Analysis on Temperature Sensitivity and Cracking Causes of Suspension Bridge Anchorage Based on Numerical Simulation

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Abstract Mass concrete, a common structure in bridge engineering, is frequently threatened by cracking. Based on the gravity anchorage of a long-span suspension bridge that has been in operation for more than ten years, the causes of the cracks growing year by year in the anchorage were analyzed in this paper. The refined numerical model of the anchorage was established via the space finite element software. Taking full account of the environmental characteristics of the bridge site, the temperature sensitivity of the anchorage was simulated and analyzed, and the stress distributions on the surface of each side of the anchorage at different temperatures were analyzed. The calculation results showed that there is little correlation between anchorage cracking and anchorage bolt force. Under condition 2 temperature increased 20 ℃, the principal tensile stress of anchorage reached to 1.5 times of the allowable stress, Under condition 6 anchorage surface from 40 ℃ suddenly dropped to 20 ℃, the principal tensile stress reached to 2.4 times of the allowable stress. Thus, under the dual effects of internal and external constraints, the cold hit effect of the mass concrete anchorage resulted in the sudden drop of the surface temperature of the anchorage concrete to produce "internal constraint cracks", and the overall temperature rise caused the expansion of the anchorage concrete to produce "external constraint cracks". The two types of cracks led to the vertical cracks of the anchorage. Besides, the environmental and construction factors were the main causes of cracking of transverse construction joints. At last, the anchorage was reinforced with high-performance concrete with an anti-crack reinforcement mesh, which presented good results in the follow-up observation, providing a certain reference value for similar projects.

Key words： bridge engineering temperature sensitivity refined numerical model suspension bridge anchorage cold hit effect internal constraint crack external constraint crack mass concrete

Received: 08 April 2022

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	JI Wei
	ZUO Xin-dai

Cite this article:

JI Wei,ZUO Xin-dai. Analysis on Temperature Sensitivity and Cracking Causes of Suspension Bridge Anchorage Based on Numerical Simulation[J]. Journal of Highway and Transportation Research and Development, 2022, 16(4): 33-42.

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http://journal10.magtechjournal.com/Jwk_gljtkj_en/EN/ OR http://journal10.magtechjournal.com/Jwk_gljtkj_en/EN/Y2022/V16/I4/33

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