Room-temperature stress reduction in welded joints through electropulsing

Conventional residual stress mitigation techniques involve long processing times at high temperatures and/or mechanical loading to build plastic compressive stress below the surface. In this study, we present a new residual stress mitigation methodology at near ambient temperature in less than a minute. This is demonstrated on a welded joint of 316 L stainless steel, where low-frequency DC current pulses are shown to recrystallize the specimen and reduce residual stress. We present experimental evidence of -30 % reduction in electrical resistance, which corresponded to -40 % decrease in both microhardness and residual stress, measured by the X-ray diffraction tests. Similar improvement was qualitatively observed through significant decrease in the low-angle grain boundary density, which also reflects the decrease of the residual stress. The technique can be applied to relieve residual stress in conditions difficult for the conventional processing, such as locations with extreme space constraints or objects that cannot be heat treated.

Automated summary

A new residual stress mitigation technique involving low-frequency DC current pulses is able to reduce residual stress in less than a minute near ambient temperature, as demonstrated on a welded joint of 316 L stainless steel. Experimental evidence showed significant reduction in electrical resistance, microhardness, and residual stress.