Your search keyword '"H.G. Jhang"' showing total 4 results

1. KSTAR magnet structure design

Author

K.-I. You, Y.K. Oh, N.I. Her, G.S. Lee, J.W. Sa, J.Y. Kim, C.H. Choi, D.K. Lee, and H.G. Jhang

Subjects

Physics, Nuclear engineering, Solenoid, Radius, Superconducting magnet, Condensed Matter Physics, Electronic, Optical and Magnetic Materials, Nuclear magnetic resonance, Structural load, Electromagnetic coil, KSTAR, Magnet, Structure design, Electrical and Electronic Engineering

Abstract

The Korea Superconducting Tokamak Advanced Research (KSTAR) device is a steady-state-capable experimental fusion device with a fully superconducting magnet system, including toroidal field (TF) coils, central solenoid (CS) coils, and poloidal field (PF) coils. The major design consideration of the magnet system is to meet the KSTAR mission with plasma current of 2 MA and toroidal field of 3.5 T at the major radius 1.8 m and z=0. The preliminary analyses show that the magnet structure design has mechanical, electrical, and thermal stability during operation. The TF magnets have a wedged structure, including coil cases, inter-coil structures, and inter-octant joints. The CS and PF structures are designed to support the electromagnetic forces. To support the coil system against gravity and lateral loads, gravity support and lateral load structures are designed.

Published

2001

2. The KSTAR project: An advanced steady state superconducting tokamak experiment

Author

G.S Lee, J Kim, S.M Hwang, C.S Chang, H.Y Chang, M.H Cho, B.H Choi, K Kim, K.W Cho, S Cho, K.K Choh, C.H Choi, J.H Choi, J.W Choi, I.S Choi, C.J Do, T.H Ha, J.H Han, J.S Hong, K.H Hong, N.I Hur, I.S Hwang, K.H Im, H.G Jhang, Y.S Jung, B.C Kim, D.L Kim, G.H Kim, H.S Kim, J.S Kim, J.Y Kim, W.C Kim, Y.S Kim, K.H Kwon, M.C Kyum, B.J Lee, D.K Lee, H.G Lee, J.M Lee, S.G Lee, H.G Na, Y.K Oh, J.H Park, H.C Ri, Y.S Ryoo, K.Y Song, H.L Yang, J.G Yang, B.J Yoo, S.J Yoo, N.S Yoon, S.B Yoon, G.H You, K.I You, W Choe, D.-I Choi, S.G Jeong, D.Y Lee, Y.S Bae, H.S Kang, G.N Kim, I.S Ko, W Namkung, J.S Oh, Y.D Bae, Y.S Cho, B.G Hong, G Hong, C.K Hwang, S.R In, M.H Ju, H.J Lee, B.H Oh, B.J Yoon, S Baang, H.J Choi, J Hwang, M.G Kim, Y.J Kim, S.I Lee, J Yee, C.S Yoon, K.-H Chung, S.H Hong, Y.S Hwang, S.H Kim, Y.H Kim, K.H Chung, J.Y Lim, D.W Ha, S.S Oh, K.S Ryu, Q.L Wang, T.K Ko, J Joo, S Suh, J.H Lee, Y.W Lee, H.S Shin, I.H Song, J Baek, I.Y Han, Y Koh, P.Y Park, C Ryu, J.J Cho, D.M Hwang, J.A Schmidt, H.K Park, G.H Neilson, W.T Reiersen, R.T Simmons, S Bernabei, F Dahlgren, L.R Grisham, S.C Jardin, C.E Kessel, J Manickam, S.S Medley, N Pomphrey, J.C Sinnis, T.G Brown, R.B White, K.M Young, J Schultz, P.W Wang, L Sevier, M.D Carter, P.M Ryan, D.W Swain, D.N Hill, W.M Nevins, and B.J Braams

Subjects

Physics, Nuclear and High Energy Physics, Tokamak, Divertor, Nuclear engineering, Cyclotron, Pulse duration, Plasma, Fusion power, Condensed Matter Physics, law.invention, Nuclear magnetic resonance, law, Magnet, KSTAR

Abstract

The Korea Superconducting Tokamak Advanced Research (KSTAR) project is the major effort of the national fusion programme of the Republic of Korea. Its aim is to develop a steady state capable advanced superconducting tokamak to establish a scientific and technological basis for an attractive fusion reactor. The major parameters of the tokamak are: major radius 1.8 m, minor radius 0.5 m, toroidal field 3.5 T and plasma current 2 MA, with a strongly shaped plasma cross-section and double null divertor. The initial pulse length provided by the poloidal magnet system is 20 s, but the pulse length can be increased to 300 s through non-inductive current drive. The plasma heating and current drive system consists of neutral beams, ion cyclotron waves, lower hybrid waves and electron cyclotron waves for flexible profile control in advanced tokamak operating modes. A comprehensive set of diagnostics is planned for plasma control, performance evaluation and physics understanding. The project has completed its conceptual design and moved to the engineering design and construction phase. The target date for the first plasma is 2002.

Published

2000

3. The KSTAR tokamak

Author

D.W. Swain, M.C. Kyum, M. Joo, J.C. Sinnis, Won Namkung, S. Baang, B.H. Choi, W. Reiersen, S.M. Hwang, Neil Pomphrey, J.Y. Lim, Kie-hyung Chung, S.R. In, W. M. Nevins, D.K. Lee, J.S. Hong, J.H. Schultz, B. Montgomery, D.L. Kim, C.H. Cho, Y.K. Oh, D.-I. Choi, G.H. You, L. Sevier, D.Y. Lee, K.H. Im, K.S. Kim, F. Dahlgren, Thomas Brown, Moo-Hyun Cho, R.T. Simmons, J. A. Schmidt, J. Manickam, Hyeon K. Park, S. Bernabei, L. R. Grisham, C.E. Kessel, Yong-Seok Hwang, Y.S. Cho, S.G. Lee, George H. Neilson, J.H. Park, W.C. Kim, H.Y. Chang, Kyekyoon Kim, P.W. Wang, Y.S. Jung, J.Y. Kim, B.J. Yoon, B.Y. Lee, K.-H. Chung, S. Cho, D. N. Hill, J.G. Yang, SeulChan Hong, J.H. Han, Jinchoon Kim, Stephen Jardin, N.I. Huh, B.G. Hong, Choong-Seock Chang, K. Young, G.S. Lee, and H.G. Jhang

Subjects

Physics, Tokamak, Toroid, business.industry, Nuclear engineering, Divertor, Electrical engineering, Superconducting magnet, law.invention, Conceptual design, law, Plasma shaping, Magnet, KSTAR, business

Abstract

The KSTAR (Korea Superconducting Tokamak Advanced Research) project is the major effort of the Korean National Fusion Program to design, construct, and operate a steady-state-capable superconducting tokamak. The project is led by Korea Basic Science Institute and shared by national laboratories, universities, and industry along with international collaboration. It is in the conceptual design phase and aims for the first plasma by mid 2002. The key design features of KSTAR are: major radius 1.8 m, minor radius 0.5 m, toroidal field 3.5 T, plasma current 2 MA, and flexible plasma shaping (elongation 2.0; triangularity 0.8; double-null poloidal divertor). Both the toroidal and the poloidal field magnets are superconducting coils. The device is configured to be initially capable of 20 s pulse operation and then to be upgraded for operation up to 300 s with non-inductive current drive. The auxiliary heating and current drive system consists of neutral beam, ICRF, lower hybrid, and ECRF. Deuterium operation is planned with a full radiation shielding.

Published

2002

4. Overview of KSTAR initial operation

Author

Kyung-Min Kim, D.K. Lee, Jong-Su Kim, D.R. Lee, Y. Yonekawa, Hyun-Seok Kim, J.S. Hong, T.S. Hahm, J.C. Kim, Patrick Diamond, K. Saito, J.M. Kwon, M.K. Park, M. Joung, S.G. Lee, B.H. Park, John Lohr, K.W. Cho, Y.K. Oh, Ki Min Kim, S.W. Yoon, G.L. Jackson, S.W. Kwak, D.S. Lim, K.M. Moon, D.S. Lee, M. Kwon, Joon-Wook Ahn, Y. Yaowei, Yong-Un Nam, Y.K. Kim, Takaki Hatae, Jung-Su Kim, K.P. Kim, Hyeon K. Park, Jong-Kyu Park, T. Mutoh, H. J. Sun, Yuichiro Kogi, S.H. Baek, H.L. Yang, T.G. Lee, R. Kumazawa, H.G. Jhang, J.K. Jin, D.H. Kim, Kazuo Kawahata, Woochang Lee, N.H. Song, S.T. Oh, Z.Y. Chen, L. Terzolo, J.Y. Kim, W.S. Han, S.G. Oh, W.H. Ko, H.T. Kim, J.S. Park, E.N. Bang, B. Patterson, Jaehyun Lee, Suk-Ho Hong, You-Moon Jeon, S.H. Park, Yoshio Nagayama, Seung Hun Lee, S. Sajjad, W.C. Lee, H.J. Lee, Yuejiang Shi, N.Y. Jeong, Yongkyoon In, W.C. Kim, Y. S. Park, Y.M. Park, Y.B. Jang, Jik-Soo Kim, Y.S. Bae, M. Leconte, S.J. Wang, S.H. Kim, S.M. Lee, K.D. Lee, O. J. Kwon, S.H. Seo, A. Mase, J.C. Seol, J.W. Yoo, Y.O. Kim, G.S. Yoon, Keishi Sakamoto, S.W. Kim, Hyun-Jong Woo, Yong-Seok Hwang, S.S. Kim, A.C. England, Kazuhiro Watanabe, A.W. Hyatt, Moo-Hyun Cho, Y.J. Kim, K.S. Lee, Choong-Seock Chang, Y.S. Kim, Jong-Gu Kwak, A.S. Welander, Y. Chu, Hee-Su Kim, S.A. Sabbagh, S.H. Hahn, C.H. Kim, D.H. Chang, Wonho Choe, Yong-Su Na, H.J. Do, S.I. Lee, M.K. Kim, J.I. Jeong, S.I. Park, D.G. Lee, B.H. Oh, S.T. Kim, J.H. Choi, K.I. Yoo, N.W. Eidietis, H.T. Park, S.R. Hong, D. Mueller, Dongcheol Seo, Larry R. Grisham, S. Kubo, Masatoshi Yagi, I. Chavdarovski, J.D. Kong, K.R. Park, J. Ju, Won Namkung, J. Leur, D. L. Hillis, S.H. Jeong, D. Humphrey, I.S. Woo, D.S. Park, Kyu-Sun Chung, M.L. Walker, H.K. Na, J.G. Bak, and H.K. Kim

Subjects

Nuclear and High Energy Physics, Materials science, Tokamak, Nuclear engineering, Pulse duration, Plasma, Condensed Matter Physics, law.invention, High-confinement mode, law, Beta (plasma physics), Magnet, KSTAR, Harmonic

Abstract

Since the successful first plasma generation in the middle of 2008, three experimental campaigns were successfully made for the KSTAR device, accompanied with a necessary upgrade in the power supply, heating, wall-conditioning and diagnostic systems. KSTAR was operated with the toroidal magnetic field up to 3.6 T and the circular and shaped plasmas with current up to 700 kA and pulse length of 7 s, have been achieved with limited capacity of PF magnet power supplies. The mission of the KSTAR experimental program is to achieve steady-state operations with high performance plasmas relevant to ITER and future reactors. The first phase (2008–2012) of operation of KSTAR is dedicated to the development of operational capabilities for a super-conducting device with relatively short pulse. Development of start-up scenario for a super-conducting tokamak and the understanding of magnetic field errors on start-up are one of the important issues to be resolved. Some specific operation techniques for a super-conducting device are also developed and tested. The second harmonic pre-ionization with 84 and 110 GHz gyrotrons is an example. Various parameters have been scanned to optimize the pre-ionization. Another example is the ICRF wall conditioning (ICWC), which was routinely applied during the shot to shot interval. The plasma operation window has been extended in terms of plasma beta and stability boundary. The achievement of high confinement mode was made in the last campaign with the first neutral beam injector and good wall conditioning. Plasma control has been applied in shape and position control and now a preliminary kinetic control scheme is being applied including plasma current and density. Advanced control schemes will be developed and tested in future operations including active profiles, heating and current drives and control coil-driven magnetic perturbation.

Published

2011