1 Young-Ju Lee Vacuum & Cryogenic Engineering Team National Fusion Research Institute Young-Ju Lee Vacuum & Cryogenic Engineering Team National Fusion.

Slides:



Advertisements
Similar presentations
Cryogenics at CERN (LHC)&Helium Inventory Brief review with emphasis given on cryogen management Americas Workshop on Linear Colliders 2014 Fermilab,
Advertisements

February 17-18, 2010 R&D ERL Roberto Than R&D ERL Cryogenics Roberto Than February 17-18, 2010 CRYOGENICS.
ITER Cryoplant System Status
Current status Arkadiy Klebaner November 21, 2012
ESS Cryogenic System Process Design Philipp Arnold Section Leader Cryogenics CEC – ICMC 2015 June 29, 2015.
CASIPP Design of Cryogenic Distribution System for CFETR CS model coil Division of Cryogenic Engineering and Technical Institute of Plasma Physics Chinese.
Large-capacity Helium refrigeration : from state-of-the-art towards FCC reference solutions Francois Millet – March 2015.
Cryogenic cavern in Asian site Conceptual design of the cryogenic system Layout of the cryogenic plant for site A & B New layout of the cryogenic system.
23 Jan 2007 LASA Cryogenics Global Group 1 ILC Cryomodule piping L. Tavian for the cryogenics global group.
SOFT 2004 OVERVIEW OF CRYOGENIC TECHNOLOGY FOR THE THERMONUCLEAR FUSION P. DAUGUET, M. BONNETON, P. BRIEND, F. DELCAYRE, B. HILBERT, A. RAVEX Air Liquide.
1 Cryogenic in Fusion Devices” Kavita Rathore MTech – NST Delhi University.
Conceptual Design Study - Cryogenic Requirements How to decide the layout of ILC cryogenic system Conceptual design of cryogenic system Layout of cryogenic.
IHEP 1.3 GHz Cryomodule and Cryogenics IHEP Cryogenic group 2nd Workshop of the IHEP 1.3 GHz SRF R&D Project Dec 2 nd, 2009.
Overview of the KSTAR commissioning M. Kwon 3 June, 2008.
The ESS Cryogenics System J. G. Weisend II, P. Arnold, J Fydrych, W. Hees, J. Jurns, A. Lundmark, X. T. Su, X.L. Wang June 2015.
Preliminary Design for the Coupling Coil Cryostat in MICE
Cryogenics Introduction, Overview and Applications Prof. Anand Bhatt APME, IT, NU.
Experience from large helium inventory management at CERN ILC Cryogenics and Helium inventory meeting CERN, Wed. 18 th of June 2014 D. Delikaris Technology.
1 Association Euratom-CEA P. Libeyre Pioneering superconductivity 23rd SOFT, Venice 21 September 2004 PIONEERING SUPERCONDUCTING MAGNETS IN LARGE TOKAMAKS.
9/17/07IRENG071 Cryogenic System for the ILC IR Magnets QD0 and QF1 K. C. Wu - BNL.
Process Definition of the Operation Modes for Super-FRS Magnet Testing CSCY - CrYogenic department in Common System, GSI, Darmstadt Y. Xiang, F. Wamers.
Performance analysis of cryogenic system and cryomodules for the complete superconducting linear accelerator at IUAC, New Delhi. T S Datta ( On behalf.
The International Workshop on Thin Films. Padova 9-12 Oct of slides Present Status of the World- wide Fusion Programme and possible applications.
MAGNET#1MAGNET#2MAGNET#3 SATELLITE VB#1 SATELLITE VB#2 SATELLITE VB#3 PRECOOLER#1PRECOOLER#2 DISTRIBUTION VALVE BOX DVB CP#1CP#3CP#2 BUFFER DEWAR LHe 5m.
Date 2007/Sept./12-14 EDR kick-off-meeting Global Design Effort 1 Cryomodule Interface definition N. Ohuchi.
ITER Liquid Helium Plants Status and Test Protocol ICEC June 29th, 2015 / Grenoble / FranceY. FABRE.
PIP-II Cryogenics Arkadiy Klebaner and Jay Theilacker PIP-II Collaboration Meeting 9 November 2015.
Manoj Kumar, B. N. Duttagupta, Rajvir Singh Doohan, S. K. Joshi, A. K. Sagar, L. Chowdhary, Rekhya Naika, Prabhat Kumar Gupta, Vivek Nema, Hemant Kumar.
17-18 December 2013 LARP VTF Workshop BNL Proposal 1 A.Marone
Overview of the ESS Linac Cryogenic Distribution System
Spoke section of the ESS linac: - the Spoke cryomodules - the cryogenic distribution system P. DUTHIL (CNRS-IN2P3 IPN Orsay / Division Accélérateurs) on.
CRYOGENIC SYSTEM of RAON Chul Jin Choi, Ki Woong Lee Cryogenics and Control Team Accelerator Division 5/23/2013 Chul Jin Choi, Ki Woong Lee Cryogenics.
1 Cryogenic System of Interaction Region (SiD, ILD, QD0, QF1, Crab Cavity) in the Japanese Mountain Site WebEx meeting : June 19 th, 2012 IPNS/Cryogenic.
Energy efficiency considerations in cryogenics Philipp Arnold Section Leader Cryogenics Proton Driver Efficiency Workshop.
CRYOGENIC SYSTEM of RAON Chul Jin Choi CnC Team, Accelerator Division Chul Jin Choi CnC Team, Accelerator Division.
Max-Planck-Institut für Plasmaphysik 1 ICEC 26- ICMC 2016 March 7-11, 2016, New Delhi, India Michael Nagel Cryogenic commissioning, cool down and first.
Cryogenic Heat loads Analysis from SST-1 Plasma Experiments N. Bairagi, V. L. Tanna and S. Pradhan SST-1 Mission Institute for Plasma Research, Bhat, Ganhinagar.
Final Design Cryogenic and mechanical configurations
LCLS-II Technical Requirements
Teleconf ACS – FREIA 28th March 2017
Optical Fiber Sensors for Cryogenic applications Presented by: Daniele Inaudi, CTO SMARTEC
Study and Development of Large Cryogenic Systems in China
Process Simulation for the LCLS-II Cryogenic Systems
Z. W. Zhou, Q. Y. Zhang*, X. F. Lu, L. B. Hu and P. Zhu
FRIB Cryogenic Support
Cryogenic behavior of the cryogenic system
Innovative He cycle Francois Millet.
EPFL-SPC, 5232 Villigen PSI, Switzerland
Cryoplant Installation Scope
N. Hasan1, P. Knudsen2 and V. Ganni2
CEPC Cryogenic System Jianqin Zhang, Shaopeng Li
CRYOGENICS OPERATIONS 2008 Organized by CERN
BriXS – MariX WG 8,9 LASA December 13, 2017.
Cryostat design Mechanical design: Thermal screens: Specifications:
Zhiwei Zhou, Qiyong Zhang* and EAST Cryogenic Team
SHMS Cryogenics and Q2(Q3Dipole) Cool Down
Cryogenic cavern in Asian site
Operation experience of cryogenic system and cryomodules for the superconducting linear accelerator at IUAC, New Delhi. T S Datta ( On behalf of Cryogenics.
High Magnetic Field Lab, CAS
ILC Experimental Hall Cryogenics An Overview
Experimental study of helium liquefier
Overarching Commissioning Plan
A Complete System for Operation of a Superconducting Magnet*
Schematic diagram of the cryogenic system
Cryogenic behavior of the magnet
ESR2 Process Cycle Design
Thermohydraulic behaviour of the cryogenic system
Conceptual design of the Cryogenic System of Comprehensive Research Facility for Key Fusion Reactor Core Systems Liangbing Hu Sep.4.
ESR2 Process Cycle Design
J. Fleiter, S. C. Hopkins, A. Ballarino
Presentation transcript:

1 Young-Ju Lee Vacuum & Cryogenic Engineering Team National Fusion Research Institute Young-Ju Lee Vacuum & Cryogenic Engineering Team National Fusion Research Institute Applied Cryogenic Engineering for the Fusion & SC Accelerator

2 Application of Cryogenic Eng. Introduction; Cryogenic System I I III Summary IV Core Cryogenic Technology II

3 Introduction

4 Global Helium Refrigerators YearIssue 1903He gas was found in a natural gas 1908First helium liquefaction by H. K. Onnes SiteNamePlaceCapacity (4.5 K eq.)Purpose KoreaKSTAR HRSDaejeon9 kWSC tokamak KHNP TRFGyeongju2 kWTritium isolator RAON HCPDaejeon18 kWSC accelerator AbroadCERN LHCGeneve (CH)18 kW (8 sets)SC accelerator ORNL SNSOak Ridge (US)~ 6 kWSC accelerator ITER HRSAxe (France)25 kW (3 sets)SC tokamak

5 To achieve the superconducting tokamak construction and operation experiences, To develop high performance steady- state operation physics and technologies that are essential for fusion reactor development Major radius, R 0 Minor radius, a Elongation,  Triangularity,  Plasma volume Plasma surface area Plasma cross section Plasma shape Plasma current, I P Toroidal field, B 0 Pulse length  N Plasma fuel Superconductor Auxiliary heating /CD Cryogenic Parameter 1.8 m 0.5 m m 3 56 m m 2 DN, SN 2.0 MA 3.5 T 300 s 5.0 H, D Nb 3 Sn, NbTi ~ 26 MW 9 KSTAR 6.2 m 2.0 m m m 2 22 m 2 SN 15 (17) MA 5.3 T 400 s 1.8 (2.5)* H, D, T Nb 3 Sn, NbTi 73 (110) MW 75 ITER SC Tokamak; KSTAR (Korea) KSTAR mission and Parameters

6 KSTAR HRS Schematic layout of the KSTAR main cryogenic system WCS and GMS LP : 2 X MYCOM400S & Siemens5010 HP : 2 X MYCOM320S & Siemens5810 Electricity : 3.6 MW Mass flow : ~1.1 kg/s ORS : Coalescer & Charcoal adsorber Pure GHe : 12,000 Nm 3 Impure helium tank : 100 m Recovery comp. & purifier : 32 g/s Cold Box Cooling power : 9 6 expander turbines 11 Al fin-plate HXs (4 blocks) 2 X 80 K adsorber 20 K adsorber Cryogenic valves : 49 EA 7 Al LHe/SHe HXs 2 X SHe circulator Cold compressor Thermal damper: 4 m 3 LHe (4.3 K) Distribution Box#1 D/B# cryogenic valves. 6 warm valves - Dimension : 3.5 m X 6 m 5 cryogenic transfer lines (CTLs) - TL1 : 27 m, 17 internal cooling tubes - TL2 : 6.2 m, 25 internal cooling tubes - TL3 : 6.2 m 18 internal cooling tubes - TL5 : 26 m, 4 internal cooling tubes - TL6 : 16 m, 8 internal cooling tubes Helium Distribution System & KSTAR

7 Process flow diagram of the KSTAR main cryogenics System Design; Refrigerator

8 Simple P&ID of the KSTAR HDS System Design; Distribution System

9 9 SC Accelerator; RAON (Korea)

10 Core Cryogenic Technology

11 Extreme Core Technology & Cryogenic Engineering ParameterTechnologyApplication Low Temperature300~4.2 K; Cryogenic engineering Commercial; water, foods, … Industrial; LNG, LPG, …. Science; nitrogen, hydrogen, helium, … High Temperature ~ 1000 K; Material & high energy engineering Metal & alloy Energy; nuclear fission & fusion Science; accelerator Low Pressure 1E5 ~ 1E-10 Pa; Vacuum technology Industrial; semiconductor & application, foods, … Space science, energy, …. High Pressure~ 100 bar Pressure vessel Energy; heat exchanger Deep sea High Voltage~ 10 kV Glow discharge Electrical energy transport Fusion energy High Currents~ 10 kAFusion energy High Magnetic Fields ~ 10 Tesla Medical; MRI Science Fusion energy High Frequency~ GHzScience (accelerator, …)

12 Temperature

13 Pressure

14 Vacuum Pressure

15 Magnetic Fields

16 Frequency

17 Application of Cryogenic Engineeing

18 Helium Refrigerator  Pressure vessel; Helium storage tank  Helium recovery system  Warm helium compressor  Helium purifier  Oil/dust filters  Vacuum cryostat; Cold box  Heat exchanger  Cryogenic turbine & cold compressor  Instruments; cryogenic valve, flowmeter, temperature/ pressure sensor, etc….  Control/monitoring/safety engineering

19 Fusion Engineering  Superconducting cable (cable-in-conduit type)  Superconducting magnet (~ 10 Tesla, fast sweep)  Magnet quench protection system  Current feeder (300 ~ 4.5 K)  Helium distribution system  Vacuum cryostat  System design engineering  System analysis (FEA & thermo-hydraulic analysis)  Performance test facilities  Instrumentation & control system  High voltage insulation (~10 kV)

20 SC Accelerator Engineering  DC superconducting magnet (LTS & HTS, ~ 1 Tesla)  Magnet quench protection system  Current feeder (300 ~ 4.5 K)  Superconducting cavity and cryomodule  Helium distribution system  Vacuum cryostat  System design engineering  System analysis (FEA & thermo-hydraulic analysis)  Performance test facilities  Instrumentation & control system

21 The Other Application Area  LNG industry  Liquid nitrogen industry  Hydrogen gas liquefaction & storage  MRI  Space science & engineering  Etc.

22 Summary

23 Summary  Helium cryogenic engineering has more than 100 years of history.  But, there have been applied in many areas such as future fusion energy, industry, medical science, space science, pure science, and so on, for the mankind.  As time goes on, the cryogenic engineering will be much more important together with core technologies such as high/low temperature, high/low pressure, high voltage/ currents, high frequency, and so on.

24 THANK YOU FOR THE ATTENTION!!!

Feedback: Privacy Policy Feedback
Do Not Sell My Personal Information
About project: SlidePlayer Terms of Service

© 2024 SlidePlayer.com Inc. All rights reserved.