Thermodynamic Analysis of Hydrogen Production from Methanol-Ethanol-Glycerol Mixture through Dry Reforming

Thermodynamic Analysis of Hydrogen Production from Methanol-Ethanol-Glycerol Mixture through Dry Reforming

Thermodynamic properties of methanol-ethanol-glycerol dry reforming have been studied with the method of Gibbs free energy minimisation for hydrogen production from methanol-ethanol-glycerol mixture. Equilibrium compositions were determined as a function of CO2/methanol-ethanol-glycerol molar ratios...

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Main Authors: N.N. Saimon, M. Jusoh, M.J. Kamaruddin, A. Arsad, Z.Y. Zakaria
Format: Article
Language:English
Published: AIDIC Servizi S.r.l. 2017-03-01
Series:Chemical Engineering Transactions
Online Access:https://www.cetjournal.it/index.php/cet/article/view/1573
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spelling doaj-741a8e9ed4224d9099d42c44255c8d5a2021-02-18T21:11:09ZengAIDIC Servizi S.r.l.Chemical Engineering Transactions2283-92162017-03-015610.3303/CET1756162Thermodynamic Analysis of Hydrogen Production from Methanol-Ethanol-Glycerol Mixture through Dry ReformingN.N. SaimonM. JusohM.J. KamaruddinA. ArsadZ.Y. ZakariaThermodynamic properties of methanol-ethanol-glycerol dry reforming have been studied with the method of Gibbs free energy minimisation for hydrogen production from methanol-ethanol-glycerol mixture. Equilibrium compositions were determined as a function of CO2/methanol-ethanol-glycerol molar ratios (CMEG) (1 : 6 – 6 :1) where methanol-ethanol-glycerol is 1 : 1 : 1; reforming temperatures (573 – 1,273 K) at atmospheric pressure (unless stated otherwise). Optimum conditions for hydrogen production are CMEG 1 : 6, temperature 1,273 K, 1 bar pressure. This point is also optimum for the production of synthesis gas. Comparison of the moles of hydrogen produced from methanol-ethanol-glycerol mixture versus ethanol-glycerol mixture was made and exhibit paradoxical effects. Higher pressure and higher CMEG ratio does not encourage hydrogen formation. Under identified optimum conditions, carbon formation can be thermodynamically inhibited. The carbon yield can be reduced through reforming at higher temperatures.https://www.cetjournal.it/index.php/cet/article/view/1573
collection DOAJ
language English
format Article
sources DOAJ
author N.N. Saimon
M. Jusoh
M.J. Kamaruddin
A. Arsad
Z.Y. Zakaria
spellingShingle N.N. Saimon
M. Jusoh
M.J. Kamaruddin
A. Arsad
Z.Y. Zakaria
Thermodynamic Analysis of Hydrogen Production from Methanol-Ethanol-Glycerol Mixture through Dry Reforming
Chemical Engineering Transactions
author_facet N.N. Saimon
M. Jusoh
M.J. Kamaruddin
A. Arsad
Z.Y. Zakaria
author_sort N.N. Saimon
title Thermodynamic Analysis of Hydrogen Production from Methanol-Ethanol-Glycerol Mixture through Dry Reforming
title_short Thermodynamic Analysis of Hydrogen Production from Methanol-Ethanol-Glycerol Mixture through Dry Reforming
title_full Thermodynamic Analysis of Hydrogen Production from Methanol-Ethanol-Glycerol Mixture through Dry Reforming
title_fullStr Thermodynamic Analysis of Hydrogen Production from Methanol-Ethanol-Glycerol Mixture through Dry Reforming
title_full_unstemmed Thermodynamic Analysis of Hydrogen Production from Methanol-Ethanol-Glycerol Mixture through Dry Reforming
title_sort thermodynamic analysis of hydrogen production from methanol-ethanol-glycerol mixture through dry reforming
publisher AIDIC Servizi S.r.l.
series Chemical Engineering Transactions
issn 2283-9216
publishDate 2017-03-01
description Thermodynamic properties of methanol-ethanol-glycerol dry reforming have been studied with the method of Gibbs free energy minimisation for hydrogen production from methanol-ethanol-glycerol mixture. Equilibrium compositions were determined as a function of CO2/methanol-ethanol-glycerol molar ratios (CMEG) (1 : 6 – 6 :1) where methanol-ethanol-glycerol is 1 : 1 : 1; reforming temperatures (573 – 1,273 K) at atmospheric pressure (unless stated otherwise). Optimum conditions for hydrogen production are CMEG 1 : 6, temperature 1,273 K, 1 bar pressure. This point is also optimum for the production of synthesis gas. Comparison of the moles of hydrogen produced from methanol-ethanol-glycerol mixture versus ethanol-glycerol mixture was made and exhibit paradoxical effects. Higher pressure and higher CMEG ratio does not encourage hydrogen formation. Under identified optimum conditions, carbon formation can be thermodynamically inhibited. The carbon yield can be reduced through reforming at higher temperatures.
url https://www.cetjournal.it/index.php/cet/article/view/1573
work_keys_str_mv AT nnsaimon thermodynamicanalysisofhydrogenproductionfrommethanolethanolglycerolmixturethroughdryreforming
AT mjusoh thermodynamicanalysisofhydrogenproductionfrommethanolethanolglycerolmixturethroughdryreforming
AT mjkamaruddin thermodynamicanalysisofhydrogenproductionfrommethanolethanolglycerolmixturethroughdryreforming
AT aarsad thermodynamicanalysisofhydrogenproductionfrommethanolethanolglycerolmixturethroughdryreforming
AT zyzakaria thermodynamicanalysisofhydrogenproductionfrommethanolethanolglycerolmixturethroughdryreforming
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