• Title/Summary/Keyword: ITER 연료주기

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Tritium Fuel Cycle Technology of ITER Project (ITER 사업의 삼중수소 연료주기 기술)

  • Yun, Sei-Hun;Chang, Min-Ho;Kang, Hyun-Goo;Kim, Chang-Shuk;Cho, Seung-Yon;Jung, Ki-Jung;Chung, Hong-Suk;Song, Kyu-Min
    • Journal of Hydrogen and New Energy
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    • v.23 no.1
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    • pp.56-64
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    • 2012
  • The ITER fuel cycle is designed for DT operation in equimolar ratio. It involves not only a group of fuelling system and torus cryo-pumping system of the exhaust gases through the divertor from the torus in tokamak plant, but also from the exhaust gas processing of the fusion effluent gas mixture connected to the hydrogen isotope separation in cryogenic distillation to the final safe storage & delivery of the hydrogen isotopes in tritium plant. Tritium plant system supplies deuterium and tritium from external sources and treats all tritiated fluids in ITER operation. Every operation and affairs is focused on the tritium inventory accountancy and the confinement. This paper describes the major fuel cycle processes and interfaces in the tritium plant in aspects of upcoming technologies for future hydrogen and/or hydrogen isotope utilization.

Mathematical Modeling of Scheduling Problems for the Fusion Fuel Cycle (핵융합 공정주기에서의 생산 계획 최적화)

  • Lee, Suh-Young;Ha, Jin-Kuk;Lee, In-Beum;Lee, Euy Soo
    • Korean Chemical Engineering Research
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    • v.58 no.4
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    • pp.596-603
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    • 2020
  • In this study, a mathematical model for optimal operation of the fusion fuel cycle is developed based on scheduling approach. The fusion fuel cycle consists of a system for storing and supplying deuterium and tritium, and receiving and separating process after the fusion reaction. Except that tritium is a radioactive material, most of these processes consist of catalytic reactions and separation process. For these reasons, it is possible to apply scheduling approach which is also widely utilized to chemical plants to derive the optimal operating scenarios. The developed model determined the optimal regeneration cycle to minimize the amount of tritium inside the vacuum pumps. Based on the characteristics of various device in the fusion reactor, the optimal tritium plant operation scenario is evaluated. The formulated model was applied to the actual tokamak scenario and utilized to analyze the fuel flow and balance of ITER fuel cycle.

Tritium Fuel Cycle of the International Thermonuclear Experimental Reactor (국제핵융합실험로 삼중수소 연료주기)

  • Song, Kyu-Min;Sohn, Soon Hwan;Chung, Hongsuk;Yun, Sei-Hun;Jung, Ki Jung
    • Korean Chemical Engineering Research
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    • v.50 no.4
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    • pp.595-603
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    • 2012
  • International Thermonuclear Experimental Reactor (ITER) will be constructed in 2019 according to the JIA (Joint Implementation Agreement) of 7 countries. The ITER fusion fuel cycle consists of fusion vacuum vessel, tritium plant and fuelling system. The tritium plant provides the functions of storage, delivery, separation, removal and recovery of the deuterium and tritium used as fusion fuels for the ITER. The tritium plant systems supply deuterium and tritium from external sources and treat all tritiated fluids from ITER operation through Storage and Delivery System (SDS), Tokamak Exhaust Processing (TEP), Isotope Separation System (ISS), Water Detritiation System & Atmosphere Detritiation System (WDS & ADS) and Analysis System (ANS). In this paper, the functions and design requirements of the major systems in the tritium plant and the status of R&D are described. Korean party is developing the SDS for ITER tritium plant and partially attaining the WDS technology through the construction and operation experience of the Wolsong Tritium Removal Facility (WTRF). Now it is expected that researchers in other fields such as chemical engineering take part in the development of upcoming technologies for ISS and TEP.