加氢裂化装置主分馏系统产品脱空度和进料过汽化率的优化

石油炼制与化工 ›› 2026, Vol. 57 ›› Issue (5): 92-101.

加氢裂化装置主分馏系统产品脱空度和进料过汽化率的优化

康君¹,盖朋波²,李国庆¹

1. 华南理工大学化学与化工学院
2. 山东京博石化有限公司

收稿日期:2025-11-14 修回日期:2026-01-08 出版日期:2026-05-12 发布日期:2026-04-24
通讯作者: 李国庆 E-mail:gqli1@scut.edu.cn

OPTIMIZATION OF PRODUCT QUALITY AND FEED OVER-VAPORIZATION RATE IN THE MAIN FRACTIONATION SYSTEM OF HYDROCRACKING UNIT

Received:2025-11-14 Revised:2026-01-08 Online:2026-05-12 Published:2026-04-24

摘要/Abstract

摘要： 主分馏系统是加氢裂化装置的主要耗能单元，其进料过汽化率及产品脱空度均直接影响装置操作与用能。基于此，利用PRO/Ⅱ软件构建的严格机理模型对某加氢裂化装置主分馏系统进行了全流程模拟，结果发现：进料过汽化率决定了主分馏塔塔顶冷却负荷、加热炉热负荷、塔底注汽量和喷气燃料/柴油侧线塔热负荷；柴油侧线塔热负荷及加热炉负荷与喷气燃料-粗汽油脱空度δ₁关联性弱；喷气燃料侧线塔热负荷基本不受柴油-喷气燃料脱空度δ₂的影响。进而，以年化总费用最小为目标函数，建立了4-5-7结构BP神经网络代理模型对主分馏系统进行优化，并采用遗传（GA）算法优化求解最优进料过汽化率和产品脱空度组合条件，结果表明系统最佳进料过汽化率为40.67%，最佳产品脱空度δ₁、δ₂分别为-0.06 ℃、-0.64 ℃。在此最佳优化条件下，主分馏系统经济效益可增加666.9万元/a。

关键词: 加氢裂化装置, 主分馏系统, 过气化率, 脱空度, 严格机理模型, BP神经网络, 代理模型

Abstract: The main fractionation system is the primary energy-consuming unit of the hydrocracking unit, where the feed over-vaporization rate and product separation degree directly affect unit operation and energy consumption. Based on this, a rigorous mechanistic model constructed using PRO/Ⅱ software was employed to simulate the entire process of the main fractionation system in a hydrocracking unit. The results revealed that the feed over-vaporization rate determines the top cooling load of the main fractionation column, the furnace heat load, the bottom steam injection rate, and the heat load of the jet fuel/diesel side-line column. The heat load of the diesel side-line column and the furnace load showed weak correlation with the separation degree δ₁ between jet fuel and crude gasoline. The heat load of the jet fuel side-line column was largely unaffected by the separation degree δ₂ between diesel and jet fuel. Subsequently, a 4-5-7 structure BP neural network surrogate model was established to optimize the main fractionation system, with the objective function being the minimization of annualized total cost. The genetic algorithm was used to solve for the optimal combination of feed over-vaporization rate and product separation degree. The results indicated that the optimal feed over-vaporization rate is 40.67%, and the optimal product separation degrees δ₁ and δ₂ are -0.06 ℃ and -0.64 ℃, respectively. Under these optimal conditions, the main fractionation system can increase economic benefits by 6.669 million Yuan per year.

Key words: hydrocracking unit, main fractionation system, over-vaporization rate, separation degree, rigorous mechanistic model, BP neural network, surrogate model

康君盖朋波李国庆. 加氢裂化装置主分馏系统产品脱空度和进料过汽化率的优化[J]. 石油炼制与化工, 2026, 57(5): 92-101.

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