• Title/Summary/Keyword: conduction -cooled system

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A Study on the Electrical Properties of the Conduction-cooled HTS SMES System (전도냉각형 고온초전도 에너지저장장치의 전기적 특성)

  • Choi, Jae-Hyeong;Kwag, Dong-Soon;Cheon, Hyeon-Gweon;Kim, Hae-Jong;Kim, Sang-Hyun
    • Journal of the Korean Institute of Electrical and Electronic Material Engineers
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    • v.20 no.2
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    • pp.135-141
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    • 2007
  • The conduction-cooled HTS SMES is operated in cryogenic and high vacuum condition. Thus, Insulation design at cryogenic temperature and high vacuum is a key and an important element that should be established to accomplish miniaturization that is a big advantage of HTS SMES. However, the behaviors of insulators for cryogenic conditions in vacuum are virtually unknown. Therefore, we need active research and development of insulation concerning application of the conduction-cooled HTS SMES. Therefore, in this study, we experimented about insulation characteristic high vacuum and cryogenic similar to driving condition of SMES system. Also, investigated about insulation characteristic of suitable some materials to insulator for conduction-cooled HTS SMES. As this results, we possessed basis data for insulation materials selection and insulation design for development of 600 kJ class conduction-cooled HTS SMES.

Insulating Properties between Cryocooler and Magnet for the Conduction-Cooled HTS SMES System (전도냉각형 고온초전도 SMES의 냉동기와 마그네트 간의 절연 특성)

  • Choi Jae-Hyeong;Kwag Dong-Soon;Cheon Hyeon-Gweon;Kim Hae-Jong;Seong Ki-Chul;Kim Sang-Hyun
    • Progress in Superconductivity and Cryogenics
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    • v.8 no.3
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    • pp.45-48
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    • 2006
  • The conduction-cooled HTS SMES is operated in cryogenic and high vacuum condition. Thus. Insulation design at cryogenic temperature and high vacuum is a key and an important element that should be established to accomplish compact design is a big advantage of HTS SMES. However, the behaviors of insulators for cryogenic conditions in vacuum are virtually unknown. Therefore, active research and development of insulation concerning application of the conduction cooled HTS SMES was needed. In this study, the insulation characteristics at experimented high vacuum and cryogenic similar to running condition of SMES system. Also, investigated about insulation characteristics of suitable some materials to insulator for conduction-cooled HTS SMES. As these results. the basis data was obtained for insulation materials selection and insulation design for development of 600kJ class conduction-cooled HTS SMES.

A Study on Design, Fabrication Techniques and Test Results of 1.2kV 180A Inductive Superconducting Fault Current Limiter by Conduction-Cooled System (전도냉각에 의한 1.2 KV/80 A급 유도형 고온초전도 한류기의 설계, 제작 및 테스트에 관한 연구)

  • 강형구;전우용;이승제;안민철;배덕권;윤용수;고태국
    • Progress in Superconductivity and Cryogenics
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    • v.5 no.2
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    • pp.30-35
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    • 2003
  • The inductive superconducting fault current limiter (SFCLJ limits the fault current with its dc reactor. To fabricate the optimal dc reactor for inductive SFCL, several design and manufacturing technologies are necessary. In this paper, the manufacturing technology for dc reactor and cryogenic cooling method are described in detail. GM-cryocooler was used enlarge the critical current of dc reactor by cooling down the temperature of dc reactor about 20 K. Moreover, the results of short circuit test were described. Finally, the thermal characteristics of conduction-cooled system were discussed and then, sub-cooled nitrogen system was proposed to enhance the thermal stability of dc reactor.

Basic Insulation Characteristics of Conduction-Cooled HTS SMES System (전도냉각 고온초전도 SMES 시스템의 기초절연 특성)

  • Choi Jae-Hyeong;Kwang Dong-Soon;Cheon Hyeon-Gweon;Kim Sang-Hyun
    • The Transactions of the Korean Institute of Electrical Engineers C
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    • v.55 no.8
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    • pp.404-410
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    • 2006
  • Toward the practical applications, on operation of conduction-cooled HTS SMES at temperatures well below 40[K] should be investigated, in order to take advantage of a greater critical current density of HTS and considerably reduce the size and weight of the system. In order to take advantage of a greater critical current density of high temperature superconducting (HTS) and considerably reduce the size and weight of the system, conduction-cooled HTS superconducting magnetic energy storage (SMES) at temperatures well below 40[K] should be investigated. This work focuses on the breakdown and flashover phenomenology of dielectrics exposed in air and/or vacuum for temperatures ranging from room temperature to cryogenic temperature. Firstly, we summarize the insulation factors of the magnet for the conduction cooled HTS SMES. And Secondly a surface flashover as well as volume breakdown in air and/or vacuum with two kind insulators has been investigated. Finally, we will discuss applications for the HTS SMES including aging studies on model coils exposed in vacuum at cryogenic temperature. The commercial application of many conduction-cooled HTS magnets, however, requires refrigeration at temperatures below 40[K], in order to take advantage of a greater critical current density of HTS and reduce considerably the size and weight of the system. The magnet is driven in vacuum condition. The need to reduce the size and weight of the system has led to the consideration of the vacuum as insulating media. We are studying on the insulation factors of the magnet for HTS SMES. And we experiment the spacer configure effect in the dielectric flashover characteristics. From the results, we confirm that our research established basic information in the insulation design of the magnet.

A Study on the Electrical Properties for the Insulation Design of a Conduction-Cooled HTS SMES (전도냉각 HTS SMES 절연설계를 위한 전기적 특성연구)

  • Choi, Jae-Hyeong;Kwag, Dong-Soon;Cheon, Hyeon-Gweon;Baek, Seung-Myeong;Kim, Hae-Jong;Seong, Ki-Chul;Kim, Sang-Hyun
    • Proceedings of the Korean Institute of Electrical and Electronic Material Engineers Conference
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    • 2006.06a
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    • pp.226-227
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    • 2006
  • The conduction-cooled HTS SMES is operated in cryogenic and high vacuum condition. Thus, Insulation design at cryogenic temperature and high vacuum is a key and an important element that should be established to accomplish miniaturization that is a big advantage of HTS SMES. Therefore, we need active research and development of insulation concerning application of the conduction-cooled HTS SMES. Therefore, in this study, we experimented about insulation characteristic high vacuum and cryogenic similar to driving condition of SMES system. Also, investigated about insulation characteristic of suitable some materials to insulator for conduction-cooled HTS SMES. As this results, we possessed basis data for insulation materials selection and insulation design for development of 600 kJ class conduction-cooled HTS SMES.

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The Manufacture and Insulating Test of Mini-model for 600kJ Class Conduction Cooled HTS SMES (600kJ급 전도냉각 HTS SMES의 미니모델 제작 및 절연평가)

  • Choi, Jae-Hyeong;Kwag, Dong-Soon;Cheon, Cheon-Gweon;Min, Chi-Hyun;Kim, Hae-Jong;Kim, Sang-Hyun
    • The Transactions of The Korean Institute of Electrical Engineers
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    • v.56 no.3
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    • pp.588-593
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    • 2007
  • The 600kJ class high temperature superconducting magnetic energy storage (HTS SMES) system is being developed by Korean Electrotechnology Research Institute (KERI). The system is operated in cryogenic temperature and high vacuum condition. The SMS magnet was cooled by conduction cooling method using a Gifford-McMahon cycle cryocooler. Thus, electric insulation design at cryogenic temperature and high vacuum is a key and an important element that should be established to accomplish compact design is a big advantage of HTS SMES. This paper describes the electric insulation design, fabrication and experimental results for a mini model of conduction cooled HTS SMES.

Insulation test of Mini model for the Development of the conduction cooled HTS SMES (전도냉각형 HTS SMES 개발을 위한 미니모델의 절연성능평가)

  • Choi, Jae-Hyeong;Kwag, Dong-Soon;Cheon, Hyeon-Gweon;Kim, Hae-Jong;Seong, Ki-Chul;Kim, Sang-Hyun
    • Progress in Superconductivity and Cryogenics
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    • v.9 no.1
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    • pp.32-36
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    • 2007
  • The 600 kJ calss high-temperature superconducting(HTS) SMES(superconducting magnetic energy storage) system is being developed by Korean Electrotechnology Research Institute(KERI). The system is operated in cryogenic temperature and high vacuum condition. The SMES magnet was cooled by conduction cooling method using a Gifford-McMahon cycle cryocooler. Thus the electric insulation design at cryogenic temperature and high vacuum is a key and an important element. Because it accomplish compact design that is a big advantage of HTS SMES. This paper describes the electric insulation design, fabrication and experimental results for a mini model of conduction cooled HTS SMES.

Current Status of Liquid-Free Superconducting System Develo (액체를 사용하지 않는 초전도시스템의 개발 동향)

  • 장호명
    • Proceedings of the Korea Institute of Applied Superconductivity and Cryogenics Conference
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    • 1999.02a
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    • pp.1-6
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    • 1999
  • The recent progress in the new cooling technology for superconducting systems without liquid cryogens is briefly presented. In these conduction-cooled systems, the super-conducting magnets are cooled by a direct contact with closed-cycle cryocoolers and only electricity is supplied to maintain the cryogenic temperatures. It is reported that at least 20 conduction-cooled (low Tc or high Tc) super- conducting systems have been constructed, tested, or commercially used worldwide. Some of the significant design issues are discussed in comparison with the conventional liquid-helium cooled systems.

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Development of a Conduction-Cooled Superconducting Magnet System for Material Separation (물질분리를 위한 전도냉각형 초전도자석 시스템 개발)

  • Choi, Y.S.;Kim, D.L.;Lee, B.S.;Yang, H.S.;Jung, W.M.
    • Progress in Superconductivity
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    • v.10 no.1
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    • pp.50-54
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    • 2008
  • A conduction-cooled superconducting magnet system is developed for material separation. The superconducting magnet for material separation has to be designed to have a strong magnetic field in a control volume. Since the magnetic field gradient is larger at the end rather than at the center of the magnet, we developed a design method to optimize the superconducting magnet for material separation. The safety of the superconducting magnet is evaluated, taking into account the electro-magnetic field, heat and structure. The superconducting coil is successfully wound by the wet-winding method. The superconducting coil is installed in a cryostat maintaining high vacuum, and cooled down to approximately 4 K by a two-stage GM cryocooler. The performance of the conduction-cooled superconducting magnet system is discussed with respect to the supplied current, cooling medium and cooling power of a cryocooler.

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Study on the Electrical Insulation of Current Lead in the conduction-cooled 1-2kV Class High-Tc Superconducting DC Reactor (전도냉각되는 1-2kV급 고온초전도 직류리액터 전류도입부의 전기적 절연에 대한 연구)

  • 배덕권;안민철;이찬주;정종만;고태국;김상현
    • Progress in Superconductivity and Cryogenics
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    • v.4 no.1
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    • pp.30-34
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    • 2002
  • In this Paper, Insulation of current lead in the conduction-cooled DC reactor for the 1.2kV class 3 high-Tc superconducting fault current limiter(SFCL) is studied. Thermal link which conducts heat energy but insulates electrical energy is selected as a insulating device for the current lead in the conduction-cooled Superconducting DC reactor. It consists of oxide free copper(OFC) sheets, Polyimide films, glass fiberglass reinforced Plastics (GFRP) plates and interfacing material such an indium or thermal compound. Through the test of dielectric strength in L$N_2$, polyimide film thickness of 125 ${\mu}{\textrm}{m}$ is selected as a insulating material. Electrical insulation and heat conduction are contrary to each other. Because of low heat conductivity of insulator and contact area between electrical insulator and heat conductor, thermal resistance of conduction-cooled system is increased. For the reducing of thermal resistance and the reliable contact between Polyimide and OFC, thermal compound or indium can be used As thermal compound layer is weak layer in electrical field, indium is finally selected for the reducing of thermal resistance. Thermal link is successfully passed the test. The testing voltage was AC 2.5kVrms and the testing time was 1 hour.