Sun Lanyi(Professor)

Published:2022-10-26Author:王兆兴Number of Visits:83

  


  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.comsunlanyi@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)  1990-1994Petroleum 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 Press2017









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”