Numerical analysis for particle deposit formation in reactor cyclone of residue fluidized catalytic cracking

Hyungtae Cho; Bumjoon Cha; Sungwon Kim; Jaewook Ryu; Junghwan Kim; Il Moon

doi:10.1021/ie302509q

Numerical analysis for particle deposit formation in reactor cyclone of residue fluidized catalytic cracking

Hyungtae Cho, Bumjoon Cha, Sungwon Kim, Jaewook Ryu, Junghwan Kim, Il Moon

Department of Chemical and Biomolecular Engineering

Research output: Contribution to journal › Article › peer-review

12 Citations (Scopus)

Abstract

Computational particle fluid dynamics (CPFD) simulation was carried out to analyze flow patterns in order to understand the mechanism of deposit formation on the cyclone duct during the residue fluidized catalytic cracking (RFCC) process. The CPFD simulation was based on the multiphase particle-in-cell (MP-PIC) method, in which the particle phase was solved by the stochastic Lagrangian model and the fluid phase was analyzed by the Eulerian method. In the first stage, a low-speed zone at a duct angle of 90 (an inlet position of 0) was discovered in the basic design of the cyclone, and this zone was predicted to be the initial region of deposit. Case studies were carried out for several stages of deposit growth to investigate the effects of deposit size on cyclone performance. A scouring phenomenon which hampers deposit growth is expected to occur when the deposit reaches 90 mm in thickness. When the deposit reaches 150 mm, the carryover rate abruptly doubles.

Original language	English
Pages (from-to)	7252-7258
Number of pages	7
Journal	Industrial and Engineering Chemistry Research
Volume	52
Issue number	22
DOIs	https://doi.org/10.1021/ie302509q
Publication status	Published - 2013 Jun 5

All Science Journal Classification (ASJC) codes

Chemistry(all)
Chemical Engineering(all)
Industrial and Manufacturing Engineering

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10.1021/ie302509q

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title = "Numerical analysis for particle deposit formation in reactor cyclone of residue fluidized catalytic cracking",

abstract = "Computational particle fluid dynamics (CPFD) simulation was carried out to analyze flow patterns in order to understand the mechanism of deposit formation on the cyclone duct during the residue fluidized catalytic cracking (RFCC) process. The CPFD simulation was based on the multiphase particle-in-cell (MP-PIC) method, in which the particle phase was solved by the stochastic Lagrangian model and the fluid phase was analyzed by the Eulerian method. In the first stage, a low-speed zone at a duct angle of 90 (an inlet position of 0) was discovered in the basic design of the cyclone, and this zone was predicted to be the initial region of deposit. Case studies were carried out for several stages of deposit growth to investigate the effects of deposit size on cyclone performance. A scouring phenomenon which hampers deposit growth is expected to occur when the deposit reaches 90 mm in thickness. When the deposit reaches 150 mm, the carryover rate abruptly doubles.",

author = "Hyungtae Cho and Bumjoon Cha and Sungwon Kim and Jaewook Ryu and Junghwan Kim and Il Moon",

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AU - Cho, Hyungtae

AU - Cha, Bumjoon

AU - Kim, Sungwon

AU - Ryu, Jaewook

AU - Kim, Junghwan

AU - Moon, Il

PY - 2013/6/5

Y1 - 2013/6/5

N2 - Computational particle fluid dynamics (CPFD) simulation was carried out to analyze flow patterns in order to understand the mechanism of deposit formation on the cyclone duct during the residue fluidized catalytic cracking (RFCC) process. The CPFD simulation was based on the multiphase particle-in-cell (MP-PIC) method, in which the particle phase was solved by the stochastic Lagrangian model and the fluid phase was analyzed by the Eulerian method. In the first stage, a low-speed zone at a duct angle of 90 (an inlet position of 0) was discovered in the basic design of the cyclone, and this zone was predicted to be the initial region of deposit. Case studies were carried out for several stages of deposit growth to investigate the effects of deposit size on cyclone performance. A scouring phenomenon which hampers deposit growth is expected to occur when the deposit reaches 90 mm in thickness. When the deposit reaches 150 mm, the carryover rate abruptly doubles.

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