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International Journal of Production Research Volume 42, 2004 - Issue 1
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Original Articles

An intelligent parameter selection system for the direct metal laser sintering process

Y. Ning Department of Mechanical Engineering, National University of Singapore, 9 Engineering Drive 1, Singapore 117576
,
J. Y. H. Fuh Department of Mechanical Engineering, National University of Singapore, 9 Engineering Drive 1, Singapore 117576
,
Y. S. Wong Department of Mechanical Engineering, National University of Singapore, 9 Engineering Drive 1, Singapore 117576
&
H. T. Loh Department of Mechanical Engineering, National University of Singapore, 9 Engineering Drive 1, Singapore 117576
Pages 183-199 | Received 01 Jun 2003, Published online: 21 Feb 2007

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S. A. Fatemi, J. Zamani Ashany, A. Jalali Aghchai & A. Abolghasemi. (2017) Experimental investigation of process parameters on layer thickness and density in direct metal laser sintering: a response surface methodology approach. Virtual and Physical Prototyping 12:2, pages 133-140.
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Sharanjit Singh, VishalS. Sharma & Anish Sachdeva. (2012) Optimization and Analysis of Shrinkage in Selective Laser Sintered Polyamide Parts. Materials and Manufacturing Processes 27:6, pages 707-714.
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PrashantK. Jain, PulakM. Pandey & P.V.M. Rao. (2008) Experimental investigations for improving part strength in selective laser sintering. Virtual and Physical Prototyping 3:3, pages 177-188.
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Hayri Sezer, Joseph Tang, AMM Nazmul Ahsan & Sudhir Kaul. (2022) Modeling residual thermal stresses in layer-by-layer formation of direct metal laser sintering process for different scanning patterns for 316L stainless steel. Rapid Prototyping Journal 28:9, pages 1750-1763.
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Arfan Majeed, Yingfeng Zhang, Jingxiang Lv, Tao Peng, Zahid Atta & Altaf Ahmed. (2020) Investigation of T4 and T6 heat treatment influences on relative density and porosity of AlSi10Mg alloy components manufactured by SLM. Computers & Industrial Engineering 139, pages 106194.
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Sharanjit Singh, Vishal S. Sharma & Anish Sachdeva. (2018) Application of response surface methodology to analyze the effect of selective laser sintering parameters on dimensional accuracy. Progress in Additive Manufacturing 4:1, pages 3-12.
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Mevlüt Yunus Kayacan & Nihat Yılmaz. (2019) DMLS İLE EKLEMELİ İMALATTA DENGESİZ SICAKLIK DAĞILIMI ve PARÇAYA ETKİLERİNİN ARAŞTIRILMASI. Academic Platform Journal of Engineering and Science 7:1, pages 1-1.
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Anoop Verma & Rahul Rai. (2016) Sustainability-induced dual-level optimization of additive manufacturing process. The International Journal of Advanced Manufacturing Technology 88:5-8, pages 1945-1959.
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Jatender Pal Singh, Pulak M. Pandey & Anita Kamra Verma. (2016) Fabrication of three dimensional open porous regular structure of PA-2200 for enhanced strength of scaffold using selective laser sintering. Rapid Prototyping Journal 22:4, pages 752-765.
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Vishal S. Sharma, Sharanjit Singh, Anish Sachdeva & Parmod Kumar. (2013) Influence of sintering parameters on dynamic mechanical properties of selective laser sintered parts. International Journal of Material Forming 8:1, pages 157-166.
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F. Calignano, D. Manfredi, E. P. Ambrosio, L. Iuliano & P. Fino. (2012) Influence of process parameters on surface roughness of aluminum parts produced by DMLS. The International Journal of Advanced Manufacturing Technology 67:9-12, pages 2743-2751.
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A.K. Singh & Regalla Srinivasa Prakash. (2010) DOE based three‐dimensional finite element analysis for predicting density of a laser‐sintered part. Rapid Prototyping Journal 16:6, pages 460-467.
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A.K. Singh & Regalla Srinivasa Prakash. (2010) Response surface‐based simulation modeling for selective laser sintering process. Rapid Prototyping Journal 16:6, pages 441-449.
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Jie Xiang, Min Wu, Ping Duan, Wei-Hua Cao & Yong He. (2008) Coordinating fuzzy control of the sintering process. IFAC Proceedings Volumes 41:2, pages 7717-7722.
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N. Raghunath & Pulak M. Pandey. (2007) Improving accuracy through shrinkage modelling by using Taguchi method in selective laser sintering. International Journal of Machine Tools and Manufacture 47:6, pages 985-995.
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