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Industrial and Engineering Chemistry Research
Volumn 52, Issue 41, 2013, Pages 14601-14612
Design and control of stand-alone hydrogen production systems with maximum waste heat recovery
Author keywords

[No Author keywords available]
Indexed keywords

AUTOTHERMAL REFORMING; DESIGN AND CONTROL; HYDROGEN PRODUCTION COSTS; HYDROGEN PRODUCTION SYSTEMS; OPTIMAL OPERATING CONDITIONS; SINGLE-INPUT SINGLE-OUTPUT; UNKNOWN DISTURBANCE; WASTE HEAT RECOVERY SYSTEMS;
EID: 84886030494     PISSN: 08885885     EISSN: 15205045     Source Type: Journal    
DOI: 10.1021/ie400937t     Document Type: Article
Times cited : (12)
References (21)
  • 1
    • 77951130710 scopus 로고    scopus 로고
    • Challenges for renewable hydrogen production from biomass
    • Levin, D. B.; Chahine, R. Challenges for renewable hydrogen production from biomass Int. J. Hydrogen Energy 2010, 357, 4962
    • (2010) Int. J. Hydrogen Energy , vol.357 , pp. 4962
    • Levin, D.B.1    Chahine, R.2
  • 4
    • 69349104589 scopus 로고    scopus 로고
    • Comparison of steam and autothermal reforming of methanol using a packed-bed low-cost copper catalyst
    • Tang, H.-Y.; Erickson, P.; Yoon, H. C.; Liao, C.-H. Comparison of steam and autothermal reforming of methanol using a packed-bed low-cost copper catalyst Int. J. Hydrogen Energy 2009, 34, 7656
    • (2009) Int. J. Hydrogen Energy , vol.34 , pp. 7656
    • Tang, H.-Y.1    Erickson, P.2    Yoon, H.C.3    Liao, C.-H.4
  • 6
    • 32544433894 scopus 로고    scopus 로고
    • 2 capture and storage. Part A: Review and selection of promising conversion and capture technologies
    • 2 capture and storage. Part A: Review and selection of promising conversion and capture technologies Prog. Energy Combust. Sci. 2006, 32, 215
    • (2006) Prog. Energy Combust. Sci. , vol.32 , pp. 215
    • Damen, K.1    Van Troost, M.2    Faaij, A.3    Turken, W.4
  • 7
    • 69349101029 scopus 로고    scopus 로고
    • A combined methanol autothermal steam reforming and PEM fuel cell pilot plant unit: Experimental and simulation studies
    • Ouzounidou, M.; Ipsakis, D.; Voutetakis, S.; Papadopoulou, S.; Seferlis, P. A combined methanol autothermal steam reforming and PEM fuel cell pilot plant unit: Experimental and simulation studies Energy 2009, 1, 733
    • (2009) Energy , vol.1 , pp. 733
    • Ouzounidou, M.1    Ipsakis, D.2    Voutetakis, S.3    Papadopoulou, S.4    Seferlis, P.5
  • 8
    • 15344346904 scopus 로고    scopus 로고
    • Kinetics, simulation and optimization of methanol steam reformer for fuel cell applications
    • Choi, Y.; Stenger, H. G. Kinetics, simulation and optimization of methanol steam reformer for fuel cell applications J. Power Sources 2005, 79, 81
    • (2005) J. Power Sources , vol.79 , pp. 81
    • Choi, Y.1    Stenger, H.G.2
  • 9
    • 33747195797 scopus 로고    scopus 로고
    • Exergy analysis and optimization of methanol generating hydrogen system for PEMFC
    • Wang, S.; Wang, S. Exergy analysis and optimization of methanol generating hydrogen system for PEMFC Int. J. Hydrogen Energy 2006, 31, 1747
    • (2006) Int. J. Hydrogen Energy , vol.31 , pp. 1747
    • Wang, S.1    Wang, S.2
  • 10
    • 33748975861 scopus 로고    scopus 로고
    • Dynamic modeling of a methanol reformer - PEMFC stack system for analysis and design
    • Stamps, A. T.; Gatzke, E. P. Dynamic modeling of a methanol reformer-PEMFC stack system for analysis and design J. Power Sources 2006, 161, 356
    • (2006) J. Power Sources , vol.161 , pp. 356
    • Stamps, A.T.1    Gatzke, E.P.2
  • 11
    • 81155126411 scopus 로고    scopus 로고
    • Adsorption enhanced steam reforming of methanol for hydrogen generation in conjunction with fuel cell: Process design and reactor dynamics
    • Li, M.; Duraiswamy, K.; Knobbe, M. Adsorption enhanced steam reforming of methanol for hydrogen generation in conjunction with fuel cell: Process design and reactor dynamics Chem. Eng. Sci. 2012, 67, 26
    • (2012) Chem. Eng. Sci. , vol.67 , pp. 26
    • Li, M.1    Duraiswamy, K.2    Knobbe, M.3
  • 12
    • 79952243533 scopus 로고    scopus 로고
    • Modeling and analysis of miniaturized methanol reformer for fuel cell powered mobile applications
    • Vadlamudi, V. K.; Palanki, S. Modeling and analysis of miniaturized methanol reformer for fuel cell powered mobile applications Int. J. Hydrogen Energy 2011, 36, 3364
    • (2011) Int. J. Hydrogen Energy , vol.36 , pp. 3364
    • Vadlamudi, V.K.1    Palanki, S.2
  • 13
    • 69449088407 scopus 로고    scopus 로고
    • Control of a heat-integrated proton exchange membrane fuel cell system with methanol reforming
    • Wu, W.; Pai, C.-C. Control of a heat-integrated proton exchange membrane fuel cell system with methanol reforming J. Power Sources 2009, 194, 920
    • (2009) J. Power Sources , vol.194 , pp. 920
    • Wu, W.1    Pai, C.-C.2
  • 14
    • 84856563004 scopus 로고    scopus 로고
    • A rigorous computational model for hydrogen production from bio-ethanol to feed a fuel cell stack
    • Nieto Degliuomini, L.; Biset, S.; Luppi, P.; Basualdo, M. S. A rigorous computational model for hydrogen production from bio-ethanol to feed a fuel cell stack Int. J. Hydrogen Energy 2012, 37, 3108
    • (2012) Int. J. Hydrogen Energy , vol.37 , pp. 3108
    • Nieto Degliuomini, L.1    Biset, S.2    Luppi, P.3    Basualdo, M.S.4
  • 16
    • 79952440259 scopus 로고    scopus 로고
    • Computational fluid dynamics simulation of ethanol steam reforming in catalytic wall microchannel
    • Uriza, I.; Arzamendi, G.; Lopez, E.; Llorca, J.; Gandia, L. M. Computational fluid dynamics simulation of ethanol steam reforming in catalytic wall microchannel Chem. Eng. J. 2011, 167, 603
    • (2011) Chem. Eng. J. , vol.167 , pp. 603
    • Uriza, I.1    Arzamendi, G.2    Lopez, E.3    Llorca, J.4    Gandia, L.M.5
  • 18
    • 0242694564 scopus 로고    scopus 로고
    • Water gas shift reaction kinetics and reactor modeling for fuel cell grade hydrogen
    • Choi, Y.; Stenger, H. G. Water gas shift reaction kinetics and reactor modeling for fuel cell grade hydrogen J. Power Sources 2003, 124, 432
    • (2003) J. Power Sources , vol.124 , pp. 432
    • Choi, Y.1    Stenger, H.G.2
  • 19
    • 84875747160 scopus 로고    scopus 로고
    • Hydrogen recovery from Tehran refinery off-gas using pressure swing adsorption, gas absorption and membrane separation technologies: Simulation and economic evaluation
    • Mivechian, A.; Pakizeh, M. Hydrogen recovery from Tehran refinery off-gas using pressure swing adsorption, gas absorption and membrane separation technologies: Simulation and economic evaluation Korean J. Chem. Eng. 2013, 30, 432
    • (2013) Korean J. Chem. Eng. , vol.30 , pp. 432
    • Mivechian, A.1    Pakizeh, M.2
  • 20
  • 21
    • 84885990173 scopus 로고    scopus 로고
    • http://www.icispricing.com/il-home.asp.

* 이 정보는 Elsevier사의 SCOPUS DB에서 KISTI가 분석하여 추출한 것입니다.