能源与动力学院
通讯地址:江苏省镇江市丹徒区长晖路666号
个人邮箱:guconghuigch@163.com
邮政编码:212000
办公地点:长山校区能动楼407
传真:
副教授,硕士生导师,博士,主持国家自然科学基金委青年项目、镇江市船舶动力设备性能重点实验室开放课题、烟草工艺过程企业横向课题多项、教育教改项目多项。在Renewable Energy、Fuel Processing Technology、Fuel、Powder Technology、化工学报、化工进展等国内外期刊发表学术论文30余篇,教改论文4篇,授权发明专利7件(含PCT 1件),软件著作权10余件。已指导多名硕士研究生获批江苏省研究生创新计划项目(2023年,2024年,2025年)。
2019年,被江苏科技大学评为师德优秀教师;2020年,被江苏科技大学评为优秀教师;2020年,被江苏科技大学评为优秀学业导师;2020年,被江苏科技大学评为年度考核优秀;2020年,被江苏省高校微课教学组委会评为微课二等奖;2020年,被南京工程热物理学会评为宁镇扬地区高校能源动力类专业青年教师线上授课竞赛一等奖。
招生专业:动力工程及工程热物理,供热、供燃气、通风及空调工程,能源动力、土木水利。
1、气固两相流动与传热传质
2、烟草工艺过程及模拟
3、气液两相混合与雾化过程模拟
4、生物质热解与燃烧
(1)国家自然科学基金青年项目,2020.01-2022.12,主持;
(2)烟草工艺(香糖料雾化)横向课题,2023-2025,主持;
(3)烟草工艺(质量评价体系)相关横向课题,2020.03-2021.03,主持;
(4)烟草工艺(气流烘丝)横向课题,2021.06-2023.06,主持;
(5)2019年镇江市船舶动力设备性能重点实验室开放课题,2019.09-2020.09,主持;
(6)2018年江苏科技大学高等教育立项课题,2018.12-2019.12,主持;
(7)2020年江苏科技大学高等教育立项课题,2020.12-2021.12,主持;
(8)2021年江苏科技大学国际化教育教学研究项目,2021.11-2023.11,主持;
(9)2018年江苏科技大学教育教学改革研究课题,2018.09-2020.12,第二负责人;
1. 用于预测烟丝在滚筒烘丝机内热质传递规律的数值方法 ZL 201811373807.4,发明专利,2020,第一
2. 滚筒烘干机内干燥过程数值模拟系统软件 2020SR0466303,软件著作权,2020,第一
3. 带抄板滚筒内湿颗粒停留时间分布模拟系统 2020SR0746063,软件著作权,2020,第一
4. 高水分烟丝干燥工艺流程分析与调控系统 2021SR0437289,软件著作权,2021,第一
5. 用于研究冷态化颗粒运动特性的流化床实验装置 ZL 202121225287X,实用新型,2021,第一
6. 船用LNG冷能利用冷电联供系统, ZL202011202164.4,发明专利,2022,第一
7. 一种优化有机朗肯循环系统性能的数值方法 PCT221628.0,发明专利,第一
8. 利用LNG冷能和工业余热回收的发电系统及其工作方法, ZL202211274192.6,发明专利,2024,第一
9. 用于提高潮湿颗粒输送均匀性的流化床管道装置,ZL 202011562128.9,发明专利,2025,第一
1.Gu C* , Zhang Y , Liu Y ,et al. Numerical investigation on mixing characteristics of S-shaped biomass particles in a rotary drum[J]. Renewable Energy, 2025, 243:122535. DOI:10.1016/j.renene.2025.122535.
2.Zhu J , Gu C* , Du M ,et al. Experimental study on the motion characteristics of non-spherical biomass particulate systems in a fluidization tube[J].Chemical Engineering Science, 2025, 303:120960. DOI:10.1016/j.ces.2024.120960.
3.Deng K , Gu C*, Zhu J ,et al. Experimental study on flow behavior of wet elongated biomass particles and aggregation-fragmentation evolution of cluster system in a lifting tube[J]. Particuology, 2025, 98:249-264. DOI:10.1016/j.partic.2025.02.004.
4.Zhao Haichao, Gu Conghui*, Xu Bingyang, et al. Numerical analysis on the transport properties and residence time distribution of ribbon biomass particles in a riser reactor based on CFD-DEM approach[J]. Particuology, 2024, 87:133-146.
5.Du M P, Yang J J, Tao Y, Xu B Y, Gu C H*, et al. Experimental Study on the Agglomeration Behavior of Elongated Biomass Particles in a Lifting Tube[J].ACS Omega, 2024, 9(4):4931-4948. DOI:10.1021/acsomega.3c08719.
6.Conghui Gu*, Haichao Zhao, Bingyang Xu, et al. CFD-DEM simulation of distribution and agglomeration characteristics of bendable chain-like biomass particles in a fluidized bed reactor[J]. Fuel, 2023, 340, 127570.
7.Gu C*, Zhang Y, Tang C, Olegovich OV, Gloria KN. Research on synchronous optimization effect of working fluid components and node parameters of organic Rankine cycle (ORC)[J]. Case Studies in Thermal Engineering. 2022, 30:101742.
8.Conghui Gu*, Jiabin Fan, Danping Pan, et al. Effect of baffle structure on the dynamic transportation behavior of s-liked biomass fuels in a rotating drum[J]. Energy Science& Engineering, 2021, 9(5): 743-756.
9.Conghui Gu*, Yujian Zhang, Danping Pan, et al. Visual experimental analysis of the residence time of flexible biomass particles in a baffled rotating cylindrical tube[J]. Energy & Fuels, 2020, 34:1851-1858.
10.Conghui Gu*, Shouguang Yao, Danping Pan, et al. Experimental research on the drying characteristics of flexible fibrous biomass fuels in the baffled-rotary cylinder[J]. Energy & Fuels, 2019, 33:2285-2292.
11.Gu Conghui*, Yuan Zhulin, Sun Shanshan, et al. Simulation investigation of drying characteristics of wet filamentous biomass particles in a rotary kiln[J]. Fuel Processing Technology, 2018,178: 344-352.
12.Conghui Gu, Chao Zhang, Xin Zhang, et al. Modeling and Simulation of Drying Characteristics on Flexible Filamentous Particles in Rotary Dryers. Korean Journal of Chemical Engineering, 2017, 34(1):20-28.
13.Conghui Gu, Zhulin Yuan,Yaming Yan, Dengshan Luo, et al. Experimental Study on Heat and Mass Transfer of Millet in a Fixed Furnace. International Journal of Food Engineering, 2017,13(1).
14.Gu Conghui, Li Peng, Yuan Zhulin, et al. A new corrected formula to predict mean residence time of flexible filamentous particles in rotary dryers. Powder Technology, 2016, 303:168-175.
15.Gu Conghui., Zhang X., Li B., et al. Study on heat and mass transfer of flexible filamentous particles in a rotary dryer[J]. Powder Technology, 2014, 267:234–239.
16.赵海超、许冰洋、张军、顾丛汇*、杨俊杰、袁竹林. 丝状生物质颗粒在矩形提升管内分布特性研究[J]. 太阳能学报, 2023
17.顾丛汇,张玉健,姚寿广. LNG燃料动力渔船冷能利用方案设计及其优化方案分析[J],船舶工程,2022
18.顾丛汇, 范嘉彬, 袁竹林.生物质湿颗粒干燥特性实验与模拟研究[J]. 热力发电, 2021, 50(2): 49-54.
19.顾丛汇, 姚寿广, 袁竹林. 抄板结构对纤丝状生物质颗粒流动特性的影响[J]. 江苏科技大学学报(自然科学版), 2020, 34(4): 35-42.
20.顾丛汇, 李斌,袁竹林等. 散体颗粒在滚筒内运动特性的实验研究与数值模拟[J]. 东南大学学报:自然科学版, 2015, 03(03): 491-496.
21.顾丛汇, 鲁端峰, 袁竹林等. 纤维对PM_(2.5)过滤性能的影响[J]. 化工学报, 2014, 06(06): 2137-2147.
(1)国家自然科学基金青年项目,2020.01-2022.12,主持;
(2)烟草工艺(香糖料雾化)横向课题,2023-2025,主持;
(3)烟草工艺(质量评价体系)相关横向课题,2020.03-2021.03,主持;
(4)烟草工艺(气流烘丝)横向课题,2021.06-2023.06,主持;
(5)2019年镇江市船舶动力设备性能重点实验室开放课题,2019.09-2020.09,主持;
(6)2018年江苏科技大学高等教育立项课题,2018.12-2019.12,主持;
(7)2020年江苏科技大学高等教育立项课题,2020.12-2021.12,主持;
(8)2021年江苏科技大学国际化教育教学研究项目,2021.11-2023.11,主持;
(9)2018年江苏科技大学教育教学改革研究课题,2018.09-2020.12,第二负责人;
1. 用于预测烟丝在滚筒烘丝机内热质传递规律的数值方法 ZL 201811373807.4,发明专利,2020,第一
2. 滚筒烘干机内干燥过程数值模拟系统软件 2020SR0466303,软件著作权,2020,第一
3. 带抄板滚筒内湿颗粒停留时间分布模拟系统 2020SR0746063,软件著作权,2020,第一
4. 高水分烟丝干燥工艺流程分析与调控系统 2021SR0437289,软件著作权,2021,第一
5. 用于研究冷态化颗粒运动特性的流化床实验装置 ZL 202121225287X,实用新型,2021,第一
6. 船用LNG冷能利用冷电联供系统, ZL202011202164.4,发明专利,2022,第一
7. 一种优化有机朗肯循环系统性能的数值方法 PCT221628.0,发明专利,第一
8. 利用LNG冷能和工业余热回收的发电系统及其工作方法, ZL202211274192.6,发明专利,2024,第一
9. 用于提高潮湿颗粒输送均匀性的流化床管道装置,ZL 202011562128.9,发明专利,2025,第一
1.Gu C* , Zhang Y , Liu Y ,et al. Numerical investigation on mixing characteristics of S-shaped biomass particles in a rotary drum[J]. Renewable Energy, 2025, 243:122535. DOI:10.1016/j.renene.2025.122535.
2.Zhu J , Gu C* , Du M ,et al. Experimental study on the motion characteristics of non-spherical biomass particulate systems in a fluidization tube[J].Chemical Engineering Science, 2025, 303:120960. DOI:10.1016/j.ces.2024.120960.
3.Deng K , Gu C*, Zhu J ,et al. Experimental study on flow behavior of wet elongated biomass particles and aggregation-fragmentation evolution of cluster system in a lifting tube[J]. Particuology, 2025, 98:249-264. DOI:10.1016/j.partic.2025.02.004.
4.Zhao Haichao, Gu Conghui*, Xu Bingyang, et al. Numerical analysis on the transport properties and residence time distribution of ribbon biomass particles in a riser reactor based on CFD-DEM approach[J]. Particuology, 2024, 87:133-146.
5.Du M P, Yang J J, Tao Y, Xu B Y, Gu C H*, et al. Experimental Study on the Agglomeration Behavior of Elongated Biomass Particles in a Lifting Tube[J].ACS Omega, 2024, 9(4):4931-4948. DOI:10.1021/acsomega.3c08719.
6.Conghui Gu*, Haichao Zhao, Bingyang Xu, et al. CFD-DEM simulation of distribution and agglomeration characteristics of bendable chain-like biomass particles in a fluidized bed reactor[J]. Fuel, 2023, 340, 127570.
7.Gu C*, Zhang Y, Tang C, Olegovich OV, Gloria KN. Research on synchronous optimization effect of working fluid components and node parameters of organic Rankine cycle (ORC)[J]. Case Studies in Thermal Engineering. 2022, 30:101742.
8.Conghui Gu*, Jiabin Fan, Danping Pan, et al. Effect of baffle structure on the dynamic transportation behavior of s-liked biomass fuels in a rotating drum[J]. Energy Science& Engineering, 2021, 9(5): 743-756.
9.Conghui Gu*, Yujian Zhang, Danping Pan, et al. Visual experimental analysis of the residence time of flexible biomass particles in a baffled rotating cylindrical tube[J]. Energy & Fuels, 2020, 34:1851-1858.
10.Conghui Gu*, Shouguang Yao, Danping Pan, et al. Experimental research on the drying characteristics of flexible fibrous biomass fuels in the baffled-rotary cylinder[J]. Energy & Fuels, 2019, 33:2285-2292.
11.Gu Conghui*, Yuan Zhulin, Sun Shanshan, et al. Simulation investigation of drying characteristics of wet filamentous biomass particles in a rotary kiln[J]. Fuel Processing Technology, 2018,178: 344-352.
12.Conghui Gu, Chao Zhang, Xin Zhang, et al. Modeling and Simulation of Drying Characteristics on Flexible Filamentous Particles in Rotary Dryers. Korean Journal of Chemical Engineering, 2017, 34(1):20-28.
13.Conghui Gu, Zhulin Yuan,Yaming Yan, Dengshan Luo, et al. Experimental Study on Heat and Mass Transfer of Millet in a Fixed Furnace. International Journal of Food Engineering, 2017,13(1).
14.Gu Conghui, Li Peng, Yuan Zhulin, et al. A new corrected formula to predict mean residence time of flexible filamentous particles in rotary dryers. Powder Technology, 2016, 303:168-175.
15.Gu Conghui., Zhang X., Li B., et al. Study on heat and mass transfer of flexible filamentous particles in a rotary dryer[J]. Powder Technology, 2014, 267:234–239.
16.赵海超、许冰洋、张军、顾丛汇*、杨俊杰、袁竹林. 丝状生物质颗粒在矩形提升管内分布特性研究[J]. 太阳能学报, 2023
17.顾丛汇,张玉健,姚寿广. LNG燃料动力渔船冷能利用方案设计及其优化方案分析[J],船舶工程,2022
18.顾丛汇, 范嘉彬, 袁竹林.生物质湿颗粒干燥特性实验与模拟研究[J]. 热力发电, 2021, 50(2): 49-54.
19.顾丛汇, 姚寿广, 袁竹林. 抄板结构对纤丝状生物质颗粒流动特性的影响[J]. 江苏科技大学学报(自然科学版), 2020, 34(4): 35-42.
20.顾丛汇, 李斌,袁竹林等. 散体颗粒在滚筒内运动特性的实验研究与数值模拟[J]. 东南大学学报:自然科学版, 2015, 03(03): 491-496.
21.顾丛汇, 鲁端峰, 袁竹林等. 纤维对PM_(2.5)过滤性能的影响[J]. 化工学报, 2014, 06(06): 2137-2147.
(1)国家自然科学基金青年项目,2020.01-2022.12,主持;
(2)烟草工艺(香糖料雾化)横向课题,2023-2025,主持;
(3)烟草工艺(质量评价体系)相关横向课题,2020.03-2021.03,主持;
(4)烟草工艺(气流烘丝)横向课题,2021.06-2023.06,主持;
(5)2019年镇江市船舶动力设备性能重点实验室开放课题,2019.09-2020.09,主持;
(6)2018年江苏科技大学高等教育立项课题,2018.12-2019.12,主持;
(7)2020年江苏科技大学高等教育立项课题,2020.12-2021.12,主持;
(8)2021年江苏科技大学国际化教育教学研究项目,2021.11-2023.11,主持;
(9)2018年江苏科技大学教育教学改革研究课题,2018.09-2020.12,第二负责人;
1. 用于预测烟丝在滚筒烘丝机内热质传递规律的数值方法 ZL 201811373807.4,发明专利,2020,第一
2. 滚筒烘干机内干燥过程数值模拟系统软件 2020SR0466303,软件著作权,2020,第一
3. 带抄板滚筒内湿颗粒停留时间分布模拟系统 2020SR0746063,软件著作权,2020,第一
4. 高水分烟丝干燥工艺流程分析与调控系统 2021SR0437289,软件著作权,2021,第一
5. 用于研究冷态化颗粒运动特性的流化床实验装置 ZL 202121225287X,实用新型,2021,第一
6. 船用LNG冷能利用冷电联供系统, ZL202011202164.4,发明专利,2022,第一
7. 一种优化有机朗肯循环系统性能的数值方法 PCT221628.0,发明专利,第一
8. 利用LNG冷能和工业余热回收的发电系统及其工作方法, ZL202211274192.6,发明专利,2024,第一
9. 用于提高潮湿颗粒输送均匀性的流化床管道装置,ZL 202011562128.9,发明专利,2025,第一
1.Gu C* , Zhang Y , Liu Y ,et al. Numerical investigation on mixing characteristics of S-shaped biomass particles in a rotary drum[J]. Renewable Energy, 2025, 243:122535. DOI:10.1016/j.renene.2025.122535.
2.Zhu J , Gu C* , Du M ,et al. Experimental study on the motion characteristics of non-spherical biomass particulate systems in a fluidization tube[J].Chemical Engineering Science, 2025, 303:120960. DOI:10.1016/j.ces.2024.120960.
3.Deng K , Gu C*, Zhu J ,et al. Experimental study on flow behavior of wet elongated biomass particles and aggregation-fragmentation evolution of cluster system in a lifting tube[J]. Particuology, 2025, 98:249-264. DOI:10.1016/j.partic.2025.02.004.
4.Zhao Haichao, Gu Conghui*, Xu Bingyang, et al. Numerical analysis on the transport properties and residence time distribution of ribbon biomass particles in a riser reactor based on CFD-DEM approach[J]. Particuology, 2024, 87:133-146.
5.Du M P, Yang J J, Tao Y, Xu B Y, Gu C H*, et al. Experimental Study on the Agglomeration Behavior of Elongated Biomass Particles in a Lifting Tube[J].ACS Omega, 2024, 9(4):4931-4948. DOI:10.1021/acsomega.3c08719.
6.Conghui Gu*, Haichao Zhao, Bingyang Xu, et al. CFD-DEM simulation of distribution and agglomeration characteristics of bendable chain-like biomass particles in a fluidized bed reactor[J]. Fuel, 2023, 340, 127570.
7.Gu C*, Zhang Y, Tang C, Olegovich OV, Gloria KN. Research on synchronous optimization effect of working fluid components and node parameters of organic Rankine cycle (ORC)[J]. Case Studies in Thermal Engineering. 2022, 30:101742.
8.Conghui Gu*, Jiabin Fan, Danping Pan, et al. Effect of baffle structure on the dynamic transportation behavior of s-liked biomass fuels in a rotating drum[J]. Energy Science& Engineering, 2021, 9(5): 743-756.
9.Conghui Gu*, Yujian Zhang, Danping Pan, et al. Visual experimental analysis of the residence time of flexible biomass particles in a baffled rotating cylindrical tube[J]. Energy & Fuels, 2020, 34:1851-1858.
10.Conghui Gu*, Shouguang Yao, Danping Pan, et al. Experimental research on the drying characteristics of flexible fibrous biomass fuels in the baffled-rotary cylinder[J]. Energy & Fuels, 2019, 33:2285-2292.
11.Gu Conghui*, Yuan Zhulin, Sun Shanshan, et al. Simulation investigation of drying characteristics of wet filamentous biomass particles in a rotary kiln[J]. Fuel Processing Technology, 2018,178: 344-352.
12.Conghui Gu, Chao Zhang, Xin Zhang, et al. Modeling and Simulation of Drying Characteristics on Flexible Filamentous Particles in Rotary Dryers. Korean Journal of Chemical Engineering, 2017, 34(1):20-28.
13.Conghui Gu, Zhulin Yuan,Yaming Yan, Dengshan Luo, et al. Experimental Study on Heat and Mass Transfer of Millet in a Fixed Furnace. International Journal of Food Engineering, 2017,13(1).
14.Gu Conghui, Li Peng, Yuan Zhulin, et al. A new corrected formula to predict mean residence time of flexible filamentous particles in rotary dryers. Powder Technology, 2016, 303:168-175.
15.Gu Conghui., Zhang X., Li B., et al. Study on heat and mass transfer of flexible filamentous particles in a rotary dryer[J]. Powder Technology, 2014, 267:234–239.
16.赵海超、许冰洋、张军、顾丛汇*、杨俊杰、袁竹林. 丝状生物质颗粒在矩形提升管内分布特性研究[J]. 太阳能学报, 2023
17.顾丛汇,张玉健,姚寿广. LNG燃料动力渔船冷能利用方案设计及其优化方案分析[J],船舶工程,2022
18.顾丛汇, 范嘉彬, 袁竹林.生物质湿颗粒干燥特性实验与模拟研究[J]. 热力发电, 2021, 50(2): 49-54.
19.顾丛汇, 姚寿广, 袁竹林. 抄板结构对纤丝状生物质颗粒流动特性的影响[J]. 江苏科技大学学报(自然科学版), 2020, 34(4): 35-42.
20.顾丛汇, 李斌,袁竹林等. 散体颗粒在滚筒内运动特性的实验研究与数值模拟[J]. 东南大学学报:自然科学版, 2015, 03(03): 491-496.
21.顾丛汇, 鲁端峰, 袁竹林等. 纤维对PM_(2.5)过滤性能的影响[J]. 化工学报, 2014, 06(06): 2137-2147.
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