FAIR MT/Cryogenics, Seong Yeub Shim Beam-Tube Eddy Loss S. Y. Shim.

Slides:

Advertisements

Similar presentations

Heat Transfer to Solids in a Flowing Fluid

Advertisements

Electrical Machines LSEGG216A 9080V.

Application of Steady-State Heat Transfer

First Wall Heat Loads Mike Ulrickson November 15, 2014.

Cryogenic Experts Meeting (19 ~ ) Heat transfer in SIS 300 dipole MT/FAIR – Cryogenics Y. Xiang, M. Kauschke.

A.KOVALENKO SUPERCONDUCTING MAGNETS for NICA BOOSTER & COLLIDER NICA ROUND TABLE DISCUSSION - 3 JINR, Dubna, November 05, 2008.

Method of beam extraction from a synchrotron by the instrumentality of multilayer Cu-Fe shield Bondarenko Alexey.

SIS 100 – Fast ramped superconducting magnets E. Fischer, GSI Darmstadt Meeting of the Design Study Committee for the EU contract "DIRACsecondary-Beams"

The Analysis of a…. Here is what we wanted to learn:  How do stirling engines work?  Which design aspects have the greatest effect on their performance?

Undulator R & D Jim Clarke STFC Daresbury Laboratory, UK BAW-2 SLAC Jan 2011.

Thermal Analysis of short bake out jacket version 1 12-Nov-2013.

First Wall Thermal Hydraulics Analysis El-Sayed Mogahed Fusion Technology Institute The University of Wisconsin With input from S. Malang, M. Sawan, I.

HTS Solenoid Punch: Team Supercool. The Story So Far tos/boxeo/box-punch.jpg.

Chapter 2 Transformers.

Chapter 1 MAGNETIC CIRCUIT.

R&D Status and Plan on The Cryostat N. Ohuchi, K. Tsuchiya, A. Terashima, H. Hisamatsu, M. Masuzawa, T. Okamura, H. Hayano 1.STF-Cryostat Design 2.Construction.

2004/01/17 Sangjin Park PREM, Hanyang University

1 Calorimeter Thermal Analysis with Increased Heat Loads September 28, 2009.

Status of CEPC Detector magnet

IHEP participation in SIS300 production UNILAC SIS 18 SIS 100/300 HESR Super FRS NESR CR RESR Institute for High Energy Physics Protvino, Russia FAIR meeting.

Calorimeter Analysis Tasks, July 2014 Revision B January 22, 2015.

Design of electrostatic septum for slow extraction from J-PARC main ring 2005, March 2nd ICFA septa workshop 2005 Acc. Lab., KEK M. Tomizawa, Y. Arakaki,

SIS 100 main magnets G. Moritz, GSI Darmstadt (for E. Fischer, MT-20 4V07)) Cryogenic Expert Meeting, GSI, September 19/

Daniel Schoerling TE-MSC-MNC 1 Magnets Daniel Schoerling on behalf of WP 2.2 and WP 2.16 ELENA Project Review 14 th – 15 th October IT.

Ultra-Compact Electrical Machines for Wind Energy DE-FOA : Demo Machine C. L. Goodzeit and M. J. Ball May 1, 2014 Part 1: Design and Construction.

Topic 2. Development and Design of DC machines

LHC Phase II Collimator Compact jaw simulations New FLUKA => ANSYS mapping scheme New 136mm x 950mm jaw –60cm primary collimator –Helical cooling channel.

1 Numerical study of the thermal behavior of an Nb 3 Sn high field magnet in He II Slawomir PIETROWICZ, Bertrand BAUDOUY CEA Saclay Irfu, SACM Gif-sur-Yvette.

Jürgen Florenkowski GSI, Darmstadt Agenda Annual Report Meeting EU construction ( CNI ) contract "DIRAC-PHASE-1" for the FAIR project September 26, 2006.

Updated status of the PSB impedance model C. Zannini and G. Rumolo Thanks to: E. Benedetto, N. Biancacci, E. Métral, B. Mikulec, N. Mounet, T. Rijoff,

Liesbeth Vanherpe, Olivier Crettiez, Alexey Vorozhtsov, Thomas Zickler Quadrupole Electro-magnets for Linac4 at CERN ATS Seminar, CERN, July 11, 2013.

Summary of Winding Pack Thermal Results K. Freudenberg

Baby MIND coil modules assembly the aluminium folded strip solution 1 Alexey, Philippe, Gabriella, Helder, Herman Baby Mind Magnet CERN June.

Magnet design issues & concepts for the new injector P.Fabbricatore INFN-Genova Magnet design issues & concepts for the new injector P.Fabbricatore INFN-Genova,

SIS 300 Magnet Design Options. Cos n  magnets; cooling with supercritical Helium GSI 001 existing magnet built at BNG measured in our test facility 6.

Design of DC septum magnets based on measurements and 3D calculation of an R&D septum magnet for Rapid Cycle Synchrotron of J-PARC Masao Watanabe, Accelerator.

DCLL ½ port Test Blanket Module thermal-hydraulic analysis Presented by P. Calderoni March 3, 2004 UCLA.

ESS | A Preliminary Feasibility Assessment of Power Converters and Magnets for Beam Raster System| | Carlos A. Martins, ESS Preliminary Feasibility.

Cold test of SIS-300 dipole model Sergey Kozub Institute for High Energy Physics (IHEP), Protvino, Moscow region, Russia.

CONSTRUCTION  The dc machines used for industrial electric drives have three major parts. Field system Armature and Commutator. Field system  The field.

Status of work on the HOM coupler. 2 nd Harmonic cavity Meeting 11/II-2016 Thermal analyses with shims (Y.Terechkine). Gennady Romanov On behalf of Y.Terechkine.

Design of wide aperture/thin septa of extraction system for J-PARC-50GeV ring 1. The outline of septa system for 50GeVring 2. Designing of thin septa and.

XVII SuperB Workshop and Kick Off Meeting - La Biodola (Isola d'Elba) Italy May 28 th June 2 nd 2011 P.Fabbricatore Sezione di Genova The air core magnets.

CERN –GSI/CEA MM preparation meeting, Magnetic Measurements WP.

TUTORIAL 1 7/3/2016.

CERN Cryolab CO 2 cooling for pixel detectors Investigation of heat transfer Christopher Franke, Torsten Köttig, Jihao Wu, Friedrich Haug TE-CRG-CI.

Heat Transfer Su Yongkang School of Mechanical Engineering # 1 HEAT TRANSFER CHAPTER 9 Free Convection.

24 June 2013 GSI, Darmstadt Helmholtz Institut Mainz Bertalan Feher, PANDA EMP First Measurements for a Superconducting Shield for the PANDA Polarized.

Preliminary analysis of a 16 T sc dipole with cos-theta lay-out INFN team October 2015.

L-8 MAGNETIC CIRCUITS ELE 1001: Basic Electrical Technology

Yingshun Zhu Design of Small Aperture Quadrupole Magnet for HEPS-TF

Anti project. F. Raffaelli. INFN CERN, April 05 th, Thermal Analysis of the Anti transportation. -Calculation of the manhole loads due to the valve.

SIS 100 Vacuum chamber Recooler String system Components

Mechanical behavior of the EuroCirCol 16 T Block-type dipole magnet during a quench Junjie Zhao, Tiina Salmi, Antti stenvall, Clement Lorin 1.

Multitube Helicon Source with Permanent Magnets

Some Design Considerations and R &D of CEPCB Dipole Magnet

High Gradient Magnet Design for SPring-8 Upgrade Plan

Hansaba College of Engineering & Technology

RB and RQ shunted BusBar current carrying capacities

The design schemes of the low field dipole magnets

Characteristic Analysis and Experimental Verification for a Double-sided Permanent Magnet Linear Synchronous Generator According to Magnetization Array.

Development of the Canted Cosine Theta Superconducting Magnet

Little module (HeatLoadCalculator) available at:

Maxwell and Ansys simulations for the CAPP detector

I. Bogdanov, S. Kozub, V. Pokrovsky, L. Shirshov,

Magnetic gap calculation

Peter McIntyre Visit Overview Slides

CEPC Collider Magnets CHEN, Fusan November 13, 2018.

Analysis on Solenoidal High Temperature Superconducting Magnet using COMSOL MultiPhysics® Abhinav Kumar Department of Mechanical Engineering, Lovely Professional.

Chapter 32 Problems 6,7,9,16,29,30,31,37.

Presentation transcript:

FAIR MT/Cryogenics, Seong Yeub Shim Beam-Tube Eddy Loss S. Y. Shim

FAIR MT/Cryogenics, Seong Yeub Shim Table of contents Motivation Computation –Highlight data Summary

FAIR MT/Cryogenics, Seong Yeub Shim Motivation Early Studies –Simple analytical approach –2D analysis –3D analysis Analysis issues –Effect of cooling pipe & ribs –Temperature profile during magnet operation Improvements in this study –2D+3D analysis including cooling pipe and ribs –Extract eddy loss and temperature profile during the cycles up to 62 th –Check design criterion

FAIR MT/Cryogenics, Seong Yeub Shim Operation condition & Criterion Operation scenario –maximum : 1.9 T –minimum : T –Ramping rate : 4 T/sec –High field flat top duration : 0.1 sec –Low field flat bottom duration : 0.8 sec Temperature Criterion given by UHV group –In order to keep UHV  Highest Temperature < 15 K Lowest Temperature < 6 K  t  sec

FAIR MT/Cryogenics, Seong Yeub Shim Length of the Chamber : 2976 mm Wall thickness : 0.3 mm Aperture : 128 mm  58 mm Rib thickness : 3 mm Rib pitch : 20 mm Cooling tube diameter : 5 mm Cooling tube thickness : 0.5 mm Dimension

FAIR MT/Cryogenics, Seong Yeub Shim FE model 1.VC with Cooling pipe 2.Coils 3.Air (Vacuum region) 4.Iron 5.Far field elements Material parameter 1.c(T) 2.k(T) 3.M(H) for iron 4.  = 5.0   m 5.  r = 1 Eddy current, its loss and the temperature on Beam-Tube are calculated simultaneously. FE model

FAIR MT/Cryogenics, Seong Yeub Shim Magnet operation

FAIR MT/Cryogenics, Seong Yeub Shim Magnetic flux density during machine operation

FAIR MT/Cryogenics, Seong Yeub Shim Joule Heat Generation due to eddy current (position 1) The unit in this result is watt/m 3. The average power loss is 3.43 watt/m. The result without cooling pipe shows the loss of 2.37 watt/m.

FAIR MT/Cryogenics, Seong Yeub Shim Temperature profile with respect to the circumference of the VC

FAIR MT/Cryogenics, Seong Yeub Shim Temperature curve as a function of cycle (time)

FAIR MT/Cryogenics, Seong Yeub Shim Joule Heat Generation (position 2)

FAIR MT/Cryogenics, Seong Yeub Shim Change the cooling pipe position The cooling pipe is shifted to the side of the Beam-Tube, position 2. As we expected, the loss is increased ~ 22 % compared with original position, position 1.

FAIR MT/Cryogenics, Seong Yeub Shim Temperature profile

FAIR MT/Cryogenics, Seong Yeub Shim Criterion

FAIR MT/Cryogenics, Seong Yeub Shim Temperature profile

FAIR MT/Cryogenics, Seong Yeub Shim Joule Loss Distribution

FAIR MT/Cryogenics, Seong Yeub Shim Joule Loss Distribution

FAIR MT/Cryogenics, Seong Yeub Shim Summery of Eddy Loss Beam-Tube Cooling pipe Beam-Tube Cooling pipe ribs maximum loss14.37 watt24.12 watt25.95 watt average loss7.21 watt11.52 watt12.4 watt 72 % 60 % Number of SIS100 dipole : 108Total loss : 1340 watt It is 15 % of total dynamic heat load of the FAIR. In order to reduce the load, the electrical insulation between the cooling pipe and ribs/Beam-Tube is now considered and tested.