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Laser powder bed fusion of high-strength low-alloy steels with post-heat treatment design for enhanced mechanical performance

Soumya Sridar, Zhangwei Wang, Wei Xiong

2024Materials Science and Engineering A10 citationsDOIOpen Access PDF

Abstract

A commonly used structural steel, namely high-strength low-alloy (HSLA) steel, HSLA-100, was fabricated using the laser powder bed fusion process in this work. Critical processing parameters such as laser power and scanning speed for achieving the least porosity were identified. The designed post-heat treatment differs from the traditionally manufactured HSLA steels. The optimum homogenization time was 80 min at 950 °C with the lowest prior austenite grain size. The peak hardness was achieved after tempering at 550 °C for 5 h, and atom probe tomography showed that the fraction of Cu and M 2 C (M: Mo, Cr) was the highest along with the co-precipitation of these strengthening phases at this condition. The yield strength (YS) and elongation (%El) of the builds printed with optimized parameters (porosity∼0.5%, YS = 875 MPa, and %El = 23%) were superior to those printed with factory-default parameters (porosity∼3%, YS = 772 MPa, and %El = 15%) after applying the designed post-heat treatment. Despite the anisotropy observed in the low-temperature toughness, the ductile-to-brittle transition temperature is below −40 °C for samples with a notch in the XZ plane and between −20 and −40 °C for samples with a notch in the XY plane. This work demonstrates the successful adaptation of HSLA-100 steel in additive manufacturing, and thus is critical for scaling up engineering applications at a higher technology readiness level.

Topics & Concepts

Materials scienceAustenitePorosityHigh-strength low-alloy steelMetallurgyCharpy impact testAlloyToughnessComposite materialBrittlenessLaser power scalingCompactionMicrostructureLaserOpticsPhysicsAdditive Manufacturing Materials and ProcessesAdvanced Materials Characterization TechniquesHigh Entropy Alloys Studies