Details
| Original language | English |
|---|---|
| Article number | 113125 |
| Journal | Energy Conversion and Management |
| Volume | 221 |
| Early online date | 10 Jul 2020 |
| Publication status | Published - 1 Oct 2020 |
Abstract
Methane decomposition is a promising approach to reduce the carbon footprint of hydrogen production. Solid carbon is one of the products and can improve the economics as a valuable byproduct or it is to be stored. The morphology of the produced carbon affects not only its economic value, but thermodynamic properties as well. Thermodynamic properties of graphite are usually used for modelling and simulation tasks for methane decomposition. In this study, the impact of the produced carbon type on the decomposition of methane is analyzed. Based on experimental data from literature for e.g. amorphous carbon, carbides, carbon filaments and nanotubes, the equilibrium of the methane decomposition reaction in dependence of temperature and carbon type is evaluated. The highest equilibrium methane conversion is observed for multiwall carbon nanotubes and the lowest for coke as carbon product. If another carbon morphology than graphite occurs, the reaction enthalpy is, in average, increased by 17.6%. To evaluate the potential influence on a production process, a methane decomposition process based on an electrically heated moving bed reactor is simulated. The specific electrical energy input and the methane consumption is calculated in dependence of the main process parameters and the produced carbon type. In a base case simulation the specific electrical energy input is 1.13kWh/NmH23. About 60% of the electrical power is required for heating the reactor. The energy input is highly affected by the amount of recycled bed material, the effectiveness of heat transfer, the methane conversion and by the carbon type. In the simulated temperature range of between 800 and 1300 K, the specific electrical energy input for a produced carbon type that differs from graphite is in average increased by 14.2% and by 58% in maximum. Further research on thermodynamic properties of different carbon types and their relevance for different methane pyrolysis processes is required.
Keywords
- Carbon properties, Hydrogen production, Methane decomposition, Methane pyrolysis
ASJC Scopus subject areas
- Energy(all)
- Renewable Energy, Sustainability and the Environment
- Energy(all)
- Nuclear Energy and Engineering
- Energy(all)
- Fuel Technology
- Energy(all)
- Energy Engineering and Power Technology
Sustainable Development Goals
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In: Energy Conversion and Management, Vol. 221, 113125, 01.10.2020.
Research output: Contribution to journal › Article › Research › peer review
}
TY - JOUR
T1 - Hydrogen production by methane decomposition
T2 - Analysis of thermodynamic carbon properties and process evaluation
AU - Marquardt, T.
AU - Bode, A.
AU - Kabelac, S.
N1 - Funding Information: This research did not receive any specific grant from funding agencies in the public, commercial, or not-for-profit sectors.
PY - 2020/10/1
Y1 - 2020/10/1
N2 - Methane decomposition is a promising approach to reduce the carbon footprint of hydrogen production. Solid carbon is one of the products and can improve the economics as a valuable byproduct or it is to be stored. The morphology of the produced carbon affects not only its economic value, but thermodynamic properties as well. Thermodynamic properties of graphite are usually used for modelling and simulation tasks for methane decomposition. In this study, the impact of the produced carbon type on the decomposition of methane is analyzed. Based on experimental data from literature for e.g. amorphous carbon, carbides, carbon filaments and nanotubes, the equilibrium of the methane decomposition reaction in dependence of temperature and carbon type is evaluated. The highest equilibrium methane conversion is observed for multiwall carbon nanotubes and the lowest for coke as carbon product. If another carbon morphology than graphite occurs, the reaction enthalpy is, in average, increased by 17.6%. To evaluate the potential influence on a production process, a methane decomposition process based on an electrically heated moving bed reactor is simulated. The specific electrical energy input and the methane consumption is calculated in dependence of the main process parameters and the produced carbon type. In a base case simulation the specific electrical energy input is 1.13kWh/NmH23. About 60% of the electrical power is required for heating the reactor. The energy input is highly affected by the amount of recycled bed material, the effectiveness of heat transfer, the methane conversion and by the carbon type. In the simulated temperature range of between 800 and 1300 K, the specific electrical energy input for a produced carbon type that differs from graphite is in average increased by 14.2% and by 58% in maximum. Further research on thermodynamic properties of different carbon types and their relevance for different methane pyrolysis processes is required.
AB - Methane decomposition is a promising approach to reduce the carbon footprint of hydrogen production. Solid carbon is one of the products and can improve the economics as a valuable byproduct or it is to be stored. The morphology of the produced carbon affects not only its economic value, but thermodynamic properties as well. Thermodynamic properties of graphite are usually used for modelling and simulation tasks for methane decomposition. In this study, the impact of the produced carbon type on the decomposition of methane is analyzed. Based on experimental data from literature for e.g. amorphous carbon, carbides, carbon filaments and nanotubes, the equilibrium of the methane decomposition reaction in dependence of temperature and carbon type is evaluated. The highest equilibrium methane conversion is observed for multiwall carbon nanotubes and the lowest for coke as carbon product. If another carbon morphology than graphite occurs, the reaction enthalpy is, in average, increased by 17.6%. To evaluate the potential influence on a production process, a methane decomposition process based on an electrically heated moving bed reactor is simulated. The specific electrical energy input and the methane consumption is calculated in dependence of the main process parameters and the produced carbon type. In a base case simulation the specific electrical energy input is 1.13kWh/NmH23. About 60% of the electrical power is required for heating the reactor. The energy input is highly affected by the amount of recycled bed material, the effectiveness of heat transfer, the methane conversion and by the carbon type. In the simulated temperature range of between 800 and 1300 K, the specific electrical energy input for a produced carbon type that differs from graphite is in average increased by 14.2% and by 58% in maximum. Further research on thermodynamic properties of different carbon types and their relevance for different methane pyrolysis processes is required.
KW - Carbon properties
KW - Hydrogen production
KW - Methane decomposition
KW - Methane pyrolysis
UR - http://www.scopus.com/inward/record.url?scp=85087686598&partnerID=8YFLogxK
U2 - 10.1016/j.enconman.2020.113125
DO - 10.1016/j.enconman.2020.113125
M3 - Article
AN - SCOPUS:85087686598
VL - 221
JO - Energy Conversion and Management
JF - Energy Conversion and Management
SN - 0196-8904
M1 - 113125
ER -