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NTIS 바로가기Journal of nuclear fuel cycle and waste technology = 방사성폐기물학회지, v.19 no.3, 2021년, pp.279 - 287
Shin, Jae Sung (Korea Atomic Energy Research Institute) , Oh, Seong Y. (Korea Atomic Energy Research Institute) , Park, Seung-Kyu (Korea Atomic Energy Research Institute) , Kim, Taek-Soo (Korea Atomic Energy Research Institute) , Park, Hyunmin (Korea Atomic Energy Research Institute) , Lee, Jonghwan (Korea Atomic Energy Research Institute)
For application in nuclear decommissioning, underwater laser cutting studies were conducted on thick stainless-steel plates for various cutting directions using a 6 kW fiber laser. For cutting along the horizontal direction with horizontal laser irradiation, the maximum cutting speed was 110 mm...
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G.R. Lee, B.J. Lim, and C.D. Park, "Evaluation of Metal Cutting Technologies for Decommissioning of Nuclear Power Plants", Transactions of the Korean Nuclear Society Spring Meeting, 19S-510, Korean Nuclear Society, Jeju (2019).
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K. Tamura and R. Yamagishi, "Observation of the Molten Metal Behaviors During the Laser Cutting of Thick Steel Specimens Using Attenuated Process Images", J. Nucl. Sci. Technol., 54(6), 655-661 (2017).
K. Tamura and S. Toyama, "Laser Cutting Performances for Thick Steel Specimens Studied by Molten Metal Removal Conditions", J. Nucl. Sci. Technol., 54(9), 1011-1017 (2017).
C. Chagnot, G. de Dinechin, and G. Canneau, "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", Nucl. Eng. Des., 240(10), 2604-2613 (2010).
P.A. Hilton and A. Khan, "Underwater Cutting Using a 1 ㎛ Laser Source", J. Laser Appl., 27, 032013 (2015).
A. Choubey, R.K. Jain, S. Ali, R. Singh, S.C. Vishwakarma, D.K. Agrawal, R. Arya, R. Kaul, B.N. Upadhyaya, and S.M. Oak, "Studies on Pulsed Nd:YAG Laser Cutting of Thick Stainless Steel in Dry Air and Underwater Environment for Dismantling Applications", Opt. Laser Technol., 71, 6-15 (2015).
J.S. Shin, S.Y. Oh, H. Park, C.M. Chung, S. Seon, T.S. Kim, L. Lee, B.S. Choi, and J.K. Moon, "High-speed Fiber Laser Cutting of Thick Stainless Steel for Dismantling Tasks", Opt. Laser Technol., 94, 244-247 (2017).
J.S. Shin, S.Y. Oh, H. Park, C.M. Chung, S. Seon, T.S. Kim, L. Lee, and J. Lee, "Laser Cutting of Steel Plates up to 100 mm in Thickness With a 6-kW Fiber Laser for Application to Dismantling of Nuclear Facilities", Opt. Laser Eng., 100, 98-104 (2018).
S. Seon, J.S. Shin, S.Y. Oh, H. Park, C.M. Chung, T.S. Kim, L. Lee, and J. Lee, "Improvement of Cutting Performance for Thick Stainless Steel Plates by Step-like Cutting Speed Increase in High-power Fiber Laser Cutting", Opt. Laser Technol., 103, 311-317 (2018).
J.S. Shin, S.Y. Oh, H. Park, C.M. Chung, S. Seon, T.S. Kim, L. Lee, and J. Lee, "Cutting Performance of Thick Steel Plates up to 150 mm in Thickness and Large Size Pipes With a 10-kW Fiber Laser for Dismantling of Nuclear Facilities," Ann. Nucl. Energy, 122, 62-68 (2018).
J.S. Shin, S.Y. Oh, H. Park, T.S. Kim, L. Lee, C.M. Chung, and J. Lee, "Underwater Cutting of 50 and 60 mm Thick Stainless Steel Plates Using a 6-kW Fiber Laser for Dismantling Nuclear Facilities", Opt. Laser Technol., 115, 1-8 (2019).
S.Y. Oh, J.S. Shin, T.S. Kim, H. Park, L. Lee, C.M. Chung, and J. Lee, "Effect of Nozzle Types on the Laser Cutting Performance for 60-mm-thick Stainless Steel", Opt. Laser Technol., 119, 105607 (2019).
J.S. Shin, S.Y. Oh, S. Park, H. Park, T.S. Kim, L. Lee, Y. Kim, and J. Lee, "Underwater Cutting of Stainless Steel up to 100 mm Thick for Dismantling Application in Nuclear Power Plants", Ann. Nucl. Energy, 147, 107655 (2020).
S.Y. Oh, J.S. Shin, S. Park, T. S. Kim, H. Park, L. Lee, and J. Lee, "Underwater Laser Cutting of Thick Stainless Steel Blocks Using Single and Dual Nozzles", Opt. Laser Technol., 136, 106757 (2021).
J.S. Shin, S.Y. Oh, S.K. Park, H. Park, and J. Lee, "Improved Underwater Laser Cutting of Thick Steel Plates Through the Initial Oblique Cutting", Opt. Laser Technol., 141, 107120 (2021).
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