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Ignition and Combustion Characteristics of Overloaded Wire Insulations Under Weakly Buoyancy or Microgravity Environments

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Physical Science Under Microgravity: Experiments on Board the SJ-10 Recoverable Satellite

Part of the book series: Research for Development ((REDE))

Abstract

The electric wire, cable and components are the potential igniters, which might cause fire under certain unexpected circumstances. This chapter focuses on the pre-ignition characteristics by overload, the soot emission from the wire insulation during the pre-ignition and ignition stages, the smoke release and distribution characteristics of wire insulation combustion. We reviewed the research work on wire insulations completed by the authors. We first presented the functional simulation methods. The concept of “function simulation” means that the simulation is satisfied in heat transfer sense. A low pressure narrow channel method (LPNCM) was proposed to study fire initiation of wire insulation at microgravity. Then we introduced the experiments completed in microgravity by using the China recoverable satellites of SJ-8 and SJ-10. The experimental hardware were developed to perform the experiments of wire insulation experiments caused by overload on board the SJ-8 and SJ-10 China recoverable satellites, respectively. In the experiments, the pre-fire characteristics including the temperature and radiation characteristics of the wire insulations were presented. For the SJ-10 experiments, the smoke emissions of overloaded wires insulations were investigated. Two smoke emitting modes, namely the end smoke jet and the bubbling smoke jet were identified with polyethylene insulation. The results show that the morphology of pyrolysis front dominated the direction and the range of the end smoke jet. The effects of the insulation thickness and the excess current on the temperature rise were discussed.

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References

  1. Robert F (1994) Risks and issues in fire safety on the space station, NASA TM-106430

    Google Scholar 

  2. Friedman R (1998) Fire safety in extraterrestrial environments. NASA TM-207417

    Google Scholar 

  3. Limero T, Wilson S, Perlot S, James J (1992) The role of environmental health system air quality monitors in space station contingency operations. SAE Trans 101:1521

    Google Scholar 

  4. Babrauskas V (2003) Information on specific materials and devices. In: Babrauskas V (ed) Ignition handbook: principles and applications to fire safety engineering, fire investigation, risk management and forensic science. Fire Science Publishers, Issaquah, pp 774–795

    Google Scholar 

  5. Greenberg PS, Sacksteder KR, Kashiwagi T (1994) Wire insulation flammability experiment: USML-1 1 Year post mission summary. NASA CP 3272 2, p 631

    Google Scholar 

  6. Thomas HC, Donald AP 1971 Burning of Teflon-insulated wires in supercritical oxygen at normal and zero gravities. NASA TM-2174

    Google Scholar 

  7. Greenberg PS, Sacksteder KR, Kashiwagi T (1995) Wire insulation flammability. NASA CP 10174, p 25

    Google Scholar 

  8. Kikuchi M, Fujita O, Ito K, Sato A, Sakuraya T (1998) Experimental study on flame spread over wire insulation in microgravity. Proc Combust Inst 27:2507

    Article  Google Scholar 

  9. Kikuchi M, Fujita O, Ito K, Sato A, Sakuraya T (2000) Flame spread over polymeric wire insulation in microgravity. Space Forum 6:245

    Google Scholar 

  10. Fujita O, Kikuchi M, Ito K, Nish K (2000) Effective mechanisms to determine flame spread rate over thylene-tetrafluoroethylene wire insulation: discussion on dilution gas effect based on temperature measurements. Proc Combust Inst 28:2905

    Article  Google Scholar 

  11. Fujita O, Nish K, Ito K (2002) Effect of low external flow on flame spread over polyethylene-insulated wire in microgravity. Proc Combust Inst 29:2545

    Article  Google Scholar 

  12. Umem A, Uchi M, Hira T (2002) Physical model analysis of flame spreading along an electrical wire in microgravity. Proc Combust Inst 29:2535–2543

    Article  Google Scholar 

  13. Kong WJ, Lao SQ, Zhang PY (2006) Study on wire insulation flammability at microgravity by functional simulation method. J Combust Sci Technol 12(1):1–4

    Google Scholar 

  14. Chen LF, Xin Z, Kong WJ (2006) Functional simulations of the fire precursor of the wire insulation in quiescent microgravity environment. Chin J Space Sci 26(3):235–240

    Google Scholar 

  15. Kong WJ, Wang BR, Law SQ (2007) Study on fire precursor of wire insulation in low-pressure environments. J Eng Thermophys 28(6):1047–1049

    ADS  Google Scholar 

  16. Kong WJ, Wang BR, Zhang WK (2008) Study on prefire phenomena of wire insulation in microgravity. Microgravity Sci Technol 20:107–113

    Article  ADS  Google Scholar 

  17. Nakamura Y, Yoshimura N, Matsumura T et al (2008) Flame spread over polymer-insulated wire in sub-atmospheric pressure: similarity to microgravity phenomena. Prog Scale Model, 17–27

    Google Scholar 

  18. Nakamura Y, Yoshimura N, Ito H et al (2009) Flame spread over electric wire in sub-atmospheric pressure. Proc Combust Inst 32:2559–2566

    Article  Google Scholar 

  19. Fujita O, Kyono T, Kido Y (2011) Ignition of wire insulation with short-term excess electric current in microgravity. Proc Combust Inst 33(2):2617–2623

    Article  Google Scholar 

  20. Takano Y, Fujita O, Shigeta N (2013) Ignition limits of short-term overloaded electric wires in microgravity. Proc Combust Inst 34(2):2665–2673

    Google Scholar 

  21. Takahashi S, Ito H, Nakamura Y, Fujita O (2013) Extinction limits of spreading flames over wires in microgravity. Combust Flame 160:1900–1902

    Article  Google Scholar 

  22. Takahashi S, Takeuchi H, Ito H, Nakamura Y, Fujita O (2013) Study on unsteady molten insulation volume change during flame spreading over wire insulation in microgravity. Proc Combust Inst 34(2):2657–2664

    Article  Google Scholar 

  23. Osorio AF, Mizutani K, Fernandez-Pello C, Fujita O (2015) Microgravity flammability limits of ETFE insulated wires exposed to external radiation. Proc Combust Inst 35:2683–2689

    Article  Google Scholar 

  24. Hu LH, Zhang YS, Yoshioka K et al (2015) Flame spread over electric wire with high thermal conductivity metal core at different inclinations. Proc Combust Inst 35(3):2607–2614

    Article  Google Scholar 

  25. Fujita O (2015) Solid combustion research in microgravity as a basis of fire safety in space. Proc Combust Inst 35(3):2487–2502

    Article  Google Scholar 

  26. Hu WR, Zhao JF, Long M, Zhang XW, Liu QS, Hou MY, Kang Q, Wang YR, Xu SH, Kong WJ, Zhang H, Wang SF, Sun YQ, Hang HY, Huang YP, Cai WM, Zhao Y, Dai JW, Zheng HQ, Duan EK, Wang JF (2014) Space program SJ-10 of microgravity research. Microgravity Sci Technol 26:159–169

    Article  ADS  Google Scholar 

  27. Xue S, Kong W (2019) Smoke emission and temperature characteristic of the long-term overloaded wire in space. J Fire Sci 37(2): 99–116

    Google Scholar 

  28. Xue S, Kong W (2018) Overload characteristic of typical electric wire insulation material in microgravity. In: Keynote lecture, 12th Asian microgravity symposium, Zhuhai, China, 12–16 November 2018

    Google Scholar 

  29. Ivanov AV, Balashov YV (1999) Experimental verification of material flammability in space. NASA/CR-1999-209405

    Google Scholar 

  30. Zik O, Olami Z, Moses E (1998) Fingering instability in combustion. Phys Rev Lett 81(18):3868–3871

    Article  ADS  Google Scholar 

  31. Zik O, Olami Z, Moses E (1998) Fingering instability in solid fuel combustion: the characteristic scales of the developed state. The Combustion Institute, pp 2815–2830

    Google Scholar 

  32. Wichman IS, Olson SL (2003) Flamelet formation in hele-shaw flow. NASA/CP-2003-212376/REV1, pp 29–31

    Google Scholar 

  33. Olson SL, Miller FJ, Jahangirian S, Wichman IS (2009) Flame spread over thin fuels in actual and simulated microgravity conditions. Combust Flame 2009:1214–1226

    Article  Google Scholar 

  34. Zhang X (2007) Simulation of flame spread over thin solid fuel under microgravity using narrow channel on ground. Chin J Theor Appl Mech 39(4):466–472

    Google Scholar 

  35. Zhang X (2008) Opposed-flow flame spread over a thin solid material in narrow channels in normal and microgravity. J Eng Thermophys 29(2):347–350

    Google Scholar 

  36. Zhang X, Yu Y (2008) Comparability of flame spread over thin solid fuel surface under different gravities. J Combust Sci Technol 14(4):289–294

    Google Scholar 

  37. Xiao Y, Hu J, Wang SF (2010) A narrow channel experimental study on flammability characteristics of thermally thin fuels under simulated microgravity conditions. J Astronaut 31(7):1877–1882

    Google Scholar 

  38. Wang K, Wang BR, Ai YH, Kong WJ (2012) Study on the pre-ignition characteristics of wire insulation in the narrow channel setup. Sci China Technol Sci 55:2132–2139

    Article  Google Scholar 

  39. Xiao Y, Ren T, Wang SF (2010) Flame spread over thermally thick fuels in narrow channel apparatus. J Eng Thermophys 31(8):1423–1426

    Google Scholar 

  40. Wang K, Ai YH, Wang BR, Kong WJ (2012) Study on pre-fire characteristics of wire insulation by overload in weakly buoyant environment. J Eng Thermophys 33(4):689–693

    Google Scholar 

  41. Wang K, Wang BR, Kong WJ, Liu FS (2014) Study on the pre-ignition temperature variations of wire insulation under overload conditions in microgravity by the functional simulation method. J Fire Sci 32(3):257–280

    Article  Google Scholar 

  42. Bergman TL, Lavine AS, Incropera FP (2011) Fundamentals of heat and mass transfer, 7th edn. Wiley, Jefferson City, USA

    Google Scholar 

  43. Gebhart B, Jaluria Y, Mahajan RL, Sammakia B (1988) Buoyancy-induced flows and transport. Hemisphere, Washington, DC

    Google Scholar 

  44. Hu WR, Tang BC (2017) Kang Q progress of microgravity experimental satellite SJ-10. Aeron Aero Open Access J 1(3):00016

    Google Scholar 

  45. Zhao HG, Qiu JW, Tang BC et al (2016) The SJ-10 recoverable microgravity satellite of China. J Space Explor 5(1):101

    Google Scholar 

  46. Wang Y, Zhao H, Zhang Y et al (2016) Establishing and evaluation of the microgravity level in the SJ-10 recoverable satellite. Aeros China 17(4):3–13

    Google Scholar 

  47. Kong WJ, Wang BR, Xia W (2016) Experimental facility for wire insulation combustion in SJ-10. Physics 45(4):219–224

    Google Scholar 

  48. Greenberg PS, Ku JC (1997) Soot volume fraction imaging. Appl Opt 36(22):5514–5522

    Article  ADS  Google Scholar 

  49. Iuliis SD, Barbini M, Benecchi S et al (1998) Determination of the soot volume fraction in an ethylene diffusion flame by multiwavelength analysis of soot radiation. Combust Flame 115(s1–2):253–261

    Google Scholar 

  50. Xia W, Wang K, Wang BR et al (2016) Study on combustion characteristics of overloaded wire insulation at the early stage of fire in weak buoyancy. J Eng Thermophys 37(4):876–882

    Google Scholar 

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Author information

Authors and Affiliations

  1. Institute of Engineering Thermophysics, Chinese Academy of Sciences, University of Chinese Academy of Sciences, Beijing, China

    Wenjun Kong, Kai Wang, Wei Xia & Shao Xue

  2. Beihang University, Beijing, China

    Wenjun Kong

  3. Commercial Aircraft Engine Co., Ltd., Aero Engine Corporation of China, Shanghai, China

    Kai Wang

Authors
  1. Wenjun Kong
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  2. Kai Wang
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  3. Wei Xia
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  4. Shao Xue
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Corresponding author

Correspondence to Wenjun Kong .

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Editors and Affiliations

  1. Chinese Academy of Sciences, Beijing, China

    Wenrui Hu

  2. Chinese Academy of Sciences, Beijing, China

    Qi Kang

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Kong, W., Wang, K., Xia, W., Xue, S. (2019). Ignition and Combustion Characteristics of Overloaded Wire Insulations Under Weakly Buoyancy or Microgravity Environments. In: Hu, W., Kang, Q. (eds) Physical Science Under Microgravity: Experiments on Board the SJ-10 Recoverable Satellite. Research for Development. Springer, Singapore. https://doi.org/10.1007/978-981-13-1340-0_9

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