扫 描 看 全 文
程沛源,程东海.激光增材修复1Cr15Ni4Mo3N的力学性能与显微组织[J].电焊机,2022,52(7):18-23.
CHENG Peiyuan, CHENG Donghai.Microstructure and Mechanical Properties of Laser Additive Repair of 1Cr15Ni4Mo3N Steel[J].Electric Welding Machine, 2022, 52(7): 18-23.
为研究激光增材修复lCrl5Ni4Mo3N后,修复层的性能是否能够满足工作需要,开展激光增材修复lCr l5Ni4Mo3N力学性能与显微组织研究,利用WDW-100试验机检测修复试样的抗拉强度,利用光学显微镜(OM)和扫描电镜(SEM)观察接头显微组织及断口形貌。结果表明,激光增材修复lCrl5Ni4Mo3N成形良好,2 mm深修复试样抗拉强度可达母材的92.7%,3 mm深修复试样抗拉强度可达母材的89.7%,修复接头呈现韧性断裂;激光热循环作用下第二相粒子的粗化导致组织显微硬度值呈现:基体>修复层>热影响区;修复层与基体冶金结合致密,接头由基体、热影响区及修复层构成,基体主要由回火马氏体夹杂少量残余奥氏体构成,热影响区主要由回火马氏体夹杂少量回火索氏体构成,修复层由马氏体+奥氏体双相组织构成。
In order to study whether the properties of the repairing layer can meet the work needs after laser additive repair of lCrl5Ni4Mo3N, the mechanical properties and microstructure of laser additive repair of lCrl5Ni4Mo3N was conducted. WDW-100 testing machine was used to test the tensile strength of samples. The OM and SEM were used to survey and analyze the microstructure and fracture morphology of the joints. Research indicates that the forming of the laser additive repair of lCrl5Ni4Mo3N is good. The tensile strength of 2 mm deep repairing sample can reach 92.7% of the base material, the tensile strength of 3 mm deep repairing sample can reach 89.7% of the base material. The repairing joint shows ductile fracture. Due to coarsening of second-phase particles caused by laser thermal cycle, the microhardness value of microstructure are: base material>repairing layer>HAZ. The metallurgical combination of repairing layer and substrate is dense. The joint consists of base material,HAZ and repairing layer. The base material is mainly composed of tempered martensite and contains retained austenite,the HAZ is mainly composed of tempered martensite and contains tempered sorbite, and the repairing layer consists of a martensite and austenite dual-phase structure.
激光增材修复lCrl5Ni4Mo3N韧性断裂第二相粒子显微硬度
laser additive repairlCrl5Ni4Mo3Nductile fracturesecond phase particlemicrohardness
赵先存,宋为顺,杨志勇,等. 高强度超高强度不锈钢[M]. 北京:冶金工业出版社,2008.
张国军,陈凤,张贵一,等. 厚度沉淀硬化不锈钢双面焊接接头组织及性能演变[J]. 电焊机,2020,50(10):18-21.
ZHANG Guojun,Chen Feng,Zhang Guiyi,et al. Microstructure and properties evolution of double sided welding joints for heavy thickness precipitation hardening stainless steel[J].Electric Welding Machine,2020,50(10):18-21.
吴奎林,谭俊哲,曹铁山. 热处理工艺对1Cr15Ni4Mo3N钢组织和性能的影响[J]. 理化检测:物理分册,2012,48(2):76-82.
WU Kuilin,TAN Junze,CAO Tieshan. Effect of Heat Treatment Process on Microstructure and Properties of 1Cr15Ni4Mo3N Steel[J]. Physical Testing and Chemical Analysis(Part A:Physical Testing),2012,48(2):76-82.
古立新,金建军.回火温度对lCrl5Ni4Mo3N钢组织和性能的影响[J]. 材料工程,2007(1):7.
GU Lixin,JIN Jianjun. Effects of Tempering Temperature on Microstructure and Mechanical Properties of 1Cr15Ni4Mo3N Steel[J].Journal of Materials Engineering,2007(1):7.
Kalainathan S, Sathyajith S, Swaroop S. Effect of laser shot peen-ing without coating on the surface properties and corrosion be-havior of 316L steel [J]. Optics and Lasers in Engineering, 2012, 50(12): 1740-1745.
C H Tang, F T Cheng, H C Man. Improvement in cavitation erosion resistance of acopper-based propeller alloy by laser surface melting[J]. Surface and Coatings Technology,2004,182:300-307.
赵伟, 张柯, 刘平, 等. 激光熔覆Ni基WC复合熔覆层组织与性能的研究[J].动能材料,2019,50(01): 01098-01109.
ZHAO Wei, ZHANG Ke, LIU Ping, et al. Study on microstructure and properties of laser cladding Ni-based WC composite coating[J].Journal of Functional Materials, 2019,50(01): 01098-01109.
钦兰云,庞爽,杨光,等.激光沉积修复ZL114A铝合金的显微组织及显微硬度研究[J]. 红外与激光工程,2017,46(5):1-6.
QIN Lanyun,PANG Shuang,YANG Guang,et al. Microstructure and micro-hardness of laser deposition repair ZL114A aluminum alloy[J]. Infrared and Laser Engineering,2017,46(5):1-6.
谢雨田,吴光辉,王春霞,等. 激光熔覆修复合金球墨铸铁风冷辊的研究[J]. 热加工工艺,2012,41(24):168-172.
XIE Yutian,WU Guanghui,WANG Chunxia,et al. Study on Alloy Ductile Iron Air-cooled Roller Repaired by Laser Cladding[J]. Hot Working Technology,2012,41(24):168-172.
刘海涛,司超阳,霍登平,等. 激光熔覆修复15-5PH不锈钢的拉伸性能及组织研究[J]. 航空制造技术,2017(10):86-90.
LIU Haitao,SI Chaoyang,HUO Dengping,et al. Study on Tensile Property and Microstructure of Laser Cladding Repaired of 15-5PH Stainless Steel[J]. Aeronautical Manufacturing Technology,2017(10):86-90.
夏国俊,姚喆赫,陈健,等. 激光增材再制造IN939修复区显微组织与拉伸性能研究[J]. 表面技术,2021,50(02):277-286.
XIA Guojun,YAO Zhehe,CHEN Jian,et al. Microstructure and Tensile Properties of IN939 Repaired Zone by Laser Additive Remanufacturing[J]. Surface Technology,2021,50(02):277-286.
相关作者
相关机构
公网安备11010802024621