Studies on laser rapid manufacturing of cross-thin-walled porous structures of Inconel 625

International Journal of Advanced Manufacturing Technology

Volumn 61, Issue 5-8, 2012, Pages 757-770

  Paul, C P ^a   Mishra, S K ^a   Premsingh, C H ^a   Bhargava, P ^a   Tiwari, P ^a   Kukreja, L M ^a  

^a RAJA RAMANNA CENTRE FOR ADVANCED TECHNOLOGY   (India)

Author keywords

CO 2 laser; Cross thin wall fabrication strategy; Inconel 625; Laser cladding; Laser rapid manufacturing; Porous structure

Indexed keywords

CONTINUOUS WAVE; ENGINEERING COMPONENTS; FABRICATED STRUCTURES; FABRICATION STRATEGIES; INCONEL; INCONEL-625; INDEPENDENT CONTROL; LASER ENERGIES; LASER RAPID MANUFACTURING; METALLURGICAL PROPERTIES; NICHE AREAS; PARAMETRIC DEPENDENCE; PER UNIT; POROUS STRUCTURES; RAPID MANUFACTURING;

CARBON DIOXIDE; COMPRESSION TESTING; FABRICATION; LASER CLADDING; SCANNING ELECTRON MICROSCOPY; YIELD STRESS;

POROSITY;

EID: 84864541431     PISSN: 02683768     EISSN: 14333015     Source Type: Journal    
DOI: 10.1007/s00170-011-3742-3     Document Type: Article

References (42)

1. Davis ME (2002) Ordered porous materials for emerging applications. Nature 417:813-821
2. Rubow KL (2009) Porous metal for aerospace. Adv Mater Process 167:26-28
3. Shapovalov V (1994) Porous metals. MRS Bull 19:24-28
4. Ryan G, Pandit A, Apatsidis DP (2006) Fabrication methods of porous metals for use in orthopaedic applications. Biomaterials 27:2651-2670
5. Ahsan MN, Paul CP, Kukreja LM, Pinkerton AJ (2011) Porous structures fabrication by continuous and pulsed laser metal deposition for biomedical applications: modelling and experimental investigation. J Mater Process Technol 211:602-609
6. Castilho M, Pires I, Gouveia B, Rodrigues J (2011) Structural evaluation of scaffolds prototypes produced by three-dimensional printing. Int J Adv Manuf Technol. doi:10.1007/s00170-011-3219-4
7. Laser Engineered Net Shaping (2002) http://www.sandia.gov/mst/pdf/LENS. pdf (accessed on May 30, 2011)
8. Xue L, Islam MU, Theriault A (2001) Laser consolidation process for the manufacturing of structural components for advanced robotic mechatronic system - a state of art review. In: Proceedings of 6th Int Symposium on Artificial Intelligence and Robotics & Automation in Space (i-SAIRAS 2001). Canadian Space Agency, Quebec, Canada, pp 1-8, AM080
9. Paul CP, Alemohammad H, Toyserkani E, Khajepour A, Corbin S (2007) Cladding of WC-12 Co on low carbon steel using a pulsed Nd:YAG laser. Mater Sci Eng, A 464:170-176
10. Davis SJ, Watkins KG, Dearden G, Fearon E, Zeng J (2006) Optimum deposition parameters for the direct laser fabrication (DLF) of quasi-hollow structures. In: Proc of Photon Conf. OPD, Manchester, pp 3-14
11. Song L, Singh VB, Dutta B, Mazumder J (2011) Control of melt pool temperature and deposition height during direct metal deposition process. Int J Adv Manuf Technol. doi:10.1007/ s00170-011-3395-2
12. Moat RJ, Pinkerton A, Li L, Withers PJ, Preuss M (2009) Crystallographic texture and microstructure of pulsed diode laserdeposited Waspaloy. Acta Mater 5:1220-1229
13. Nowotny S, Scharek S, Beyer E, Richter K-H (2007) Laser beam build-up welding: precision in repair, surface cladding, and direct 3D metal deposition. J Therm Spray Tech 16:344-348
14. Imran MK, Masood SH, Brandt M (2010) Bimetallic dies with direct metal-deposited steel on Moldmax for high-pressure die casting application. Int J Adv Manuf Technol 52:855-863
15. Paul CP, Jain A, Ganesh P, Negi J, Nath AK (2006) Laser rapid manufacturing of Colmonoy-6 components. Opt Lasers Eng 44:1096-1109
16. Paul CP, Ganesh P, Mishra SK, Bhargava P, Negi J, Nath AK (2007) Investigating laser rapid manufacturing for Inconel-625 components. Opt Laser Technol 39:800-805
17. Ganesh P, Kaul R, Paul CP, Tiwari P, Rai SK, Prasad RC, Kukreja LM (2010) Fatigue and fracture toughness characteristics of laser rapid manufactured Inconel 625 structures. Mater Sci Eng, A 527:7490-7497
18. Santo L (2008) Laser cladding of metals: a review. Int J Surf Sci Eng 2:327-336
19. Toyserkani E, Khajepour A, Corbin S (2005) Laser cladding, 1st edn. CRC Press, Florida
20. Gu D, Shen Y (2008) Processing conditions and microstructural features of porous 316 L stainless steel components by DMLS. Appl Surf Sci 255:1880-1887
21. Li R, Shi Y, Wang Z, Wang L, Liu J, Jiang W (2010) Densification behavior of gas and water atomized 316 L stainless steel powder during selective laser melting. Appl Surf Sci 256:4350-4356
22. Li R, Liu J, Shi Y, Du M, Xie Z (2010) 316 L stainless steel with gradient porosity fabricated by selective laser melting. J Mater Eng Perform 19:666-671
23. Krishna BV, Bose S, Bandyopadhyay A (2007) Low stiffness porous Ti structures for load bearing implants. Acta Biomater 3:997-1006
24. http://www.specialmetals.com/documents/Inconel%20alloy%20625.pdf (accessed on May 30, 2011)
25. Thivillon L, Bertrand Ph, Laget B, Smurov I (2009) Potential of direct metal deposition technology for manufacturing thick functionally graded coatings and parts for reactors components. J Nucl Mater 385:236-241
26. Dinda GP, Dasgupta AK, Majumder J (2009) Laser aided direct metal deposition of Inconel 625 superalloy: microstructural evolution and thermal stability. Mater Sci Eng, A 509:98-104
27. Paul CP, Bhargava P, Ganesh P, Mishra SK, Premsingh CH, Kukreja LM (2008) Porous surface structures by continuous and pulsed laser direct metal deposition for biomedical applications. Proc Int Conf Process Fabri Adv Mater, New Delhi, India, pp 784-793
28. Nath AK, Reghu T, Paul CP, Ittoop MO, Bhargava P (2005) Highpower transverse flow CW CO2 laser for material processing applications. Opt Laser Technol 37:329-333
29. Paul CP, Bhargava P, Negi J, Nath AK (2003) Laser rapid manufacturing using Co-axial powder feeding system. In: Proc XIII National Conf Indian Soc Mech Engr. India, Roorkee, PE-071
30. Mumtaz KA, Erasenthiran P, Hopkinson N (2008) High density selective laser melting of Waspaloy®. J Mater Process Technol 195:77-87
31. How do you select an experimental design? (2010) http://www.itl.nist.gov/ div898/handbook/pri/section3/pri33.htm#Response%20Surface%28method%29 (accessed on May 30, 2011)
32. Response surface methodology (2004) http://reports-archive.adm.cs.cmu. edu/anon/isri2004/CMU-ISRI-04-136.pdf (accessed on May 30, 2011)
33. ANOVA: Analysis of Variance between groups (1996) http://www.physics. csbsju.edu/stats/anova.html (accessed on May 30, 2011)
34. ASTM Standard E9 (2009) Standard test methods of compression testing of metallic materials at room temperature. ASTM International, West Conshohocken, PA, 2003
35. ASTM Standard E384 (2009) E384-99e1 Standard test method for microindentation hardness of materials. ASTM International, West Conshohocken, PA
36. Lawrence J, Pou J, Low DK, Toyserkani E (eds) (2010) Advances in laser materials processing technology. Research and applications. CRC Press and Woodhead Publishing, Cambridge
37. Ahmed N, Voisey KT, McCartney DG (2010) Investigation into the effect of beam shape on melt pool characteristics using analytical modeling. Opt Lasers Eng 48:548-554
38. Peyre P, Aubry P, Fabbro R, Neveu R, Longuet A (2008) Analytical and numerical modelling of the direct metal deposition laser process. J Phys D Appl Phys 41:025403
39. Pinkerton AJ, Li L (2004) Modelling the geometry of a moving laser melt pool and deposition track via energy and mass balances. J Phys D Appl Phys 37:1885-1895
40. Pinkerton A, Wan W, Li L (2008) Component repair using laser direct metal deposition. Proc Inst Mech Eng B J Eng Manuf 222:827-836
41. Banhart J (2001) Manufacture, characterization and application of cellular metals and metal foams. Prog Mater Sci 46:559-632
42. Nakajima H (2007) Fabrication, properties and application of porous metals with directional pores. Prog Mater Sci 52:1091-1173