화학공학소재연구정보센터
로그인 로그아웃 연락처 사이트맵
Korean Journal of Chemical Engineering, Vol.36, No.12, 2133-2142, December, 2019
DOI10.1007/s11814-019-0397-5  Export Citation
Poly(phenylene sulfide)-graphite composites for bipolar plates with preferred morphological orientation
Ho-Joon Park, Jong Seok Woo1, and Soo-Young Park
  • Department of Polymer Science & Engineering, Polymeric Nanomaterials Laboratory, School of Applied Chemical Engineering, Kyungpook National University, 80 Daehak-ro, Buk-gu, Daegu 41566, Korea
  • 1Advanced Center of Engineering, Morgan Advanced Materials, 23, Dalseong2cha 4-ro, Guji-myeon, Dalseong-gun, Daegu 43013, Korea
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Bipolar plates in phosphoric acid fuel cells require inertness to phosphoric acid as well as excellent electrical, thermal, and mechanical properties. For this application, we prepared poly(phenylene sulfide) (PPS)-graphite composites with random or ordered graphite orientations by compression and extrusion-compression processes, respectively. Due to current limitations of extruding graphite-filled polymers, only moderately high graphite concentrations were used (up to 40wt%). The compressed composites contained graphite sheets in a planar orientation (parallel to the pressing direction) and exhibited highly anisotropic electrical and thermal conductivity, with much higher in-plane than through-plane components. In contrast, composites that were extruded prior to compression exhibited randomly oriented graphite due to shearing forces during extrusion and therefore displayed isotropic properties. Thus, their throughplane electrical and thermal conductivity was superior to those of the ordered composite, while the in-plane properties were inferior. Notably, the internal graphitic structure affected the electrical conductivity more than the thermal conductivity. The randomly oriented composite also exhibited superior flexural strength, although the thermal stability of the two composites was almost equal. This study offers insights into the structure-property relationship of PPS-graphite composites as well as the effect of the orientation of conductive two-dimensional fillers on anisotropic properties.
Keywords:Poly(phenylene sulfide);Graphite;Extrusion;Compression;Anisotropy
  1. Lee SH, Kakati N, Maiti J, Jee SH, Kalita DJ, Yoon YS, Thin Solid Films, 529, 374 (2013)
  2. Sun H, Cooke K, Eitzinger G, Hamilton P, Pollet B, Thin Solid Films, 528, 199 (2013)
  3. Cunningham BD, Baird DG, J. Power Sources, 168(2), 418 (2007)
  4. Dhakate SR, Mathur RB, Kakati BK, Dhami TL, Int. J. Hydrog. Energy, 32(17), 4537 (2007)
  5. Pachauri RK, Chauhan YK, Int. J. Elec. Power, 74, 49 (2016)
  6. Gao C, Zhang S, Lin Y, Li F, Guan S, Jiang Z, Compos. Part B-Eng., 79, 124 (2015)
  7. Ma H, Chu B, Hsiao BS, Eur. Polym. J., 87, 398 (2017)
  8. Jung H, Yu S, Bae NS, Cho SM, Kim RH, Cho SH, et al., ACS Appl. Mater. Interfaces, 7, 15256 (2015)
  9. Lee MH, Kim HY, Oh SM, Kim BC, Bang D, Han JT, Woo JS, Int. J. Hydrog. Energy, 43(48), 21918 (2018)
  10. Kim NH, Kuila T, Kim KM, Nahm SH, Lee JH, Polym. Test, 31, 537 (2012)
  11. Park M, Park JH, Yang BJ, Cho J, Kim SY, Jung I, Compos. Pt. A-Appl. Sci. Manuf., 109, 124 (2018)
  12. Khandelwal M, Mench MM, J. Power Sources, 161(2), 1106 (2006)
  13. Suherman H, Sulong AB, Sahari J, Ceram. Int., 39, 1277 (2013)
  14. Choi H, Woo JS, Han JT, Park SY, Nanotechnology, 28, 465706 (2017)
  15. Ajayan PM, Stephan O, Colliex C, Trauth D, Science, 265(5176), 1212 (1994)
  16. Gubler U, Raunhardt M, Stump A, Thin Solid Films, 515(4), 1737 (2006)
  17. Bauhofer W, Kovacs JZ, Compos. Sci. Technol., 69, 1486 (2009)
  18. Karsli NG, Yesil S, Aytac A, Compos. Part B-Eng., 63, 154 (2014)
  19. Russello M, Diamanti EK, Catalanotti G, Ohlsson F, Hawkins SC, Falzon BG, Compos. Struct., 206, 272 (2018)
  20. Zakaria MY, Sulong AB, Sahari J, Suherman H, Compos. Part B-Eng., 83, 75 (2015)
  21. Zhang R, Dowden A, Deng H, Baxendale M, Peijs T, Compos. Sci. Technol., 69, 1499 (2009)
  22. Ghasemi R, Elmquist L, Wear, 320, 120 (2014)
  23. Potschke P, Fornes TD, Paul DR, Polymer, 43(11), 3247 (2002)
  24. Thostenson ET, Chou TW, J. Phys. D-Appl. Phys., 35, L77 (2002)
  25. Derieth T, Bandlamudi G, Beckhaus P, Kreuz C, Mahlendorf F, Heinzel A, J. New Mater. Electrochem. Syst., 11, 21 (2008)
  26. Mathur RB, Dhakate SR, Gupta DK, Dhami TL, Aggarwal RK, J. Mater. Process. Technol., 203, 184 (2008)
  27. Guo JX, Liu YJ, Prada-Silvy R, Tan YQ, Azad S, Krause B, Potschke P, Grady BP, J. Polym. Sci. B: Polym. Phys., 52(1), 73 (2014)
  28. Xing J, Ni QQ, Deng B, Liu Q, Compos. Sci. Technol., 134, 184 (2016)
  29. Ameli A, Jung PU, Park CB, Compos. Sci. Technol., 76, 37 (2013)
  30. Jia Y, He H, Geng Y, Huang B, Peng X, Compos. Sci. Technol., 145, 55 (2017)
  31. Karimi M, Ghajar R, Montazeri A, Compos. Struct., 201, 528 (2018)
  32. Ding P, Zhang J, Song N, Tang S, Liu Y, Shi L, Compos. Sci. Technol., 109, 25 (2015)
  33. Antunes RA, de Oliveira MCL, Ett G, Ett V, J. Power Sources, 196(6), 2945 (2011)
  34. San FGB, Tekin G, Int. J. Energy Res., 37(4), 283 (2013)
  35. Xiao M, Lu Y, Wang SJ, Zhao YF, Meng YZ, J. Power Sources, 160(1), 165 (2006)
  36. Lee HS, Kim HJ, Kim SG, Ahn SH, J. Mater. Process. Technol., 187, 425 (2007)
  37. Dweiri R, Sahari J, J. Power Sources, 171(2), 424 (2007)