Investigations on the thermal conditions during laser beam welding of high-strength steel 100Cr6

IF 3.9 Q2 ENGINEERING, INDUSTRIAL
Eric Wasilewski, Nikolay Doynov, Ralf Ossenbrink, Vesselin Michailov
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Abstract

This study examines the thermal conditions during laser beam welding of 100Cr6 high-strength steel using a TruDisk5000 disc laser with a continuous adjustable power range of 100–5000 W. Two parameter sets, characterized by laser power and welding speeds, were analyzed by thermal-metallurgical FE simulations to determine their impact on the thermal conditions during welding. The results show a significant shift in heat coupling, with conduction transitioning to deep penetration welding. As a result of the high welding speeds and reduced energy input, extremely high heating rates up to 2∙104 K s−1 (set A) respectively 4∙105 K s−1 (set B) occur. Both welds thus concern a range of temperature state values for which conventional Time-Temperature-Austenitization (TTA) diagrams are currently not defined, requiring calibration of the material models through general assumptions. Also, the change in energy input and welding speed causes significantly steep temperature gradients with a slope of approximately 5∙103 K mm−1 and strong drops in the temperature rates, particularly in the heat affected zone. The temperature cycles also show very different cooling rates for the respective parameter sets, although in both cases they are well below a cooling time t8/5 of 1 s, so that the phase transformation always leads to the formation of martensite. Since the investigated parameters are known to cause a loss of technological strength and conditionally result in cold cracks, these results will be used for further detailed experimental and numerical investigation of microstructure, hydrogen distribution, and stress-strain development at different restraint conditions.

100Cr6高强度钢激光焊接热条件的研究
本研究使用功率范围为100 - 5000w的连续可调TruDisk5000圆盘激光器,研究了100Cr6高强度钢的激光束焊接过程中的热条件。通过热冶金有限元模拟,分析了激光功率和焊接速度两组参数对焊接过程热条件的影响。结果表明,热耦合发生了明显的转变,由传导过渡到深熔接。由于焊接速度快,能量输入少,加热速率极高,分别达到2∙104 K s−1 (a组)和4∙105 K s−1 (B组)。因此,这两个焊接都涉及到一系列温度状态值,而传统的时间-温度-奥氏体化(TTA)图目前还没有定义,需要通过一般假设来校准材料模型。此外,能量输入和焊接速度的变化导致温度梯度急剧下降,斜率约为5∙103 K mm−1,温度速率急剧下降,特别是在热影响区。在不同的参数下,温度循环也显示出不同的冷却速率,尽管在这两种情况下,它们都远低于冷却时间8/5 (1 s),因此相变总是导致马氏体的形成。由于已知所研究的参数会导致技术强度损失并有条件地导致冷裂纹,因此这些结果将用于进一步详细的微观结构、氢分布和不同约束条件下应力-应变发展的实验和数值研究。
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 Industrial and Manufacturing Engineering
Advances in Industrial and Manufacturing Engineering Engineering-Engineering (miscellaneous)
CiteScore
6.60
自引率
0.00%
发文量
31
审稿时长
18 days
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