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Mucool Test Area Cryostat & cooling-loop design

Mucool Test Area Cryostat & cooling-loop design. Christine Darve Fermilab/Beams Division/ Cryogenic Department/ Engineering and Design Group MuCool / MICE 02/21/03. MuCool MICE. MuCool Test Area. Cryostat design. FERMILAB. BD/Cryogenic Department. Specifications.

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Mucool Test Area Cryostat & cooling-loop design

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  1. Mucool Test Area Cryostat & cooling-loop design Christine Darve Fermilab/Beams Division/ Cryogenic Department/ Engineering and Design Group MuCool / MICE 02/21/03

  2. MuCool MICE MuCool Test Area MuCool/MICE review

  3. Cryostat design MuCool/MICE review

  4. FERMILAB BD/Cryogenic Department Specifications The Linac beam will deposit within the absorber a maximum heat deposition of 150 Watt P= 1.2 atm, T= 17 K Dr < 5% DT~ 1 K (could be 3 K) Safety gudelines: “ Guidelines for the Design, Fabrication, Testing, Installation and Operation of LH2 Targets–20 May 1997”, Fermilab by Del Allspach et al. Fermilab ES&H (5032) code/standard ASME, NASA NEC (art 500) CGA MuCool/MICE review

  5. FERMILAB BD/Cryogenic Department Materials • Caltech LH2 pump • Max LH2 mass-flow = 450 g/s (0.12 MPa, Tin=17 K) • DP total < 0.36 psig References: • “A high power liquid hydrogen target for parity violation experiments”, E.J. Beise et al., Research instruments & methods in physics research (1996), 383-391” • “ MuCool LH2 pump test report”, C. Darve and B. Norris, (09/02) Lab-G magnet MuCool/MICE review

  6. FERMILAB BD/Cryogenic Department Conceptual Design MuCool/MICE review

  7. Legend: Heat transfer by conduction through supports Heat transfer by radiation and through MLI FERMILAB BD/Cryogenic Department Heat load calculations Magnet @ 300 K Cryostat vacuum vessel @ 300 K 1.5 W (39 W if no MLI) 67 W N2 Cryostat Thermal shield @ 80 K Cooling line 6 W 0.2 W 17 W Absorber @ 20 K Cryostat windows 0.3 W 48 W He General refrigeration system Safety factor =2 CD, 12/07/01 MuCool/MICE review

  8. FERMILAB BD/Cryogenic Department “Materials list” - Cryostat Design • LH2 Absorber • Vacuum vessel • Thermal shield • Hydrogen buffer • Vacuum window • Transfer lines • Safety devices • Heat exchanger • LH2 pump • Motor • Supports • Equipment The MTA cryostat is mainly composed of: Cryogens used: • LN2 to cool Thermal shield • Ghe to cool LH2 cryo-system • LH2 to cool cryo-system (beam+static) MuCool/MICE review

  9. FERMILAB BD/Cryogenic Department Assembly • Vacuum vessel: MAWP=25 psig; SS, 16 IPS Sch10, 48 IPS Sch10 • Dome (SS, 0.25 inch) • Plate (SS, 0.25 inch) • Central support (1 inch) • Thermal shield (Al) +MLI (Al, Mylar) • Aluminum braids • Aluminum cooling line • He, H2 and N2 Piping (SS, 1-2 inch IPS) • Hydrogen buffer(SS,f 3 inch) • Vacuum window Flange, Al, SS, Al seal • Vacuum pump flange • Relief vacuum MuCool/MICE review

  10. Pressure relief valve – LH2 : II C 4 a (iii) Relief pressure (10 psig or 25 psid) Sized for max. heat flux produced by air condensed on the LH2 loop at 1 atm. 2 valves ACGO => 0.502 inch2 ASME code Redundant Capacity = 52 g/s Pressure relief valve – Insulation vacuum : II D 3 MAWP (15 psig internal) Capable of limiting the internal pressure in vacuum vessel to less than 15 psig following the absorber rupture (deposition of 25 liter in the vacuum space) Vapor evaluation q= 20 W/cm2 Take into account DP connection piping and entrance/exit losses 3 parallel plates (FNAL design) => 2 inch Calculated Capacity = 197 g/s Redundant Relief system must be flow tested FERMILAB BD/Cryogenic Department Pressure safety devices MuCool/MICE review

  11. FERMILAB BD/Cryogenic Department MTA Cryostat Design • Heat exchanger assembly • Coil (copper, f 0.55 inch) • Outer shell (SS, 6 inch tube) • LH2 pump assembly • LH2 pump and shaft with foam • Motor outer shield • Absorber assembly: • Black/Wing windows and manifold design • Interface of the systems • Bimetallic junction • Indium Doubled-seal • Supports • G10 spider and rods MuCool/MICE review

  12. Equipment Pressure transducers Temperature sensors Flowmeter Heater Valves and actuators Vacuum pump cart Other instrumentation FERMILAB BD/Cryogenic Department MTA Cryostat Design • Safety constraints: • N2 guard • Low excitation current • Interlocks • Minimum spark energies for ignition of H2 in air is 0.017 mJ at 1 atm, 300 K • Lower pressure for ignition is ~1 psia (min abs. 0.02 psia // 1.4 mbar) MuCool/MICE review

  13. Cryo-pumping Position of cryostat vacuum windows Interfaces: atmosphere or vacuum behind cryostat vacuum windows Absorber Instrumentation routing and ports FERMILAB BD/Cryogenic Department Comments/questions MuCool/MICE review

  14. Cryostat 3D model current focuses: Change orientation of the heat exchanger Final LN2 cooling system Implementation of vacuum windows Heater implementation Supports Instrumentation implementation FERMILAB BD/Cryogenic Department MTA Cryostat design – Conclusions MuCool/MICE review

  15. As it looks today MuCool/MICE review

  16. Cooling-loop design (Introduction to Oxford analysis) MuCool/MICE review

  17. Manifold optimization of nozzle distribution and geometry The beam as a fluid sub-domain FERMILAB BD/Cryogenic Department Cooling-loop Design mass flow Velocity at nozzle Given geometry, Power and nozzle distribution DP Heat transfer coeff. DT Flow Simulation by Wing Lau/ Stephanie Yang (Oxford) • Simulate MTA manifold geometry • Simulate beam at 150 W (vol. deposition, ø10mm, 3 sigma gaussian) • Calculate heat transfer coefficients and temperature distribution for MTA conditions (DV ~ 0.5 m/s – 4 m/s) MuCool/MICE review

  18. m_dot=450 g/s 11 supply / 15 return nozzles Nozzle dia. = 0.6 inch FERMILAB BD/Cryogenic Department Pressure drop calculations Study of the thermo-hydraulic behavior in LH2 absorber w/ DT=1 K Will a velocity at the nozzle lower than 2 m/s be enough for ionization cooling (i.e. DT< 1K)? 5.3% 17.5% 13.2% Nozzle supply velocity = 3 m/s Maximum allowable DP = 0.364 psi Total DP calculated = 0.301 psi 5.3% 15.1% 38.3% MuCool/MICE review

  19. 11 supply nozzles 15 return nozzles Nozzle diameter: 0.43 inch Model A FERMILAB BD/Cryogenic Department Temperature distribution simulation By Wing Lau and Stephanie Yang (Oxford) MuCool/MICE review

  20. Model A V_sup = 2 m/s FERMILAB BD/Cryogenic Department Temperature distribution simulation By Wing Lau and Stephanie Yang (Oxford) DT< 1 K But … DP = 90 psi (DP adm.=76psi) MuCool/MICE review

  21. Model A V_sup = 0.5 m/s FERMILAB BD/Cryogenic Department Temperature distribution simulation By Wing Lau and Stephanie Yang (Oxford) DT< 1 K Model A Lower limit for the solution with m_dot = 38 g/s MuCool/MICE review

  22. 8 supply nozzles 12 return nozzles Nozzle diameter: 0.63 inch Model B FERMILAB BD/Cryogenic Department Temperature distribution simulation By Wing Lau and Stephanie Yang (Oxford) MuCool/MICE review

  23. Model B V_sup = 2 m/s FERMILAB BD/Cryogenic Department Temperature distribution simulation By Wing Lau and Stephanie Yang (Oxford) DT< 1 K But … DP = 0.101 psi (DP adm.=0.119 psi) MuCool/MICE review

  24. FERMILAB BD/Cryogenic Department MTA cooling loop system – Conclusions Cooling loop Focuses: The Model A proves that DT=1K is achieved if nozzle velocity is 0.5 m/s Therefore any configuration with at least 26 nozzles, larger then 0.43 inch diameter will meet our requirement. Model C will permit us to cross-check the current solution. Proposed Solution: 11 supply/15 return, Dia 0.6” MuCool/MICE review

  25. FERMILAB BD/Cryogenic Department Process Instrumentation Diagram MuCool/MICE review

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