Process Simulation and Modeling of Fluidized Catalytic Cracker Performance in Crude Refinery

Rajeev N.; Prasad R. Krishna; Ragula U. B. Reddy

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Process Simulation and Modeling of Fluidized Catalytic Cracker Performance in Crude Refinery

机译：粗炼厂流化催化裂化装置性能的过程模拟和建模

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The simulation of fluidized catalytic cracking (FCC) process was performed using Aspen HYSYS. The effect of crude flow rate on naphtha flow, coke yield, and catalyst to oil ratio in FCC were simulated. The interaction effects of riser height, inlet crude flow rate and operating temperature on naphtha mass flow, catalyst to oil ratio, and coke yield were studied by Box-Behnken design. The maximum yield of naphtha (100000 kg/h) was obtained for FCC operating temperature within 520-600 degrees C and riser height greater than 30 m. The catalyst to oil ratio of above 12 was obtained for operating temperature beyond 590 degrees C for the entire riser height variation of 10 to 60 m in FCC. The increase in riser height resulted in increase production of naphtha, but beyond 60 m of riser height secondary cracking occurs resulting in reduction in yield of naphtha.

机译：使用Aspen HYSYS对流化催化裂化（FCC）过程进行了仿真。模拟了原油流速对FCC中石脑油流速，焦炭收率和催化剂与油比的影响。采用Box-Behnken设计研究了立管高度，入口原油流速和操作温度对石脑油质量流量，催化剂与油的比以及焦炭收率的相互作用。在FCC工作温度在520-600摄氏度范围内且立管高度大于30 m的情况下，石脑油的最大产量（100000 kg / h）获得了。对于FCC中10-60 m的整个提升管高度变化，在超过590摄氏度的工作温度下，获得了高于12的催化剂/油比。冒口高度的增加导致石脑油的产量增加，但冒口高度超过60 m时，发生二次裂化，导致石脑油收率下降。

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《Petroleum Science and Technology》 |2015年第4期|共8页
作者
Rajeev N.; Prasad R. Krishna; Ragula U. B. Reddy;
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正文语种 eng
中图分类石油、天然气加工工业;
关键词
fluidized catalytic cracker; Aspen HYSYS; Box-Behnken design; catalyst to oil ratio; process simulation;

机译：流化催化裂化装置;Aspen HYSYS;Box-Behnken设计;催化剂与油比;工艺模拟;

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1. Process Simulation and Modeling of Fluidized Catalytic Cracker Performance in Crude Refinery [J] . Rajeev N., Prasad R. Krishna, Ragula U. B. Reddy Petroleum Science and Technology . 2015,第1a4期

机译：粗炼厂流化催化裂化装置性能的过程模拟和建模
2. Dynamic modeling and simulation of a fluidized catalytic cracking process. Part I: Process modeling [J] . In-Su Han, Chang-Bock Chung Chemical Engineering Science . 2001,第5期

机译：流化催化裂化过程的动态建模和仿真。第一部分：流程建模
3. Dynamic modeling and simulation of a fluidized catalytic cracking process. Part II: Property estimation and simulation [J] . In-Su Han, Chang-Bock Chung Chemical Engineering Science . 2001,第5期

机译：流化催化裂化过程的动态建模和仿真。第二部分：属性估计和模拟
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机译：炼油厂运营计划中原油蒸馏装置（CDU）和流化催化裂化器（FCC）优化的数学编程方法
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机译：现代流化催化裂化器的建模，仿真，稳定性分析和控制。
6. Application of a Fluid–Structure Interaction Model for Analysis of the Thermodynamic Process and Performance of Boil-Off Gas Compressors [O] . Bin Zhao, Shuangmei Zhou, Jianmei Feng, 2019

机译：流体结构相互作用模型在蒸发气体压缩机的热力过程分析中的应用
7. Petroleum refinery workers exposure to PAHs at fluid catalytic cracker, coker, and asphalt processing units. [O] . 1983

机译：石油炼油厂工人在液态催化饼干，焦型饼干和沥青加工单位接触PAH。
8. Petroleum Refinery Workers Exposure to PAHs at Fluid Catalytic Cracker, Coke, and Asphalt Processing Units [R] . Futagaki, S. K. 1981

机译：石油炼制工人暴露于流化催化裂化器，焦炭和沥青处理装置中的paHs

Process Simulation and Modeling of Fluidized Catalytic Cracker Performance in Crude Refinery

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