You are here

Home » Content

FARKLI MALZEMELERİN LAZERLE KESİLMESİ

Laser Cutting of Different Materials

Journal Name:

  • Uludağ Üniversitesi Mühendislik-Mimarlık Fakültesi Dergisi

Publication Year:

  • 2013

Key Words:

Keywords (Original Language):

Author NameUniversity of AuthorFaculty of Author
Abstract (2. Language): 
In this paper; in general potential developments and trends of a particular machining field by extensively evaluating present studies of laser beam machining have been discussed. As it is indicated below, technical literatures have been subsumed under five major headlines: Experimental studies, reviews, optimization researches of the cutting parameters, theoretical modelling studies of laser beam cutting and academic studies relating to laser cutting.
Bookmark/Search this post with
Abstract (Original Language): 
Bu yayında; lazer ışını kullanarak imalat konularında literatürde mevcut yayınların geniş bir değerlendirilmesi yapılarak lazerle malzeme kesim alanındaki olası gelişmeler tartışılmıştır. Literatürde mevcut yayınlar aşağıda sunulacağı üzere beş ana başlık altında toplanmışlardır: Deneysel çalışmalar, derleme çalışmaları, kesme parametrelerinin optimizasyonu çalışmaları, lazerle kesmeye yönelik teorik modelleme çalışmaları ve lazerle kesme ile ilgili diğer akademik çalışmalar.
FULL TEXT (PDF): 
PDF icon mak18_02-08syf079-099.pdf
  • 2
79-99
  • Turkish

REFERENCES

References: 

1. Adelmann B. and Hellmann R. (2011). Fast laser cutting optimization algorithm, Physics
Procedia, 12, 591-598.
2. Ahn D.G. and Byun K.W. (2009). Influence of cutting parameters on surface
characteristics of cut section in cutting of Inconel 718 sheet using CW Nd:YAG laser,
Trans. Nonferrous Met. Soc. China, 19, s32-39.
3. Arif A.F.M., Yilbas B.S. and Abdul Aleem B.J (2009). Laser cutting of thick sheet metals:
Residual stress analysis, Optics & Laser Technology, 41, 224-232.
4. Baskoro A.S., Herwandi, Ismail KGS, Siswanta A., and Kiswanto G. (2011). Analysis of
cutting process of materials using low power laser diode and CO2, International Journal of
Mechanical & Mechatronics Engineering, 11 [6], 13-18.
5. Baumeister M., Dickmann K. and Hoult (2006). T. Fiber laser micro-cutting of stainless
steel sheets, Appl. Phys. A, 85, 121–124.
6. Boutinguiza M., Pou J., Lusquiños F., Quintero F., Soto R., Amor M.P, Watkins K. and
Steen W.M. (2002). CO2 laser cutting of slate, Optics and Lasers in Engineering, 37, 15-
25.
7. Caiazzo F., Curcio F., Daurelio G. and Minutolo F.M.C. (2005). Laser cutting of different
polymeric plastics (PE, PP and PC) by a CO2 laser beam, Journal of Materials Processing
Technology, 159, 279-285.
8. Castañeda J. C. H., Sezer H.K. and Lin L. (2011a). Single and dual gas jet effect in
Ytterbium-doped fibre laser cutting of dry pine wood, Int J Adv Manuf Technol, 56, 539-
552.
9. Castañeda J. C. H., Sezer H.K. and Lin L. (2011b). The effect of moisture content in fibre
laser cutting of pine wood, Optics and Lasers in Engineering, 49, 1139-1152.
10. Chagnot C., Dinechin de G. and Canneau G. (2010). Cutting performances with new
industrial continuous wave ND:YAG high power lasers-For dismantling of former nuclear
workshops, the performances of recently introduced high power continuous wave
ND:YAG lasers are assessed, Nuclear Engineering and Design, 240, 2604-2613.
11. Chen S.L. and O’Neil W. (1997). The effects of power rippling on CO2 laser cutting,
Optic&Laser Technology, 29[3], 125-134.
12. Chen X., Ji L., Bao Y. And Jiang Y. (2012). Improving cutting quality by analysis of
microstructure characteristics and solidification behaviour of recast layer formation on
laser cut ceramic, Journal of the European Ceramic Society, 32, 2203-2211.
13. Choudhury I.A. and Shirley S. (2010). Laser cutting of polymeric materials: An
experimental investigation, Optics & Laser Technology, 42, 503-508.
14. Danilov V. I., Zuev L. B., Kuznetsova N. I., Malov A. N., Orishich A. M., Fomin V. M.
and Shulyat’ev V. B. (2006). Specific features of laser cutting of steel sheets and
monitoring of sample quality after laser influence, Journal of Applied Mechanics and
Technical Physics, 47[4] 608-615.
Uludağ Üniversitesi Mühendislik-Mimarlık Fakültesi Dergisi, Cilt 18, Sayı 2, 2013
95
15. Davim J.P, Barricas N., Conceicao M. and Oliveira C. (2008). Some experimental studies
on CO2 laser cutting quality of polymeric materials, Journal of Materials Processing
Technology, 198, 99-104.
16. Dubey A.K. and Yadava V. (2008a). Laser beam machining—A review, International
Journal of Machine Tools & Manufacture, 48, 609-628.
17. Dubey A. K. and Yadava V. (2008b). Experimental study of Nd:YAG laser beam
machining—An overview, Journal of Materials Processing Technology, 195, 15-26.
18. Dubey A. K. and Yadava V. (2008c). Multi-objective optimisation of laser beam cutting
process, Optics & Laser Technology, 40, 562-570.
19. Dubey A.K. and Yadava V. (2008d). Multi-objective optimization of Nd:YAG laser cutting
of nickel-based superalloy sheet using orthogonal array with principal component analysis,
Optics and Lasers in Engineering, 46, 124-132.
20. El-Taweel T. A., Abdel-Maaboud A. M., Azzam B. S., and Mohammad A. E. (2009).
Parametric studies on the CO2 laser cutting of Kevlar-49 composite, Int. J. Adv. Manuf.
Technol., 40, 907-917.
21. Eltawahni H. A., A. G. Olabi and K. Y. Benyounis (2010). Assessment and optimization of
CO2 laser cutting process of PMMA, International Conference on Advances in Materials
and Processing Technologies, American Institute of Physics, Paris, 1553-1558.
22. Eltawahni H. A., Olabi A. G. and Benyounis K. Y. (2011). Investigating the CO2 laser
cutting parameters of MDF wood composite material, Optics & Laser Technology, 43, 648-
659.
23. Eltawahni H.A., Hagino M., Benyounis K.Y., Inoue T. and Olabi A.G (2012). Effect of
CO2 laser cutting process parameters on edge quality and operating cost of AISI316L,
Optics & Laser Technology, 44, 1068- 1082.
24. Ghany K.A. and Newishy M. (2005) Cutting of 1.2 mm thick austenitic stainless steel sheet
using pulsed and CW Nd:YAG laser, Journal of Materials Processing Technology, 168,
438-447.
25. Glod P.V. (2011). Effects of oxygen pressure in laser cutting, Metalurgia International, 16
[1], 18-25.
26. Jimin C., Jianhua Y., Shuai Z., Tiechuan Z. and Dixin G. (2007). Parameter optimization of
non-vertical laser cutting, Int. J. Adv. Manuf. Technol., 33, 469-473.
27. Jurków D., Malecha K., Stiernstedt J. and Golonka L. (2011). Influence of tapes’ properties
on the laser cutting process, Journal of the European Ceramic Society, 31, 1589-1595.
28. Karataş C., Keles O., Uslan I. and Usta Y. (2006). Laser cutting of steel sheets: Influence
of workpiece thickness and beam waist position on kerf size and stria formation, Journal of
Materials Processing Technology, 172, 22-29.
29. Kek T. and Grum J. (2009). Monitoring laser cut quality using acoustic emission,
International Journal of Machine Tools & Manufacture, 49, 8-12.
30. Kek T. and Grum J. (2010). AE Signals during laser cutting of different steel sheet
thickness, J. Acoustic Emission,28, 179-187.
31. Kovalev O.B., Yudin P.V. and Zaitsev A.V. (2009). Modeling of flow separation of assist
gas as applied to laser cutting of thick sheet metal, Applied Mathematical Modelling, 33,
3730-3745.
Çavdar, K. ve Tanrısever, T.: Farklı Malzemelerin Lazerle Kesilmesi
96
32. Kulenovic M., Begic D., Cekic A. and Bliedtner J. (2010). Laser cutting of tungsten alloy
using nitrogen assist gas, Annals of DAAAM for 2010 & Proceedings of the 21st
International DAAAM Symposium, Vienna, 21[1], 54-546.
33. Kurt M, Kaynak Y., Bagci E., Demirer H., and Kurt M. (2009). Dimensional analyses and
surface quality of the laser cutting process for engineering plastics, Int J Adv Manuf
Technol, 41, 259-267.
34. Lamikiz A., López L.N. de L., Sánchez J.A., Pozo del D., Etayo J.M., and López J.M.
(2005). CO2 laser cutting of advanced high strength steels (AHSS), Applied Surface
Science, 242, 362-368.
35. Lei H., Yi Z. and Chenglong M. (2009). Technological study of laser cutting silicon steel
controlled by rotating gas flow, Optics & Laser Technology, 41, 328-333.
36. Li C.H., Tsai M.J. and Yang C.D. (2007). Study of optimal laser parameters for cutting
QFN packages by Taguchi’s matrix method, Optics & Laser Technology, 39, 786-795.
37. Li X.Z., Tai Y.P., Nie Z.G., Zhang L.P., (2012). Laser cutting profile characterization using
dynamic speckle method, Optik-Int. J. Light Electron Opt.
38. Li Z.L., Zheng H.Y., Lim G.C., Chu P.L., and Li L. (2010). Study on UV laser machining
quality of carbon fibre reinforced composites, Composites: Part A, 41, 1403-1408.
39. Liu J., Zhao C., Hu H. and Shuai C. (2012). Systemic optimization of linear cavity Ybdoped
double-clad fiber laser, Optik - Int. J. Light Electron Opt,
10.1016/j.ijleo.2012.02.007.
40. Madić M. and Radovanović M. (2012) Investigation into the effect of the cutting
parameters on the burr height in CO2 laser nitrogen cutting of AISI 304 stainless steel,
Metalurgia International, XVII[7], 74-78.
41. Majumdar J. D. and Manna I. (2003). Laser processing of materials, Sadhana, 28 [3-4],
495-562.
42. Meijer J. (2004). Laser beam machining (LBM), state of the art and new opportunities,
Journal of Materials Processing Technology, 149, 2-17.
43. Muhammad N., Whitehead D., Boor A. and Li L. (2010). Comparison of dry and wet fibre
laser profile cutting of thin 316L stainless steel tubes for medical device applications,
Journal of Materials Processing Technology, 210, 2261-2267.
44. Nisar S., Sheikh M.A., Li L. and Safdar S. (2010). The effect of material thickness, laser
power and cutting speed on cut path deviation in high-power diode laser chip-free cutting
of glass, Optics & Laser Technology, 42, 1022-1031.
45. Nisar S., Li L., Sheikh M.A. and Pinkerton A.J. (2010) The effect of continuous and pulsed
beam modes on cut path deviation in diode laser cutting of glass, Int J Adv Manuf Technol,
49, 167-175.
46. Pandey A.K. and Dubey A.K. (2012a). Taguchi based fuzzy logic optimization of multiple
quality characteristics in laser cutting of Duralumin sheet, Optics and Lasers in
Engineering, 50, 328-335.
47. Pandey A.K. and Dubey A.K. (2012b). Simultaneous optimization of multiple quality
characteristics in laser cutting of titanium alloy sheet, Optics & Laser Technology, 44,
1858-1865.
Uludağ Üniversitesi Mühendislik-Mimarlık Fakültesi Dergisi, Cilt 18, Sayı 2, 2013
97
48. Patel J.M. and Patel D.M. (2011). Parametric investigation in CO2 laser cutting-Quality of
hardox-400 materials, International Journal of Engineering Science and Technology, 3[7],
5979-5984.
49. Parry J., Ahmed R., Dear F., Shephard J., Schmidt M., Li L. and Hand D. (2011). A fiberlaser
process for cutting thick Yttria-stabilized Zirconia: Application and modeling,
International Journal of Applied Ceramic Technology, 8 [6], 1277-1288.
50. Pfeifer R., Herzog D., Hustedt M. and Barcikowski S. (2010). Pulsed Nd:YAG laser
cutting of NiTi shape memory alloys—Influence of process parameters, Journal of
Materials Processing Technology, 210, 1918-1925.
51. Powell J., Al-Mashikhi S.O., Kaplan A.F.H. and Voisey K.T. (2011). Fibre laser cutting of
thin section mild steel: An explanation of the ‘striation free’ effect, Optics and Lasers in
Engineering, 49, 1069-1075.
52. Quintero F., Pou J., Ferñandez J.L., Doval A.F., Lusquiños F., Boutinguiza M., Soto R.,
and Amor M.P. (2006). Optimization of an off-axis nozzle for assist gas injection in laser
fusion cutting, Optics and Lasers in Engineering, 44, 1158-1171.
53. Quintero F., Riveiro A., Lusquiños F., Comesaña R. and Pou J. (2011). CO2 laser cutting of
phenolic resin boards, Journal of Materials Processing Technology, 211, 1710-1718.
54. Rashid R.A.R. , Sun S., Wang G. and Dargusch M.S. (2012). The effect of laser power on
the machinability of the Ti-6Cr-5Mo-5V-4Al beta titanium alloy during laser assisted
machining, International Journal of Machine Tools & Manufacture, 63, 41-43.
55. Rao R. and Yadava V. (2009). Multi-objective optimization of Nd:YAG laser cutting of
thin superalloy sheet using grey relational analysis with entropy measurement, Optics &
Laser Technology, 41, 922-930.
56. Riveiro A., Quintero F., Lusquiños F., Comesaña R. and Pou J (2010). Parametric
investigation of CO2 laser cutting of 2024-T3 alloy, Journal of Materials Processing
Technology, 210, 1138-1152.
57. Riveiro A., Quintero F., Lusquiños F., Comesaña R., ve Pou J. (2011). Effects of
processing parameters on laser cutting of aluminium–copper alloys using off-axial
supersonic nozzles, Applied Surface Science, 257, 5393-5397.
58. Riveiro A., Quintero F., Lusquiños F , Val del J., Comesaña R., Boutinguiza M., and Pou J.
(2012). Experimental study on the CO2 laser cutting of carbon fiber reinforced plastic
composite, Composites: Part A, 43, 1400-1409.
59. Salem H. G., Mansour M.S, Badr Y. and Abbas W.A. (2008). CW Nd:YAG laser cutting of
ultra low carbon steel thin sheets using O2 assist gas, Journal of Materials Processing
Technology, 196, 64-72.
60. Scintilla L.D. and Tricarico L. (2012). Experimental investigation on fiber and CO2 inert
gas fusion cutting of AZ31 magnesium alloy sheets, Optics and Laser Technology.
61. Shanjin L. and Yang W. (2006). An investigation of pulsed laser cutting of titanium alloy
sheet, Optics and Lasers in Engineering, 44, 1067-1077.
62. Sharma A. and Yadava V. (2008). Robust parameter design and multi-objective
optimization of laser beam cutting for aluminium alloy sheet, Int. J. Adv. Manuf. Technol.,
38, 268-277.
Çavdar, K. ve Tanrısever, T.: Farklı Malzemelerin Lazerle Kesilmesi
98
63. Sharma A. and Yadava V. (2012). Modelling and optimization of cut quality during pulsed
Nd:YAG laser cutting of thin Al-alloy sheet for straight profile, Optics & Laser
Technology, 44, 159-168.
64. Stournaras A., Stavropoulos P., Salonitis K. and Chryssolouris G. (2009). An investigation
of quality in CO2 laser cutting of aluminum, CIRP Journal of Manufacturing Science and
Technology, 2, 61-69.
65. Su C. T., Hsiao Y. H. and Chia-Chin Chang (2012). Parameter optimization design for
touch panel laser cutting process, IEEE Transactions on Automation Science and
Engineering, 9 [2], 320-329.
66. Tahir B.A, Ahmed R., Ashiq M. G. B., Ahmed A., and Saeed M.A. (2012). Cutting of
nonmetallic materials using Nd:YAG laser beam, Chinese Physical Society and IOP
Publishing Ltd, 21[4], 1-4.
67. Thawari G., Sundar J.K.S, Sundararajan G. and Joshi S.V. (2005). Influence of process
parameters during pulsed Nd:YAG laser cutting of nickel-base superalloys, Journal of
Materials Processing Technology, 170, 229-239.
68. Tsai M.J., Li C.H. and Chen C.C. (2008). Optimal laser-cutting parameters for QFN
packages by utilizing artificial neural networks and genetic algorithm, Journal of Materials
Processing Technology, 208, 270-283.
69. Vossen G. and Schüttler J. (2012). Mathematical modelling and stability analysis for laser
cutting, Mathematical and Computer Modelling of Dynamical System, 18[4], 439-463.
70. Wang X. and Wang J. (2010). Laser 3D machining with variable process parameters,
International Conference on Advances in Materials and Processing Technologies,
American Institute of Physics, Paris, 1157-1162.
71. Wang X.C., H.Y. Zheng, Chu P.L., Tan J.L., Teh K.M., Liu T., Ang B.C.Y. and Tay G.H.
(2010). High quality femtosecond laser cutting of alumina substrates, Optics and Lasers in
Engineering, 48, 657-663.
72. Yan Y., Li L., Sezer K., Whitehead D., Ji L., Bao Y. and Jiang Y. (2011). Experimental
and theoretical investigation of fibre laser crack-free cutting of thick-section alumina,
International Journal of Machine Tools & Manufacture, 51, 859-870.
73. Yan Y., Li L., Sezer K., Whitehead D., Ji L., Bao Y. and Jiang Y. (2012). Nano-second
pulsed DPSS Nd:YAG laser striation-free cutting of alumina sheets, International Journal
of Machine Tools & Manufacture, 53, 15-26.
74. Yang C.B, Deng C.S. and Chiang H.L. (2012). Combining the Taguchi method with
artificial neural network to construct a prediction model of a CO2 laser cutting experiment,
Int. .J Adv. Manuf. Technol., 59, 1103-1111.
75. Yilbas B.S. (2008). Laser cutting of thick sheet metals: Effects of cutting parameters on
kerf size variations, Journal of Materials Processing Technology, 201, 285-290.
76. Yilbas B.S., Karatas C., Uslan I., Keles O., Usta Y., Yilbas Z., and Ahsan M. (2008).
Wedge cutting of mild steel by CO2 laser and cut-quality assessment in relation to normal
cutting, Optics and Lasers in Engineering, 46, 777-784.
77. Yilbas B.S., Arif A.F.M. and Abdul Aleem B.J. (2010). Laser Cutting of Rectangular
Blanks in Thick Sheet Steel: Effect of Cutting Speed on Thermal Stresses, Journal of
Materials Engineering and Performance, 19[2], 177-184.
Uludağ Üniversitesi Mühendislik-Mimarlık Fakültesi Dergisi, Cilt 18, Sayı 2, 2013
99
78. Yilbas B.S., Akhtar S. and Chatwin C. (2011). Laser hole cutting into bronze: Thermal
stress analysis, Optics & Laser Technology, 43, 1119-1127.
79. Yilbas B.S. and Arif A.F.M (2011). Laser cutting of steel and thermal stress development,
Optics & Laser Technology, 43, 830-837.
80. Yilbas B.S. and Akhtar S.S. (2012). Laser cutting of Kevlar laminates and thermal stress
formed at cutting sections, Optics and Lasers in Engineering, 50, 204-209.
81. Yilbas B.S., Akhtar S.S. and Karatas C. (2012). Laser cutting of alumina tiles: Heating and
stress analysis, Journal of Manufacturing Processes.
82. Zhou B. H. and Mahdavian S.M. (2004). Experimental and theoretical analyses of cutting
nonmetallic materials by low power CO2-laser, Journal of Materials Processing
Technology, 146, 188-192.

Thank you for copying data from http://www.arastirmax.com