METHODS OF RESIDUAL STRESS REDUCTION FOR METAL PARTS MANUFACTURED USING SELECTIVE LASER MELTING (A REVIEW)

被引：2

作者：

Lim, Chong Heng ^{[1
,2
]}

Krishnan, Manickavasagam ^{[2
]}

Li, Hua ^{[1
]}

机构：

[1] Nanyang Technol Univ, Sch Mech & Aerosp Engn, Singapore Ctr 3D Printing, 50 Nanyang Ave, Singapore 639798, Singapore

[2] Adv Remfg & Technol ARTC, Addit Mfg Grp, 3 CleanTech Loop,CleanTech Two 01-01, Singapore 637143, Singapore

来源：

PROCEEDINGS OF THE 3RD INTERNATIONAL CONFERENCE ON PROGRESS IN ADDITIVE MANUFACTURING | 2018年

基金：

新加坡国家研究基金会;

关键词：

Selective Laser Melting; Additive Manufacturing; Residual Stress; Welding; 316L STAINLESS-STEEL; CRYOGENIC TREATMENT; DISTORTION; POWER; SLM;

D O I：

10.25341/D4901Z

中图分类号：

R318 [生物医学工程];

学科分类号：

0831 ;

摘要：

Residual stress is commonly associated with metallic parts produced from Selective Laser Melting (SLM) process in Additive Manufacturing (AM). Residual stress is often the limiting factor for employing metal parts fabricated using SLM process in final application. This paper presents a review of residual stress reduction strategies and methods used in SLM process, categorized as pre-processing, in-situ, and post-processing type. Methods used to relieve residual stresses in welded parts which may be applicable to AM produced parts are also discussed.

引用

页码：315 / 320

页数：6

共 50 条

[31] Study on the Quality and Performance of CoCrMo Alloy Parts Manufactured by Selective Laser Melting
Zhang Guoqing
Yang Yongqiang
Lin Hui
Song Changhui
Zhang Zimian
Journal of Materials Engineering and Performance, 2017, 26 : 2869 - 2877
[32] Analysis of Modern Optical Inspection Systems for Parts Manufactured by Selective Laser Melting
Giganto, Sara
Martinez-Pellitero, Susana
Cuesta, Eduardo
Meana, Victor M.
Barreiro, Joaquin
SENSORS, 2020, 20 (11)
[33] Study on tribology performance of CoCrMo alloy parts manufactured by selective laser melting
Zhang G.
Yang Y.
Lin H.
Song C.
Zhang Z.
Yu J.
Yang, Yongqiang (meyqyang@scut.edu.cn), 2016, Science Press (43):
[34] Residual stress in additively manufactured Inconel cubes; Selective Laser Melting versus Electron Beam Melting and a comparison of modelling techniques
Wensrich, C. M.
Luzin, V.
Hendriks, J. N.
Pant, P.
Gregg, A. W. T.
MATERIALS & DESIGN, 2024, 244
[35] Residual stress measurement techniques for Ti6Al4V parts fabricated using selective laser melting: state of the art review
Acevedo, Ruben B. O.
Kantarowska, Klaudia
Santos, Edson Costa
Fredel, Marcio C.
RAPID PROTOTYPING JOURNAL, 2023, 29 (08) : 1549 - 1564
[36] EFFECT OF LASER BORONIZING ON MICROSTRUCTURE AND HARDNESS OF MARAGING STEEL PARTS MANUFACTURED BY SELECTIVE LASER MELTING
Bucelis, Kestutis
Skamat, Jelena
Cernasejus, Olegas
31ST INTERNATIONAL CONFERENCE ON METALLURGY AND MATERIALS, METAL 2022, 2022, : 443 - 448
[37] Influence of Interlayer Laser Remelting on Residual Stress During Forming Using Selective Laser Melting
Yi Yali
Wu Hongbo
Jia Changzhi
Jin Herong
CHINESE JOURNAL OF LASERS-ZHONGGUO JIGUANG, 2023, 50 (24):
[38] Embedding sensors using selective laser melting for self-cognitive metal parts
Jung, Im Doo
Lee, Min Sik
Lee, Jungsub
Sung, Hyokyung
Choe, Jungho
Son, Hye Jin
Yun, Jaecheol
Kim, Ki-bong
Kim, Moobum
Lee, Seok Woo
Yang, Sangsun
Moon, Seung Ki
Kim, Kyung Tae
Yu, Ji-Hun
ADDITIVE MANUFACTURING, 2020, 33
[39] Properties of aluminum metal matrix composites manufactured by selective laser melting
Felber, Christian
Roedl, Florian
Haider, Ferdinand
INTERNATIONAL JOURNAL OF MATERIALS RESEARCH, 2021, 112 (07) : 552 - 564
[40] AlSi12 in-situ alloy formation and residual stress reduction using anchorless selective laser melting
Vora, Pratik
Mumtaz, Kamran
Todd, Iain
Hopkinson, Neil
ADDITIVE MANUFACTURING, 2015, 7 : 12 - 19

← 1 2 3 4 5 →