TY - JOUR
T1 - Thermodynamic assessment of a solar-driven integrated membrane reactor for ethanol steam reforming
AU - Wang, Hongsheng
AU - Wang, Bingzheng
AU - Lundin, Sean Thomas B.
AU - Kong, Hui
AU - Su, Bosheng
AU - Wang, Jian
N1 - Publisher Copyright:
© 2021 by the authors. Licensee MDPI, Basel, Switzerland.
PY - 2021/11/1
Y1 - 2021/11/1
N2 - To efficiently convert and utilize intermittent solar energy, a novel solar-driven ethanol steam reforming (ESR) system integrated with a membrane reactor is proposed. It has the potential to convert low-grade solar thermal energy into high energy level chemical energy. Driven by chemical potential, hydrogen permeation membranes (HPM) can separate the generated hydrogen and shift the ESR equilibrium forward to increase conversion and thermodynamic efficiency. The thermodynamic and environmental performances are analyzed via numerical simulation under a reaction temperature range of 100–400◦ C with permeate pressures of 0.01–0.75 bar. The highest theoretical conversion rate is 98.3% at 100◦ C and 0.01 bar, while the highest first-law efficiency, solar-to-fuel efficiency, and exergy efficiency are 82.3%, 45.3%, and 70.4% at 215◦ C and 0.20 bar. The standard coal saving rate (SCSR) and carbon dioxide reduction rate (CDRR) are maximums of 101 g·m−2·h−1 and 247 g·m−2·h−1 at 200◦ C and 0.20 bar with a hydrogen generation rate of 22.4 mol·m−2·h−1. This study illustrates the feasibility of solar-driven ESR integrated with a membrane reactor and distinguishes a novel approach for distributed hydrogen generation and solar energy utilization and upgradation.
AB - To efficiently convert and utilize intermittent solar energy, a novel solar-driven ethanol steam reforming (ESR) system integrated with a membrane reactor is proposed. It has the potential to convert low-grade solar thermal energy into high energy level chemical energy. Driven by chemical potential, hydrogen permeation membranes (HPM) can separate the generated hydrogen and shift the ESR equilibrium forward to increase conversion and thermodynamic efficiency. The thermodynamic and environmental performances are analyzed via numerical simulation under a reaction temperature range of 100–400◦ C with permeate pressures of 0.01–0.75 bar. The highest theoretical conversion rate is 98.3% at 100◦ C and 0.01 bar, while the highest first-law efficiency, solar-to-fuel efficiency, and exergy efficiency are 82.3%, 45.3%, and 70.4% at 215◦ C and 0.20 bar. The standard coal saving rate (SCSR) and carbon dioxide reduction rate (CDRR) are maximums of 101 g·m−2·h−1 and 247 g·m−2·h−1 at 200◦ C and 0.20 bar with a hydrogen generation rate of 22.4 mol·m−2·h−1. This study illustrates the feasibility of solar-driven ESR integrated with a membrane reactor and distinguishes a novel approach for distributed hydrogen generation and solar energy utilization and upgradation.
KW - Ethanol steam reforming (ESR)
KW - Hydrogen generation
KW - Hydrogen permeation membrane (HPM)
KW - Mid/low-temperature solar energy
KW - Solar thermochemistry
KW - Thermodynamic efficiency
UR - http://www.scopus.com/inward/record.url?scp=85119923955&partnerID=8YFLogxK
U2 - 10.3390/molecules26226921
DO - 10.3390/molecules26226921
M3 - Article
C2 - 34834013
AN - SCOPUS:85119923955
SN - 1420-3049
VL - 26
JO - Molecules
JF - Molecules
IS - 22
M1 - 6921
ER -