開啟主選單

求真百科

楊慶春,男,合肥工業大學化學與化工學院講師。

目錄

人物履歷

2008年09月–2012年06月,蘭州理工大學石油化工學院化學工程與工藝專業學習,獲工學學士學位;

2012年09月–2017年06月,華南理工大學化學與化工學院化學工程專業學習,獲工學博士學位

研究方向

化工過程模擬與優化;智能化工技術與應用。

研究成果

(1)構建煤制乙二醇/甲醇/烯烴/IGCC/SNG/油等系統多尺度數學模型;

(2)成功開發多種低碳、高效、高經濟效益的煤化工新工藝。

科研項目

(1)安徽省自然科學基金青年科學基金項目,低碳高效的煤制乙二醇過程開發與多目標優化(JZ2019AKZR0236),2019-07至2021-06,10萬元,主持;

(2)安徽昊源化工集團有限公司合作項目,合成氣經草酸二甲酯加氫合成乙二醇新工藝開發(HY202007-555),2020-06至2022-05,12萬元,主持;

(3)合肥工業大學,學術新人提升A計劃項目,JZ2018HGTA0278,煤制乙二醇過程基礎模型、過程開發與優化,2018-05至2019-12,5萬元,主持;

(4)合肥工業大學人才引進計劃項目,煤/油頁岩制油過程全生命周期分析(407-0371000045),2017-07至2018-06,4萬元,主持;

(5)國家自然科學基金面上項目,油頁岩煉製過程油氣提質增效技術創新與系統集成(21676101),2017-01至2020-12,99萬元,參與;

(6)國家科學技術部973項目,熱解油氣提質技術評價與高效煉製過程集成及多目標優化(2014CB744306),2014-01至2018-12,420萬元,參與;

(7)國家自然科學基金委員會重點項目,資源/能源化工過程的全生命周期模型、系統分析與優化(21136003),2012-01至2016-12,300萬元,參與;

(8)國家科學技術部973項目,能量/質量耦合梯級利用的多目標優化綜合(2012CB720504),2012-01至2016-12,150萬元,骨幹參與

獲獎及專利情況

獲獎

安徽省科學技術獎三等獎 1項(2020,排名7/10)

專利

授權發明專利 4項

[1]  一种集成化学链和二氧化碳利用技术的煤制甲醇系统及方法, 2018-3-19, 中国, ZL201810224796.7. 
[2]  一种固体热载体油页岩炼制集成干馏气制氢系统及工艺, 2014-11-17, 中国, ZL201410652443.9. 
[3] 一种油页岩干馏气化学链制氢联合发电系统及工艺, 2014-8-29, 中国, ZL201410436632.2. 
[4] 一种油页岩炼油集成伴生煤气化制氢综合利用系统及工艺, 2014-6-11, 中国, ZL201410259090.6. 

學術成果

著作論文

[1] Conceptual design, techno-economic and environmental evaluation of a coal-based polygeneration process for ethylene glycol and polymethoxy dimethyl ethers production. Journal of Cleaner Production 2021, 298: 126757.

[2] Opportunities for CO2 utilization in coal to green fuel process: optimal design and performance evaluation. ACS Sustainable Chemistry & Engineering 2020, 8: 1329-1342.

[3] Optimal design and exergy analysis of biomass-to-ethylene glycol process. Bioresource Technology 2020, 275: 123972.

[4] Technoeconomic and environmental evaluation of oil shale to liquid fuels process in comparison with conventional oil refining process. Journal of Cleaner Production 2020, 255: 120198.

[5] Technoeconomic and environmental analysis of ethylene glycol production from coal and natural gas compared with oil-based production. Journal of Cleaner Production 2020, 273: 123120.

[6] Comparative techno-economic analysis of oil-based and coal-based ethylene glycol processes. Energy Conversion and Management 2019, 198: 111814.

[7] Thermodynamic and techno-economic analysis of coal to ethylene glycol process (CtEG) with different coal gasifiers. Energy Conversion and Management 2019, 191: 80-92.

[8] Efficient utilization of CO2 in a coal to ethylene glycol process integrated with dry/steam-mixed reforming: conceptual design and techno-economic analysis. ACS Sustainable Chemistry & Engineering 2019; 7: 3496-3510.

[9] Life cycle comparison of greenhouse gas emissions and water consumption for coal and oil shale to liquid fuels. Resources, Conservation and Recycling 2019; 144: 74-81.

[10] Process simulation, analysis and optimization of a coal to ethylene glycol process. Energy 2018; 155: 521-534.

[11] Composite Metric for Simultaneous Technical and Economic Analysis and Optimization of Energy Conversion Processes. Journal of Cleaner Production 2018; 179: 266-277.

[12] Development of a coke oven gas assisted coal to ethylene glycol process for high techno-economic performance and low emission. Industrial & Engineering Chemistry Research 2018; 57: 7600-7612.

[13] Simulation, exergy analysis and optimization of a shale oil hydrogenation process for clean fuels production. Applied Thermal Engineering 2018; 140: 102-111.

[14] Advanced exergy analysis of an oil shale retorting process. Applied Energy 2016; 165: 405-415.

[15] Framework for Advanced Exergoeconomic Performance Analysis and Optimization of an Oil Shale Retorting Process. Energy 2016; 109: 62-76.

[16] Conceptual design and techno-economic evaluation of efficient oil shale refinery process with oil and gas products upgradation. Energy Conversion and Management 2016; 126: 898-908.

[17] Application of House of Quality in evaluation of low rank coal pyrolysis polygeneration technologies. Energy Conversion and Management 2015; 99: 231-241.

[18] Development of an Oil Shale Retorting Process Integrated with Chemical Looping for Hydrogen Production. Industrial & Engineering Chemistry Research 2015; 54: 6156-6164.

[19] 石油與煤路線制乙二醇過程的技術經濟分析. 化工學報 2020; 71(5): 2164-2172.

[20] 集成CO2高效利用的煤制乙二醇過程設計與系統分析. 化工學報 2019; 70(2): 772-779. [1]

參考資料