A REVIEW ON ADDITIVE MANUFACTURING
LASER TECHNOLOGY METHODS, DISTINCTIONS AND APPLICATIONS IN MANUFACTURING ENGINEERING
Keywords:
Manufacturing; Additive; Technique; Freeform; LaserAbstract
Additive manufacturing also called free form fabrication is not yet in use by most manufacturing industries in Nigeria. A study into the awareness of additive manufacturing technique in south western Nigeria shows that 60% respondent have not heard of the technology not to talk of using the technique in production process. This review focus on definitions of each category of the additive manufacturing techniques. The study further explain laser technology as a form of additive manufacturing technique Also review on parameter variation in laser technology manufacturing for the benefit of application in manufacturing process was done. The study concludes on possible research gaps. This review can be used as educative awareness in seminars.
References
REFERENCES
Abioye T.E. and P.K Farayibi (2017). A study on the awareness level of additive manufacturing technology in south-western Nigeria. African Journal of Science, Technology, Innovation and Development. Vol. 9(2), pp. 157-162.
Alemohammad, H., Esmaeili, S., and Toyserkani E. (2007): Deposition of Co–Ti alloy on mild steel substrate using laser cladding. Materials Science and Engineering, 456 (1–2): 156–161.
ASTM (2012).Committee F42 on Additive Manufacturing Technologies. Terminology for Additive Manufacturing Technologies; International: West Conshohocken, PA, USA.
Avadhanulu, M.N. (2009): An Introduction to Lasers: Theory and Applications. S.Chand and Company Ltd.: New Delhi.
Azari, A. and Nikzad, S. (2009). The evolution of rapid prototyping in dentistry: A review. Rapid Prototyp. J., 15, pp. 216–225
Baker, T.N. (2010): Laser surface modification of titanium alloys, in Surface Engineeringof Light Alloys, H. Dong, Editor. , Woodhead Publishing. UK. pp. 398–443.
Bojinović, M., Mole, N. and Štok, B.A (2015): computer simulation study of the effects of temperature change rate on austenite kinetics in laser hardening. Surface and Coatings Technology, 273: 60–76. 30.
Bose, S.; Vahabzadeh, S. and Bandyopadhyay, A. (2013). Bone tissue engineering using 3D printing. Mater. Today 16, pp. 496–504
Derby, B. (2012). Printing and prototyping of tissues and scaffolds. Science, 338, pp.921–926
Gupta, N. and Nataraj, N. (2014): A dual weighted residual method for an optimal control problem of laser surface hardening of steel. Mathematics and Computers in Simulation, 103: 12–32
Hemmati, I., V. OcelÃk, and J.T.M. De Hosson, (2011): The effect of cladding speed on phaseconstitution and properties of AISI 431 stainless steel laser deposited coatings. Surface and Coatings Technology, 205(21–22): 5235–5239.
Henzler, T.; Chai, L. and Wang, X.H. Integrated model for organ manufacturing: A systematic approach from medical imaging to rapid prototyping. In Organ Manufacturing; Wang, X.H., Ed.; Nova Science Publishers Inc.: Hauppauge, NY, USA, pp. 171–200.
Ion, J.C., (2005): Cladding, in Laser Processing of Engineering Materials, J.C. Ion, Editor, Butterworth-Heinemann: Oxford. pp. 296–326.
Kusinki, J., S. Kac, A. Kopia, A. Radziswewska, M. Rozmus-Gornikowska, B. Major,L.Marckar, J. and Lisiecki. A., (2012): Laser modification of materials surfacelayer-review paper. Bulleting of the polish academy of sciences, 60(4): pp. 711–728.
Li, H. C., Wang, D. G., Chen, C. Z. and Weng, F (2015): Effect of CeO2 and Y2O3 on microstructure, bioactivity and degradability of laser cladding CaO–SiO2 coating on titanium alloy. Colloids and Surfaces B: Biointerfaces, 127(0): 15–21.
Liu, X., P.K. Chu, and C. Ding, (2004): Surface modification of titanium, titanium alloys, andrelated materials for biomedical applications. Materials Science and Engineering: Reports, 47(3–4): 49–121.
Liu, Z., (2010): Laser Applied Coatings, in Shreir's Corrosion, B.C.G.L.L.R.S. Stott, Editor Elsevier: Oxford. pp. 2622–2635Majumdar, J.D. and Manna.I (2003): Laser Processing of Materials. Sadhana. Printed in India. 28(4): pp. 495–562.
Markillie, P. A. (2009). Third industrial revolution. Integr. Biol., 1, 148–149
Melchels, F.P.; Domingos, M.A.; Klein, T.J.; Malda, J.; Bartolo, P.J. and Hutmacher, D.W. (2012). Additive manufacturing of tissues and organs. Prog. Polym. Sci., 37, pp. 1079–1104
Torkamany, M.J. and Sabbaghzadeh, J. (2011): Effect of pulsed laser parameters on in-situ TiC synthesis in laser surface treatment. Optics and Lasers in Engineering, 49(4): 557–563.
Ozbolat, I.T. and Yu, Y. (2013) Bioprinting toward organ fabrication: Challenges and future trends. IEEE Trans. Biomed. Eng.60, pp. 691–699
Philippi, J.A.; Miller, E.; Weiss, L.; Huard, J.; Waggoner, A. and Campbell, P. (2008). Microenvironments engineered by inkjet bioprinting spatially direct adult stem cells toward muscle- and bone-like subpopulations. Stem Cells 26, pp.127–134.
Poulon-Quintin, A., Watanabe, I., Watanabe, E. and Bertrand, C., (2012):Microstructure and mechanical properties of surface treated cast titanium with Nd:YAG laser. Dental Materials, 28(9): 945–951.
Rajaram, N., Sheikh-Ahmad J., and Hossein C. S. Parametric study of the effect of feed speed and power on laser cut quality of 4130 steel. Wichita State University: Wichita, Kansas 67260–0035
Schrepfer, I .and Wang, X.H. (2015). Progress in 3D printing technology in health care. In Organ Manufacturing;
Schuurman, W.; Levett, P.A.; Pot, M.W.; van Weeren, P.R.; Dhert, W.J.; Hutmacher, D.W.; Melchels, F.P.; Klein, T.J. and Malda, J. (2013). Gelatin-methacrylamide hydrogels as potential biomaterials for fabrication of tissue-engineered cartilage constructs. Macromol. Biosci.13, pp. 551–561
Sears, N.A.; Seshadri, D.R.; Dhavalikar, P.S. and Cosgriff-Hernandez, E. (2016).A review of three-dimensional printing in tissue engineering. Tissue Eng. B, 22, pp 298–310.
Steen, W.M. and K. Watkins. (2003): Laser Materials Processing, 1, Springer Verlag: New York.
Tseng, W.C. and Aoh, J.N. (2013): Simulation study on laser cladding on preplaced powderlayer with a tailored laser heat source. Optics & Laser Technology, 48: 141–152.
Wang, X.; Yan, Y. and Zhang, R. (2010). Recent trends and challenges in complex organ manufacturing. Tissue Eng.Part B, 16, pp.189–197
Wang, X. (2012). Intelligent freeform manufacturing of complex organs. Artif. Org., 36, 951–961
Wang, X.; Tuomi, J.; Mäkitie, A.A.; Poloheimo, K.-S.; Partanen, J. and Yliperttula, M. (2013). The integrations of biomaterials and rapid prototyping techniques for intelligent manufacturing of complex organs. In Advances in Biomaterials Science and Applications in Biomedicine; Lazinica, R., Ed.; In Tech: Rijeka, Croatia, pp. 437–463
Wang, X.H., Ed.; Nova Science Publishers Inc.: Hauppauge, NY, USA, pp. 29–74.
Wu, X., Liang, J., Mei, J., Mitchell, C., Goodwin, P. S. and Voice, W. (2004): Microstructures of laser-deposited Ti–6Al–4V. Materials & Design,. 25(2): 137–144.
Yakovlev, A., P. Bertrand, and I. Smurov, (2004): Laser cladding of wear resistant metal matrix composite coatings. Thin Solid Films, 453–454(0): 133–138.
Yeong, W.Y.; Chua, C.K.; Leong, K.F.; Chandrasekaran, M. and Lee, M.W. (2006) Indirect fabrication of collagen scaffold based on inkjet printing technique. Rapid Rrot. J.12, 229–237.
Farayibi, P.K.; Bakare, M. S.; Abioye, T.E. and Oke. (2015) P. K Potential opportunities of additive manufacturing technology in Nigeria. Proceedings of the Inter-Disciplinary Academic Conference on Uncommon Development Vol. 4 No.2 January, 15-16. University of Jos Multi-purpose Hall, Main Campus, Jos, Plateau State www.hummingpub.com
Abioye T.E. and P.K Farayibi (2017). A study on the awareness level of additive manufacturing technology in south-western Nigeria. African Journal of Science, Technology, Innovation and Development. Vol. 9(2), pp. 157-162.
Alemohammad, H., Esmaeili, S., and Toyserkani E. (2007): Deposition of Co–Ti alloy on mild steel substrate using laser cladding. Materials Science and Engineering, 456 (1–2): 156–161.
ASTM (2012).Committee F42 on Additive Manufacturing Technologies. Terminology for Additive Manufacturing Technologies; International: West Conshohocken, PA, USA.
Avadhanulu, M.N. (2009): An Introduction to Lasers: Theory and Applications. S.Chand and Company Ltd.: New Delhi.
Azari, A. and Nikzad, S. (2009). The evolution of rapid prototyping in dentistry: A review. Rapid Prototyp. J., 15, pp. 216–225
Baker, T.N. (2010): Laser surface modification of titanium alloys, in Surface Engineeringof Light Alloys, H. Dong, Editor. , Woodhead Publishing. UK. pp. 398–443.
Bojinović, M., Mole, N. and Štok, B.A (2015): computer simulation study of the effects of temperature change rate on austenite kinetics in laser hardening. Surface and Coatings Technology, 273: 60–76. 30.
Bose, S.; Vahabzadeh, S. and Bandyopadhyay, A. (2013). Bone tissue engineering using 3D printing. Mater. Today 16, pp. 496–504
Derby, B. (2012). Printing and prototyping of tissues and scaffolds. Science, 338, pp.921–926
Gupta, N. and Nataraj, N. (2014): A dual weighted residual method for an optimal control problem of laser surface hardening of steel. Mathematics and Computers in Simulation, 103: 12–32
Hemmati, I., V. OcelÃk, and J.T.M. De Hosson, (2011): The effect of cladding speed on phaseconstitution and properties of AISI 431 stainless steel laser deposited coatings. Surface and Coatings Technology, 205(21–22): 5235–5239.
Henzler, T.; Chai, L. and Wang, X.H. Integrated model for organ manufacturing: A systematic approach from medical imaging to rapid prototyping. In Organ Manufacturing; Wang, X.H., Ed.; Nova Science Publishers Inc.: Hauppauge, NY, USA, pp. 171–200.
Ion, J.C., (2005): Cladding, in Laser Processing of Engineering Materials, J.C. Ion, Editor, Butterworth-Heinemann: Oxford. pp. 296–326.
Kusinki, J., S. Kac, A. Kopia, A. Radziswewska, M. Rozmus-Gornikowska, B. Major,L.Marckar, J. and Lisiecki. A., (2012): Laser modification of materials surfacelayer-review paper. Bulleting of the polish academy of sciences, 60(4): pp. 711–728.
Li, H. C., Wang, D. G., Chen, C. Z. and Weng, F (2015): Effect of CeO2 and Y2O3 on microstructure, bioactivity and degradability of laser cladding CaO–SiO2 coating on titanium alloy. Colloids and Surfaces B: Biointerfaces, 127(0): 15–21.
Liu, X., P.K. Chu, and C. Ding, (2004): Surface modification of titanium, titanium alloys, andrelated materials for biomedical applications. Materials Science and Engineering: Reports, 47(3–4): 49–121.
Liu, Z., (2010): Laser Applied Coatings, in Shreir's Corrosion, B.C.G.L.L.R.S. Stott, Editor Elsevier: Oxford. pp. 2622–2635Majumdar, J.D. and Manna.I (2003): Laser Processing of Materials. Sadhana. Printed in India. 28(4): pp. 495–562.
Markillie, P. A. (2009). Third industrial revolution. Integr. Biol., 1, 148–149
Melchels, F.P.; Domingos, M.A.; Klein, T.J.; Malda, J.; Bartolo, P.J. and Hutmacher, D.W. (2012). Additive manufacturing of tissues and organs. Prog. Polym. Sci., 37, pp. 1079–1104
Torkamany, M.J. and Sabbaghzadeh, J. (2011): Effect of pulsed laser parameters on in-situ TiC synthesis in laser surface treatment. Optics and Lasers in Engineering, 49(4): 557–563.
Ozbolat, I.T. and Yu, Y. (2013) Bioprinting toward organ fabrication: Challenges and future trends. IEEE Trans. Biomed. Eng.60, pp. 691–699
Philippi, J.A.; Miller, E.; Weiss, L.; Huard, J.; Waggoner, A. and Campbell, P. (2008). Microenvironments engineered by inkjet bioprinting spatially direct adult stem cells toward muscle- and bone-like subpopulations. Stem Cells 26, pp.127–134.
Poulon-Quintin, A., Watanabe, I., Watanabe, E. and Bertrand, C., (2012):Microstructure and mechanical properties of surface treated cast titanium with Nd:YAG laser. Dental Materials, 28(9): 945–951.
Rajaram, N., Sheikh-Ahmad J., and Hossein C. S. Parametric study of the effect of feed speed and power on laser cut quality of 4130 steel. Wichita State University: Wichita, Kansas 67260–0035
Schrepfer, I .and Wang, X.H. (2015). Progress in 3D printing technology in health care. In Organ Manufacturing;
Schuurman, W.; Levett, P.A.; Pot, M.W.; van Weeren, P.R.; Dhert, W.J.; Hutmacher, D.W.; Melchels, F.P.; Klein, T.J. and Malda, J. (2013). Gelatin-methacrylamide hydrogels as potential biomaterials for fabrication of tissue-engineered cartilage constructs. Macromol. Biosci.13, pp. 551–561
Sears, N.A.; Seshadri, D.R.; Dhavalikar, P.S. and Cosgriff-Hernandez, E. (2016).A review of three-dimensional printing in tissue engineering. Tissue Eng. B, 22, pp 298–310.
Steen, W.M. and K. Watkins. (2003): Laser Materials Processing, 1, Springer Verlag: New York.
Tseng, W.C. and Aoh, J.N. (2013): Simulation study on laser cladding on preplaced powderlayer with a tailored laser heat source. Optics & Laser Technology, 48: 141–152.
Wang, X.; Yan, Y. and Zhang, R. (2010). Recent trends and challenges in complex organ manufacturing. Tissue Eng.Part B, 16, pp.189–197
Wang, X. (2012). Intelligent freeform manufacturing of complex organs. Artif. Org., 36, 951–961
Wang, X.; Tuomi, J.; Mäkitie, A.A.; Poloheimo, K.-S.; Partanen, J. and Yliperttula, M. (2013). The integrations of biomaterials and rapid prototyping techniques for intelligent manufacturing of complex organs. In Advances in Biomaterials Science and Applications in Biomedicine; Lazinica, R., Ed.; In Tech: Rijeka, Croatia, pp. 437–463
Wang, X.H., Ed.; Nova Science Publishers Inc.: Hauppauge, NY, USA, pp. 29–74.
Wu, X., Liang, J., Mei, J., Mitchell, C., Goodwin, P. S. and Voice, W. (2004): Microstructures of laser-deposited Ti–6Al–4V. Materials & Design,. 25(2): 137–144.
Yakovlev, A., P. Bertrand, and I. Smurov, (2004): Laser cladding of wear resistant metal matrix composite coatings. Thin Solid Films, 453–454(0): 133–138.
Yeong, W.Y.; Chua, C.K.; Leong, K.F.; Chandrasekaran, M. and Lee, M.W. (2006) Indirect fabrication of collagen scaffold based on inkjet printing technique. Rapid Rrot. J.12, 229–237.
Farayibi, P.K.; Bakare, M. S.; Abioye, T.E. and Oke. (2015) P. K Potential opportunities of additive manufacturing technology in Nigeria. Proceedings of the Inter-Disciplinary Academic Conference on Uncommon Development Vol. 4 No.2 January, 15-16. University of Jos Multi-purpose Hall, Main Campus, Jos, Plateau State www.hummingpub.com
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2019-04-28
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