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Geoscience Laser Altimeter System (GLAS) Instrument: Flight Loop Heat Pipe (LHP) Acceptance Thermal Vacuum TestTwo loop heat pipes (LHPs) are to be used for tight thermal control of the Geoscience Laser Altimeter System (GLAS) instrument, planned for flight in late 2001. The LHPs are charged with Propylene as a working fluid. One LHP will be used to transport 110 W from a laser to a radiator, the other will transport 160 W from electronic boxes to a separate radiator. The application includes a large amount of thermal mass in each LHP system and low initial startup powers. The initial design had some non-ideal flight design compromises, resulted in a less than ideal charge level for this design concept with a symmetrical secondary wick. This less than ideal charge was identified as the source of inadequate performance of the flight LHPs during the flight thermal vacuum test in October of 2000. We modified the compensation chamber design, re-built and charged the LHPs for a final LHP acceptance thermal vacuum test. This test performed March of 2001 was 100% successful. This is the last testing to be performed on the LHPs prior to instrument thermal vacuum test. This sensitivity to charge level was shown through varying the charge on a Development Model Loop Heat Pipe (DM LHP) and evaluating performance at various fill levels. At lower fills similar to the original charge in the flight units, the same poor performance was observed. When the flight units were re-designed and filled to the levels similar to the initial successful DM LHP test, the flight units also successfully fulfilled all requirements. This final flight Acceptance test assessed performance with respect to startup, low power operation, conductance, and control heater power, and steady state control. The results of the testing showed that both LHPs operated within specification. Startup on one of the LHPs was better than the other LHP because of the starter heater placement and a difference in evaporator design. These differences resulted in a variation in the achieved superheat prior to startup. The LHP with the lower superheat was sensitive to the thermal environment around the compensation chamber, while the LHP with the higher superheat (similar in design to DM LHP) was not. In response to the test results the placement of the starter heater will be optimized for the flight instrument testing for higher achieved superheat. This presentation discusses startup behavior, overall conductance of a radiator system, low power operation, high power operation, temperature control stability, and control heater power requirements as measured during this acceptance thermal vacuum test. A brief summary of 'lessons learned' will be included.
Document ID
20020014373
Acquisition Source
Goddard Space Flight Center
Document Type
Conference Paper
Authors
Baker, Charles
(Orbital Sciences Corp. Greenbelt, MD United States)
Butler, Dan
(NASA Goddard Space Flight Center Greenbelt, MD United States)
Ku, Jentung
(NASA Goddard Space Flight Center Greenbelt, MD United States)
Grob, Eric
(NASA Goddard Space Flight Center Greenbelt, MD United States)
Swanson, Ted
(NASA Goddard Space Flight Center Greenbelt, MD United States)
Nikitkin, Michael
(Dynatherm Corp. MD United States)
Powers, Edward I.
Date Acquired
August 20, 2013
Publication Date
January 1, 2001
Subject Category
Lasers And Masers
Meeting Information
Meeting: International Two-Phase Thermal Control Technology Workshop
Location: Los Angeles, CA
Country: United States
Start Date: June 7, 2001
End Date: June 8, 2001
Distribution Limits
Public
Copyright
Work of the US Gov. Public Use Permitted.

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