都健    博士    大连理工大学化工学院    教授    博士生导师

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    辽宁省优秀教师

    辽宁省教学名师

    ”兴辽英才计划“教学名师

    获宝钢教育基金会优秀教师奖

    两门国家级一流本科课程负责人

    大连理工大学领军人才

    中国系统工程学会过程系统工程专业委员会副主任委员

    中国化工学会信息技术应用专业委员会副主任委员

    中国化工学会过程模拟及仿真专业委员会委员

    美国宾夕法尼亚大学访问学者

   

研究方向：化工系统工程，致力于过程系统能质网络全局集成优化的研究，在过程系统分析与建模、化工过程能量集成、功网络集成、质量集成、水网络的优化设计、换热器网络柔性综合与先进控制集成、间歇过程热量和质量集成、复杂系统的耦合集成及优化算法等研究中取得了丰富的研究成果，发表相关学术论文百余篇，获得多项省部级科技奖励，包括中国石油和化学工业协会科技进步二等奖、辽宁省科技进步一等奖、辽宁省技术发明二等奖等。

主编或参编专著：包括《乙烯装置能量系统优化技术》（主编）、《化学工程手册（第三版）》（过程系统工程篇主稿人）、《过程系统工程辞典》（编委）等；曾获大连市优秀著作二等奖。主持国家自然科学基金项目3项，完成了多项石化企业的节能节水改造项目，取得了显著的经济效益和社会环境效益。主编教材六部，其中主编的《化工原理》（上册）教材，由高等教育出版社出版，为“十一五”国家级规划教材，获评辽宁省首届优秀教材建设奖；主编的《化工过程分析与综合》教材，由化学工业出版社出版，为化工类专业教学指导委员会推荐教材。负责的《化工原理》及《化工过程分析与合成》在线开放课程在中国大学慕课平台上线，两门课程均获评首届国家级一流本科课程。化工原理课程的建设获评辽宁省优秀教学成果一等奖。主编的化工原理教材获评辽宁省首届优秀教材奖。获宝钢教育基金会优秀教师奖、辽宁省优秀教师、辽宁省教学名师奖、”兴辽英才计划“教学名师、大连理工大学教学名师奖、大连理工大学屈伯川奖教金等多项教学奖励，是”化工原理全国石油和化工教育优秀教学团队“负责人。

  

教育经历：

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l  2000/03 - 2004/04，大连理工大学，化工学院，博士，导师：姚平经

l  1986/09 - 1989/03，大连理工大学，化工学院，硕士，导师：俞裕国

l  1982/09 - 1986/07，大连理工大学，化工学院，学士

 

科研与学术工作经历：

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l  2011/06 -至今，大连理工大学，化工学院，博士生导师

l  2010/12 -至今，大连理工大学，化工学院，教授

l  2007/09 - 2008/02，美国宾夕法尼亚大学，访问学者

l  1997/09 - 2010/11，大连理工大学，化工学院，副教授

l  1991/09 - 1997/08，大连理工大学，化工学院，讲师

l  1989/03 - 1991/08，大连理工大学，化工学院，助教

 

主持或参加科研项目（课题）及人才计划项目情况：

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l  国家自然科学基金面上项目，22178045，基于石化工业园区全产业链能效诊断的多能源网络动态调控方法，2022/01-2025/12，60万元，在研，主持

l  “兴辽英才”计划项目，XLYC1906016，三元共沸物系变压精馏分离序列及余热回收设计与控制，2020/01-2022/12，20万元，在研，主持

 

l  国家自然科学基金面上项目，21776035，基于火用分析的热耦合功交换网络综合研究，2018/01-2021/12，64万元，结题，主持

l  国家自然科学基金面上项目，21576036，柔性换热器网络综合与先进控制集成理论和方法研究，2016/01-2019/12，65万元，结题，主持

l  国家自然科学基金面上项目，20976022，多杂质体系质量和热交换网络同步集成，2010/01-2012/12，30万元，结题，主持

  

代表性文章：

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2021：

[1] Zhuang Yu, Xing Yafeng, Zhang Lei, Liu Linlin, Du Jian^*, Shen Shengqiang, An enhanced superstructure-based model for work-integrated heat exchange network considering inter-stage multiple utilities optimization. Computers & Chemical Engineering, 2021, 152: 107388.

[2] Zhang Lei, Mao Haitao, Zhuang Yu, Wang Lu, Liu Linlin, Dong Yachao, Du Jian^*, Xie Wancui, Yuan Zhihong, Odor prediction and aroma mixture design using machine learning model and molecular surface charge density profiles. Chemical Engineering Science, 2021, 245: 116947.

[3] Wang Chao, Zhuang Yu^*, Qin Yutao, Dong Yachao, Liu Linlin, Zhang Lei, Du Jian^*, Optimization and eco-efficiency analysis of extractive distillation processes with different solvents for separating the ternary mixture embedding two azeotropes. Separation and Purification Technology, 2021,269: 118763.  

[4] Zhuang Yu, Zhou Congcong, Zhang Lei, Liu Linlin, Du Jian^*, Shen Shengqiang, A simultaneous optimization model for a heat-integrated syngas-to-methanol process with Kalina Cycle for waste heat recovery. Energy, 2021,227: 120536.

[5] Wang Chao, Zhuang Yu^*, Dong Yachao, Zhou Congcong, Zhang Lei, Du Jian^*, Conceptual design of the triple-column extractive distillation processes with single entrainer and double entrainer for separating the N-hexane/acetone/chloroform ternary multi-azeotropic mixture. Chemical Engineering Science, 2021,237: 116578.

[6] Sun Xiaojing, Liu Linlin^*, Dong Yachao, Zhuang Yu, Li Jiao, Du Jian^*, Yin Hongchao, Multi-objective optimization and thermo-economic analysis of an enhanced compression-absorption cascade refrigeration system and ORC integrated system for cooling and power cogeneration. Energy Conversion and Management, 2021,236: 114068.

[7] Wang Chao, Zhuang Yu^*, Liu Linlin, Zhang Lei, Du Jian^*, Design and comparison of energy-saving double column and triple column reactive-extractive hybrid distillation processes for ternary multi-azeotrope dehydration. Separation and Purification Technology, 2021,259: 118211.

[8] Zhuang Yu^*, Zhou Congcong, Dong Yachao, Du Jian^*, Shen Shengqiang, A hierarchical optimization and design of double Kalina Cycles for waste heat recovery. Energy, 2021,219: 119593.

[9] Wang Chao, Zhuang Yu^*, Liu Linlin, Zhang Lei, Du Jian^*, Heat pump assisted extractive distillation sequences with intermediate-boiling entrainer. Applied Thermal Engineering, 2021, 186: 116511.

2020：

[1] Lei Zhang, Jian Du* et al. Integrated Solvent-Process Design Methodology based

on COSMO-SAC and Quantum Mechanics for TMQ (2,2,4-trimethyl-1,2-H-dihydroquinoline) Production. Chemical Engineering Science. 2020,226:115894.

[2] Yu Zhuang, Jian Du* et al. Simultaneous optimization of a heat-integrated coal-to-SNG/MeOH polygeneration process based on rigorous kinetic model. Industrial & Engineering Chemistry Research. 2020, 59, 51:22247. (封面)

[3] Linlin Liu, Jian Du* et al. Optimization-based framework for the synthesis of heat exchanger networks incorporating controllability. Energy. 2020,208:118292.

[4] Xiaojing Sun, Jian Du* et al. A superstructure-based simultaneous optimization of heat exchanger network and compression-absorption cascade refrigeration system for heat recovery.Industrial & Engineering Chemistry Research. 2020, 59:16017. (封面)

[5] Linlin Liu, Jian Du* et al. Multi-objective optimization of inter-plant heat exchanger networks considering utility steam supply and various locations of inter-plant steam generation/utilization.Industrial & Engineering Chemistry Research. 2020, 59:14433.

[6] Yu Zhuang, Rui Yang, Lei Zhang, Jian Du*, Shengqiang Shen. Simultaneous Synthesis of Sub and Above-ambient Heat Exchanger Networks including Expansion Process Based on an Enhanced Superstructure Model. Chinese Journal of Chemical Engineering, 2020, 28: 1344. (封底)

[7] Chao Wang, Yu Zhuang*, Linlin Liu, Lei Zhang, Jian Du*. Design and comparison of conventional and side-stream extractive distillation sequences for separating the methanol-toluene binary azeotrope with intermediate boiling entrainer. Computers and Chemical Engineering, 2020, 143: 107115.

[8] Weida Li, Yu Zhuang, Lei Zhang, Linlin Liu, Jian Du*. Process evaluation and optimization of methanol production from shale gas based on kinetics modeling. Journal of Cleaner Production, 2020, 274: 123153.

[9] Chao Wang, Yu Zhuang, Linlin Liu, Lei Zhang, Jian Du*. Design and control of a novel side-stream extractive distillation column for separating methanol-toluene binary azeotrope with intermediate boiling entrainer. Separation and Purification Technology, 2020, 239: 116581.

[10] Chao Wang, Yu Zhuang, Linlin Liu, Lei Zhang, Jian Du*. Control of Energy-Efficient extractive distillation configurations for separating methanol/toluene azeotrope with intermediate-boiling entrainer. Chemical Engineering and Processing, 2020, 149: 107862.

 2019：

[1] Linlin Liu, Jian Du* et al., Synthesis of Flexible Heat Exchanger Networks Consudering Gradually Accumulated Deposit and Cleaning Management, Industrial & Engineering Chemistry Research,2019,58(27):12124-12136.( 封面) 

[2] Siwen Gu, Jian Du* et al., Optimization-Based Framework for Designing Dynamic Flexible Heat Exchanger Networks, Industrial & Engineering Chemistry Research,2019,58(15):6026-6041.( 封面) 

[3] Weida Li, Jian Du* et al., Economic evaluation and environmental assessment of shale dehydration process, Journal of Cleaner Production, 2019,232:487-498

[4] Yu Zhuang, Jian Du* et al., An Extended Superstructure Modeling Method for Simultaneous Synthesis of Direct Work Exchanger Networks, Chemical Engineering Research and Design, 2019,144:258-271

2018：

[1] Shuai Zhang, Jian Du* et al., An optimization model for carbon capture utilization and storage supple chain: A case study in Northeastern China, Applied Energy, 2018,231:194-206

[2] Linlin Liu, Haodong Song, Lei Zhang, Jian Du^*, Heat-integrated Water Allocation Network Synthesis for Industrial Parks with Sequential and Simultaneous Design, Computers & Chemical Engineering, 2018,108: 408-424.

[3] Gu, S., Liu, L., Zhang, L., Bai, Y., Wang, S., Du, J.^* (2018). Heat exchanger networks synthesis integrated with flexibility and controllability, Chinese Journal of Chemical Engineering, doi: 10.1016/j.cjche.2018.07.017

[4] Zhuang, Y., Zhang, L., Liu, L., Meng, Q., Du, J.^* (2018). Simultaneous Synthesis of WHEN Based on Superstructure Modelling Considering Thermodynamic and Economic Factors. In Computer Aided Chemical Engineering (Vol. 44, pp. 1033-1038). Elsevier. 

[5] Liu, L., Sheng, Y., Zhang, L., Du, J.^*, Meng, Q. (2018). Water networks synthesis for industrial parks respecting to unpredictable scenarios. In Computer Aided Chemical Engineering (Vol. 44, pp. 1021-1026). 

[6] 李伟达,刘琳琳张磊,王少靖,都健.^* (2018). 基于灵敏度分析的页岩气净化流程的模拟与优化,化工学报,69(3),1008-1013. (EI, 第十六届中国化工学会信息技术应用专业委员会年会优秀论文)

2017：

[1] Yu Zhuang, Linlin Liu, Lei Zhang, Jian Du^*, Upgraded Graphical Method for the Synthesis of Direct Work Exchanger Networks. Industrial & Engineering Chemistry Research, 2017,56(48): 14304-14315.

[2] Yu Zhuang, Linlin Liu, Lei Zhang, Jian Du^*, Direct work exchanger network synthesis of isothermal process based on improved transshipment model. Journal of the Taiwan Institute of Chemical Engineers, 2017,81: 295-304.

[3] Yu Zhuang, Linlin Liu, Qilei Liu, Jian Du^*, Step-wise synthesis of work exchange networks involving heat integration based on the transshipment model, Chinese Journal of Chemical Engineering, 2017, 25: 1052–1060.

[4] Linlin Liu, Jian Wang, Haodong Song, Jian Du^*, Fenglin Yang, Multi-period water network management for industrial parks considering predictable variations. Computer and Chemical Engineering, 2017, 104: 172-184.

[5] Zhuang, Y., Liu, L., Zhang, L., & Du, J.^* (2017). Direct work exchanger network synthesis of isothermal process based on improved transshipment model. Journal of the Taiwan Institute of Chemical Engineers, 81, 295-304.

[6] Zhuang, Y., Liu, L., Zhang, L., & Du, J.^* (2017). Upgraded Graphical Method for the Synthesis of Direct Work Exchanger Networks. Industrial & Engineering Chemistry Research, 56(48), 14304-14315.

Before 2016：

[1] Linlin Liu, Jian Wang, Haodong Song, Jian Du^*, Fenglin Yang, Synthesis of Water Networks for Industrial Parks Considering Inter-plant Allocation. Computer and Chemical Engineering, 2016, 91: 307-317.

[2] Jilong Li, Jian Du^*, Zongchang Zhao, Pingjing Yao, Efficient Method for Flexibility Analysis of Large-Scale Nonconvex Heat Exchanger Networks. Industrial & Engineering Chemistry Research, 2015, 54(43), 10757- 10767.

[3] Linlin Liu, Jie Fan, Pengpeng Chen, Jian Du^*, Fenglin Yang, Synthesis of Heat Exchanger Networks Considering Fouling, Aging, and Cleaning. Industrial & Engineering Chemistry Research, 2015, 54(1): 296-306.

[4] Linlin Liu, Jian Du^*, Fenglin Yang, Combined mass and heat exchange network synthesis based on stage-wise superstructure model. Chinese Journal of Chemical Engineering, 2015, 23(9): 1502-1508.

[5] Po Yang, Linlin Liu, Jian Du^*, Jilong Li, Qingwei Meng, Heat exchanger network synthesis for batch processes by involving heat storages with cost targets, Applied Thermal Engineering, 2014, 70(2): 1276-1282.

[6] Jilong Li, Jian Du^*, Zongchang Zhao, Pingjing Yao,Structure and Area Optimization of Flexible Heat Exchanger Networks. Industrial & Engineering Chemistry Research, 2014, 53(39), 11779- 11793.

[7] Linlin Liu, Mahmoud M. El-Halwagi, Jian Du^*, Jose Maria Ponce-Ortega, Pingjing Yao, Systematic Synthesis of Mass Exchange Networks for Multicomponent Systems, Industrial & Engineering Chemistry Research, 2013, 52: 14219-14230.

 研究成果和学术奖励:

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1.都健（3/6），氨磷汀及制剂生产新工艺，辽宁省科学技术奖励委员会，辽宁省技术发明二等奖，2013.

2.都健（3/6），氨磷汀及制剂生产新工艺，辽宁省科学技术奖励委员会，大连市技术发明一等奖，2011.

3.都健（7/7），新型脲酶抑制剂NBPT工艺技术，辽宁省科学技术奖励委员会，辽宁省科技进步三等奖，2014.

4.都健（主编），化工过程分析与综合，大连市优秀著作二等奖，2011.

 

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大连理工大学化工系统工程团队

团队从事化工系统工程方向的研究，包括化工过程的模拟与优化、质（水）能集成、系统评价与算法开发，以及化工园区的节能减碳与循环经济；化工过程与产品设计；化工智能制造与过程控制；多流程/多系统综合以及热功耦合动力循环全局能量集成等。团队现有教授都健1人，副教授刘琳琳、张磊、董亚超、庄钰4人；其中博士生导师2人（都健、张磊）、硕士生导师5人（都健、张磊、刘琳琳、董亚超、庄钰）。