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Issue
Korean Journal of Chemical Engineering,
Vol.19, No.4, 658-662, 2002
Characteristics of LDPE Pyrolysis
Park JJ, Park K, Park JW, Kim DC
Pyrolysis of low-density polyethylene (LDPE) was studied in order to relieve environmental pollution and recover the monomer or fuel. LDPE was thermally decomposed with and without catalyst. First, efficiency of oil production was analyzed according to the variation of reaction conditions such as reaction temperature, types of additives and catalyst, and contacting method. In non-catalytic LDPE pyrolysis, isothermal reaction was almost similar to non-isothermal reaction. Light oil was produced with low reaction temperature (430 ℃) in the isothermal reaction, but low heating rate caused light oil production in the non-isothermal reaction. When pyrolyzed polyethylene (PE oil) was applied as an additive, no significant effect showed in the isothermal reaction. In catalytic LDPE pyrolysis (10%NiO/S-A) with additives, efficiency greatly increased especially with polystyrene (PS) addition. It was also found that the molecular weight distribution of product oil could be controlled by applying different additives. When a catalytic reactor was used, the amount of the low molecular weight compound increased as flow rate of thermally decomposed gas was lowered.
Keywords: Low Density Polyethylene (LDPE); Pyrolysis; Catalysts; Additives; Catalytic Reactor
[References]
  1. Bamford CH, Tipper CHF, Elsevier Sci. Pub. Co., 14, 44, 1975
  2. Bockhorn H, Hornung A, Hornung U, J. Anal. Appl. Pyrolysis, 46, 1, 1998
  3. Fouhy K, Kim I, Moore S, Culp E, Chem. Eng., 100(Dec.), 30, 1993
  4. Hirose T, Takai Y, Azuma N, Morioka Y, Ueno A, J. Mater. Res., 13(1), 77, 1998
  5. Ide S, Nanbu H, Kuroki T, Ikemura T, J. Anal. Appl. Pyrolysis, 6, 69, 1984
  6. Jeong SW, Kim JH, Seo G, Korean J. Chem. Eng., 18(6), 848, 2001
  7. Kim S, Korean J. Chem. Eng., 13(6), 559, 1996
  8. Kim YS, Hwang GC, Bae SY, Yi SC, Korean J. Chem. Eng., 16(2), 161, 1999
  9. KOREA PETROCHEMICAL HANDBOOK, KOREA PETROCHEMICAL INDUSTRY ASSOCIATION, 43, 2001
  10. Lee CH, Ministry Sci. Technol., 37, 2000
  11. Liebman SA, Levy EJ, "Pyrolysis and GC in Polymer Analysis," MARCEL DEKKER, INC., 156, 1985
  12. Rader CP, Baldwin SD, Cornell DD, Sadler GD, Stockel RF, ACS Symp. Ser., 609, 62, 1995
  13. Shelley S, Fouhy K, Moore S, Chem. Eng., 99(July), 30, 1992
  14. Song HS, Hyun JC, Korean J. Chem. Eng., 16(3), 316, 1999
  15. Songip AR, Masuda T, Kuwahara H, Hashimoto K, Appl. Catal. B: Environ., 2(2-3), 153, 1993
  16. Williams V, Preprint of Symposium of Waste Plastic Recycle, Tokyo, 21, 1993
[Cited By]
  1. Lee KH, Shin DH, Korean Journal of Chemical Engineering, 20(1), 89, 2003
  2. Lee KH, Jeon SG, Kim KH, Noh NS, Shin DH, Park J, Seo Y, Yee JJ, Kim GT, Korean Journal of Chemical Engineering, 20(4), 693, 2003
  3. Kim SH, Kim SS, Chun BH, Jeon JK, Korean Journal of Chemical Engineering, 22(4), 573, 2005
  4. Kwak TH, Lee S, Park JW, Maken S, Yoo YD, Lee SH, Korean Journal of Chemical Engineering, 23(6), 954, 2006
  5. Bak YC, Choi JH, Cho TH, Korean Chemical Engineering Research, 47(3), 303, 2009
  6. Lee KH, Oh SC, Korean Journal of Chemical Engineering, 27(1), 139, 2010
  7. Rotliwala YC, Parikh PA, Korean Journal of Chemical Engineering, 28(3), 788, 2011
  8. Lai J, Meng Y, Yan Y, Lester E, Wu T, Pang CH, Korean Journal of Chemical Engineering, 38(11), 2235, 2021
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