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Review of Helium Venting Analyses

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Hazard to be addressed is release of asphyxiant gas into an occupied area. ... Mass flow out of the tank modeled as isentropic expansion through choked nozzle. ... – PowerPoint PPT presentation

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Title: Review of Helium Venting Analyses


1
Review of Helium Venting Analyses
  • Chris Tutt
  • AMS-02 Project Manager

2
Review of Hazard
  • Hazard to be addressed is release of asphyxiant
    gas into an occupied area.
  • Three major helium reservoirs within AMS-02
    payload and GSE.
  • 2500-liter main helium dewar inside the payload.
  • 1000-liter master dewar used for filling main
    dewar.
  • 1000-liter transfer dewar used for filling master
    dewar.
  • Venting analysis focused on main dewar as
    enveloping case, but results for all others are
    similar.

3
Main Helium Dewar
  • Main Helium Dewar has two major components
  • Helium Tank contains the cryogen itself
  • Vacuum Case provides vacuum space around the
    tank.
  • 3 bar burst disk on helium tank defines the
    Maximum Design Pressure for the system.
  • Nominal operating pressure is 16 mbar.
  • All hardware will be extensively tested prior to
    arrival at KSC.
  • Structural analysis shows high margins for MDP.
  • All welds will be inspected per MSFC-STD-504C.
  • Both items will be proof pressure tested.
  • Both items will be vacuum leak tested.

4
Main Helium Tank
5
Vacuum Case
6
GSE Dewars
7
Tank Overpressurization
  • Two mechanisms for overpressurization of tank.
  • Failure to remove nominal boil-off from tank.
  • Large external heat source increases boil-off
    beyond pumps capability to remove.
  • First scenario requires weeks to reach burst
    pressure, so does not present safety hazard.
  • Only possible heat source for second scenario is
    ambient atmosphere and requires air leak into the
    dewar vacuum space.

8
Cause of Leak
  • Two leak scenarios were considered in analysis
  • Loss of Vacuum (LOV) Total loss of vacuum
    caused by large breach of Vacuum Case. Requires
    major accident
  • Forklift tine breaks through VC outer cylinder
  • Payload dropped during lifting operations
  • Large hardware falls on payload from significant
    height.
  • Maximum Credible Leak (MCL) 3 leak through the
    double O-Ring seals in the VC upper and lower
    support rings.
  • Leak size defined by Payload Safety Review Panel
    and used for all payload bay leak analyses.
  • LOV can be prevented operationally, so following
    discussion will focus on MCL.

9
VC O-Ring Seals
10
  • Each sealing surface has double O-ring seals.
  • In MCL, both seals are assumed to have failed in
    the same location.

OUTER CYLINDER
11
MCL Defined Leak Size
12
Venting Analysis Overview
  • Venting Analysis consists of three basic steps
  • Calculation of time required for tank to reach 3
    bar burst pressure after leak begins.
  • Calculation of mass rate of flow of helium
    leaving the main tank.
  • Calculation of oxygen levels in surrounding
    external space.
  • Only the third step is location dependent.

13
Time to Burst
  • Pre-burst pressure rise modeled as isochoric
    heating.
  • Heat flux from MCL calculated to be 655.5 W.
  • Helium thermodynamic properties from NIST
    handbook.
  • Results driven by initial temperature and fill
    level.
  • Calculated times range from 54 min (1.9K, 95
    full) to 86 min (1.7K, 80 full).

14
Typical Pressure Rise Profile
15
Time to Empty Tank
  • Mass flow out of the tank modeled as isentropic
    expansion through choked nozzle.
  • Results driven entirely by fill level.
  • The more helium in the tank, the longer it takes
    to empty.
  • Below 90 full, helium becomes two-phase prior to
    reaching 1 atm.
  • Calculated times range from 131 min after burst
    (80 full) to 239 min (95 full).

16
Typical Mass Flow Profile
17
Exterior Volume
  • Analysis done for four KSC spaces
  • Space Shuttle Processing Facility
  • Canister Rotation Facility
  • Canister
  • Payload Changeout Room
  • Results driven by three factors
  • Volume of external space
  • Air refreshment rate
  • Gas diffusion model

18
Original Gas Diffusion Assumption
  • Original discussions assumed that helium vapor
    would rise to the ceiling of external volume.

19
Current Gas Diffusion Assumption
  • At GOWG in November, GSRP requested analysis be
    redone assuming gas spreads evenly throughout the
    room.
  • Model used GSFC algorithm provided by SHOOT team.
  • Based on helium sensors measurements from
    Tevatron accident at Fermilab.
  • Venting memo describes results using second
    assumption.

20
GSFC Algorithm
Incoming Air
Ventilation Exhaust
Incoming Helium
  • Helium enters control volume at R m3/s.
  • Ambient air removed by ventilation system at Q
    m3/s.

21
Oxygen Concentration Levels in PCR
22
Oxygen Concentration Levels in Canister
23
Oxygen Concentration Levels in SSPF
24
Oxygen Concentration Levels in CRF
25
Overall Trends
  • PCR falls briefly below 19.5, but high
    ventilation rate allows rapid return to safe
    levels.
  • Canisters small volume can be rapidly
    overwhelmed, but is not normally a manned volume
    when door is shut.
  • SSPF/CRF volumes are large enough and ventilation
    rates are fast enough that oxygen level never
    falls below 19.5.

26
Proposed Safety Controls
  • GSE should be monitored for signs of temperature
    or pressure rise while AMS-02 is in manned area.
  • If leak observed, personnel should be removed
    from vulnerable areas.
  • Entire PCR
  • Elevated structures within SSPF and CRF
  • Oxygen sensors should be used to determine safety
    of atmosphere prior to reentering any area after
    venting event or opening Canister in the PCR.
  • Additonal vent lines and building modifications
    should not be necessary.
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