吴乐教授

个人简介

个人简介

吴乐，教授，博士生导师，入选陕西省青年科技新星、陕西省高校科协青年人才托举计划和西北大学青年学术英才。主要从事过程系统工程领域的研究，主要研究方向：(1) 可再生能源系统的建模与设计；(2) 化工过程智能设计和优化；(3) 化工过程的模拟、优化和全生命周期分析。主持国家自然科学基金重点项目子课题、国家自然科学基金面上项目、国家自然科学基金青年项目、陕西省科技厅项目、重点实验室开放课题等10余项，参与国家级、省部级、企业横向课题多项。现以第一作者/通讯作者发表SCI/EI论文40余篇，参加国际国内会议30余次，授权发明专利3件。任EI源期刊《石油学报（石油加工）》青年编委、《西北大学学报（自然科学版）》青年编委，同时兼任多个SCI/EI期刊审稿人。

科研项目

    纵向项目

[1]  “煤电化新”多元耦合园区/基地能源资源体系构建及关键技术. 国家自然科学基金企业创新发展联合基金集成项目(U24B6016). 2025.01~2028.12. 参加

[2]  固态储氢系统中单元间氢热协调机制及系统优化方法. 国家自然科学基金面上项目(22378328). 2024.01~2027.12. 主持

[3] 可再生能源驱动的载能化学品模块化柔性制造系统优化设计理论与方法. 国家自然科学基金重点项目(22238006). 2023.01~2027.12. 参加

[4]  陕西省青年科技新星. 陕西省科技厅. 2024.01~2025.12，主持

[5] 2023年度教育部王宽诚教育基金会资助项目. 教育部. 2023.11~2024.10，主持

[6] 2021年度教育部王宽诚教育基金会资助项目. 教育部. 2021.11~2022.10，主持

[7] 2020年度教育部王宽诚教育基金会资助项目. 教育部. 2020.11~2021.10，主持

[8]  生物质油和蜡油共炼过程的生物质和原油供应链多周期设计和优化. 工业控制技术国家重点实验室开放课题. 2021.03~2022.02，主持

[9]  基于油-热-电-氢供需协调机制的生活垃圾联产系统构建和评价. 上海市固体废物处理与资源化工程研究中心. 2021.12~2023.12，主持

[10]  基于全生命周期思想的生物质油和蜡油共炼过程的碳排放分析及多目标优化. 广西石化资源加工及过程强化技术重点实验室. 2022.01~2023.12，主持

[11]  陕西精益化工有限公司兰炭基活性炭制备及其在该公司含酚废水处理的应用. 榆林科技局. 2022.10~2024.9，主持

[12]  耦合动力学的生物质油与蜡油共炼过程的多目标-多周期优化与分析. 陕西省自然科学基金青年项目（2020JQ-577），2020.01~2021.12，主持

[13]  耦合脱氧和脱硫动力学的生物质油和直馏蜡油共炼过程优化和评价. 陕西省高校科协青年人才托举计划（20190602）. 2020.01~2021.12. 主持

[13]  西北大学青年学术英才项目（优秀结题），2020.01~2022.12，主持

[14]  基于脱氧-脱硫协调机制的生物质油和直馏蜡油混炼过程的过程集成和分析评价. 国家自然科学基金青年项目（21808183）. 2019.01~2021.12. 主持

    

    横向项目

[1] 乙烯装置模拟及能效分析项目，中石化石油化工科学研究院，2024-2025，主持

[2]  耦合动力学的氢网络求解策略和加速算法开发，中石化石油化工科学研究院，2025-2026，主持

[3] 零碳园区理论建模研究，中煤能源研究院，2024-2025，参与

[4] 水洗塔气体出口水含量检测，2024-2025，西安航天源动力工程有限公司，主持

[5] 铝硅酸盐固废感应加热炉操作参数优化系统，西安交通大学，2023-2024，主持

[6] 电极材料测试，2023-2024，西北有色金属研究院，主持

发表论文

[1]  Weibin Xu, Yang Li, Benlin Xiang, Le Wu, Lixia Kang, Yongzhong Liu. Multi-period supply chain design and optimization for modular methanol production driven by renewable energy. Energy Conversion and Management, 2024, 319: 118868.

[2]  Jingyu Zhang, Weibin Xu, Shuai Zhang, Yonghong Zhu, Le Wu. Life cycle greenhouse gas emission analysis of co-processing of algal bio-oil and vacuum gas oil in an existing refinery. Energy Conversion and Management, 2024, 307: 118370.

[3]  Kang Qin, Sishi Ye, Le Wu. Process design and analysis of a net-zero carbon emissions hydrocracking unit integrating co-processing technique with green hydrogen and electricity. Energy, 2024, 295: 131080.

[4]  Lei Zhu, Shuai Wang, Le Wu, Lixia Kang, Yongzhong Liu. Construction of a coal chemical industry park with zero carbon emission by integrating renewable energy based on life cycle analysis. Process Integration and Optimization for Sustainability, 2024, 8 (5): 1569-1580.

[5]  徐维彬; 蒋迎花; 郑岚; 王玉琪; 吴乐. 生物质油与蜡油在FCC装置中共炼产汽柴油的研究进展. 化工进展. 2024, 43 (10): 5415-5426.

[6]  Deng X, Xie C, Zhang J, Wang Y, Zheng L, Ding X, Wu L. Techno-economic analysis of municipal solid waste treatment for poly-generation system. Science of The Total Environment, 2024, 912: 168869.

[7]  Xie, C., Tian, Y., Wu, L.. Multi-period Two-stage Stochastic Programming of Supply Chain for Co-processing System of Bio-oil and Heavy Oil. ACS Sustainable Chemistry & Engineering, 2023, 11 (9): 3850-3860.

[8]  Xie C, Deng X, Zhang J, Wang Y, Zheng L, Ding X, Li X, Wu L. Multi-period design and optimization of classified municipal solid waste supply chain integrating seasonal fluctuations in waste generation. Sustainable Cities and Society, 2023, 93: 104522.

[9]  Hu, J., Chen, X., Yang, X., Li, R., Wu, L. Co-processing of gas oil and bio-oil derived from algae and straw: Techno-economic analysis. Fuel, 2023, 340: 127583.

[10]  Zhang, S., Lei, Q., Wu, L, Wang, Y., Zheng, L., Chen, X. Supply chain design and integration for the Co-Processing of bio-oil and vacuum gas oil in a refinery. Energy, 2022, 241: 122912.

[11]  Lei, Q., Zhang, S., Li, Y., Ding, X., Wang, Y., Zheng, L., Wu, L. Design and optimization of poly-generation system for municipal solid waste disposal. Journal of Cleaner Production, 2022, 370: 133611.

[12]  Tian, R., Xu, W., Li, Y., Tian, J., Wu, L. Energy Consumption Analysis of a Diesel Hydrotreating Unit Using an Aspen Simulation. Processes, 2022, 10 (10): 2055.

[13]  Wu, L.*, Yan, T., Lei, Q., Zhang, S., Wang, Y., Zheng, L.. Optimization of Co-processing of Heavy Oil and Bio-oil Based on the Coordination of Desulfurization and Deoxygenation. Energy, 2022, 239: 122558.

[14]  Wu, L.*, Yan, T., Qian, K., Hong, F.. Multi-period Design and Optimization of Co-processing of Vacuum Gas Oil and Bio-oil Integrating Supply Fluctuations of Lignocellulosic and Algal Biomass. Industrial & Engineering Chemistry Research, 2021, 60 (20): 7667-7677.

[15]  Shi, M.; Zhao, X.; Wang, Q.; Wu, L.*, Comparative Life Cycle Assessment of Co-Processing of Bio-Oil and Vacuum Gas Oil in an Existing Refinery. Processes, 2021, 9 (2), 187.

[16]  Wu, L.*, Yang, Y., Yan, T., Wang, Y., Zheng, L., Qian, K., Hong, F.. Sustainable design and optimization of co-processing of bio-oil and vacuum gas oil in an existing refinery. Renewable and Sustainable Energy Reviews, 2020, 130: 109952.

[17]   Wu L, Li L, Wang Y, Zheng L. Techno-economic analysis of co-processing of vacuum gas oil and algae hydrothermal liquefaction oil in an existing refinery. Energy Conversion and Management, 2020, 224: 113376.

[18]  Wu, L.*; Wang, Y.; Zheng, L.; Wang, P.; Han, X., Techno-economic analysis of bio-oil co-processing with vacuum gas oil to transportation fuels in an existing fluid catalytic cracker. Energy Conversion and Management 2019, 197, 111901.

[19]  Wu, L.*; Wang, Y.; Zheng, L.; Shi, M.; Li, J., Design and optimization of bio-oil co-processing with vacuum gas oil in a refinery. Energy Conversion and Management 2019, 195, 620-629.

[20]  Wu, L.*; Wang, Y.; Zheng, L.; Han, X., Stepwise optimization of hydrogen network integrated sulfur compound removal kinetics and a fluid catalytic cracker. Chemical Engineering Research and Design 2019, 151, 168-178.

[21]  Wu, L.*; Wang, Y.; Zhang, L.; Han, X.; Hong, F., Multi-objective Operational Optimization of a Hydrotreating Reactor Based on Hydrogenation Reaction Kinetics. Industrial & Engineering Chemistry Research, 2018, 57, 15785-15793.

[22]  Wu, L.; Liang, X.; Kang, L.; Liu, Y.*, Saffron, C., Hydrogen network optimization by integrating impurity distributions of a fluid catalytic cracker and hydrogenation reaction kinetics. Journal of Cleaner Production , 2018, 192, 542-552.

[23]  Wu, L.; Liu, Y.*; Zhang, Q., Operational optimization of a hydrotreating system based on removal of sulfur compounds in hydrotreaters coupled with a fluid catalytic cracker. Energy & Fuels , 2017, 31, (9), 9850–9862.

[24]  Wu, L.; Liang, X.; Kang, L.; Liu, Y.*, Integration strategies of hydrogen network in a refinery based on operational optimization of hydrotreating units. Chinese Journal of Chemical Engineering , 2017, 25, (8), 1061-1068.

[25]  Wu, L.; Liu, Y.*, Environmental impacts of hydrotreating processes for the production of clean fuels based on life cycle assessment. Fuel , 2016, 164, 352-360.

[26]  Wu, L.; Liu, Y.*; Liang, X.; Kang, L., Multi-objective optimization for design of a steam system with drivers option in process industries. Journal of Cleaner Production , 2016, 136, 89-98.

[27]  李阳, 史美荣, 沈若莹, 黄玉婷, 丁鑫, 吴乐*. 耦合加氢反应动力学和FCC杂质分配作用的生物质油与蜡油共炼过程的操作优化. 石油学报 (石油加工), 2022, 38 (1): 199-207.

[28]  吴乐*; 王竞; 王玉琪; 郑岚. 生物质油与蜡油在FCC装置共炼的多目标优化. 化工学报, 2020, 71 (5): 2182-2189.

[29]  史美荣; 吴乐*; 赵欣, 汽油品质升级过程的环境影响分析与对比. 石油学报 (石油加工) 2019, 35 (3), 594-602.

[30]  吴乐; 汤杰国; 朱强; 刘永忠*, 加氢反应过程对炼油厂加氢系统氢耗影响的分析. 石油学报 (石油加工) , 2016, 32, (5), 1030-1037. （EI）

[31]  吴乐; 朱强; 刘永忠*, 燃油加氢深度脱硫过程的生态环境影响分析. 石油学报 (石油加工) , 2016, 32, (2), 343-349. （EI）

[32]  Wu, L.*; Wang, J.; Wang, Y.; Zheng, L., Design and Integration of Bio-Oil Co-Processing with Vacuum Gas Oil in a Refinery. Chemical Engineering Transactions 2019, 76, 1171-1176.

[33]  Shi, M., Zhao, X., Wang, Q., Wu, L.*. Comparative Life Cycle Assessment of Co-Processing of Bio-Oil and Vacuum Gas Oil in an Existing Refinery. Processes 2021, 9 (2): 187.

[34]  Wu, L.; Liu, Y.*; Kang, L., Multi-objective optimization on driving options for rotating equipment in process industries to make trade-offs between economic and environmental impacts. Chemical Engineering Transactions , 2015, 45, 1093-1099. 

发明专利

[1]  吴乐, 李菲, 史美荣, 王玉琪, 郑岚, 韩小龙. 一种快速热解生物质油与直馏蜡油共炼生产汽柴油的方法. 发明专利. ZL201811565769.2

[2]  吴乐, 雷晴宇, 张帅, 王玉琪, 郑岚. 自循环、油-电平衡的生活垃圾制备油-电-气-热的方法. 发明专利. ZL202110076202.4

[3]  吴乐, 张帅, 雷晴宇, 丁鑫, 王玉琪, 郑岚. 一种脱除餐饮业油烟、颗粒物和非甲烷总烃的装置. 实用新型专利: ZL202120155115.3

教育经历

[1]   2012.9-2017.12

西安交通大学  |  化学工程  |  工学博士学位  |  博士研究生毕业

[2]   2008.9-2012.7

浙江工业大学  |  化学工程与工艺  |  工学学士学位  |  大学本科毕业

[3]   2005.9-2008.7

西安市第83中学  |  无 普通高中学毕业

工作经历

[1]   2024.11-至今

西北大学  |  化工学院  |  教授

[2]   2019.2-2024.10

西北大学  |  化工学院  |  副教授

[3]   2018.1-2019.1

西北大学  |  化工学院  |  讲师

[4]   2016.9-2017.9

密歇根州立大学  |  生物系统工程  |  访问学者

社会兼职

• [1]   任《西北大学学报（自然科学版）》青年编委

• [2]   任EI源期刊《石油学报(石油加工)》青年编委

• [3]   中国化工学会会员
  中国系统工程学会会员

研究方向

[1]  能源化工过程的多尺度-多周期-多目标设计、模拟、评价和优化

其他联系方式

[1]  邮编： 6b7454e50d43d36b84be9411bcacd6d07dddc2b0c57f502033ae18d71df234997ce7f6fc2e4fe19045b04d9344563e40a9d6dad75818a5c11655fce7238f47df4cc4f9c4518588bea01728533fe7565a2ad8380eb7a08dc1f0d94d3d0f8f8c6ae58d5a5427ceb0dba7f8c819c7fc40594b12fdbe51850b1ec387b8382a1417d5

[3]  通讯/办公地址： 73ef27c129745fda08b7b5899288d1eb6a531fdc58c54922dfbbbe2a09d2880f8defedda2176b6f2b810c80b25b3bbf119e9974126d29c6d47b46420d46957a3675b59fd5de0f5f55f590ed3a2b7b81e856fab722584af653b00fb947480691c6efa8f4f96d2c3a82f6dbfffdbf50c86be7089e3116180d44fcf14cc2fc3c740

[4]  办公室电话： 388614ec306f3008e04986007a13b0c4b29fa93823c2b83afd3ef2bea0d93eb498da65ae3ce368da85bdb8d9706e91d887b282e03c156afde8b4b97ad7ae6ee886157bcce94fd37a4b278dd54b454e05dbf84c5827ad2e72521ebbc6d15faefef04deec4b1592a5420d7425ffe87765155e0deacc4bbce7a883c2215c62df9ca

[6]  邮箱： 2beb3d3d2c288fa250251c94fb04bf07b019bebf906863b903808d09fe4f1be4a5bb40366d9871da39ce79528f097df8a2d8d479a05264698896f992b6f10c22f71ee84b0ab72beeeb0d230f2c04986ec8f2bf2f7837c1e2c02c6a4433dd1a42109f830ec3cabb0ebf47cea72ee2a9619daa619c8ff94c51e1e146cf324e79e2