Abstract
AbstractNickel-based alloys play an important role in the field of high-temperature alloys, which are widely used in nuclear reactors, aerospace and components of turbomachinery. However, the high susceptibility of welding hot crack is a main shortcoming to nickel-based alloys. One of the methods that reduce hot cracking susceptibility is by adjusting element constitution of weld metal and another method is by reducing transient stress. This article used finite element method to study the effect of cooling source on transient stress of the nickel-based alloy weld joint. The selection of appropriate cooling technique can decrease the peak of the transient von Mises stress and make the tensile stress turn into compressive stress, which is beneficial to reduce hot cracking susceptibility. The peak of the transient von Mises stress decreases as the cooling intensity increases from 0 to 15,000 W/m2 K, but increases if the cooling intensity is ineffective. When the distance between cooling source and heat source reaches 35 mm, the weld can get larger region of compressive stress. The peak of the transient von Mises stress decreases with increasing radius of cooling source and reaches minimum value at 12 mm. Combined cooling is more effective in reducing the peak of this stress than the conventional single trailing cooling source.
Highlights
Nickel-based alloys play an important role in the field of high-temperature alloys, which are widely used in nuclear reactors, aerospace and components of turbomachinery
Solidification cracking and liquation cracking occur by the solid–liquid interface separation in brittle temperature range (BTR), which is lower than the melting point of nickel-based alloys
The effect of cooling source parameters on the transient von Mises stress and hot cracking susceptibility of Nicrofer 6023H sheets was investigated by numerical simulation
Summary
Abstract: Nickel-based alloys play an important role in the field of high-temperature alloys, which are widely used in nuclear reactors, aerospace and components of turbomachinery. This article used finite element method to study the effect of cooling source on transient stress of the nickel-based alloy weld joint. The selection of appropriate cooling technique can decrease the peak of the transient von Mises stress and make the tensile stress turn into compressive stress, which is beneficial to reduce hot cracking susceptibility. Nickel-based alloys are the most widely used superalloys for the applications requiring heat and corrosion resistance such as nuclear reactors, aerospace and components of turbomachinery It has higher hot cracking susceptibility than carbon steel and stainless steel during welding. Transient stress plays an important role in reducing the hot cracking sensitivity of nickel-based weld but not residual stress. In this study, the effect of cooling technique in reducing the transient stress and playing down the hot crack sensitivity of nickel-based weld is discussed
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