23(6)：04019044.
[17]	RAFFOUL S，GARCIA R， ESCOLANO-MARGARIT D，et al. Behaviour of unconfined and FRP-confined rubberised concrete in axial compression[J]. Construction and Building Materials，2017，147：388-397.
[18]	ELGHAZOULI A Y， BOMPA D V，XU B，et al. Performance of rubberised reinforced concrete members under cyclic loading[J]. Engineering Structures，2018，166：526-545.
[19]	CAO Y G，JIANG C，WU Y F. Cross-sectional unification on the stress-strain model of concrete subjected to high passive confinement by fiber-reinforced polymer[J]. Polymers，2016，8(5)：186.
[20]	CAO Y G，LIU M Y，ZHANG Y, et al. Effect of strain rates on the stress-strain behavior of FRP-confined pre-damaged concrete [J]. Materials，2020，13：1078.
[21]	WU Y F，JIANG C. Effect of load eccentricity on the stress-strain relationship of FRP-confined concrete co-lumns[J]. Composite Structures，2013，98：228-241.
[22]	WU Y F，WEI Y. General stress-strain model for steel- and FRP-confined concrete[J]. Journal of Composites for Construction，2014，19(4)：04014069.