一、個人簡介
陳飛,中共黨員,工學(xué)博士,教授,博士研究生導(dǎo)師。就職于昆明理工大學(xué)化學(xué)工程學(xué)院,擔(dān)任院務(wù)助理、過程裝備與控制工程系主任及專業(yè)負責(zé)人工作。
入選云南省興滇英才青年拔尖人才;擔(dān)任教育部高等學(xué)校機械類專業(yè)過程裝備與控制工程專業(yè)分教學(xué)指導(dǎo)委員會委員、中國機械工業(yè)教育協(xié)會新能源與儲能工程專業(yè)教學(xué)委員會委員、云南省太陽能標(biāo)準(zhǔn)化技術(shù)委員會委員;獲第三屆云南省高校教師教學(xué)大賽一等獎、云南省優(yōu)秀博士學(xué)位論文、中國大學(xué)生機械工程大賽優(yōu)秀指導(dǎo)教師;獲昆明理工大學(xué)教學(xué)名師、優(yōu)秀教師、紅云園丁獎、教學(xué)成果一等獎(排名2/19)。
在教育教學(xué)方面:主持云南省教育教學(xué)改革研究重點項目、昆明理工大學(xué)智慧課程建設(shè)項目等共4項;以第一作者發(fā)表教改論文2篇;指導(dǎo)學(xué)生獲中國大學(xué)生機械工程創(chuàng)新創(chuàng)意大賽一等獎、西南賽區(qū)一等獎等共5項。在科學(xué)研究領(lǐng)域:主持國家自然科學(xué)基金項目、云南省基礎(chǔ)研究計劃重點項目、云南省技術(shù)開發(fā)項目、云南省高層次人才培養(yǎng)支持計劃項目等共12項;以第一或通訊作者在Energy Conversion and Management、Energy、Renewable Energy等期刊上發(fā)表論文50多篇;在科學(xué)出版社獨立出版學(xué)術(shù)專著1本;以第一發(fā)明人授權(quán)國家發(fā)明專利8項。
目前主要從事高效低成本可再生能源系統(tǒng)的研究工作,重點圍繞太陽能聚光系統(tǒng)能量轉(zhuǎn)換與儲熱、智慧光伏系統(tǒng)先進理論與技術(shù)集成開展研發(fā)與應(yīng)用。
二、主講課程
本科生:自動控制原理、微控制器應(yīng)用技術(shù)、電子線路設(shè)計
研究生:太陽能光熱轉(zhuǎn)換原理、新能源科學(xué)與工程、流動與傳熱測試技術(shù)、制冷原理與低溫工程
三、主持項目
[1]云南省科技計劃基礎(chǔ)研究專項(202501AS070118):間歇跟蹤的非成像太陽能系統(tǒng)模型構(gòu)建及其聚光-集熱-儲能機理研究【重點項目】,2025/03-2028/02
[2]云南省本科高校教育教學(xué)改革研究項目(JG2024004):“一譜三跨五舉措”相融合的人才培養(yǎng)模式探索與實踐——以過程裝備與控制工程專業(yè)為例【重點項目】,2024/09-2026/08
[3]云南省科技計劃基礎(chǔ)研究專項(202401AT070363):間隙無光線逃逸的非成像聚光器模型構(gòu)建與電熱聯(lián)產(chǎn)耦合機制研究,2024/03-2027/02
[4]云南省技術(shù)開發(fā)項目(2022530103001938):非成像太陽能聚光系統(tǒng)集成研發(fā)及應(yīng)用示范,2022/12-2027/11
[5]國家自然科學(xué)基金地區(qū)科學(xué)基金項目(51866005):高增益太陽能非成像聚光器聚能及光熱轉(zhuǎn)換機理研究,2019/01-2022/12
[6]云南省“高層次人才培養(yǎng)支持計劃”(YNWR-QNBJ-2019-173):青年拔尖人才專項,2020/01-2024/12
四、出版專著
陳飛.非成像太陽能聚光原理與應(yīng)用,ISBN:978-7-03-065732-9,北京:科學(xué)出版社,2021.12.
五、第一或通訊作者代表性科研論文
[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、第一發(fā)明人授權(quán)發(fā)明專利
[1]一種基于太陽能幾何光學(xué)的高度測量裝置及方法,ZL 201910811165.X
[2]一種自動追蹤型太陽散輻射測量儀及測量方法,ZL 202010964623.6
[3]一種圓管型太陽能復(fù)合拋物聚光器面形數(shù)學(xué)模型的構(gòu)建方法,ZL 201910761568.8
[4]一種面體分離的非成像聚光器及其數(shù)學(xué)模型的構(gòu)建方法,ZL 202211565412.0
[5]一種基于非成像聚光作用的高效對射型光電開關(guān),ZL 202310050328.3
[6]一種太陽能真空管光熱性能監(jiān)測裝置及監(jiān)測方法,ZL 202310473202.7
[7]一種太陽能供能的吸收式制冷系統(tǒng),ZL 201810414567.1
[8]一種基于太陽能真空管吸收體的全等面非成像聚光系統(tǒng),ZL 202310110542.3
