Abstract
The inevitable nexus between energy use and CO2 emission necessitates the development of sustainable energy systems. The conversion of CO2 to CH4 using green H2 in power-to-gas applications in such energy systems has attracted much interest. In this context, the present study provides a thermodynamic insight into the effect of water removal on CO2 conversion and irreversibility within a CO2 methanation reactor. A fixed-bed reactor with one intermediate water removal point, representing two reactors in series, was modeled by a one-dimensional pseudo-homogeneous model. Pure CO2 or a mixture of CO2 and methane, representing a typical biogas mixture, were used as feed. For short reactors, both the maximum conversion and the largest irreversibilities were observed when the water removal point was located in the middle of the reactor. However, as the length of the reactor increased, the water removal point with the highest conversion was shifted towards the end of the reactor, accompanied by a smaller thermodynamic penalty. The largest irreversibilities in long reactors were obtained when water removal took place closer to the inlet of the reactor. The study discusses the potential benefit of partial water removal and reactant feeding for energy-efficient reactor design.
Highlights
IntroductionEnergy use, and CO2 emissions are associated with one another
Economic growth, energy use, and CO2 emissions are associated with one another.He et al [1] stated that rapid growth in the economy and energy use has caused an increase in CO2 emissions
The results indicate that the optimal point of water removal is at a higher relative length of z/L
Summary
Energy use, and CO2 emissions are associated with one another. He et al [1] stated that rapid growth in the economy and energy use has caused an increase in CO2 emissions. Pao and Tsai [2] investigated the economy-energy-sustainability nexus. They illustrated that the reduction of CO2 emission without negative effect on the economic growth could obtain by increasing energy efficiency. The intermittent nature of renewable energy sources entails a need to consider energy storage when renewable power generation does not match the demand [5]. Among possible energy storage technologies [5,6], Power-to-Gas (PtG) concepts provide the possibility of converting surplus renewable electricity to chemical energy through the production of energy carrier components such as hydrogen (H2 ), methane (CH4 ), and methanol (CH3 OH) [7]
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