Journal
CHEMICAL ENGINEERING SCIENCE
Volume 255, Issue -, Pages -Publisher
PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.ces.2022.117646
Keywords
MTP; Thermal Coupling; Naphtha Reforming; Aromatics Production; Propylene; Modeling
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This paper presents the thermal coupling of the naphtha reforming process with the methanol to propylene (MTP) process. The integration of these processes allows the utilization of excess heat from the MTP process to meet the heat requirements of the naphtha reforming process, resulting in the elimination of intermediate heaters and increased propylene yield.
This paper presents the thermal coupling of the naphtha reforming process with methanol to propylene (MTP) process. In this integrated configuration, the required heat of the endothermic naphtha reforming process is provided by MTP which is an exothermic process. Therefore, intermediate heaters of conven-tional naphtha reforming (CNR), which were used to adjust the feed temperature of the reactors, were eliminated. The temperature of the MTP reactor increases slightly by transferring its heat to the naphtha reforming reactor; hence, the produced heat in the MTP reactor is controlled to prevent hotspot forma-tion on catalysts. Furthermore, the MTP process is cooled inherently without extra equipment. MTP and naphtha reforming processes were considered to occur in fixed-bed reactors with axial co-current feed streams. The MTP reactor feed streams are parallel while the naphtha reforming feed streams are in ser-ies. Results show that in the MTP process, produced propylene and consumed methyl ether in the three parallel reactors are 878 kmol/h and 0.034 kmol/h, respectively. Also, the molar flow rate of aromatics in naphtha reforming is 112 kmol/h. The propylene yield in thermally coupled reactors is 10% more than the conventional one. (c) 2022 Published by Elsevier Ltd.
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