湿热环境下外贴CFRP加固RC梁抗弯性能有限元分析

doi:10.19936/j.cnki.2096-8000.20240428.010

复合材料科学与工程 ›› 2024, Vol. 0 ›› Issue (4): 76-82.DOI: 10.19936/j.cnki.2096-8000.20240428.010

湿热环境下外贴CFRP加固RC梁抗弯性能有限元分析

张智梅, 马嘉辰^*

上海大学力学与工程科学学院土木工程系,上海 200444

收稿日期:2023-03-29 出版日期:2024-04-28 发布日期:2024-04-28
通讯作者: 马嘉辰(1995—),女,硕士研究生,主要从事桥梁工程加固方面的研究,18642122357@163.com。
作者简介:张智梅(1972—),女,博士,副教授,主要从事结构抗火与加固方面的研究。
基金资助:
国家自然科学基金(51978392)

Finite element analysis of flexural performance of RC beams strengthened with externally bonded CFRP under hygrothermal environment

ZHANG Zhimei, MA Jiachen^*

Department of Civil Engineering, School of Mechanics ＆ Engineering Science, Shanghai University, Shanghai 200444, China

Received:2023-03-29 Online:2024-04-28 Published:2024-04-28

摘要/Abstract

摘要： 本文研究了湿热环境下外贴CFRP加固RC梁抗弯性能。首先,基于已有的FRP-混凝土界面双参数黏结滑移模型,引入湿度和温度对断裂能G_f、界面刚度B的影响系数,建立了湿热环境下界面黏结滑移模型。然后,利用该界面模型对一组湿热条件作用下的试验梁进行有限元数值模拟,将模拟结果与试验结果进行对比分析,验证模型的正确性。最后,使用已验证的有限元模型深入分析不同湿热条件下CFRP与混凝土的宽度比和CFRP的加固量等因素对钢筋混凝土加固梁抗弯性能的影响。结果表明:本文建立的CFRP-混凝土黏结滑移模型,可以有效地模拟湿热环境下的界面性能;湿热条件下的加固梁主要发生剥离破坏,且随着湿热环境恶化,加固梁受弯承载力和对应的挠度明显下降;湿热环境下,可以通过适当增加CFRP与混凝土的宽度比和CFRP的加固量提高加固梁的受弯承载力。

关键词: 外贴CFRP加固, 湿热环境, 黏结界面, 剥离, 有限元分析

Abstract: To study the flexural performance of externally bonded CFRP-reinforced RC beams under hygrothermal environment, this paper firstly establishes an interface bond-slip model under hygrothermal environment based on the existing two-parameter bond-slip model of FRP-concrete interface and introduces the influence coefficients of humidity and temperature on fracture energy and interface stiffness. Then, the interface model is used to perform finite element numerical simulations on a set of test beams under the action of hygrothermal conditions, and the simulation results are compared with the test results to verify the correctness of the model. Finally, the validated finite element model was used to analyze in depth the effects of factors such as the width ratio of CFRP to concrete and the amount of CFRP reinforcement on the flexural performance of reinforced concrete reinforced beams under different hygrothermal conditions. The results show that the CFRP-concrete bond-slip model established in this paper can effectively simulate the interface performance under the hygrothermal environment; peeling damage mainly occurs in the reinforced beams under the hygrothermal condition, and the flexural load capacity and corresponding deflection of the reinforced beams decrease significantly with the deterioration of the hygrothermal environment; the flexural load capacity of the reinforced beams can be improved by appropriately increasing the width ratio of CFRP to concrete and the amount of CFRP reinforcement under the hygrothermal environment. The flexural load capacity of the reinforced beam can be improved by increasing the width ratio of CFRP to concrete and the amount of CFRP reinforcement.

Key words: strengthened with externally bonded CFRP, hygrothermal environment, bonding interface, peeling, finite element analysis

中图分类号:

TB332

张智梅, 马嘉辰. 湿热环境下外贴CFRP加固RC梁抗弯性能有限元分析[J]. 复合材料科学与工程, 2024, 0(4): 76-82.

ZHANG Zhimei, MA Jiachen. Finite element analysis of flexural performance of RC beams strengthened with externally bonded CFRP under hygrothermal environment[J]. COMPOSITES SCIENCE AND ENGINEERING, 2024, 0(4): 76-82.

参考文献

[1] MUKHTAR F M, AROWOJOLU O. Recent developments in experimental and computational studies of hygrothermal effects on the bond between FRP and concrete[J]. Journal of Reinforced Plastics and Composites, 2020, 39(11-12): 422-442.
[2] XIE J H, WEI M W, LI J L, et al. Effect of the chloride environmental exposure on the flexural performance of strengthened RC beams with self-anchored prestressed CFRP plates[J]. Engineering Structures, 2021, 231: 111718.
[3] GUO X Y, SHU S Y H, WANG Y L, et al. Effect of subtropical natural exposure on the bond behavior of FRP-concrete interface[J]. Polymers, 2020, 12(4): 967.
[4] 朵润民. 冻融循环和温热环境下CFRP-高强混凝土粘贴界面耐久性研究[D]. 大连: 大连理工大学, 2015.
[5] 胡克旭, 卢凡, 蔡正华. 高温下碳纤维-混凝土界面受剪性能试验研究[J]. 同济大学学报(自然科学版), 2009, 37(12): 1592-1597.
[6] LI Y, LIU X, WU M. Mechanical properties of FRP-strengthened concrete at elevated temperature[J]. Construction & Building Materials, 2017, 134: 424-432.
[7] 张大伟, 金伟良, SHRESTHA J, 等. 浸水环境下FRP-混凝土界面剪切黏结性能研究[J]. 施工技术, 2013, 42(10): 34-38.
[8] LIANG H J, LI S, LU Y Y, et al. The combined effects of wet-dry cycles and sustained load on the bond behavior of FRP-concrete interface[J]. Polymer Composites, 2019, 40(3): 1006-1017.
[9] 王苏岩, 丁荔, 洪雷, 等. 持载与干湿循环作用下CFRP加固高强混凝土梁耐久性研究[J]. 建筑结构, 2017, 47(21): 78-83.
[10] DAI J G, GAO W Y, TENG J G. Bond-slip model for FRP laminates externally bonded to concrete at elevated temperature[J]. Journal of Composites for Construction, 2013, 17(2): 217-228.
[11] BLACKBURN B P, TATAR J, DOUGLAS E P, et al. Effects of hygrothermal conditioning on epoxy adhesives used in FRP composites[J]. Construction and Building Materials, 2015, 96: 679-689.
[12] LU X Z, TENG J G, YE L P, et al. Bond-slip models for FRP sheets/plates bonded to concrete[J]. Engineering Structures, 2005, 27(6): 920-937.
[13] OUYANG Z Y, WAN B L. Nonlinear deterioration model for bond interfacial fracture energy of FRP-concrete joints in moist environments[J]. Journal of Composites for Construction, 2009, 13(1): 53-63.
[14] SHRESTHA J, ZHANG D W, UEDA T. Bond-slip models for FPR-concrete interfaces subjected to moisture conditions[J]. International Journal of Polymer Science, 2017, 2017: 1-14.
[15] TUAKTA C, BUYUKOZYURK O. Deterioration of FRP/concrete bond system under variable moisture conditions quantified by fracture mechanics[J]. Composites Part B: Engineering, 2011, 42(2): 145-154.
[16] El-DIEB A S, ALDAJAH S, BIDDAH A, et al. Long-term performance of RCM members externally strengthened by FRP exposed to different environments[J]. Arabian Journal for Science & Engineering, 2012, 37(2): 325-339.
[17] 中华人民共和国住房和城乡建设部.混凝土结构设计规范: GB 50010—2010[M]. 北京: 中国建筑工业出版社, 2011.
[18] WU Z, ISLAM S, SAID H. A three-parameter bond strength model for FRP-concrete interface[J]. Journal of Reinforced Plastics and Composites, 2008, 28(19): 2309-2323.
[19] FEI W Y, JIANG C. Quantification of bond-slip relationship for externally bonded FRP-to-concrete joints[J]. Journal of Composites for Construction, 2013, 15: 673-686.

湿热环境下外贴CFRP加固RC梁抗弯性能有限元分析

Finite element analysis of flexural performance of RC beams strengthened with externally bonded CFRP under hygrothermal environment

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

本文评价

[1]	李红军, 韩杨, 宋笑非, 郑绍文, 郑超凡, 孙九霄. 孔柱锥度对纤维柱增强夹芯结构压缩性能的影响[J]. 复合材料科学与工程, 2024, 0(4): 40-48.
[2]	赵艺, 赵刚, 范欣愉, 闫忠伟, 葛亚琼, 徐剑. 基于渐进损伤模型的热固性复合材料电阻焊接头强度的尺寸效应研究[J]. 复合材料科学与工程, 2024, 0(2): 45-51.
[3]	张弘强, 陈栋, 李成. CFRP层合板双面挖补补片设计及性能分析[J]. 复合材料科学与工程, 2024, 0(2): 52-58.
[4]	姚中强, 唐鹏飞, 顾育慧, 李军向. 针辊轧孔方式对硬质聚氨酯泡沫夹芯结构剥离性能的研究及应用[J]. 复合材料科学与工程, 2023, 0(8): 112-114.
[5]	余章杰, 张琪, 蔡登安, 戴征征, 周光明. 碳纤维/环氧树脂复合材料-金属连接结构面外拉伸失效机制[J]. 复合材料科学与工程, 2023, 0(7): 5-12.
[6]	张学文, 王继辉, 陈宏达, 倪爱清. 单向增强热塑性复合材料热冲压成型仿真与优化[J]. 复合材料科学与工程, 2023, 0(6): 104-114.
[7]	沈昊辰, 牛波, 张琪凯, 郝晶莹, 张亚运, 龙东辉. 2.5D石英纤维增强纳米孔酚醛树脂基复合材料的力学和传热性能[J]. 复合材料科学与工程, 2023, 0(4): 5-13.
[8]	辛志博, 朱彦松, 段玉岗, 王奔, 黄志文, 王宏晓, 明越科. 直升机复合材料油箱密封结构分析与试验研究[J]. 复合材料科学与工程, 2023, 0(4): 87-93.
[9]	张锦光, 邓伟, 杨桢, 邱浩, 文湘隆. 纤维增强复合材料叶轮对风机振动特性的影响研究[J]. 复合材料科学与工程, 2023, 0(3): 53-58.
[10]	张智梅, 杨旸. 外贴预应力CFRP布加固钢筋混凝土梁抗弯疲劳性能有限元分析[J]. 复合材料科学与工程, 2023, 0(2): 44-53.
[11]	许良, 胡鸿铭, 周松, 宋万万. 两次冲击距离对CFRP层合板冲击损伤和剩余压缩强度的影响[J]. 复合材料科学与工程, 2023, 0(12): 12-18.
[12]	崔开心, 卢翔, 赵耀斌. 补片搭接长度对修理层合板湿热振动特性的研究[J]. 复合材料科学与工程, 2023, 0(11): 12-20.
[13]	周勇军, 邱宇鸿, 李红周. 混杂碳/玻纤维复合材料自行车轮辋的铺层优化分析及抗疲劳验证[J]. 复合材料科学与工程, 2023, 0(11): 70-77.
[14]	刘嘉, 吴江, 张夫恩, 吴道明. 复合材料水平尾翼的后梁铺层优化研究[J]. 复合材料科学与工程, 2023, 0(11): 78-83.
[15]	元振毅, 魏方见, 孔令飞, 杨振朝, 同新星, 李言. 模具-复合材料相互作用的复合材料固化变形仿真方法研究[J]. 复合材料科学与工程, 2023, 0(10): 10-16.