A Two-Dimensional Multiphysics Coupling Model of a Middle and Low Temperature Solar Receiver/Reactor for Methanol Decomposition
Abstract: In this paper, the endothermic methanol decomposition reaction is used to obtain syngas by transforming middle and low temperature solar energy into chemical energy. A two-dimensional multiphysics coupling model of a middle and low temperature of 150~300 °C solar receiver/reactor was devel...
Main Authors: | , , , , |
---|---|
Format: | Article |
Language: | English |
Published: |
MDPI AG
2017-10-01
|
Series: | Energies |
Subjects: | |
Online Access: | https://www.mdpi.com/1996-1073/10/11/1705 |
_version_ | 1811307154763677696 |
---|---|
author | Yanjuan Wang Qibin Liu Jing Lei Jiwei Li Can Chen |
author_facet | Yanjuan Wang Qibin Liu Jing Lei Jiwei Li Can Chen |
author_sort | Yanjuan Wang |
collection | DOAJ |
description | Abstract: In this paper, the endothermic methanol decomposition reaction is used to obtain syngas by transforming middle and low temperature solar energy into chemical energy. A two-dimensional multiphysics coupling model of a middle and low temperature of 150~300 °C solar receiver/reactor was developed, which couples momentum equation in porous catalyst bed, the governing mass conservation with chemical reaction, and energy conservation incorporating conduction/convection/radiation heat transfer. The complex thermochemical conversion process of the middle and low temperature solar receiver/reactor (MLTSRR) system was analyzed. The numerical finite element method (FEM) model was validated by comparing it with the experimental data and a good agreement was obtained, revealing that the numerical FEM model is reliable. The characteristics of chemical reaction, coupled heat transfer, the components of reaction products, and the temperature fields in the receiver/reactor were also revealed and discussed. The effects of the annulus vacuum space and the glass tube on the performance of the solar receiver/reactor were further studied. It was revealed that when the direct normal irradiation increases from 200 W/m2 to 800 W/m2, the theoretical efficiency of solar energy transformed into chemical energy can reach 0.14–0.75. When the methanol feeding rate is 13 kg/h, the solar flux increases from 500 W/m2 to 1000 W/m2, methanol conversion can fall by 6.8–8.9% with air in the annulus, and methanol conversion can decrease by 21.8–28.9% when the glass is removed from the receiver/reactor. |
first_indexed | 2024-04-13T08:59:35Z |
format | Article |
id | doaj.art-12ea1aa1210b4e26a85eb3f69cd5e22a |
institution | Directory Open Access Journal |
issn | 1996-1073 |
language | English |
last_indexed | 2024-04-13T08:59:35Z |
publishDate | 2017-10-01 |
publisher | MDPI AG |
record_format | Article |
series | Energies |
spelling | doaj.art-12ea1aa1210b4e26a85eb3f69cd5e22a2022-12-22T02:53:11ZengMDPI AGEnergies1996-10732017-10-011011170510.3390/en10111705en10111705A Two-Dimensional Multiphysics Coupling Model of a Middle and Low Temperature Solar Receiver/Reactor for Methanol DecompositionYanjuan Wang0Qibin Liu1Jing Lei2Jiwei Li3Can Chen4School of Energy, Power and Mechanical Engineering, North China Electric Power University, Changping District, Beijing 102206, ChinaInstitute of Engineering Thermophysics, Chinese Academy of Sciences, Beijing 100190, ChinaSchool of Energy, Power and Mechanical Engineering, North China Electric Power University, Changping District, Beijing 102206, ChinaSchool of Energy, Power and Mechanical Engineering, North China Electric Power University, Changping District, Beijing 102206, ChinaState Grid Information & Telecommunication Branch, Beijing 100761, ChinaAbstract: In this paper, the endothermic methanol decomposition reaction is used to obtain syngas by transforming middle and low temperature solar energy into chemical energy. A two-dimensional multiphysics coupling model of a middle and low temperature of 150~300 °C solar receiver/reactor was developed, which couples momentum equation in porous catalyst bed, the governing mass conservation with chemical reaction, and energy conservation incorporating conduction/convection/radiation heat transfer. The complex thermochemical conversion process of the middle and low temperature solar receiver/reactor (MLTSRR) system was analyzed. The numerical finite element method (FEM) model was validated by comparing it with the experimental data and a good agreement was obtained, revealing that the numerical FEM model is reliable. The characteristics of chemical reaction, coupled heat transfer, the components of reaction products, and the temperature fields in the receiver/reactor were also revealed and discussed. The effects of the annulus vacuum space and the glass tube on the performance of the solar receiver/reactor were further studied. It was revealed that when the direct normal irradiation increases from 200 W/m2 to 800 W/m2, the theoretical efficiency of solar energy transformed into chemical energy can reach 0.14–0.75. When the methanol feeding rate is 13 kg/h, the solar flux increases from 500 W/m2 to 1000 W/m2, methanol conversion can fall by 6.8–8.9% with air in the annulus, and methanol conversion can decrease by 21.8–28.9% when the glass is removed from the receiver/reactor.https://www.mdpi.com/1996-1073/10/11/1705solar receiver/reactormethanol decompositionmiddle and low temperature thermochemical processes |
spellingShingle | Yanjuan Wang Qibin Liu Jing Lei Jiwei Li Can Chen A Two-Dimensional Multiphysics Coupling Model of a Middle and Low Temperature Solar Receiver/Reactor for Methanol Decomposition Energies solar receiver/reactor methanol decomposition middle and low temperature thermochemical processes |
title | A Two-Dimensional Multiphysics Coupling Model of a Middle and Low Temperature Solar Receiver/Reactor for Methanol Decomposition |
title_full | A Two-Dimensional Multiphysics Coupling Model of a Middle and Low Temperature Solar Receiver/Reactor for Methanol Decomposition |
title_fullStr | A Two-Dimensional Multiphysics Coupling Model of a Middle and Low Temperature Solar Receiver/Reactor for Methanol Decomposition |
title_full_unstemmed | A Two-Dimensional Multiphysics Coupling Model of a Middle and Low Temperature Solar Receiver/Reactor for Methanol Decomposition |
title_short | A Two-Dimensional Multiphysics Coupling Model of a Middle and Low Temperature Solar Receiver/Reactor for Methanol Decomposition |
title_sort | two dimensional multiphysics coupling model of a middle and low temperature solar receiver reactor for methanol decomposition |
topic | solar receiver/reactor methanol decomposition middle and low temperature thermochemical processes |
url | https://www.mdpi.com/1996-1073/10/11/1705 |
work_keys_str_mv | AT yanjuanwang atwodimensionalmultiphysicscouplingmodelofamiddleandlowtemperaturesolarreceiverreactorformethanoldecomposition AT qibinliu atwodimensionalmultiphysicscouplingmodelofamiddleandlowtemperaturesolarreceiverreactorformethanoldecomposition AT jinglei atwodimensionalmultiphysicscouplingmodelofamiddleandlowtemperaturesolarreceiverreactorformethanoldecomposition AT jiweili atwodimensionalmultiphysicscouplingmodelofamiddleandlowtemperaturesolarreceiverreactorformethanoldecomposition AT canchen atwodimensionalmultiphysicscouplingmodelofamiddleandlowtemperaturesolarreceiverreactorformethanoldecomposition AT yanjuanwang twodimensionalmultiphysicscouplingmodelofamiddleandlowtemperaturesolarreceiverreactorformethanoldecomposition AT qibinliu twodimensionalmultiphysicscouplingmodelofamiddleandlowtemperaturesolarreceiverreactorformethanoldecomposition AT jinglei twodimensionalmultiphysicscouplingmodelofamiddleandlowtemperaturesolarreceiverreactorformethanoldecomposition AT jiweili twodimensionalmultiphysicscouplingmodelofamiddleandlowtemperaturesolarreceiverreactorformethanoldecomposition AT canchen twodimensionalmultiphysicscouplingmodelofamiddleandlowtemperaturesolarreceiverreactorformethanoldecomposition |