+高级检索
首页 > 过刊浏览>2023年第26卷第2期 >156-162. DOI:10.3969/j.issn.1007-9629.2023.02.007
PDF HTML阅读 XML下载 导出引用 引用提醒
混凝土环境中GFRP筋性能衰退的规律及机理
作者:
作者单位:

1.泰山学院 机械与建筑工程学院, 山东 泰安 271000;2.山东农业大学 水利土木工程学院, 山东 泰安 271018;3.水发规划建设有限公司, 山东 济南 250100;4.山东斯福特实业有限公司, 山东 泰安 271000

作者简介:

李文超(1987—),男,山东泰安人,泰山学院讲师,山东农业大学博士生. E-mail: liwch@tsu.edu.cn

通讯作者:

刘福胜(1964—),男,山东潍坊人,山东农业大学教授,博士生导师,博士. E-mail: liufsh@sdau.edu.cn

中图分类号:

TU532

基金项目:

山东省重点研发计划项目(2019GHZ015);中央引导地方科技发展资金项目(YDZX20193700004703)


Degradation Law and Mechanism of GFRP Bars in Concrete Environment
Author:
Affiliation:

1.College of Mechanical and Architectural Engineering, Taishan University, Taian 271000, China;2.College of Water Conservancy and Civil Engineering, Shandong Agricultural University, Taian 271018, China;3.Shuifa Planning and Construction Co., Ltd., Jinan 250100, China;4.Shandong Safety Industrial Co., Ltd., Taian 271000, China

  • 摘要
    • |
  • 图/表
    • |
  • 访问统计
    • |
  • 参考文献 [28]
    • |
  • 相似文献
    • | | |
  • 文章评论
    摘要:

    为了探究玻璃纤维增强复合材料(GFRP)筋在模拟和真实混凝土环境中性能衰退的规律及机理,设置了碱溶液(AS)和混凝土包裹GFRP筋后置于自来水中(CS)2种侵蚀环境,采用短梁剪切法分析了GFRP筋力学性能的衰退规律,并借助扫描电子显微镜、差示扫描量热法分析了GFRP筋的微观结构和玻璃化转变温度(Tg).结果表明:随着温度的升高,GFRP筋层间剪切强度衰退的速率加快;GFRP筋在60 ℃的AS中老化183 d后层间剪切强度保留了48.6%,Tg降低了9.2%,部分纤维与树脂脱黏,树脂出现孔洞;相同条件下CS中GFRP筋的层间剪切强度保留了61.4%,Tg降低了3.4%,纤维产生浅坑.基于Arrhenius方程建立了北京地区GFRP筋的性能预测模型.

    Abstract:

    The performance degradation rule and mechanism of performance of glass fiber reinforced polymer(GFRP) bars in simulated concrete pore solution and real concrete environment were explored. The GFRP bars were conditioned in two different ways. The first part of GFRP bars were immersed in alkali solution(AS) and the second part of GFRP bars were wrapped with concrete and then submerged in tap water(CS). The mechanical property degradation of GFRP bars was analyzed by using short beam shear method. Microstructure and glass transition temperature(Tg) of GFRP bars after aging in two environments for 183 days were analyzed using scanning electron microscopy and differential scanning calorimeter respectively. The results demonstrate that the degradation rate of GFRP bars increases with the increase of temperature. After 183 days aging treatment at 60 ℃ in AS environment, the interlaminar shear strength of GFRP bars is retained at 48.6%, Tg is reduced by 9.2%, the separation between fiber and resin is observed and a few holes may be seen in the resin. However, after the same treatment of GFRP bars in the CS environment, the interlaminar shear strength of GFRP bars is retained at 61.4%, Tg is reduced by 3.4%, and the fibers has shallow pits caused by erosion. Finally, the durability prediction model of GFRP bars serving in Beijing is established by using Arrhenius equation.

    表 1 GFRP筋不同温度间的时间转换因子Table 1 TSF of GFRP bars at different temperatures
    图1 不同老化环境中的试件Fig.1 Specimens in different aging environments
    图2 短梁剪切试验Fig.2 Short-beam shear test
    图3 GFRP筋的表面形态Fig.3 Surface morphologies of GFRP bars
    图4 不同侵蚀环境下GFRP筋的层间剪切强度保留率对比Fig.4 Comparison of Y of GFRP bars in different aggressive environments
    图5 GFRP筋的微观结构Fig.5 Microstructure of GFRP bars
    图6 不同侵蚀环境中GFRP筋的玻璃转化温度对比Fig.6 Comparison of Tg of GFRP bars in different aggressive environments
    图7 基于模型3的GFRP筋长期力学性能试验数据的拟合结果Fig.7 Fitting results of long-term mechanical property test data for GFRP bars based on model 3
    图8 不同环境中GFRP筋的耐久性预测模型Arrhenius线Fig.8 Arrhenius line for durability prediction model of GFRP bars in different environments
    图9 温度为13.2 ℃时GFRP筋的长期力学模型主曲线Fig.9 Master curves of long-term mechanical property of GFRP bars at 13.2 ℃
    参考文献
    [1] 代力, 江祥林, 何雄君. 混凝土环境中GFRP筋抗拉性能加速老化试验研究[J]. 西安建筑科技大学学报(自然科学版), 2019, 51(3):383-388.DAI Li, JIANG Xianglin, HE Xiongjun. Accelerated aging tests for evaluations of tensile properties of GFRP bars embedded in concrete beams[J]. Journal of Xi'an University of Architecture & Technology(Natural Science), 2019, 51(3):383-388. (in Chinese)
    [2] 宋泽鹏, 陆春华, 宣广宇, 等. 螺纹GFRP筋与混凝土黏结性能试验与理论计算[J]. 建筑材料学报, 2021, 24(4):887-894.SONG Zepeng, LU Chunhua, XUAN Guangyu, et al. Experimental and theoretical calculation of bonding performance between threaded GFRP bar and concrete[J]. Journal of Building Materials, 2021, 24(4):887-894. (in Chinese)
    [3] 王伟, 薛伟辰. 碱环境下GFRP筋拉伸性能加速老化试验研究[J]. 建筑材料学报, 2012, 15(6):760-766.WANG Wei, XUE Weichen. Accelerated aging tests for evaluations of tensile properties of GFRP rebars exposed to alkaline solution[J]. Journal of Building Materials, 2012, 15(6):760-766. (in Chinese).
    [4] ARCZEWSKA P, POLAK M A, PENLIDIS A. Degradation of glass fiber reinforced polymer(GFRP) bars in concrete environment[J]. Construction and Building Materials, 2021, 293:123451.
    [5] 董志强, 吴刚. FRP筋增强混凝土结构耐久性能研究进展[J]. 土木工程学报, 2019, 52(10):1-19, 29.DONG Zhiqiang, WU Gang. Research progress on durability of FRP bars reinforced concrete structures[J]. China Civil Engineering Journal, 2019, 52(10):1-19, 29. (in Chinese)
    [6] EL-HASSAN H, EL-MAADDAWY T, AL-SALLAMIN A, et al. Durability of glass fiber-reinforced polymer bars conditioned in moist seawater-contaminated concrete under sustained load[J]. Construction and Building Materials, 2018, 175:1-13.
    [7] 张新越, 欧进萍. FRP筋酸碱盐介质腐蚀与冻融耐久性试验研究[J]. 武汉理工大学学报, 2007, 29(1):33-36, 54.ZHANG Xinyue, Jinping OU. Durability experimental research on resistance of acidic,alkali,salt solutions and freeze-thaw properties of FRP bar[J]. Journal of Wuhan University of Technology, 2007, 29(1):33-36, 54. (in Chinese)
    [8] BENMOKRANE B, ALI A H, MOHAMED H M, et al. Laboratory assessment and durability performance of vinyl-ester, polyester, and epoxy glass-FRP bars for concrete structures[J]. Composites, 2017, 114:163-174.
    [9] CHEN Y, DAVALOS J F, RAY I, et al. Accelerated aging tests for evaluations of durability performance of FRP reinforcing bars for concrete structures[J]. Composites Structure, 2007, 78(1):101-111.
    [10] 蔡启明, 陆春华, 延永东, 等. BFRP/GFRP筋剪切性能温度效应试验研究[J]. 建筑材料学报, 2022, 25(4):395-400.CAI Qiming, LU Chunhua, YAN Yongdong, et al. Experimental investigation of temperature effect on shear properties of BFRP/GFRP bars[J]. Journal of Building Materials, 2022, 25(4):395-400. (in Chinese)
    [11] MONTAIGU M, ROBERT M, AHMED E, et al. Laboratory characterization and evaluation of durability performance of new polyester and vinylester E-glass GFRP dowels for jointed concrete pavement[J]. Journal of Composite for Construction, 2013, 17(2):176-187.
    [12] BANK L C, GENTRY T R, THOMPSON B P, et al. A model specification for composites for civil engineering structures[J]. Construction and Building Materials, 2003, 17(6):405-437.
    [13] WU G, DONG Z Q, WANG X, et al. Prediction of long-term performance and durability of BFRP bars under the combined effect of sustained load and corrosive solutions[J]. Journal of Composite for Construction, 2015, 19(3):04014058.
    [14] MANALO A, MARANAN G, BENMOKRANE B, et al. Comparative durability of GFRP composite reinforcing bars in concrete and in simulated concrete environments[J]. Cement and concrete Composites, 2020, 109(5):103564.
    [15] LU C H, NI M Z, CHU T S, et al. Comparative Investigation on tensile performance of FRP bars after exposure to water, seawater, and alkaline solutions[J]. Journal of Materials in Civil Engeering, 2020, 32(7):04020170.
    [16] WANG Z K, ZHAO X L, XIAN G J, et al. Durability study on interlaminar shear behaviour of basalt-, glass- and carbon-fibre reinforced polymer (B/G/CFRP) bars in seawater sea sand concrete environment[J]. Construction and Building Materials, 2017, 156:985-1004.
    [17] 代力. 持续荷载与环境作用下混凝土梁中GFRP筋抗拉性能研究[D]. 武汉:武汉理工大学, 2017.DAI Li.Study on tensile properties of GFRP bars embedded in concrete beams under sustained load and environment effects[D]. Wuhan:Wuhan University of Technology, 2017. (in Chinese)
    [18] AL-SALLOUM Y A, EL-GAMAL S, ALMUSALLAM T H, et al. Effect of harsh environmental conditions on the tensile properties of GFRP bars[J]. Composites Part B, 2013, 45(1):835-844.
    [19] CHEN Y. Accelerated aging tests and long-term prediction models for durability of FRP bars in concrete[D]. Morgantown:West Virginia University, 2007.
    [20] NELSON W. Accelerated testing—Sustained models, test plans, and data analyses[M]. New York:Wiley, 1990.
    [21] LITHERLAND K L, OKLEY D R, PROCTOR B A. The use of accelerated aging procedures to predict the long term strength of GRC composites[J]. Cement and Concrete Research, 1981, 11(3):455-466.
    [22] 吴刚, 朱莹, 董志强, 等. 碱性环境中BFRP筋耐腐蚀性能试验研究[J]. 土木工程学报, 2014, 47(8):32-41.WU Gang, ZHU Ying, DONG Zhiqiang, et al. Experimental study on the corrosion resistance performance of BFRP bars in the alkaline environment[J]. China Civil Engineering Journal, 2014, 47(8):32-41. (in Chinese)
    [23] GONENC O. Durability and service-life prediction of concrete reinforcing materials[D]. Madison:University of Wisconsin-Madison, 2001.
    [24] 李承高, 郭瑞, 王俊琦, 等. CFRP@GFRP 混杂复合材料杆体在水浸泡环境下的性能演化[J]. 复合材料学报, 2021, 38(10):3290-3301.LI Chenggao, GUO Rui, WANG Junqi, et al. Property evolution of CFRP@GFRP hybrid composite rod exposed in the distilled water[J]. Acta Materiae Compositae Sinica, 2021, 38(10):3290-3301. (in Chinese)
    [25] 宣广宇, 陆春华, 徐可, 等. 不同侵蚀环境下GFRP筋抗拉性能退化试验[J]. 哈尔滨工业大学学报, 2020, 52(8):161-168.XUAN Guangyu, LU Chunhua, XU Ke, et al. Experiment on tensile properties of GFRP bars exposed to different aggressive environments[J]. Journal of Harbin Institute of Technology, 2020, 52(8):161-168. (in Chinese)
    [26] 王自柯. FRP筋在模拟海水-海砂混凝土孔溶液浸泡下的耐久性研究[D]. 哈尔滨:哈尔滨工业大学, 2018.WANG Zike. Study of the durability performances of fiber reinforced polymer(FRP) bars exposed to simulated seawater and sea sand concrete pore solution[D]. Harbin:Harbin Institute of Technology, 2018. (in Chinese)
    [27] 国家气象信息中心. 国家气象科学数据中心[DB/QL]. (2019-02-01) [2021-12-10]. http://data.cma.cn/forecast/index.html.National Meteorological Information Center. National meteorological science data center[DB/QL].(2019-02-01)[2021-12-10]. http://data.cma.cn/forecast/index.html.(in Chinese)
    [28] MUFTI A A, BANTHIA N, BENMOKRANE B, et al. Durability of GFRP composite rods[J]. Concrete International, 2007, 29(2):37-42.
    相似文献
    引证文献
引用本文

李文超,周广发,温福胜,刘福胜,焦裕钊.混凝土环境中GFRP筋性能衰退的规律及机理[J].建筑材料学报,2023,26(2):156-162

复制
分享
文章指标
  • 点击次数:161
  • 下载次数: 517
  • HTML阅读次数: 17
  • 引用次数: 0
历史
  • 收稿日期:2021-12-20
  • 最后修改日期:2022-04-27
  • 在线发布日期: 2023-03-06
文章二维码
您是第 位访问者
主管单位 :教育部
主办单位 :同济大学
地址 :上海市四平路1239号同济大学综合楼1701室
电话 :021-65981597 传真 :021-65981597
建筑材料学报 ® 2025 版权所有