کد مقاله | کد نشریه | سال انتشار | مقاله انگلیسی | نسخه تمام متن |
---|---|---|---|---|
688219 | 1460098 | 2014 | 11 صفحه PDF | دانلود رایگان |
![عکس صفحه اول مقاله: Methane dry reformer by application of chemical looping combustion via Mn-based oxygen carrier for heat supplying and carbon dioxide providing Methane dry reformer by application of chemical looping combustion via Mn-based oxygen carrier for heat supplying and carbon dioxide providing](/preview/png/688219.png)
• CLC has been utilized with assistance of H2 perm-selective membranes in DR process.
• The captured CO2 by CLC is used as feedstock for DR process.
• CH4 conversion and H2 yield reach to 73.46% and 1.459 in CLC-DRM respectively.
• 4562 kmol h−1 H2 is produced in DR side of CLC-DRM.
• H2 production is enhanced by increasing FR feed temperature of CLC-DR.
In this study, the production of H2 utilizing chemical looping combustion (CLC) in a methane dry reformer assisted by H2 perm-selective membranes in a CLC-DRM configuration has been investigated. CLC via employment of a Mn-based oxygen carrier generates large amounts of heat in addition to providing CO2 as the raw material for the dry reforming (DR) reaction. The main advantage of the CLC-DRM configuration is the simultaneous capturing and consuming of CO2 as a greenhouse gas for H2 production.A steady state one dimensional heterogeneous catalytic reaction model is applied to analyze the performance and applicability of the proposed CLC-DRM configuration. Simulation results show that CH4 is completely consumed in the fuel reactor (FR) of the CLC-DRM and pure CO2 is captured by condensation of H2O. Also, CH4 conversion and H2 yield reach 73.46% and 1.459 respectively at the outlet of the DR side in the CLC-DRM. Additionally, 4562 kmol h−1 H2 is produced in the DR side of the CLC-DRM.Finally, results indicate that by increasing the FR feed temperature up to 880 K, CH4 conversion and H2 production are enhanced to 81.15% and 4790 kmol h−1 respectively.
Journal: Chemical Engineering and Processing: Process Intensification - Volume 79, May 2014, Pages 69–79