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Craig S. ClarkAMS-02 Phase II Safety Review1 AMS-02 Thermal Control System (TCS)
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Craig S. ClarkAMS-02 Phase II Safety Review2 AMS-02 Thermal Overview AMS-02 delivered to ISS in orbiter payload bay Mounted on S3, inboard, zenith Payload Attach Site Payload nominally dissipates 2400 watts (2800 watts peak) Will meet all ISS and STS safety requirements Thermal requirements are defined in SSP 57003 (Attached Payload Interface Requirements Document) Thermal Design Goals Maintain all experiment components and sub-detectors within specified operating and survival limits (document in AMS-02 Thermal ICD) Maximize Super Fluid Helium (SFHe) endurance Optimize sub-detector temperatures to maximize science
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Craig S. ClarkAMS-02 Phase II Safety Review3 AMS-02 TCS Hardware Radiators Heaters Thermal Blankets Loop Heat Pipes (LHPs) Standard Axial Groove Heat Pipes 2-Phase CO 2 pumped loop Surface Optical Coatings
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Craig S. ClarkAMS-02 Phase II Safety Review4 Radiators AMS-02 radiators include Main Radiators (Ram and Wake), Tracker Radiators (Ram and Wake), and Zenith Cryocooler Radiators. Main Radiator Wake Main Radiator Ram Wake
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Craig S. ClarkAMS-02 Phase II Safety Review5 Main Radiators Main Radiators dissipate heat from electronics crates. Ram radiator dissipates up to 525 watts during normal operation, while the Wake Radiator dissipates up to 812 watts.
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Craig S. ClarkAMS-02 Phase II Safety Review6 Main Radiators Mounting Main Radiators are mounted to directly to the crates, which in turn are attached to the USS-02 Lower Brackets (4) Upper Brackets (4) Mid Bracket (4)
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Craig S. ClarkAMS-02 Phase II Safety Review7 Main Radiator Construction Radiators are a sandwich construction with Al face sheets and a ROHACELL® core. Axial groove heat pipes (aluminum filled with ammonia) are imbedded between face sheets. Heat pipe flanges maximize thermal contact at crates mounting locations Chotherm 1671 is used as a thermal interface filler between crates and radiators. Radiators are painted with SG121FD white paint to optimize heat rejection.
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Craig S. ClarkAMS-02 Phase II Safety Review8 AMS-02 Main Radiator Cross-section (flange removed)
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Craig S. ClarkAMS-02 Phase II Safety Review9 AMS-02 Main Radiator Heat Pipe Layout RamWake
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Craig S. ClarkAMS-02 Phase II Safety Review10 Tracker Radiators Ram and Wake Tracker Radiators are designed to reject the total heat generated inside the Tracker (144W). Heat is transported by the Tracker Thermal Control System (TTCS) which will be discussed latter.
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Craig S. ClarkAMS-02 Phase II Safety Review11 Tracker Radiators Tracker Radiator (2 x 1.225 m 2 )
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Craig S. ClarkAMS-02 Phase II Safety Review12 Tracker Radiator Construction Tracker Radiators are a sandwich construction with Al face sheets and a ROHACELL® core. Heat pipes (aluminum filled with ammonia) are imbedded between face sheets. TTCS Condensers bolt directly to heat pipe flanges (40mm wide at interface locations, but only 22mm elsewhere). Chotherm 1671 is used as a thermal interface filler between condensers and radiators. Outer surface is painted with SG121FD white paint to optimize heat rejection.
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Craig S. ClarkAMS-02 Phase II Safety Review13 Tracker Radiator Cross-Section (non-interface section)
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Craig S. ClarkAMS-02 Phase II Safety Review14 TTCS Condenser Mounting Interface
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Craig S. ClarkAMS-02 Phase II Safety Review15 Tracker Radiator Heat Pipe Layout
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Craig S. ClarkAMS-02 Phase II Safety Review16 CARBON FIBER SUPPORT STRUTS TTCS CO 2 CONDENSERS (old design) EMBEDDED HEAT PIPE RADIATOR PANEL
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Craig S. ClarkAMS-02 Phase II Safety Review17 Zenith Radiator The Zenith Radiator (4 separate panels) is design to reject the waste heat generated by the Cryocoolers (60- 160W each). Heat is transported to each radiator panel via 2 Loop Heat Pipes (LHPs) attached to a single cryocooler. The LHPs utilize propylene as a working fluid which flows directly through aluminum tubes embedded in the Radiator. Aluminum tubes in the radiator transition to stainless steel tubes running to the evaporator via a bi-metallic joint.
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Craig S. ClarkAMS-02 Phase II Safety Review18 Zenith Radiator Panels
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Craig S. ClarkAMS-02 Phase II Safety Review19 Zenith Radiator Construction Radiators are a sandwich construction with Al face sheets and a ROHACELL® core. 3mm aluminum tubes are brazed to upper face sheet. Radiator panels are mounted to top of TRD Upper Honeycomb Panel via brackets and glass-fiber pins. Outer surface is coated with silver-Teflon. Multi-layer Insulation (MLI) is used between Radiator and TRD.
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Craig S. ClarkAMS-02 Phase II Safety Review20 Zenith Radiator Cross-Section Radiator Mounting Radiator Cross-section
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Craig S. ClarkAMS-02 Phase II Safety Review21 Multi-Layer Insulation (MLI) Blankets
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Craig S. ClarkAMS-02 Phase II Safety Review22 Multi-Layer Insulation (MLI) Blankets Numerous components of AMS-02 will be covered with MLI blankets All blankets will meet NASA standards for grounding and venting, and will be constructed according to “MLI for AMS Guidelines” (CTSD- SH-1782) All blankets will be positively secured. Typical construction will include multiple layers of aluminized Mylar separated by Dacron scrim. Betacloth will protect exposed surfaces.
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Craig S. ClarkAMS-02 Phase II Safety Review23 MLI for AMS Guidelines Written by Crew and Thermal Systems Division (CTSD-SH-1782, September 30, 2005) Based on requirements from ISS, STS and MSFC Electrical Bonding and Grounding All blankets with surface area greater than 100cm 2 will have at least two (2) grounding assemblies. Resistance from aluminized surface to ground shall be less than (<) 5,000 Ohms Resistance from ground to spacecraft structure shall be less than (<) 1 Ohm
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Craig S. ClarkAMS-02 Phase II Safety Review24 Heaters Heaters on AMS-02 are primarily used to: Warm up components to “switch on” temperature after power outages (including initial turn-on). Maintain components above minimum operating limits during operation. Thaw CO 2 (TTCS system) and NH 3 (heat pipes) in case of extended power outages in cold environments. Manage TTCS operation
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Craig S. ClarkAMS-02 Phase II Safety Review25 Heaters (continued) Most heaters are both thermostatically and computer controlled. Analyses have been performed to evaluate effect of “run away” heaters. All safety critical heaters are two-fault tolerant. No heaters are required to control any hazards.
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Craig S. ClarkAMS-02 Phase II Safety Review26 Heat Pipes Standard axial groove heat pipes are used in several location to help distribute heat: Main and Tracker radiators have embedded heat pipes mounted directly to heat sources. Heat pipes are mounted to one of the USS-02 joints to help dissipate heat from the CAB during magnet charging. Heat pipes are used on the CAB base plates to minimize gradients. All heat pipes are aluminum filled with high purity ammonia. Heat pipes are designed to survive freezing/thawing cycles without excessive pressure or rupture.
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Craig S. ClarkAMS-02 Phase II Safety Review27 Thermal Optical Coatings Passive thermal design of AMS-02 include the use of thermal optical coatings. MLI blankets or plain Betacloth covers are used to improve optics of some surfaces. Main and Tracker radiators are painted with SG121FD white paint to improve heat rejection. The Zenith Radiator, along with parts of the Vacuum Case, USS-02, High Voltage Bricks, and CAB are covered with silver-Teflon film to reduce peak temperatures.
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Craig S. ClarkAMS-02 Phase II Safety Review28 Cryocooler Cooling Each of the 4 Cryocoolers dissipate up to 160W of heat in order to remove 4 – 10W of heat from the Cryomagnet system. Loop Heat Pipes (2 per Cryocooler) are used to transport this heat to the Zenith Radiator where it is rejected via radiation. The Loop Heat Pipes (LHPs), provided by IberEspacio/Madrid, are similar to those successfully demonstrated as part of COM2PLEX flown on STS-107. Propylene is used as a working fluid to avoid any freezing. Freezing point of propylene is -185C.
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Craig S. ClarkAMS-02 Phase II Safety Review29 Loop Heat Pipe System for 1 Cryocooler Radiator panel Fluid Lines Redundant Evaporators
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Craig S. ClarkAMS-02 Phase II Safety Review30 LHP Configuration Each LHP has a vapor line running to the Zenith Radiator and a liquid line returning. Lines in and out of the evaporator are stainless steel tube. These tubes transition to aluminum tubes at the edge of the Zenith Radiator via a bi-metallic joint. “Pumping” pressure is achieved via capillary action in the LHP wick (nickel).
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Craig S. ClarkAMS-02 Phase II Safety Review31 LHP Schematic
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Craig S. ClarkAMS-02 Phase II Safety Review32 Crycooler to LHP Interface Cryocooler LHP Evaporators bolt to either side of the Cryocooler heat reject collar. Indium foil is used as a thermal interface. Evaporator
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Craig S. ClarkAMS-02 Phase II Safety Review33 LHP Heaters Heaters are mounted to the evaporators for LHP startup and to keep Cryocoolers above their minimum storage limits.
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Craig S. ClarkAMS-02 Phase II Safety Review34 LHP Bypass Valve A bypass valve is used to keep Cryocoolers from getting too cold in power outage situations. A bellows system filled with Argon is used to set the temperature set point of the valve.
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Craig S. ClarkAMS-02 Phase II Safety Review35 LHP Bypass Valve Schematic (Argon)
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Craig S. ClarkAMS-02 Phase II Safety Review36 CAB Thermal System The Cryomagnet Avionics Box (CAB) is used to monitor and control the Cryomagnet. Heat dissipation can vary from 35W to 800W. Two Loop Heat Pipes (LHPs) will transport heat from the CAB base plate to the outer skin of the Wake Radiator. Final design details are under review.
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Craig S. ClarkAMS-02 Phase II Safety Review37 CAB Thermal System LHP are similar to Cryocooler LHPs, except that ammonia, rather than propylene will be used as the working fluid. A bypass valve on the LHP will be used to bypass the radiator if CAB temperature approach lower limits.
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Craig S. ClarkAMS-02 Phase II Safety Review38 CAB Thermal System CAB
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Craig S. ClarkAMS-02 Phase II Safety Review39 CAB Thermal System Additional axial groove heat pipes will be attached on the USS between the Upper Trunnion Bridge Beam and the Upper Vacuum Case Interface Joint.
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Craig S. ClarkAMS-02 Phase II Safety Review40 TRD Thermal Design The TRD must be isothermal to +/-3ºC The TRD and Upper Time Of Flight (UTOF) are enclosed in a common thermal enclosure made of MLI blankets. The Zenith Radiator is mounted on top of the TRD using low conductivity pins. Primary TRD interfaces to USS-02 joints are insulated with titanium spacers.
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Craig S. ClarkAMS-02 Phase II Safety Review41 TRD Thermal Design Zenith Radiator TRD UTOF
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Craig S. ClarkAMS-02 Phase II Safety Review42 TRD Thermal Design The MLI blanket enclosure is made of 7- layer MLI, except for the portion under the Zenith radiator which is 10-layer. Heaters are mounted on the TRD M- structure to help minimize gradients and to maintain the detector components (flipper valves) within operating limits.
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Craig S. ClarkAMS-02 Phase II Safety Review43 TRD MLI M-structure
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Craig S. ClarkAMS-02 Phase II Safety Review44 TRD Gas Thermal Design The TRD Gas system consists of two parts; the Supply (Box S) and the Circulation (Box C). Box S includes a high pressure Xenon tank, a high pressure CO 2 tank, a mixing tank, pre- heater volumes, valves, pressure sensors, and associated tubing all mounted on an aluminum base plate. Box C includes two pumps, monitoring tubes and valves. Both Box S and Box C are enclosed in an MLI blanket.
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Craig S. ClarkAMS-02 Phase II Safety Review45 TRD Gas Thermal Design Xe Tank CO 2 Tank Circulation Box (Box C) Valve blocks
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Craig S. ClarkAMS-02 Phase II Safety Review46 TRD Gas Tank Heaters Active heating is required to keep both the Xenon and CO 2 tanks above their respective saturation temperatures. This is required in order to measure the amount of gas left in the tanks. Extremely long time constants preclude short term heating only. The Xenon tank should stay above 20ºC The CO 2 tank should stay above 34ºC
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Craig S. ClarkAMS-02 Phase II Safety Review47 TRD Gas Tank Heaters Kapton foil heaters are glued to the surface of the composite over-wrapped stainless steel tanks. On each tank there are two strings of eight heater patches (one per power feed). Four thermostats in series are used for each string to protect against over heating the tanks. Each tank is wrapped with MLI.
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Craig S. ClarkAMS-02 Phase II Safety Review48 TRD Gas Tank Heaters heaters thermostats
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Craig S. ClarkAMS-02 Phase II Safety Review49 TRD Gas Pre-Heaters A Pre-heater is used to warm small volumes of Xenon and CO 2 making transfer to the mixing tank more controlled. Heater is computer controlled using temperature sensors on heater plate. Heater will only be activated for brief periods (<15 minutes per day) 4 thermostats in series protects against over heating.
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Craig S. ClarkAMS-02 Phase II Safety Review50 TRD Gas Valve Blocks The are 5 groups of valves in Box S mounted together with support brackets. Brackets are isolated from the base plate with G10 spacers. Each block of valves is individually wrapped with MLI. Resistive heaters are mounted on each valve support bracket to maintain valves above operating limits. A single thermostat is used to control each valve block heater (Except for the tower valve which has 4 in series) Two additional thermostats in series are mounted on the base plate to control power to all valve heaters.
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Craig S. ClarkAMS-02 Phase II Safety Review51 TRD Gas Box C Box C pumps the low pressure gas mixture from Box S to the TRD detector. The two pumps are enclosed in a pressurized canister. Kapton foil heaters are mounted on this canister to maintain the pumps above their operating limits. Resistive heaters are mounted on a block of valves to maintain valve temperature limits.
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Craig S. ClarkAMS-02 Phase II Safety Review52 TRD Gas Box C
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Craig S. ClarkAMS-02 Phase II Safety Review53 TRD Gas Box C Both the canister heater and the valve block heater are each controlled with a single thermostat. The two additional thermostats on the base plate cut heater power in hot environments.
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Craig S. ClarkAMS-02 Phase II Safety Review54 TRD Gas 28V Heater Schematic A c c c c c c c c Xe vessel <20W T Xe vessel <20W T CO2 vessel <24W T CO2 vessel <24W T Preheater <15W <10W T Valve Tower <10W tower<10W T Preheater <15W <<<10W<10W T Valve Tower <10W tower<10W T B A B c c c c c c c c UPDATE
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Craig S. ClarkAMS-02 Phase II Safety Review55 TRD Gas 120V Heater Schematic 4 valve unit 11W T 2 valvefilter 7W T 2 Valve GP50 5W C-tank 10W T 4C-valves 4W T 4 valve unit 11W T 2 valvefilter 7W T 2 Valve GP50 5W T C-tank 10W T 4C-valves 4W T ABAB ABAB T UPDATE
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Craig S. ClarkAMS-02 Phase II Safety Review56 Thermal Design of other AMS-02 Subsystems Extensive work has also been performed on the thermal design of other AMS-02 Detectors and subsystems not described here Designs include MLI, thermal fillers, thermal optical coatings, etc. None of these designs affect any pressure systems or other safety critical components.
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