一、个人简介
陈飞,中共党员,工学博士,教授,博士研究生导师。就职于昆明理工大学化学工程学院,担任院务助理、过程装备与控制工程系主任及专业负责人工作。
入选云南省兴滇英才青年拔尖人才;担任教育部高等学校机械类专业过程装备与控制工程专业分教学指导委员会委员、中国机械工业教育协会新能源与储能工程专业教学委员会委员、云南省太阳能标准化技术委员会委员;获第三届云南省高校教师教学大赛一等奖、云南省优秀博士学位论文、中国大学生机械工程大赛优秀指导教师;获昆明理工大学教学名师、优秀教师、红云园丁奖、教学成果一等奖(排名2/19)。
在教育教学方面:主持云南省教育教学改革研究重点项目、昆明理工大学智慧课程建设项目等共4项;以第一作者发表教改论文2篇;指导学生获中国大学生机械工程创新创意大赛一等奖、西南赛区一等奖等共5项。在科学研究领域:主持国家自然科学基金项目、云南省基础研究计划重点项目、云南省技术开发项目、云南省高层次人才培养支持计划项目等共12项;以第一或通讯作者在Energy Conversion and Management、Energy、Renewable Energy等期刊上发表论文50多篇;在科学出版社独立出版学术专著1本;以第一发明人授权国家发明专利8项。
目前主要从事高效低成本可再生能源系统的研究工作,重点围绕太阳能聚光系统能量转换与储热、智慧光伏系统先进理论与技术集成开展研发与应用。
二、主讲课程
本科生:自动控制原理、微控制器应用技术、电子线路设计
研究生:太阳能光热转换原理、新能源科学与工程、流动与传热测试技术、制冷原理与低温工程
三、主持项目
[1]云南省科技计划基础研究专项(202501AS070118):间歇跟踪的非成像太阳能系统模型构建及其聚光-集热-储能机理研究【重点项目】,2025/03-2028/02
[2]云南省本科高校教育教学改革研究项目(JG2024004):“一谱三跨五举措”相融合的人才培养模式探索与实践——以过程装备与控制工程专业为例【重点项目】,2024/09-2026/08
[3]云南省科技计划基础研究专项(202401AT070363):间隙无光线逃逸的非成像聚光器模型构建与电热联产耦合机制研究,2024/03-2027/02
[4]云南省技术开发项目(2022530103001938):非成像太阳能聚光系统集成研发及应用示范,2022/12-2027/11
[5]国家自然科学基金地区科学基金项目(51866005):高增益太阳能非成像聚光器聚能及光热转换机理研究,2019/01-2022/12
[6]云南省“高层次人才培养支持计划”(YNWR-QNBJ-2019-173):青年拔尖人才专项,2020/01-2024/12
四、出版专著
陈飞.非成像太阳能聚光原理与应用,ISBN:978-7-03-065732-9,北京:科学出版社,2021.12.
五、第一或通讯作者代表性科研论文
[1]EnergyAn optimization design method and optical performance analysis on multi-sectioned compound parabolic concentrator with cylindrical absorber. 2020, 197 (4): 117212
[2]Energy Conversion and ManagementModel building and optical performance analysis on a novel designed compound parabolic concentrator. 2020, 209 (4): 112619
[3]EnergyPreliminary investigation on photo-thermal performance of a novel embedded building integrated solar evacuated tube collector with compound parabolic concentrator. 2020, 202 (6): 117706
[4]Renewable EnergyAnalyzing thermal properties of solar evacuated tube arrays coupled with mini-compound parabolic concentrator. 2020, 153 (12): 155-167
[5]EnergyInvestigation on structural and optical characteristics for an improved compound parabolic concentrator based on cylindrical absorber. 2021, 219 (3): 119683
[6]EnergyModel verification and photo-thermal conversion assessment of a novel facade embedded compound parabolic concentrator. 2021, 220 (4): 119739
[7]Renewable EnergyDesign optimization and optical performance analysis on multi-sectioned compound parabolic concentrator with plane absorber. 2021, 168 (5): 913-926
[8]EnergyDesign and analysis of a novel multi-sectioned compound parabolic concentrator with multi-objective genetic algorithm. 2021, 225 (6): 120216
[9]Renewable EnergyModel construction and optical properties investigation for multi-sectioned compound parabolic concentrator with particle swarm optimization. 2021, 179 (12): 379-394
[10]EnergyModel construction and performance investigation of multi-section compound parabolic concentrator with solar vacuum tube. 2022, 250 (3): 123887
[11]Renewable EnergyConstruction and analysis of a compound parabolic concentrator to eliminate light escape in the interlayer of solar vacuum tube. 2022, 191 (4): 225-237
[12]Renewable EnergyA novel solution method for reflector shape of solar compound parabolic concentrator and verification. 2022, 192 (6):385-395
[13]EnergyModel construction and performance analysis for asymmetric compound parabolic concentrator with circular absorber. 2023, 267 (1): 126597
[14]EnergyConstruction and concentrating performance of a critically truncated compound parabolic concentrator without light escape. 2023, 269 (2): 126843
[15]EnergyPreliminary study on photo-thermal conversion investigation of compound parabolic concentrator for eliminate light escape in vacuum tube interlayer. 2023, 271 (3): 126979
[16]Renewable EnergyPhotothermal conversion performance based on optimized design of multi-section compound parabolic concentrator. 2023, 209 (4): 286-297
[17]Energy Conversion and ManagementModel construction and combined electric-thermal-hydrogen co-production performance for multi-section compound parabolic concentrator. 2023, 289 (5): 117182
[18]EnergyPreliminary investigation on optical performance of linear fresnel lens coupled compound parabolic concentrator. 2023, 278 (5): 127910
[19]EnergySurface construction and optical performance analysis of compound parabolic concentrator with concentrating surface separated from absorber. 2023, 282 (7): 128432
[20]EnergyOptical and thermal performance-cost evaluation for different segmentation of a novel equal-length multi-section compound parabolic concentrator. 2023, 283 (8): 128483
[21]Renewable EnergyModel construction and performance research of the optimized compound parabolic concentrator based on critical truncation and multi-section congruent. 2023, 217 (8): 119201
[22]EnergyModel construction and performance investigation of compound parabolic concentrator based on satellite solar wing photovoltaic arrays. 2023, 285 (10): 129398
[23]EnergyModel construction and energy harvesting investigation of shell shaped multi-section compound parabolic concentrator with solar vacuum tube. 2024, 294 (2): 130643
[24]EnergyOptical performance investigation for spatially separated non-imaging concentrator with congruent plane concentrating surface.2024, 299 (4):131432
[25]Arabian Journal for Science and EngineeringResearch on the model construction and characteristics of solar radiation received by solar wing coupled with compound parabolic concentrator. 2024, 13369 (6):09278
[26]RenewableEnergyModel construction and photothermal conversion performance of a miniature non-imaging concentrator for capturing solar radiation in full sunlight. 2025, 238 (1):121970
[27]Energy Conversion and ManagementNon-imaging concentrator coupled with all-glass solar superconducting heat pipe and its photothermal conversion characterization studies. 2025, 325 (1):119367
[28]Applied Thermal EngineeringEnhancing thermal energy collection performance for non-imaging concentrating solar system with evacuated tube absorber by heat storage rods.2025, 268 (2):125908
[29]Renewable EnergyEnergy capture and conversion characteristics of asymmetric compound parabolic concentrator with equal-length multi-section design. 2025, 245 (3):122798
[30]Sustainable Energy Technologies and AssessmentsResearch dynamics and applications of tracking technology and devices in solar energy utilization system. 2025, 75 (3):104256
六、第一发明人授权发明专利
[1]一种基于太阳能几何光学的高度测量装置及方法,ZL 201910811165.X
[2]一种自动追踪型太阳散辐射测量仪及测量方法,ZL 202010964623.6
[3]一种圆管型太阳能复合抛物聚光器面形数学模型的构建方法,ZL 201910761568.8
[4]一种面体分离的非成像聚光器及其数学模型的构建方法,ZL 202211565412.0
[5]一种基于非成像聚光作用的高效对射型光电开关,ZL 202310050328.3
[6]一种太阳能真空管光热性能监测装置及监测方法,ZL 202310473202.7
[7]一种太阳能供能的吸收式制冷系统,ZL 201810414567.1
[8]一种基于太阳能真空管吸收体的全等面非成像聚光系统,ZL 202310110542.3
