评估新开发的用于修复高强度钢结构的 LTT 合金成分的抗疲劳裂纹生长性能

IF 3.8 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY Journal of Advanced Joining Processes Pub Date : 2024-05-01 DOI:10.1016/j.jajp.2024.100226
Victor Igwemezie , Ali Mehmanparast , Supriyo Ganguly
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引用次数: 0

摘要

众所周知,拉伸残余应力(TRS)是影响焊接接头完整性的一个因素。焊接过程中产生的 TRS 会加速疲劳破坏。在过去的二十年里,人们一直致力于开发填充合金,通过引入压残余应力(CRS)来降低 TRS,从而抵消高强度钢焊接接头中的 TRS。这些研究基于奥氏体(γ)向马氏体(α')转变的理论,填充合金通常被称为低转变温度(LTT)合金。许多研究报告表明,使用 LTT 合金制造的焊接接头的疲劳强度(FS)比传统填料高出许多倍。据报道,它在修复高强度钢结构方面特别有用。然而,有关这些 LTT 合金疲劳裂纹生长(FCG)行为的研究却很少。在这项工作中,我们开发了基于铁-铬-镍-钼的 LTT 焊接金属成分,评估了其 FCG 行为,并将结果与传统焊丝(ER70S-6)进行了比较。结果发现,ER70S-6 焊接金属在相对较快的冷却条件下具有极高的韧性,但相关热影响区(HAZ)的抗 FCG 性能较差,这掩盖了韧性焊接金属的优点。高热输入或导致 ER70S-6 焊接件冷却缓慢的情况会降低其抗 FCG 的能力。遗憾的是,尽管 LTT 合金的马氏体起始温度较低,为 231±7,而且预期诱导 CRS 会产生有利影响,但其抗 FCG 性能却最低。LTT 合金似乎有一种内在的微观结构特征或 "断层",降低了其抗 FCG 的能力。虽然 LTT 合金焊接金属的耐 FCG 性较差,但其相关 HAZ 的耐 FCG 性却高于 ER70S-6 焊接金属的相关 HAZ。据观察,将 ER70S-6 焊接金属与裂纹前沿垂直对齐可产生最高的抗疲劳裂纹萌生和扩展能力。就 ER70S-6 而言,焊接金属在缺口顶端诱发了 CRS,从而产生了较高的抗疲劳性。在 LTT 合金中,焊接金属的垂直排列略有改善。
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Assessment of fatigue crack growth resistance of newly developed LTT alloy composition for the repair of high strength steel structures

Tensile residual stress (TRS) is a well-known factor that deteriorate the integrity of welded joints. Fatigue failure is accelerated by the existence of TRS introduced during the welding process. There have been efforts in the last two decades to develop filler alloys that can reduce TRS by introducing compressive residual stress (CRS) to oppose the TRS in high strength steel welded joints. These works are based on the theory of austenite (γ) to martensite (α’) transformation and the filler is often called a low transformation-temperature (LTT) alloy. Many studies have reported that the fatigue strength (FS) of weld joint made with LTT alloy is many times better than that of the conventional fillers. It is reported to be particularly useful in the repair of high strength steel structures. However, studies on the fatigue crack growth (FCG) behaviour of these LTT alloys is scarce. In this work, we developed Fe-CrNiMo based LTT weld metal composition, assessed its FCG behaviour and compared the results with that of a conventional welding wire (ER70S-6). It is found that ER70S-6 weld metal obtained under relatively fast cooling is extremely tough, but the associated heat affected zone (HAZ) has poor resistance to FCG which obscured the benefit of the tough weld metal. High heat input or condition that results to slow cooling of the ER70S-6 weldment deteriorates its resistance to FCG. Unfortunately, despite its low martensite start temperature of 231±7 and the anticipated beneficial effect of induced CRS, the LTT alloy studied had the lowest FCG resistance. The LTT alloy appears to have an intrinsic microstructural feature or a ‘fault line’ that reduced its resistance to FCG. While the LTT alloy weld metal has poor resistance to FCG, the associated HAZ resisted FCG more than the HAZ associated with ER70S-6 weld metal. It is observed that aligning the ER70S-6 weld metal perpendicular to the crack front produced the highest resistance to fatigue crack initiation and propagation. In the case of ER70S-6, it is believed that the weld metal induced a CRS at the notch tip which resulted to the high fatigue resistance. In the case of the LTT alloy, perpendicular alignment of the weld metal produced slight improvement.

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CiteScore
7.10
自引率
9.80%
发文量
58
审稿时长
44 days
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