Reliability Analysis of Compressive Fatigue Life of Cement Concrete under Temperature Differential Cycling

IF 1.5 4区工程技术 Q3 CONSTRUCTION & BUILDING TECHNOLOGY

Advances in Civil Engineering Pub Date : 2024-01-31 DOI:10.1155/2024/8852631

Chengyun Tao, Lin Dong, Tianlai Yu, Qian Chen

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引用次数: 0

Abstract

Cement concrete, as an extensively used engineering material, is omnipresent in various infrastructure projects such as bridges and roads. However, these structures often need to operate for extended periods under varying and harsh environmental conditions, facing not only complex vehicular loads but also the effects of temperature differential cycling. Consequently, understanding how temperature differential cycling impacts the compressive fatigue life of cement concrete has become a pivotal research topic. In this study, through a comprehensive experimental design, the fatigue life of cement concrete under typical temperature difference conditions (20–60°C) and different number of temperature differential cycling (60, 120, 180, 240, 300) was tested at three stress levels (0.70, 0.75, 0.85). Statistical analysis was conducted to obtain the Weibull distribution parameters of the compressive fatigue life of cement concrete. The P_f–S–N relationship of concrete considering reliability was analyzed, and a fatigue life prediction model under different reliability probabilities was established. The results show that the fatigue life of concrete subjected to temperature differential cycling follows a two-parameter Weibull distribution well. From the P_f–N curve, it can be seen that, regardless of the stress level, the calculated fatigue life under the same reliability probability decreases with the increase of temperature differential cycling times. At a 95% reliability probability, the decrease can reach 77.5%–87.5%. Based on the exponential function, a concrete fatigue life prediction model based on different reliability levels was established. Using this model, the S–lgN curve was plotted, and it was found that, regardless of the temperature differential cycling, an increase in reliability probability could lead to a 7.3%–14.4% reduction in logarithmic fatigue life (lgN). Additionally, this study also defined a fatigue life safety factor related to the number of temperature differential cycling and reliability probability, aiming to provide a theoretical basis for the design of cement concrete materials under the coupled environment of temperature differential cycling and fatigue loading.

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温差循环条件下水泥混凝土抗压疲劳寿命的可靠性分析

水泥混凝土作为一种广泛使用的工程材料，在桥梁和道路等各种基础设施项目中无处不在。然而，这些结构往往需要在不同的恶劣环境条件下长时间运行，不仅要面对复杂的车辆荷载，还要面对温差循环的影响。因此，了解温差循环如何影响水泥混凝土的抗压疲劳寿命已成为一个关键的研究课题。本研究通过综合实验设计，测试了水泥混凝土在典型温差条件（20-60°C）和不同温差循环次数（60、120、180、240、300）下的疲劳寿命，应力水平分别为 0.70、0.75、0.85。通过统计分析得出了水泥混凝土抗压疲劳寿命的 Weibull 分布参数。分析了考虑可靠性的混凝土 Pf-S-N 关系，建立了不同可靠性概率下的疲劳寿命预测模型。结果表明，混凝土在温差循环作用下的疲劳寿命很好地遵循了双参数 Weibull 分布。从 Pf-N 曲线可以看出，无论应力水平如何，在相同的可靠概率下，计算出的疲劳寿命随着温差循环次数的增加而减少。在 95% 的可靠性概率下，下降幅度可达 77.5% 至 87.5%。根据指数函数，建立了基于不同可靠性水平的混凝土疲劳寿命预测模型。利用该模型绘制了 S-lgN 曲线，结果发现，无论循环温差如何，可靠性概率的增加都会导致对数疲劳寿命（lgN）减少 7.3%-14.4%。此外，该研究还定义了与温差循环次数和可靠性概率相关的疲劳寿命安全系数，旨在为水泥混凝土材料在温差循环和疲劳荷载耦合环境下的设计提供理论依据。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Advances in Civil Engineering Engineering-Civil and Structural Engineering

CiteScore

4.00

自引率

5.60%

发文量

612

审稿时长

15 weeks

期刊介绍： Advances in Civil Engineering publishes papers in all areas of civil engineering. The journal welcomes submissions across a range of disciplines, and publishes both theoretical and practical studies. Contributions from academia and from industry are equally encouraged. Subject areas include (but are by no means limited to): -Structural mechanics and engineering- Structural design and construction management- Structural analysis and computational mechanics- Construction technology and implementation- Construction materials design and engineering- Highway and transport engineering- Bridge and tunnel engineering- Municipal and urban engineering- Coastal, harbour and offshore engineering-- Geotechnical and earthquake engineering Engineering for water, waste, energy, and environmental applications- Hydraulic engineering and fluid mechanics- Surveying, monitoring, and control systems in construction- Health and safety in a civil engineering setting. Advances in Civil Engineering also publishes focused review articles that examine the state of the art, identify emerging trends, and suggest future directions for developing fields.