Abstract

We studied the influence of aging temperature on microstructure and mechanical properties in an ultra-low carbon Cu bearing steel in the present study. During the aging process, a continuous recovery of matrix associated with formation and growth of Cu precipitates could be observed during aging processes, exerting significant effects on the mechanical properties of the steel. At aging temperature below 600 °C, the mechanical properties were dominated by the precipitation strengthening effect, leading to excessive matrix strengthening and poor low-temperature toughness. Conversely, steel aged at temperatures above 650 °C exhibited an extraordinary improvement in toughness at the expense of strength, which can be attributed to the synergistic effects of softening matrix, coarsened Cu precipitates and formation of reverted austenite. After aging at 650 °C, reverted austenite formed at the lath boundaries. Increasing the aging temperature to 700 °C lowered the thermal stability of reverted austenite, consequently, the reverted austenite was partially transformed to fresh martensite. After aging at 650 °C for 0.5 h, the mechanical properties were optimized as follows—yield strength = 854 MPa, tensile strength = 990 MPa, elongation = 19.8% and Charpy impact energy = 132 J at −80 °C.

Highlights

  • Ultra-low carbon Cu-bearing steels, such as ASTM A710, HSLA-80, HSLA-100 and NUCu-140, have been extensively developed over recent decades [1,2,3,4]

  • When the aging temperature increased to 700 ◦ C, the thermal stability of the reverted austenite was decreased because the average contents of the austenite-stabilizing elements were lowered

  • The formation and coarsening of Cu precipitates increased with aging temperature

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Summary

Introduction

Ultra-low carbon Cu-bearing steels, such as ASTM A710, HSLA-80, HSLA-100 and NUCu-140, have been extensively developed over recent decades [1,2,3,4]. In practical applications, these steels require high strength, good low temperature toughness and excellent weldability. Because the C additive decreases the weldability and impact toughness of steel, decreasing the C content without adversely affecting the mechanical properties has been a significant strategy in steel development. Understanding the Cu precipitation mechanism is crucial for improving the mechanical properties of Cu-bearing steels. The early stage of Cu precipitation is characterized by coherent body-centered cubic (bcc) particles with small size (

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