Study on ultimate bearing capacity of CHS X-joints strengthened with CFRP

YANG Yong; HE Xiang

doi:10.12299/jsues.23-0109

Volume 37 Issue 3

Sep. 2023

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Article Navigation > Journal of Shanghai University of Engineering Science > 2023 > 37(3): 296-304

YANG Yong, HE Xiang. Study on ultimate bearing capacity of CHS X-joints strengthened with CFRP[J]. Journal of Shanghai University of Engineering Science, 2023, 37(3): 296-304. doi: 10.12299/jsues.23-0109

Citation:

YANG Yong, HE Xiang. Study on ultimate bearing capacity of CHS X-joints strengthened with CFRP[J]. Journal of Shanghai University of Engineering Science, 2023, 37(3): 296-304. doi: 10.12299/jsues.23-0109

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Study on ultimate bearing capacity of CHS X-joints strengthened with CFRP

doi: 10.12299/jsues.23-0109

YANG Yong,
HE Xiang

School of Civil Engineering, Guizhou University, Guiyang 550025, China

Received Date: 2023-04-25
Publish Date: 2023-09-30

Abstract

Abstract

In order to study the influence of carbon fiber reinforced plastic (CFRP) on the X-shaped circular steel tubular joints, the ABAQUS finite element software was redeveloped. The VGM model was compiled into the VUSDFLD subroutine by Fortran language. The finite element analysis of 90 joint models was carried out, and the effects of the ratio of the outer diameter of the branch to the main pipe β, the ratio of the diameter to the thickness of the main pipe γ, the ratio of the length of CFRP to the diameter of the main pipe L, and the number of CFRP layers n on the bearing capacity of the joints were studied. The results show that CFRP can reduce the stress concentration of the joint and improve the bearing capacity of the joint. The cracking of the joint will occur at the weld root where the inner side of the saddle point weld of the intersecting line intersects with the branch pipe. With increasing of the load, the crack develops from the weld saddle point along the intersecting line to the crown point. Parameters analysis of the joint show that with the increasing of γ, the ultimate bearing capacity of the joint decreases gradually, with the increasing of β, the ultimate bearing capacity of the joint increases gradually, with the increasing of n and L, the ultimate bearing capacity of the joint will increase. For the failure of the joint occured in the weld, the formula for the weld bearing capacity of the CFRP strengthened X-shaped circular steel tube intersecting joint was proposed. Compared with the finite element results, it can be found that the results of the formula fitted are unsafe when the wall thickness of the main pipe of the joint is small and the outer diameter of the branch pipe is large.
- strengthening,
- intersecting connection,
- carbon fiber reinforced plastic (CFRP),
- subroutine,
- weld bead

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References(18)

References

[1]	黄政华, 张其林, 杨宗林, 等. 平面钢管桁架的面外稳定分析模型研究[J] . 土木工程学报,2011,44(5):49 − 56.
[2]	陈以一, 陈扬骥. 钢管结构相贯节点的研究现状[J] . 建筑结构,2002,32(7):52 − 55.
[3]	丁芸孙. 圆管结构相贯节点几个设计问题的探讨[J] . 空间结构,2002,18(4):13 − 15.
[4]	蔡艳青, 邵永波, 岳永生. 环口板加强型T型圆钢管节点承载力的试验研究[J] . 工程力学,2011,28(9):90 − 94, 102.
[5]	HAN J, LIANG Y. The strength research of pressure pipeline reinforced with CFRP[J] . Applied Mechanice and Materials,2013,4:446 − 447.
[6]	ELCHALAKANI M. Rehabilitation of corroded steel CHS under combined bending and bearing using CFRP[J] . Journal of Constructional Steel Research,2016,125:26 − 42.
[7]	王东锋, 邵永波, 欧佳灵. CFRP加固含腐蚀缺陷圆钢管混凝土短柱轴压承载力试验研究[J] . 工程力学,2021,38(10):188 − 199.
[8]	KABIR, M. Z. A. NAZARI. Enhancing ultimate compressive strength of notch embedded steel cylinders using overwrap CFRP patch[J] . Applied Composite Materials,2011,19(3/4):723 − 738.
[9]	宋生志, 魏建军, 陈成. 碳纤维布(CFRP)加固T形圆钢管节点的静力性能研究[J] . 建筑钢结构进展,2015,17(2):57 − 64.
[10]	FU Y G, TONG L W, HE L, et, al. Experimental and numerical investigation on behavior of CFRP-strengthened circular hollow section gap K-joints[J] . Thin-Walled Structures,2016,102:80 − 97. doi: 10.1016/j.tws.2016.01.020
[11]	李康帅, 邵永波. CFRP加固TT型空心截面管节点轴压性能试验[J] . 空间结构,2022,28(3):86 − 91 , 76.
[12]	王伟, 廖芳芳, 陈以一, 等. 基于微观机制的钢结构节点延性断裂预测与裂后路径分析[J] . 工程力学,2014,31(3):101 − 108, 115.
[13]	RICE J R, TRACEY D M. On the ductile enlargement of voids in triaxial stress fields[J] . Journal of the Mechanics and Physics of Solids,1969,17(3):201 − 217.
[14]	LIAO F F, WANG W, CHEN Y Y, et al. Parameter calibrations and application of micromechanical fracture models of structural steels[J] . Structural Engineering & Mechanics,2012,42(2):153 − 17.
[15]	尹越, 车鑫宇, 韩庆华, 等. 基于微观断裂机制的XK型相贯节点极限承载力分析[J] . 土木工程学报,2017,50(7):20 − 26, 121.
[16]	马栋. 碳纤维加固圆钢管T型相贯节点受压性能试验研究[D]. 青岛: 山东科技大学, 2016.
[17]	邵永波, 史曼瑜. CFRP加固含凹痕缺陷的T形管节点静力性能研究[J] . 建筑钢结构进展,2020,22(4):68 − 74.
[18]	住房和城乡建设部. 钢结构设计标准: GB 50017—2017 [S]. 北京: 中国建筑工业出版社, 2018.