A Study of the Effect of Post-Heating Pulse on Hot Cracking Susceptibility in Pulsed Laser Welding of Invar Alloy

IF 0.5 4区 工程技术 Q4 ENGINEERING, MARINE
Dong-sheng Zhao, Zhen-yu Huang, Yujun Liu, T. Miao
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引用次数: 1

Abstract

Hot cracking is one of the major challenges in laser welding of Invar alloy. In this study, welding hot cracking susceptibility experiments are conducted with fish-bone-type Invar alloy sheets under pulsed laser welding condition. The pulse wave consists of two distinct power levels: welding pulse and post-heating pulse. The welding temperature field can be controlled by changing the duration of the post-heating pulse. The results of experimental measurements and finite element method calculation show that increasing of the post-heating pulse duration leads to a decline in the cooling rate of weld metal within the brittle temperature range, although the welding hot cracking susceptibility decreases at first and then increases. Neither the heat input nor the cooling rate is the only decisive factor for hot cracking during the welding process. Invar alloy is widely applied in precision measurement devices and low-temperature-resistant structures for its low linear expansion coefficient at ambient temperature, which is less than 1.6 × 10—6 k—1, about 1/10 of the low carbon steel, and it changes very little within a large temperature range (Corbacho et al. 1998; Park et al. 2011; Zhao et al. 2015; Qiu et al. 2016). With the increase in demand for natural gas, the liquefied natural gas (LNG) carrier has been developed rapidly as a means of long-distance transport. The material of primary and secondary barriers on the containment insulation system of membrane-type LNG carrier is welded Invar alloy with a thickness of .7 mm, which directly contacts the — 163°C LNG (American Bureau of Shipping 2006; Bureau Veritas 2011; Wang et al. 2006). The total weld length of Invar alloy on an LNG carrier over 13 million cubic meters can reach up to 100 km according to statistics. Hot cracking is the major problem in the welding of Invar alloy, and currently Tungsten inert gas (TIG) arc welding is commonly used. However, the problem of hot cracking cannot be solved completely, and requires that the operator have good technical knowledge. Invar alloy has high hot cracking susceptibility during the welding process because of its single-phase austenite structure and high content of Ni (Kou 2003). Studies show that the welding hot cracking susceptibility of Invar alloy can be reduced when elements such as Ti, Mn, and Mo are added (Hirata et al. 2001), but these alloying elements will increase the linear expansion coefficient of the weld, resulting in the deterioration of mechanical properties at low temperature. Thus, laser welding and friction stir welding are proposed by researchers to solve the welding hot cracking problem of Invar alloy from the aspect of reducing welding heat input.
后加热脉冲对因瓦尔合金脉冲激光焊接热裂敏感性的影响研究
热裂是英瓦尔合金激光焊接的主要难题之一。在脉冲激光焊接条件下,对鱼骨型Invar合金薄板进行了焊接热裂敏感性试验。脉冲波由两个不同的功率级组成:焊接脉冲和后加热脉冲。通过改变后加热脉冲的持续时间,可以控制焊接温度场。实验测量和有限元计算结果表明,随着后加热脉冲持续时间的增加,焊缝金属在脆性温度范围内的冷却速率有所下降,但焊接热裂敏感性先减小后增大。在焊接过程中,热输入和冷却速度都不是热裂的唯一决定性因素。因瓦尔合金因其在常温下的低线性膨胀系数,小于1.6 × 10-6 k-1,约为低碳钢的1/10,在较大的温度范围内变化很小,被广泛应用于精密测量装置和耐低温结构中(Corbacho et al. 1998;Park et al. 2011;Zhao et al. 2015;Qiu et al. 2016)。随着天然气需求的增加,液化天然气(LNG)运输船作为一种长途运输工具得到了迅速发展。膜式LNG运输船密封保温系统的主、次屏障材料采用厚度为0.7 mm的英瓦尔合金焊接,直接接触- 163℃LNG(美国船级社2006;Bureau Veritas 2011;Wang et al. 2006)。据统计,1300多万立方米LNG运输船的因瓦尔合金焊缝总长度可达100公里。热裂是英瓦尔合金焊接中的主要问题,目前常用的是钨惰性气体(TIG)电弧焊。但热裂问题并不能完全解决,需要操作人员具备良好的技术知识。因瓦尔合金由于其单相奥氏体组织和高镍含量,在焊接过程中具有较高的热裂易感性(Kou 2003)。研究表明,添加Ti、Mn、Mo等元素可降低Invar合金的焊接热裂敏感性(Hirata et al. 2001),但这些合金元素会增加焊缝的线膨胀系数,导致低温下力学性能恶化。因此,研究人员提出了激光焊接和搅拌摩擦焊接,从减少焊接热输入的角度解决因瓦尔合金的焊接热裂问题。
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来源期刊
CiteScore
1.10
自引率
0.00%
发文量
19
期刊介绍: Original and timely technical papers addressing problems of shipyard techniques and production of merchant and naval ships appear in this quarterly publication. Since its inception, the Journal of Ship Production and Design (formerly the Journal of Ship Production) has been a forum for peer-reviewed, professionally edited papers from academic and industry sources. As such it has influenced the worldwide development of ship production engineering as a fully qualified professional discipline. The expanded scope seeks papers in additional areas, specifically ship design, including design for production, plus other marine technology topics, such as ship operations, shipping economics, and safety. Each issue contains a well-rounded selection of technical papers relevant to marine professionals.
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