Abstract
Selective laser surface melting, which brings together the bionic theory and the laser process, is an effective way to enhance the thermal fatigue behavior of materials. In this study, in order to examine the relationship between the mechanical properties and thermal fatigue behavior of materials processed by selective laser surface melting, the tensile properties at room temperature and elevated temperature of treated specimens and untreated specimens after different numbers of thermal fatigue cycles were investigated and compared. Moreover, the microstructure evolution and the microhardness of the laser-affected zone were investigated after different numbers of thermal fatigue cycles. The results show that microhardness of the laser-melted zone gradually decreases with an increasing number of thermal fatigue cycles; the number of thermal fatigue cycles has little effect on the grain size in the laser-melted zone, and the percentage of low-angle grain boundaries decreases with an increasing number of thermal fatigue cycles. The strength of specimens gradually decreases, whereas the fracture elongation gradually increases with an increasing number of thermal fatigue cycles at room temperature and elevated temperature. In addition, the stress distribution on the specimen surface during tensile test was investigated using the finite element method, and the results indicate that the stress transfer exists between the laser-affected zone and the untreated zone.
Highlights
H13 tool steel, which is mainly comprised of Cr-Mo-V element in different percentages, belongs to the chromium hot-work tool steel
The results of the experimental studies and practical applications show that H13 hot-work tool steel with the alternating hard and soft structure processed by the selective laser surface melting can increase the thermal fatigue behavior
The laser-affected zone contains a part of martensite and retained austenite
Summary
H13 tool steel, which is mainly comprised of Cr-Mo-V element in different percentages, belongs to the chromium hot-work tool steel. The bionic laser surface treatment method has been carried out to enhance the thermal fatigue behavior of hot-work tool steel. This new method combines the laser surface processing with the bionic theory, and it is a selective process on the surface of materials. Cong et al [28,29,30] used the selective laser surface melting and alloying to repair hot cracks on H13 hot-work tool steel and suggested that the repaired specimens processed by selective laser treatment can increase the thermal fatigue life. The results of the experimental studies and practical applications show that H13 hot-work tool steel with the alternating hard and soft structure processed by the selective laser surface melting can increase the thermal fatigue behavior. The finite element as an attempt, was adopted to understand the stress distribution of the specimen during tensile testing
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