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《建筑科学与工程学报》[ISSN:1673-2049/CN:61-1442/TU]

Issue:

2024年02期

Page:

49-57

Research Field:

建筑结构

Publishing date:

Info

Title:

Research on restrained shrinkage effect of composite beam stud on high performance concrete

Author(s):

ZHAN Yulin¹; 2;  WANG Jikun¹;  SHAO Junhu³;  SHEN Dong⁴;  JING Guoqiang⁵;  JIA Yinjun¹

(1. School of Civil Engineering, Southwest Jiaotong University, Chengdu 610031, Sichuan, China; 2.Institute of Civil Engineering Materials, Southwest Jiaotong University, Chengdu 610031, Sichuan, China; 3.School of Architecture and Civil Engineering, Chengdu University, Chengdu 610106, Sichuan, China; 4.Wenzhou Qidu Bridge North Branch Bridge Construction Co., Ltd, Wenzhou 325052, Zhejiang, China; 5.China Railway Bridge Science Research Institute, Ltd, Wuhan 430034, Hubei, China)

Keywords:

steel-concrete composite beam;  stud;  high performance concrete;  orthogonal test;  restrained shrinkage;  cracking risk

PACS:

TU528.572

DOI:

10.19815/j.jace.2022.03142

Abstract:

In order to explore the shrinkage characteristics and cracking behavior of high performance concrete under stud restrained, steel-concrete composite components were made, and the effects of different factors of studs on the shrinkage strain, restrained degree and cracking risk of high performance concrete were analyzed through experiments. The effect of stud diameter, spacing and height on restrained shrinkage of high performance concrete was study by orthogonal test, and the main sensitive factors were obtained. The results show that the development trend of restrained shrinkage strain of high performance concrete is smoother than that of ordinary concrete. The sensitivity of each factor to restrained shrinkage is in the order of diameter, spacing and height. The concrete shrinkage presents a certain shrinkage gradient in the height direction, and the restrained shrinkage strain increases with the increase of height. But the stud height changing at 30 mm, spacing changing at 75 mm, diameter changing at 150 mm have little effect on restrained shrinkage. The restrained effect of studs on concrete can be defined as three stages, namely, the restrained enhancement stage, the restrained descent stage and the restrained stability stage. The maximum cracking risk of composite beam members occurs at the root of studs. When the stud spacing decreases from 150 mm to 75 mm, and the diameter increases from 13 mm to 22 mm, the maximum cracking risk increases by 20.03% and 36.05%, respectively. But the change of stud height has no effect on the maximum cracking risk. The shrinkage and cracking risk of concrete can be effectively reduced by using high performance concrete and stud arrangement with small diameter and high height.

References:

[1] 雷 瑛,梁腾飞.玄武岩纤维增强钢筋混凝土早期开裂及抗压强度分析[J].合成纤维,2021,50(2):54-57.
LEI Ying,LIANG Tengfei.Analysis of early cracking and compressive strength of basalt fiber reinforced concrete[J].Synthetic Fiber in China,2021,50(2):54-57.
[2]ZHANG Y D,AFROZ S,NGUYEN Q D,et al.Analytical model predicting the concrete tensile stress development in the restrained shrinkage ring test[J].Construction and Building Materials,2021,307:124930.
[3]GILBERT R I.Cracking caused by early-age deformation of concrete-prediction and control[J].Procedia Engineering,2017,172:13-22.
[4]马丽娜,贡金鑫,赵艳华.高性能混凝土约束收缩对氯离子扩散的影响[J].建筑科学与工程学报,2017,34(6):85-92.
MA Lina,GONG Jinxin,ZHAO Yanhua.Influence of constrained shrinkage cracking on chloride ion diffusivity of high performance concrete[J].Journal of Architecture and Civil Engineering,2017,34(6):85-92.
[5]DEBOODT T,FU T F,IDEKER J H.Evaluation of FLWA and SRAs on autogenous deformation and long-term drying shrinkage of high performance concrete[J].Construction and Building Materials,2016,119:53-60.
[6]王 钧,栾 奕,叶焕军.玄武岩纤维混凝土梁裂缝和变形试验研究[J].建筑科学与工程学报,2016,33(4):76-81.
WANG Jun,LUAN Yi,YE Huanjun.Experimental research on crack and deformation of basalt fiber reinforced concrete beams[J].Journal of Architecture and Civil Engineering,2016,33(4):76-81.
[7]KHAN I,XU T F,CASTEL A,et al.Early-age tensile creep and shrinkage-induced cracking in internally restrained concrete members[J].Magazine of Concrete Research,2019,71(22):1167-1179.
[8]HUANG L P,HUA J M,KANG M,et al.Influence of reinforcement configuration on the shrinkage and cracking potential of high-performance concrete[J].Construction and Building Materials,2017,140:20-30.
[9]SUN G J,XUE S D,QU X S,et al.Experimental investigation of creep and shrinkage of reinforced concrete with influence of reinforcement ratio[J].Advances in concrete construction,2019,7(4):211-218.
[10]李 聪,陈宝春,黄卿维.超高性能混凝土圆环约束收缩试验研究[J].工程力学,2019,36(8):49-58.
LI Cong,CHEN Baochun,HUANG Qingwei.Experimental research on shrinkage of ultra-high performance concrete under restrained rings[J].Engineering Mechanics,2019,36(8):49-58.
[11]程 新,詹炳根,周 安.玄武岩纤维对泡沫混凝土收缩开裂的影响[J].合肥工业大学学报(自然科学版),2019,42(8):1114-1118.
CHENG Xin,ZHAN Binggen,ZHOU An.Effect of basalt fiber on shrinkage and cracking of foam concrete[J].Journal of Hefei University of Technology(Natural Science),2019,42(8):1114-1118.
[12]李福海,文 涛,唐慧琪,等.干寒大温差下早龄期混凝土收缩特性及防裂技术[J].西南交通大学学报,2023,58(6):1405-1412.
LI Fuhai,WEN Tao,TANG Huiqi,et al.Shrinkage characteristics and anti-crack technology of early-age concrete under large dry-cold temperature difference[J].Journal of Southwest Jiaotong University,2023,58(6):1405-1412.
[13]王 成,张立宇,姜怡林,等.混凝土圆环约束收缩性能试验研究[J].路基工程,2022(1):58-61.
WANG Cheng,ZHANG Liyu,JIANG Yilin,et al.Experimental research on ring-constrained shrinkage performance of concrete[J].Subgrade Engineering,2022(1):58-61.
[14]HOSSAIN A B,WEISS J.Assessing residual stress development and stress relaxation in restrained concrete ring specimens[J].Cement and Concrete Composites,2004,26(5):531-540.
[15]混凝土物理力学性能试验方法标准:GB/T 50081-2019[S].北京:中国建筑工业出版社,2019.
Standard for test methods of concrete physical and mechanical properties:GB/T 50081-2019[S].Beijing:China Architecture & Building Press,2019.
[16]FU Q A,XU W R,BU M X,et al.Orthogonal experimental study on hybrid-fiber high-durability concrete for marine environment[J].Journal of Materials Research and Technology,2021,13:1790-1804.
[17]王 婧.高强钢纤维混凝土收缩性能研究[J].硅酸盐通报,2017,36(8):2869-2873.
WANG Jing.Experiment study on the shrinkage behavior of high performance steel fiber reinforced concrete[J].Bulletin of the Chinese Ceramic Society,2017,36(8):2869-2873.
[18]崔乃夫,崔宏环,刘卫涛,等.玄武岩纤维混凝土力学性能影响因素及机理分析[J].低温建筑技术,2018,40(5):1-4.
CUI Naifu,CUI Honghuan,LIU Weitao,et al.Analysis of influence factors of mechanical properties of basalt fiber concrete[J].Low Temperature Architecture Technology,2018,40(5):1-4.
[19]华建民,刘 琦,冯 超.高强混凝土收缩与栓钉内约束相互作用的影响研究[J].硅酸盐通报,2018,37(3):873-880.
HUA Jianmin,LIU Qi,FENG Chao.Interaction between high-strength concrete shrinkage and interior restraint of the stud[J].Bulletin of the Chinese Ceramic Society,2018,37(3):873-880.
[20]HOSSAIN A B,WEISS J.Assessing residual stress development and stress relaxation in restrained concrete ring specimens[J].Cement and Concrete Composites,2004,26(5):531-540.

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Last Update: 2024-03-25