Sun Lanyi(Professor)

  Name：

Sun Lanyi

Academic Title：

Professor

Advisor Type：

Doctoral   supervisor

  Department：

Department of   Chemical Engineering

Research   Interests：

Separation   engineering, process simulation and control

  E-Mail：

sunlanyi@163.com；sunlanyi@upc.edu.cn

  Telephone：

◎Educational Background

(1)  1997-2001, Department of chemical   engineering, Tsinghua University, major in chemical engineering, doctoral   degree.

(2)  1994-1997, Institute of chemical   engineering, Tianjin University, major in chemical engineering, master's   degree.

(3)  1990-1994，Petroleum University refining   Department, petroleum processing major, bachelor's degree.

◎Work Experience

(1)  2012.09 to now, Professor, School of   chemical engineering, China University of Petroleum (East China).

(2)  2005.04-2012.08, associate professor,   School of chemical engineering, China University of Petroleum (East China).

(3)  2002.01-2004.12, Delft University of   technology, Netherlands, postdoctoral.

◎Research Direction

[1]Process simulation, optimization,   control and energy saving.

[2]Strengthening of separation and reaction   process.

[3] Technology development of separation   and reaction equipment.

[4] Design and application of new   solvent.

◎Research Project

[1]Subproject ofNational Key R&D Program of China:Demonstration of key technology of methanol to   polymethoxy dimethyl ether, 2018-2021

[2]General project of national Natural   Science Foundation of China:Fundamental Research of Low Transition   Temperature Mixtures (LTTMs) Applying to Extractive Distillation Process, 2017-2020

[3] General project of national Natural   Science Foundation of China:Optimization and control of self-heat recuperation   distillation, 2015-2018

[4] General project of national Natural   Science Foundation of China:Study on the design and optimization of   the dividing wall column coupled with reactive distillation, 2013-2016

[5]Key R & D Program in Shandong   Province: Design and experimental study of green solvent for the separation   of olefins and alkanes in coking naphtha ,2019-2020

[6] Key R & D Program in Shandong   Province: Research on cleaner production technology and equipment of diethyl   carbonate and methyl ethyl carbonate, 2015-2016

[7]Scientific Research Award Fund for   Outstanding Young and middle-aged Scientists of Shandong Province: Modeling   and optimal control of catalytic distillation column, 2013-2014

[8]Science and Technology Innovation   foundation of CNPC: Study on high efficiency catalyst and reaction process   for dehydrogenation of Isobutane to Isobutene, 2013-2014

[9]Qingdao science and technology planning   project: Development and Research on Key Technologies of VOCs absorption   treatment with low transition temperature mixtures (LTTMS), 2019-2020

[10]Qingdao Development Zone Science and   technology project: Study on the preparation of biodiesel by high efficiency   reaction separation integrated reactor, 2013-2015

[11]Enterprise entrusted project:   Development of numerical simulation and process simulation technology   for underground coal gasification, 2019-2020

[12]Enterprise entrusted project: Development   of distribution plate for high efficiency residue hydrogenation reactor, 2018-2020

[13]Enterprise entrusted project: Development   of process package for synthesis of methyl ethyl carbonate by continuous   reactive distillation, 2016-2017

[14]Enterprise entrusted project: Development   of 10000 t / a isophorone (acetone gas phase polycondensation and separation)   production process package, 2016-2017

[15]Enterprise entrusted project: Research   on utilization scheme and software development of LNG cold energy in   refinery, 2014-2016

◎Representative Papers and Patents

1. Paper

[1] Liu, J.; Yan, J.; Liu, W.; Kong, J.;   Wu, Y.; Li, X.; Sun, L.; Design and multi-objective optimization of   reactive-extractive dividing wall column with organic Rankine cycles   considering safety, Separation and Purification Technology, 2022,   287(15): 120512.

[2] Liu, J.; Liu, X.; Li, J.; Ren, J.;   Wang, J.; Sun, L.; Design and control of side-stream extractive distillation   to separate acetic acid and cyclohexanone from wastewater by varying   pressure, Process Safety and Environmental Protection, 2022,   159:1127-1149.

[3] Luo, F.; Liu, X.; Chen, S.; Song,   Y.; Yi, X.; Xue, C.; Li, J.; Sun, L.; Comprehensive evaluation of a deep   eutectic solvent based CO₂ capture process through experiment and   simulation, ACS Sustainable Chemistry   & Engineering, 2021, 9(30): 10250-10265.

[4] Liu, J.; Gao, L.; Ren, J.; Liu, W.;   Liu, X.; Sun, L.; Dynamic process intensification of dimethyl ether reactive   distillation based on output multiplicity, Industrial & Engineering   Chemistry Research, 2020, 59(45): 20155-20167.

[5] Ma, S.; Liu, J.; Xu, W.; Sun, F.;   Jiang, J.;Sun, L.; Experiment and simulation for CO₂ capture   using low transition temperature mixtures as solvents, International Journal of Greenhouse Gas   Control, 2020, 103: 103178.

[6] Song, Y.; Chen, S.; Luo, F.; Sun,   L.; Absorption of toluene using deep eutectic solvents: quantum chemical   calculations and experimental investigation, Industrial & Engineering Chemistry Research, 2020, 59(52): 22605-22618.

[7] Shang, X.; Ma, S.; Pan, Q.; Li, J.;   Sun, Y.; Ji, K.; Sun, L.; Process analysis of extractive distillation for the   separation of ethanol-water using deep eutectic solvent as entrainer, Chemical   Engineering Research and Design, 2019, 148: 298-311.

[8] Ma, S.; Shang, X.; Li, L.; Song, Y.;   Pan, Q.; Sun, L.; Energy-saving thermally coupled ternary extractive   distillation process using ionic liquids as entrainer for separating ethyl   acetate-ethanol-water ternary mixture, Separation and Purification   Technology, 2019, 226: 337-349.

[9] Li, J.; Zhang, F.; Pan, Q.; Yang,   Y.; Sun, L.; Performance enhancement of reactive dividing   wall column based on self-heat recuperation technology, Industrial   & Engineering Chemistry Research, 2019.

[10] Pan, Q.; Li, J.; Shang, X.; Ma, S.;   Liu, J.; Sun, M.; Sun, L.; Controllability, energy-efficiency and safety   comparisons of different control schemes for producing n-butyl acetate in a   reactive dividing wall column, Industrial & Engineering Chemistry   Research, 2019, 58(22): 9675-9689.

[11] Pan, Q.; Shang, X.; Li, J.; Ma, S.;   Li, L.; Sun, L.; Energy-efficient separation process and control scheme for   extractive distillation of ethanol-water using deep eutectic solvent, Separation   and Purification Technology, 2019, 219: 113-126.

[12] Sun, L.; Luo, F.; Liu, R.; Yang,   H.; Huang, L.; Li, J.; Isobaric liquid–liquid equilibrium measurements and   thermodynamics modeling for systems: Benzene+ cyclohexane+ DESs at 303.15 and   323.15 K. Journal of Chemical & Engineering Data, 2019, 64(3):   1113-1121.

[13] Ma, S.; Shang, X.; Li, L.; Pan, Q.;   Xue, C.; Ji, K.; Sun, L.; Optimization and control of CO2 capture using low   transition temperature mixtures. International Journal of Greenhouse Gas   Control, 2019, 81: 126-136.

[14] Ma, S.; Shang, X.; Zhu, M.; Li, J.;   Sun, L.; Design, optimization and control of extractive distillation for the   separation of isopropanol-water using ionic liquids, Separation and   Purification Technology, 2019, 209: 833-850.

[15] Sun, Y.; Fu, D.; Ma, S.; Ma, Z.;   Sun, L.; Isobaric vapor–liquid equilibrium data for two binary systems   n-hexane+ 1, 2-dimethoxyethane and methylcyclopentane+ 1, 2-dimethoxyethane   at 101.3 kPa, Journal of Chemical & Engineering Data, 2018, 63(2):   395-401.

[16] Ma, S.; Shang, X.; Li, J.; Li, L.;   Sun, Y.; Yang, Y.; Sun, L.; Liquid–liquid extraction of benzene using low   transition temperature mixtures: COSMO-SAC predictions and experiments, Journal   of Chemical & Engineering Data, 2018, 63(12): 4749-4760.

[17] Ma, S.; Li, J.; Li, L.; Shang, X.;   Liu, S.; Xue, C.; Sun, L.; Liquid–liquid extraction of benzene and   cyclohexane using sulfolane-based low transition temperature mixtures as   solvents: Experiments and simulation, Energy & Fuels, 2018, 32(7):   8006-8015.

[18] Zhu, M.; Hou, Y.; Yu, N.; Chen, M.;   Ma, Z.; Sun, L.; Design and control of a middle-vessel batch distillation for   separating DMC–EMC–DEC mixture, Chinese Journal of Chemical Engineering,   2018, 26(9): 1837-1844.

[19] Wang, J.; Yu, N.; Chen, M.; Cong, L.;   Sun, L.; Composition control and temperature inferential control of dividing   wall column based on model predictive control and PI strategies, Chinese   Journal of Chemical Engineering, 2018, 26(5): 1087-1101.

[20] Li, L.; Guo, L.; Tu, Y.; Yu, N.;   Sun, L; Tian, Y; Li, Q.; Comparison of different extractive distillation   processes for 2-methoxyethanol/toluene separation: Design and control. Computers   & Chemical Engineering, 2017, 99: 117-134.

[21] Chen, M.; Yu, N.; Cong, L.; Wang,   J.; Zhu, M.; Sun, L.; Design and control of a heat pump-assisted azeotropic   dividing wall column for EDA/water separation, Industrial &   Engineering Chemistry Research, 2017, 56(34): 9770-9777.

[22] Yu, N.; Li, L.; Chen, M.; Wang, J.;   Liu, D.; Sun, L.; Novel reactive distillation process with two side streams   for dimethyl adipate production, Chemical Engineering and Processing:   Process Intensification, 2017, 118: 9-18.

[23] Ma, S.; Yu, Q.; Hou, Y.; Li, J.;   Li, Y.; Ma, Z.; Sun, L.; Screening monoethanolamine as solvent to extract   phenols from alkane, Energy & Fuels, 2017, 31(11): 12997-13009.

[24] Ma, S.; Hou, Y.; Sun, Y.; Li, J.;   Li, Y.; Sun, L.; Simulation and experiment for ethanol dehydration using low   transition temperature mixtures (LTTMs) as entrainers, Chemical   Engineering and Processing: Process Intensification, 2017, 121: 71-80.

[25] Li, L.; Tu, Y.; Sun, L.; Hou, Y.;   Zhu, M.; Guo, L.; Li, Q; Tian, Y.; Enhanced efficient extractive distillation   by combining heat-integrated technology and intermediate heating, Industrial   & Engineering Chemistry Research, 2016, 55(32): 8837-8847.

[26] Li, L.; Sun, L.; Yang, D.; Zhong,   W.; Zhu, Y.; Tian, Y.; Reactive dividing wall column for hydrolysis of methyl   acetate: Design and control, Chinese Journal of Chemical Engineering,   2016, 24(10): 1360-1368.

[27] Zhai, J.; Liu, Y.; Li, L.; Zhu, Y.;   Zhong, W.; Sun, L.; Applications of dividing wall column technology to   industrial-scale cumene production, Chemical Engineering Research and   Design, 2015, 102: 138-149.

[28] Li, L.; Sun, L.; Wang, J.; Zhai, J.;   Liu, Y.; Zhong, W.; Tian, Y.; Design and control of different pressure   thermally coupled reactive distillation for methyl acetate hydrolysis, Industrial   & Engineering Chemistry Research, 2015, 54(49): 12342-12353.

[29] Liu, Y.; Zhai, J.; Li, L.; Sun, L.;   Zhai, C.; Heat pump assisted reactive and azeotropic distillations in   dividing wall columns, Chemical Engineering and Processing: Process   Intensification, 2015, 95: 289-301.

[30] Sun, L.; Wang, Q.; Li, L.; Zhai,   J., Liu, Y.; Design and control of extractive dividing wall column for   separating benzene/cyclohexane mixtures, Industrial & Engineering   Chemistry Research, 2014, 53(19): 8120-8131.

[31] Sun, L.; Bi, X.; Shortcut method   for the design of reactive dividing wall column, Industrial &   Engineering Chemistry Research, 2014, 53(6): 2340-2347.

2.Patent

[1] Gas-liquid distributor and   gas-liquid distribution disc, 201921503100.0

[2] Gas-liquid distributor and   gas-liquid distribution disc, 201921449004.2

[3] Jet swirl type gas-liquid distributor,   201921234142.9

[4] Production method for linear   alkylbenzenes, 201810079546.9

[5] Equipment and method for preparing   isophorone through acetone gas phase condensation

, 201710766032.6

[6] Equipment and method for producing dimethyl   adipate, 201610628645.9

[7] Apparatus and method for producing   dimethyl adipate, 201610634150.7

[8] Process and device for separating   turpentine oil through heat pump distillation of partition tower,   201610452203.3

[9] Heavy oil catalytic cracking process   for producing heavy and light arene products in productive mode, 201510493527.7

[10] Method for producing aromatic   hydrocarbon to the maximum from heavy oil, 201510493528.1

[11] Catalyst used for preparing   isobutene through isobutane dehydrogenation and preparation method and   application thereof, 201410841652.8

[12] Catalyst used for preparing   isobutene through isobutane dehydrogenation and preparation method and   application thereof, 201410841699.4

[13] Method for separating   methylcyclohexane and toluene through differential pressure thermal coupling   extractive rectification, 201210051656.7

◎Representative Works

[1] 《过程工业能量系统优化:换热网络与蒸汽动力系统》, Chemical   Industrial Press, 2021

[2] 《换热器工艺设计》Second Edition, China Petrochemical Press,   2019

[3] 《过程模拟实训—Aspen HYSYS教程》Second   Edition, China Petrochemical Press, 2018

[4] 《化工过程模拟实训—Aspen Plus教程》Second   Edition,Chemical Industrial Press, 2017

[5] 《过程模拟实训—Pro/Ⅱ教程》，China   Petrochemical Press，2017

◎Awards and Honors

[1] Guided by engineering ability, build   a talent training system for chemical engineering, the first prize of higher   education teaching achievements in Shandong Province, 2018

[2] China University of Petroleum (East   China) low carbon energy and chemical engineering innovation team (innovation   team project), first prize of Qingdao scientific and technological progress,   2018

[3] Development and application of   three-dimensional composite tray with high efficiency, high throughput and   high operational flexibility and its supporting tower internals, first prize   of scientific and technological progress of Shandong Province, 2012

◎Courses Offered

Undergraduate：“Chemical process   simulation”“Principles of chemical engineering”

Postgraduate：“Progress in chemical   reaction and separation engineering” “advanced   separation engineering”“Chemical system engineering”

◎Student Training

1.Supervise Postgraduate Students

As of 2021, there are 8 doctoral   students and 69 graduate students. Most graduates sign contracts with   well-known enterprises such as Sinopec, PetroChina, Wanhua Chemical Group   Co., Ltd. and Zhejiang Supcon Technology Co..

2.Admissions Instructions：

Major: Chemical Engineering and technology, materials and chemical   engineering

Admission requirements:

Good ideological and moral character.

Strong English ability, able to read English literature.

Solid basic knowledge, strong innovation spirit and scientific research   ability.

◎Part-time Academic Job

Reviewer of Journal of “Industrial &   Engineering Chemistry Research” “Separation and Purification Technology” “Chemical   Engineering and Processing-Process Intensification” “Chemical Engineering   & Technology” “Journal of Chemical & Engineering Data” “China Petroleum   Processing & Petrochemical Technology” and “CIESC Journal”