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    Cr-Mo-B系NM500耐磨钢的制备及热处理工艺优化

    Preparation and Heat Treatment Process Optimization of Cr-Mo-B Series NM500 Wear Resistant Steel

    • 摘要: 在Cr-Mo-B系NM450钢成分基础上调整合金元素含量,采用洁净钢生产技术和轧制工艺制备20 mm厚NM500耐磨钢板,并进行淬火和回火处理,研究了不同淬火温度(880,900,920 ℃)和回火温度(200,250,300,350,400 ℃)下试验钢的显微组织与性能,获得最佳的热处理工艺。结果表明:随着淬火温度升高,试验钢组织中未溶铁素体减少,奥氏体晶粒尺寸先减小后略微增大,抗拉强度、−20 ℃冲击吸收能量与表面硬度均增大,而断后伸长率降低;除了880 ℃淬火后的表面硬度不满足标准要求,其他条件下淬火态试验钢的力学性能均满足标准要求。920 ℃淬火后随着回火温度升高,马氏体分解加速,基体中固溶碳含量减少,碳化物增多,强度整体呈降低趋势,断后伸长率先降后增再降,−20 ℃冲击吸收能量和表面硬度均降低;弯曲试验后仅200 ℃回火试样未发生断裂且表面无微裂纹产生,200 ℃回火后的磨损质量损失明显小于400 ℃回火后。920 ℃淬火+200 ℃回火后,试验钢的综合力学性能最优,表面硬度为496 HBW,抗拉强度为1 552 MPa,断后伸长率为15.0%,−20 ℃冲击吸收能量为46 J,180°冷弯性能合格,均达到GB/T 24186—2022标准要求。

       

      Abstract: Throgh adjusting alloy element content on the basis of the composition of Cr-Mo-B series NM450 steel, the 20 mm thick NM500 wear resistant steel plate was prepared by clean steel production technology and rolling process, and then was quenched and tempered. The microstructure and properties of the test steel at different quenching temperatures (880,900,920 ℃) and tempering temperatures (200,250,300,350,400 ℃) were studied, and the best heat treatment process was obtained. The results show that with the increase of quenching temperature, the undissolved ferrite in the test steel microstructure decreased, the austenite grain size first decreased and then slightly increased, the tensile strength, −20 ℃ impact absorbed energy and surface hardness all increased, and the percentage elongation after fracture decreased. In addition to the surface hardness after quenching at 880 ℃ did not meet the standard requirements, the mechanical properties of the test steel under other conditions met the standard requirements. After quenching at 920 ℃, with the increase of tempering temperature, the decomposition of martensite accelerated, the carbon content soluted in the matrix decreased, the number of carbides increased, the strength showed an overall decreasing trend, the percentage elongation after fracture first decreased, then increased and then decreased, and −20 ℃ impact absorbed energy and surface hardness both decreased. After bending test, only the 200 ℃ tempered sample did not fracture and there were no microcracks on the surface. The wear mass loss after tempering at 200 ℃ was significantly less than that after tempering at 400 ℃. After quenching at 920 ℃ and tempering at 200 ℃, the test steel had the best comprehensive mechanical properties with surface hardness of 496 HBW, tensile strength of 1 552 MPa, percentage elongation after fracture of 15.0%, −20 ℃ impact absorbed energy of 46 J, and qualified 180 ° cold bending property, and the properties all met the requirements of GB/T 24186—2022 standard.

       

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