• DocumentCode
    790279
  • Title

    Development of 400 V Solar Array Technology for Low Earth Orbit Plasma Environment

  • Author

    Hosoda, Satoshi ; Okumura, Teppei ; Kim, Jeong-Ho ; Toyoda, Kazuhiro ; Cho, Mengu

  • Author_Institution
    Dept. of Electr. Eng., Kyushu Inst. of Technol., Kitakyushu
  • Volume
    34
  • Issue
    5
  • fYear
    2006
  • Firstpage
    1986
  • Lastpage
    1996
  • Abstract
    To realize a 400 V operation in low Earth orbit (LEO), problems of arcing caused by interaction between spacecraft and surrounding LEO plasma must be overcome. This paper is a summary report of the laboratory tests carried out to develop a 400 V solar array technology. Among various designs tested, a design of covering a solar array surface with transparent film, called film coupon, was the most promising mitigation method to prevent arc inception. The authors carried out various tests on the film coupons considering a realistic situation encountered in orbit. The coupon biased to -400 V in LEO-like plasma had no arc for more than 25 h. Other tests involved UV exposure, atomic-oxygen exposure, thermal cycling, and debris impact. Conductive substrate made of carbon fiber reinforced plastic suffered many arcs at -400 V. Sustained arc between a solar cell and the substrate was also observed upon a simulated debris impact. Therefore, the use of flexible substrate is adequate for 400 V solar array in LEO environment. To avoid the snapover effect near the positive end of the array circuit, only the negative part of the array circuit exceeding the arc-inception threshold should be covered by film, or an electron collector should be deployed
  • Keywords
    arcs (electric); astrophysical plasma; carbon fibre reinforced plastics; solar cell arrays; spacecraft charging; 400 V; UV exposure; arc mitigation; arc-inception threshold; array circuit; atomic-oxygen exposure; carbon fiber reinforced plastic; conductive substrate; debris impact; electron collector; film coupon; low earth orbit plasma environment; snapover effect; solar array surface; solar array technology; solar cell; spacecraft charging; thermal cycling; transparent film; Circuit simulation; Electrons; Fiber reinforced plastics; Low earth orbit satellites; Photovoltaic cells; Plasma simulation; Space technology; Space vehicles; Substrates; Testing; Arc mitigation; high-voltage solar array; low Earth orbit (LEO); spacecraft charging;
  • fLanguage
    English
  • Journal_Title
    Plasma Science, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    0093-3813
  • Type

    jour

  • DOI
    10.1109/TPS.2006.883287
  • Filename
    1710074