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Recent advances in naphtha catalytic cracking by nano ZSM-5:A review 被引量:15
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作者 Shayan Miar Alipour 《Chinese Journal of Catalysis》 SCIE EI CAS CSCD 北大核心 2016年第5期671-680,共10页
This review discussed the use of nano ZSM‐5 in naphtha catalytic cracking. The impact of nano ZSM‐5 on product selectivity, reaction conversion and catalyst lifetime were compared with micro‐sized ZSM‐5. The appli... This review discussed the use of nano ZSM‐5 in naphtha catalytic cracking. The impact of nano ZSM‐5 on product selectivity, reaction conversion and catalyst lifetime were compared with micro‐sized ZSM‐5. The application of nano ZSM‐5 not only increased the catalyst lifetime, but also gave more stability for light olefins selectivity. The effects of the reaction parameters of temperature and feedstock on the performance of nano ZSM‐5 were investigated, and showed that high temperature and linear alkanes as feedstock improved light olefin selectivity and conversion. 展开更多
关键词 Nano ZSM-5 Crystal size naphtha cracking Light olefins Reaction parameters
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Intensification of Ethylene Production from Naphtha via a Redox Oxy-Cracking Scheme: Process Simulations and Analysis 被引量:9
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作者 Vasudev Pralhad Haribal Yun Chen +1 位作者 Luke Neal Fanxing Li 《Engineering》 2018年第5期714-721,共8页
Ethylene production by the thermal cracking of naphtha is an energy-intensive process (up to 40 GJ heat per tonne ethylene), leading to significant formation of coke and nitrogen oxide (NOx), along with 1,8- 2 kg ... Ethylene production by the thermal cracking of naphtha is an energy-intensive process (up to 40 GJ heat per tonne ethylene), leading to significant formation of coke and nitrogen oxide (NOx), along with 1,8- 2 kg of carbon dioxide (CO2) emission per kilogram of ethylene produced, We propose an alternative pro- cess for the redox oxy-cracking (ROC) of naphtha, In this two-step process, hydrogen (H2) from naphtha cracking is selectively comhusted by a redox catalyst with its lattice oxygen first, The redox catalyst is subsequently re-oxidized by air and releases heat, which is used to satisfy the heat requirement for the cracking reactions, This intensified process reduces parasitic energy consumption and CO2 and NOx emissions, Moreover, the formation of ethylene and propylene can he enhanced due to the selective com-bustion of H2, In this study, the ROC process is simulated with ASPEN Plus^R based on experimental data from recently developed redox catalysts, Compared with traditional naphtha cracking, the ROC process can provide up to 52% reduction in energy consumption and CO2 emissions, The upstream section of the process consumes approximately 67% less energy while producing 28% more ethylene and propylene for every kilogram of naphtha feedstock, 展开更多
关键词 ETHYLENE naphtha cracking Process intensification Chemical looping Process simulations
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A coupled CFD simulation approach for investigating the pyrolysis process in industrial naphtha thermal cracking furnaces
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作者 Mohsen Rezaeimanesh Ali Asghar Ghoreyshi +1 位作者 S.M.Peyghambarzadeh Seyed Hassan Hashemabadi 《Chinese Journal of Chemical Engineering》 SCIE EI CAS CSCD 2022年第4期528-542,共15页
In the steam thermal cracking of naphtha,the hydrocarbon stream flows inside tubular reactors and is exposed to flames of a series of burners in the firebox.In this paper,a full three-dimensional computational fluid d... In the steam thermal cracking of naphtha,the hydrocarbon stream flows inside tubular reactors and is exposed to flames of a series of burners in the firebox.In this paper,a full three-dimensional computational fluid dynamics(CFD)model was developed to investigate the process variables in the firebox and reactor coil of an industrial naphtha furnace.This comprehensive CFD model consists of a standard k-εturbulence model accompanied by a molecular kinetic reaction for cracking,detailed combustion model,and radiative properties.In order to improve the steam cracking performance,the model is solved using a proposed iterative algorithm.With respect to temperature,product yield and specially propylene-toethylene ratio(P/E),the simulation results agreed well with industrial data obtained from a mega olefin plant of a petrochemical complex.The deviation of P/E results from industrial data was less than 2%.The obtained velocity,temperature,and concentration profiles were used to investigate the residence time,coking rate,coke concentration,and some other findings.The coke concentration at coil exit was1.9×10^(-3)%(mass)and the residence time is calculated to be 0.29 s.The results can be used as a scientific guide for process engineers. 展开更多
关键词 naphtha thermal cracking CFD modeling Systems engineering Residence time Product yield
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Development of RSDS-III Technology for Ultra-Low-Sulfur Gasoline Production 被引量:2
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作者 Xi Yuanbing Zhang Dengqian +1 位作者 Chu Yang Gao Xiaodong 《China Petroleum Processing & Petrochemical Technology》 SCIE CAS 2015年第2期46-49,共4页
The 3rd generation catalytic cracking naphtha selective hydrodesulfurization(RSDS-III) technology developed by RIPP included the catalysts selective adjusting(RSAT) technology, the development of new catalysts and opt... The 3rd generation catalytic cracking naphtha selective hydrodesulfurization(RSDS-III) technology developed by RIPP included the catalysts selective adjusting(RSAT) technology, the development of new catalysts and optimized process conditions. The pilot plant test results showed that the RSDS-III technology could be adapted to different feedstocks. The sulfur content dropped from 600 μg/g and 631 μg/g to 7 μg/g and 9 μg/g, respectively, by RSDS-III technology when feed A and feed B were processed to meet China national V gasoline standard, with the RON loss of products equating to 0.9 units and 1.0 unit, respectively. While the feed C with a medium sulfur content was processed according to the full-range naphtha hydrotreating technology, the sulfur content dropped from 357 μg/g in the feed to 10 μg/g in gasoline, with the RON loss of product decreased by only 0.6 units. Thanks to the high HDS activity and good selectivity of RSDS-III technology, the ultra-low-sulfur gasoline meeting China V standard could be produced by the RSDS-III technology with little RON loss. 展开更多
关键词 catalytic cracking naphtha RSDS-III TECHNOLOGY DEVELOPMENT
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