梁友才科研成果
发布日期:2024-05-03 专利申请、商标注册、软件著作权、资质办理快速响应 微信:543646
姓名 | 梁友才 | 性别 | 男 |
学校 | 华南理工大学 | 部门 | 电力学院 |
学位 | 教授 | 学历 | 教授 |
职称 | 教授 | 联系方式 | |
邮箱 | liangyoucai@scut.edu.cn | ||
软件产品登记测试全国受理 软件著作权666元代写全部资料全国受理 实用新型专利1875代写全部资料全国受理 |
更新日期:2023年10月12日 姓 名 梁友才 性 别 男 出生年月 1985年9月 籍贯 广西玉林市 民 族 汉族 政治面貌 群众 最后学历 博士研究生毕业 最后学位 工学博士 技术职称 教授 导师类别 博、硕导 行政职务 Email liangyoucai@scut.edu.cn 工作单位 电力学院 邮政编码 通讯地址 单位电话 个人简介 梁友才,华南理工大学电力学院教授,博士生导师,广东省高层次引进人才入选者(2022年)。2015年1月毕业于天津大学内燃机燃烧学国家重点实验室并获得博士学位,2016年-2019年进入英国格拉斯哥大学詹姆斯瓦特工程学院从事博士后研究工作。一直致力于能源高效转化及梯级利用的研究工作。先后获得国家自然科学基金面上项目、省基金等项目7项,参与EPSRC、国家重点基础研究发展计划(973项目)等共5项。发表学术论文50余篇,引用1592次。 研究方向:能源梯级利用,热力循环设计及优化,先进动力循环,制冷技术,分布式能源 工作经历 2015年1月-2016年1月 天津大学 博士后2016年2-2016年11月 天津商业大学 讲师2016年12-2019年12月 格拉斯哥大学 Research Associate2020年9月至今 华南理工大学电力学院 教授 教育经历 2004年9月-2008年7月:本科,车辆工程,昆明理工大学2008年9月-2011年7月:硕士,动力机械及工程,昆明理工大学2011年9月-2014年12月:博士,动力机械及工程,天津大学 获奖、荣誉称号 2008年6月,获“云南省优秀毕业生”;2011年5月,获“云南省三好学生”;2013年12月,获2013年博士研究生国家奖学金;2021年7月,获International Journal of Green Energy期刊“The Most Downloaded Review Paper Award” ;2021年10月,获华南理工大学2020-2021优秀班主任;2022年7月,获International Journal of Green Energy期刊“The Most Downloaded Original Paper Award”;2022年7月,第14届绿色能源国际会议“Best student paper award”指导老师;2022年12月,入选广东省高层次引进人才称号;2023年7月,第15届绿色能源国际会议“Best student paper award”指导老师。2023年7月,华南理工大学2022-2023优秀班主任。 社会、学会及学术兼职 (1) SCI期刊Frontiers in Energy Research (IF=4.008)Associate Editor(2) Applied Science-basel (IF=2.7)Guest Editor(3) 14th International Green energy conference技术委员会成员(4) 14th International conference of green energy分会主席(5) 国家自然科学基金评审专家(6) 广东省自然科学基金评审专家(7) 广东省高层次人才评审专家(8) Applied Energy, Energy Conversion and Management等10余个国际期刊审稿人 研究领域 主要从事热力循环设计及优化相关研究。研究内容主要包括动力循环,热泵系统以及制冷循环的设计,循环优化,联合系统的热经济性评价,联产系统的能量输出管理等。 科研项目 1、华南理工大学“双一流”建设启动基金,2020.09-2026.12,主持2、国家自然科基金面上项目,2022.01-2025.12,主持3、广东省基础与应用基础研究基金面上项目(2022A1515011496),2022.01-2024.12,主持4、广东省基础与应用基础研究基金区域联合基金项目(青年基金项目2020A1515110297) 2020.10-2023.09,主持5、中央高校科研基本业务费项目SCUT (2020ZYGXZR027),2020.1-2021.12,主持6、传热强化与过程节能教育部重点实验室开放课题,2021.1-2021.12,主持7、EPSRC (Ref: EP/N020472/1), 2016.10–2019.12, 第一参与人8、EPSRC (Ref: EP/P028829/1),2017.5 –2020.4,参与 9、天津大学战略布局-产学研培育自主基金,2016.1-2016.12,主持10、国家重点基础研究发展计划(973项目)(NO.2011CB707201),2010年11月-2015年11月,参与11、国家自然科学基金(NO.51206117),2011.1-2015.12,参与12、天津市自然科学基金(NO. 12JCQNJC04400),2012.4-2015.4,参与 发表论文 [1] Shu G, Liang Y, Wei H*, et al. A review of waste heat recovery on two-stroke IC engine aboard ships [J]. Renewable and Sustainable Energy Reviews, 2013, 19: 385-401. (ESI高被引论文)[2] Liang Y, Shu G, Wei H, et al. Effect of oxygen enriched combustion and water–diesel emulsion on the performance and emissions of turbocharged diesel engine [J]. Energy Conversion and Management, 2013, 73: 69-77.[3] Liang Y, Shu G, Tian H, et al. Analysis of an electricity–cooling cogeneration system based on RC–ARS combined cycle aboard ship [J]. Energy Conversion and Management, 2013, 76: 1053-1060. [4] Liang Y, Shu G, Tian H, et al. Theoretical analysis of a novel electricity–cooling cogeneration system (ECCS) based on cascade use of waste heat of marine engine [J]. Energy Conversion and Management, 2014, 85: 888-894. [5] Liang Y, Shu G*, Tian H, Sun Z. Investigation of a cascade waste heat recovery system based on coupling of steam Rankine cycle and NH3-H2O absorption refrigeration cycle [J]. Energy conversion and management, 2018 166: 607-703 [6] Sun Z, Liang Y*, Liu S, et al. Comparative analysis of thermodynamic performance of a cascade refrigeration system for refrigerant couples R41/R404A and R23/R404A [J]. Applied Energy, 2016, 184: 19-25. [7] Liang Y, Al-Tameemi M, Yu Z*. Investigation of a gas-fuelled water heater based on combined power and heat pump cycles [J]. Applied Energy, 2018, 212: 1476-1488 [8] Liang Y, Bian X, Qian W, Pan M*, Ban Z, Yu Z. Theoretical analysis of a regenerative supercritical carbon dioxide Brayton cycle/organic Rankine cycle dual loop for waste heat recovery of a diesel/natural gas dual-fuel engine. Energy Conversion and Management. 2019 Oct 1;197:111845. [9] Liang Y, Yu Z*, Li W. A waste heat driven cooling system based on combined organic Rankine and vapour compression refrigeration cycles. Applied Sciences. 2019 Jan;9(20):4242. [10] Sun Z*, Wang C, Liang Y*, Sun H, Liu S, Dai B. Theoretical study on a novel CO2 two-stage compression refrigeration system with parallel compression and solar absorption partial cascade refrigeration system. Energy conversion and management 2019 Nov 22:112278 [11] Pan M, Zhu Y, Bian X, Liang Y*, Lu F, Ban Z. Theoretical analysis and comparison on supercritical CO2 based combined cycles for waste heat recovery of engine[J]. Energy Conversion and Management, 2020, 219: 113049. [12] Pan M, Bian X, Zhu Y, Liang Y*,Thermodynamic analysis of a combined supercritical CO2 and ejector expansion refrigeration cycle for engine waste heat recovery jector refrigeration. Energy Conversion and Management,2020, 224: 113373. [13] Liang Y, Sun Z, Dong M, Lu J, Yu Z*. Investigation of a refrigeration system based on combined supercritical CO2 power and transcritical CO2 refrigeration cycles by waste heat recovery of engine[J]. International Journal of Refrigeration, 2020, 118:470-482. [14] Sun Z*, Wang Q, Liang Y*, Su D, Sun H, Liu S, Zhao S. Experimental study on improving the performance of dry evaporator with rectifying nozzle type critical distributor. International Journal of Refrigeration, 2020, 111: 39-52.[15] Pan M, Zhu Y, Liang Y*, et al. Performance assessment of a waste-heat driven CO2-based combined power and refrigeration cycle for dual-temperature refrigerated truck application[J]. Energy Conversion and Management, 2021, 249: 114863. [16] Pan M, Huang Y, Zhu Yan, Liang Y*,Yu G*. Co- and Tri- Generation System Based on Absorption Refrigeration Cycle: A Review. International Journal of Green energy,2020: 1-25. (下载量最多综述论文奖,仅1项)[17] Sun Z*, Li J, Liang Y*, Sun H, Liu S, Yang L, Wang C, Dai B. Performance Assessment of CO2 supermarket refrigeration system in different climate zones of China. Energy conversion and management, 2020, 208: 112572. [18] Pan M, Zhao H, Liang D, Zhu Yan, Liang Y*, Bao G. A Review of the Cascade Refrigeration System. Energies 2020, 13, 2254.[19] Liang Y*, Yu Z. Experimental investigation of an Organic Rankine cycle system using an oil-free scroll expander for low grade heat recovery. International Journal of Green energy, 2021, 18(8): 812-821 (下载量最多原创性论文奖,仅1项)[20] Liang Y, Mckeown A, Yu Z*, et al. Experimental study on a heat driven refrigeration system based on combined organic Rankine and vapour compression cycles[J]. Energy Conversion and Management, 2021, 234: 113953.[21] Zhu Y, Liang Y, Liang Y, et al. Analysis of modified CO2 based combined power and ejector-expansion refrigeration cycle with dual evaporators activated by engine exhaust[J]. International Journal of Green Energy, 2023: 1-16.[22] Liang Y, Zhu Y, Sun Z, et al. Feasibility assessment of a CO2 based power, cooling, and heating system driven by exhaust gas from ocean-going fishing vessel [J]. Journal of Cleaner Production, 2023: 137058.[23] Liang Y, Wu J, Zhu Y, et al. Thermodynamic and economic analysis of refrigerant mixture R290/R1234ze used in an ORC-EERC system for low temperature heat sources. Applied Thermal Engineering, 229 (2023): 120635.[24] Liang Y, Ye K, Zhu Y, et al. Thermodynamic analysis of two-stage and dual-temperature ejector refrigeration cycles driven by the waste heat of exhaust gas. Energy 278 (2023): 127862.国际会议报告[23] Liang Y, Shu G. *, Wei H., Liang X., Tian H. Theoretical analysis of a novel electricity-cool cogeneration system driven by a ship diesel engine waste heat based on Rankine-absorption combined cycle, 26th International Conference on Efficiency, Cost, Optimization, Simulation and Environmental Impact of Energy Systems, ECOS 2013; Guilin; China. [24] Liang Y, Shu G*, Tian H, et al. Thermodynamic Analysis of an Electricity-Cooling WHR Cogeneration System Aboard Ships using Siloxanes as Working Fluids [R]. SAE Technical Paper, 2014. Detroit, USA (EI)[25] Liang Y. Theoretical Analysis of a Novel Electricity-Cooling Cogeneration System Based on Waste Heat Recovery of Marine Engine [R]. SAE Technical Paper, 2016. Detroit, USA(EI)[26] Liang Y, Yu Z.*. Working fluid selection for a combined system based on coupling of organic Rankine cycle and air source heat pump cycle. Energy Procedia. 2019 Feb 1;158:1485-90. Hongkong, China. (ISTP)[27] Liang Y, Mckeown A., Yu G., Yu Z.*, Experimental research on a small air-source heat pump with an oil-free scroll compressor. The 5th Sustainable Thermal Energy Management International Conference 2019. Hangzhou, China.[28] Liang Y, Yu Z*, Mckeown A, Theoretical analysis of an ORC-VCR based air conditioning system by heat recovery of jacket coolant. ORC2019, Athens, Greece.[29] Zhu Yan, Pan M, Wang Z, and Liang Y*, Analysis of modified CO2 based combined power and ejector-expansion refrigeration cycle with dual evaporators activated by engine exhaust heat, the 14th International Green Energy Conference (IGEC-XIV), 2022(最佳学生论文,仅3项)[30] Liang Y, Zhu Y, Ye K, Research on waste heat driven CO2 based combined power and ejector refrigeration cycle, 14th International Green Energy Conference (IGEC-XIV) , 2022(特邀报告)[31] Liang Y, Zhu Y, Ye K, Ejector based refrigeration system for engine waste heat recovery, 4th International Symposium on Advanced Measurement, Analysis and Control for Energy and Environment (AMACEE2022), 2022 online (12.15-12.16特邀报告) 科研创新 [1]舒歌群,梁友才,卫海桥等.发明专利,朗肯循环海水淡化双效余热回收系统。公开号:CN103216283A,公告日2013-07-24[2]舒歌群,刘丽娜,梁友才,赵健,田华,于国鹏。两级朗肯循环的柴油机排气余热回收系统,公开号:CN102777240A,公开日:2012-11-14[3]宁静红,梁友才,毛力,朱宗升。柔性转子接触密封的螺杆制冷压缩机,中国CN106351831A,公开日2018-05-11,排名2/4(发明专利)[4]宁静红,梁友才,毛力,朱宗升。带轴向柔动十字联接环的涡旋式压缩机,中国CN1064019544A,公开日2017-02-15,排名2/4(发明专利)[5]李晓宁,舒歌群,李团兵,梁友才,王轩。内燃机蒸汽增压余热回收系统。授权公布号:CN103742293B,授权公布日:2015-05-13, 排名4/5(发明专利)[6]田华,梁友才,舒歌群等.船用发动机的冷电双效余热回收系统。公开:CN103245126A,公告日2013-08-14[7]梁友才,吴锦涛,朱雁,陆继东,钟弘毅,林湛棠,裴越。一种正逆耦合循环冷电联产系统,申请号:202211144549.9 申请日:2022-09-20[8]梁友才,叶俊豪,朱雁,陆继东。一种制冷系统、使用方法及制冷设备,申请号:2022116401302,公开日:2023-04-18[9]梁友才,朱雁,叶凯,吴锦涛,叶俊豪,陆继东。一种太阳能增强型喷射式双温热源热泵空调系统及制冷设备,申请号:202310297237X,公开日:2023-08-11 教学活动 空调用制冷技术,热力发电厂,热管理技术 指导学生情况 在读博士3名:[1] 叶凯 2021级[2] 朱雁 2022级[3] 凌珣杰 2022级 (硕博连读)在读硕士7名:[1] 叶俊豪 2021级[2] 吴锦涛 2021级[3] 丁锦能 2022级[4] 胡成贤 2022级[5] 雷霆 2022级[6] 李正勇 2023级[7] 王建明 2023级 我的团队 以长江学者陆继东教授领衔的能源清洁转化与系统优化团队,团队其他成员:刘定平、卢志民、姚顺春、董美蓉
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