Investigation of the relationship between the strength limit and the long time fatigue of steel reinforcements of reinforced concrete structures

Transfer of innovative technologies Pub Date : 2021-10-29 DOI:10.32347/tit2021.42.0201

D. Chernyshev, Yulia Makarenko, T. Khomutetska, V. Makarenko

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Abstract

The results of experimental studies have shown a strong effect of diffusion hydrogen on the static and cyclic parameters of crack resistance of reinforcing steel. It was found that with increasing flooding, especially when the hydrogen content exceeds 5 cm3/100g, both static strength and long-term strength (fatigue) decrease sharply. Moreover, these areas of hydrogen solution in reinforcing steel are characterized by a viscous nature of fracture, while for heavily flooded reinforcement (from 5 to 12 cm3/100g) is characterized by brittle fracture by the mechanism of microcracking in the hardened (martensite or troostite structure). The analysis of the obtained experimental results allowed to determine the optimal hydrogen content in the reinforcing steel (3…5 cm3/100g), the excess of which can cause a decrease in the crack resistance of the reinforcement during long-term operation, especially in corrosive environments. The mechanism of hydrogen influence on crack resistance of metal at static and alternating loading which consists in diffusion and dislocation movement of hydrogen in structure of a reinforcing core that as a result that causes strong flooding of steel and its embrittlement is offered. It is established that carbon and low-alloy sieves, which are characterized by ferritic-pearlitic and sorbitol structure provide high resistance, especially to long-term fatigue, and the transition to steels with a structure of martensite or tempered (transient structure of bainite) structure of bainite sharply reduces reinforcing steel, which makes it impossible to use in the manufacture of reinforcement involved in reinforced concrete structures designed for long-term operation (more than 50…60 years). Thus, the obtained diagram can be recommended to designers of reinforced concrete structures for hydraulic purposes, as it greatly facilitates the reasonable choice of reinforcement in the development of reinforced concrete structures for responsible and long-term use.

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钢筋混凝土结构钢筋强度极限与长时间疲劳关系的研究

试验研究结果表明，扩散氢对钢筋抗裂性能的静态和循环参数有较强的影响。研究发现，随着注水量的增加，特别是当含氢量超过5 cm3/100g时，静强度和长期强度(疲劳强度)均急剧下降。此外，钢筋中氢溶液的这些区域具有粘性断裂的特征，而对于重度浸水的钢筋(从5到12 cm3/100g)则具有脆性断裂的特征，其机制是硬化(马氏体或troote组织)中的微裂纹。通过对所获得的实验结果的分析，可以确定钢筋中的最佳氢含量(3…5 cm3/100g)，过量的氢含量会导致钢筋在长期使用中抗裂性下降，特别是在腐蚀性环境中。提出了氢在静载荷和交变载荷作用下影响金属抗裂性能的机理，即氢在增强芯结构中的扩散和位错运动，从而引起钢的强浸水和脆化。结果表明，以铁素体-珠光体和山梨糖醇组织为特征的碳和低合金筛具有较高的抗疲劳性能，特别是抗长期疲劳性能，并且向马氏体组织或贝氏体回火组织(瞬态组织)转变的钢急剧减少了钢筋。这使得它不可能用于制造涉及长期使用(超过50…60年)的钢筋混凝土结构的钢筋。因此，所获得的图可以推荐给水工用钢筋混凝土结构的设计者，极大地促进了钢筋混凝土结构开发中合理选择钢筋，实现负责任和长期使用。

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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Transfer of innovative technologies

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