Electrochemical reforming of glycerol into hydrogen in a batch-stirred electrochemical tank reactor equipped with stainless steel electrodes: Parametric optimization, total operating cost, and life cycle assessment. Issue 4 (August 2022)
- Record Type:
- Journal Article
- Title:
- Electrochemical reforming of glycerol into hydrogen in a batch-stirred electrochemical tank reactor equipped with stainless steel electrodes: Parametric optimization, total operating cost, and life cycle assessment. Issue 4 (August 2022)
- Main Title:
- Electrochemical reforming of glycerol into hydrogen in a batch-stirred electrochemical tank reactor equipped with stainless steel electrodes: Parametric optimization, total operating cost, and life cycle assessment
- Authors:
- Peralta-Reyes, Ever
Vizarretea-Vásquez, Diego
Natividad, Reyna
Aizpuru, Aitor
Robles-Gómez, Edson
Alanis, Claudia
Regalado-Méndez, Alejandro - Abstract:
- Abstract: The electrochemical reforming of glycerol was carried out in a batch-stirred electrochemical tank reactor equipped with stainless steel electrodes. A response surface methodology constituted by a Face-Centered Central Composite Design was performed to establish the optimal operational conditions to produce hydrogen. Studied parameters were glycerol concentration ( C G ), current intensity ( I ) and temperature ( T ), while chosen responses were hydrogen and oxygen concentrations ( C H 2 and C O 2 ). A maximum C H 2 (79.18 mg/L) and minimum C O 2 (46.24 mg/L) with a global desirability of 67%, were achieved at multi-optimal conditions, including C G, = 3.46 mol/L, I = 5.21 A, and T = 70 °C. All studied parameters were significant for both chosen responses ( η C H 2 and η C O 2 ) since all values of the sensitivity index were higher than 0.5. The analysis of interaction between parameters suggests than C G and T simultaneous increase will bring a decrease in C H2 . The experimental data were fitted to a quadratic polynomial surrogate model, with correlation coefficients of 0.9801 and 0.9967 for η C H 2 and η C O 2, respectively. The reduced root-mean-square error was 0.065 and 0.054 for η C H 2 and η C O 2, respectively. This suggests a successful optimization of the BSETR operational parameters. The hydrogen production process assessed in this work, is a promising green energy technology that uses waste glycerol as a carbon-based fuel and a low-cost anode materialAbstract: The electrochemical reforming of glycerol was carried out in a batch-stirred electrochemical tank reactor equipped with stainless steel electrodes. A response surface methodology constituted by a Face-Centered Central Composite Design was performed to establish the optimal operational conditions to produce hydrogen. Studied parameters were glycerol concentration ( C G ), current intensity ( I ) and temperature ( T ), while chosen responses were hydrogen and oxygen concentrations ( C H 2 and C O 2 ). A maximum C H 2 (79.18 mg/L) and minimum C O 2 (46.24 mg/L) with a global desirability of 67%, were achieved at multi-optimal conditions, including C G, = 3.46 mol/L, I = 5.21 A, and T = 70 °C. All studied parameters were significant for both chosen responses ( η C H 2 and η C O 2 ) since all values of the sensitivity index were higher than 0.5. The analysis of interaction between parameters suggests than C G and T simultaneous increase will bring a decrease in C H2 . The experimental data were fitted to a quadratic polynomial surrogate model, with correlation coefficients of 0.9801 and 0.9967 for η C H 2 and η C O 2, respectively. The reduced root-mean-square error was 0.065 and 0.054 for η C H 2 and η C O 2, respectively. This suggests a successful optimization of the BSETR operational parameters. The hydrogen production process assessed in this work, is a promising green energy technology that uses waste glycerol as a carbon-based fuel and a low-cost anode material (7.5 USD¢/kg H2 ) as stainless steel. The carbon footprint of the hydrogen production by the optimized process is 0.192 kg CO2 eq and this can be reduced 92.1% when using a solar photovoltaic system to energize the electrodes. Graphical Abstract: ga1 Highlights: Glycerol electrochemical reforming was successfully conducted in a BSRTR achieving a 13.29% of glycerol conversion at 80 min. Optimal operating variables of glycerol electrochemical reforming are C G = 3.46 mol/L, I = 5.21 A, T = 70 °C, and t = 80 min. Green hydrogen production cost by glycerol electrochemical reforming process is 2.74 USD$/kg H2 . Carbon footprint of the optimized hydrogen production by glycerol electrochemical reforming (0.192 kg CO2, eq ) was determined by LCA. Carbon footprint of the studied process can be reduced 92.1% if solar PV energy is used. … (more)
- Is Part Of:
- Journal of environmental chemical engineering. Volume 10:Issue 4(2022)
- Journal:
- Journal of environmental chemical engineering
- Issue:
- Volume 10:Issue 4(2022)
- Issue Display:
- Volume 10, Issue 4 (2022)
- Year:
- 2022
- Volume:
- 10
- Issue:
- 4
- Issue Sort Value:
- 2022-0010-0004-0000
- Page Start:
- Page End:
- Publication Date:
- 2022-08
- Subjects:
- Biodiesel -- Electrochemical reforming -- Hydrogen -- Life cycle assessment -- Parametric optimization -- Waste glycerol
Chemical engineering -- Environmental aspects -- Periodicals
Environmental engineering -- Periodicals
Chemical engineering -- Environmental aspects
Environmental engineering
Periodicals
660.0286 - Journal URLs:
- http://www.sciencedirect.com/science/journal/22133437 ↗
http://www.elsevier.com/journals ↗ - DOI:
- 10.1016/j.jece.2022.108108 ↗
- Languages:
- English
- ISSNs:
- 2213-2929
- Deposit Type:
- Legaldeposit
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- Available online (eLD content is only available in our Reading Rooms) ↗
- Physical Locations:
- British Library DSC - BLDSS-3PM
British Library HMNTS - ELD Digital store - Ingest File:
- 22534.xml