姓名：柳长昕

职称：副教授

学位：工学博士

电子邮箱：liu_changxin@dlmu.edu.cn

研究方向：

1. 微型温差发电（MTEG）及摩擦纳米发电（TENG）技术；

2. 水下机器人及智能机械臂；

3. 水下微纳能源复合采集技术；

4. “热触觉”水下多维感知技术

5. 船舶余热利用及效提升；

团队已发表SCI检索论文40余篇，授权发明专利10余项，承担各级课题多项。

部分论文&专利：

[1] Changxin Liu*, Wenxiang Ye, Huaan Li, Jianhao Liu, Cong Zha, Zhuofan Mao, Xinxiang Pan. Experimental study on cascade utilization of ship's waste heat based on TEG-ORC combined cycle[J]. International Journal of Energy Research, 2021, 45(3): 4184-4196.

[2] Ye W X, Liu C X*, Liu J H, Wang H B, Yang S J, Pan X X. Research on TEG-ORC Combined Bottom Cycle for Cascade Recovery from Various Vessel Waste Heat Sources [J]. Arabian Journal for Science and Engineering, 2021. DOI:10.1007/s13369-021-06050-3.

[3] LIU C X*, LIU J H, YE W X, LI H A, ZHAO C,, PAN X X. Study on a new cascade utilize method for ship waste heat based on TEG-ORC combined cycle [J]. Environmental Progress & Sustainable Energy, 2021, 40(5):72-81.

[4] LIU C X*, LI H, YE W X, LIU J H, WANG H B, XU M Y, PAN X X,. Simulation research of TEG-ORC combined cycle for cascade recovery of vessel waste heat [J]. International Journal of Green Energy, 2021, 18(11): 1173-84.

[5] LIU C X*, ZHAO C, LIU J H, WANG J Y, WANG Y, FAN Y H, ZHAO K Y, SHAN B C, QU Z Y, MA K F, XU M Y, PAN X X. Design and study of a combining energy harvesting system based on thermoelectric and flapping triboelectric nanogenerator [J]. International Journal of Green Energy, 2021, 18(12): 1304-10.

[6] LIU C*, ZHAO K, FAN Y, GAO Y, ZHOU Z, LI M, GAO Y , PAN X. A flexible thermoelectric film based on Bi2Te3 for wearable applications [J]. Functional Materials Letters, https://doi.org/10.1142/S179360472251005.

[7] Changxin Liu, Xinxiang Pan, Xiaofeng Zheng Yuying Yan, Weizhong Li, An experimental study of a novel prototype for two-stage thermoelectric generator from vehicle exhaust, Journal of the Energy Institute. 2016, 89(2):271-281.

[8] Liu CX, Li FM, Zhao C, Ye WX, et al. Experiment research of thermal electric power generation from ship incinerator exhaust heat[C]. Earth and Environmental Science. Hubei, China: 2019, 227(2): 022-031.

[9] LIU J, LIU C*, ZHAO C, LI H, QU G, MAO Z, ZHOU Z. Design of Self-powered Environment Monitoring Sensor Based on TEG and TENG[C]; 2021 IEEE 16th International Conference on Nano/Micro Engineered and Molecular Systems (NEMS), Xiamen, PEOPLES R CHINA,2021, pp. 749-753.

[10] ChangxinLiu*, BaichuanShan, NanxiChen, JianhaoLiu, ZhenghuiZhou, QingyongWang, YuGao, YunfeiGao, ZhitaoHan, ZhijianLiu, MinyiXu. A material recognition method underwater application based on Micro Thermoelectric Generator [J]. Sensors and Actuators:A. Physical, DOI:10.1016/j.sna.2022.113503.

[11] Liu Changxin, Liu Jianhao, Shan Baichuan, Mi Jianchun, Xu Minyi. A wind driven rotational direct current triboelectric nanogenerator for self-powered inactivation of seawater microorganisms. Materials Today Energy.

[12] C. X. Liu, W.Z. Li, An Experimental Study of a Two-stage Thermoelectric Generator Using Heat Pipe in Vehicle Exhaust. Distributed Generation and Alternative Energy Journal, 2015. 30(1): p. 15-37.

[13] Changxin Liu，Weizhong Li. An experimental study of a novel prototype for thermoelectric power generation from Vehicle exhaust [J]. Distributed Generation & Alternative Energy Journal. 2013. Vol. 28, No. 4: p.32-48.

[14] X.F. ZHENG, C.X. LIU, R. BOUKHANOUF, Y.Y. YAN*, W.Z. LI, Experimental study of a domestic thermoelectric cogeneration system. Applied Thermal Engineering. 2014, 62(1), 69-79.

[15] X.F. ZHENG, C.X. LIU, Y.Y. YAN*, Q. WANG, A Review of Thermoelectrics Research - Recent developments and potentials for sustainable and renewable energy applications. Renewable and Sustainable Energy Reviews. 2014. 32,486-503.

[16] WANG H, FAN Z Q, ZHAO T C, DONG J L, WANG S Y, WANG Y, XIAO X, LIU C X, PAN X X, ZHAO Y P, XU M Y. Sandwich-like triboelectric nanogenerators integrated self-powered buoy for navigation safety [J]. Nano Energy, 2021, 84.

[17] WANG S, WANG Y, LIU D H, ZHANG Z Y, LI W X, LIU C X, DU T L, XIAO X, SONG L G, PANG H C, XU M Y. A robust and self-powered tilt sensor based on annular liquid-solid interfacing triboelectric nanogenerator for ship attitude sensing [J]. Sensors and Actuators a-Physical, 2021, 317.

[18] 柳长昕等，一种应用于小型岛礁的太阳能温差发电与空气取水一体化装置:CN, 201811172924.4[P].2018.

[19] 柳长昕等，船舶余热回收两级温差发电装置及发电方法:CN, 201710952747.0[P].2017.

[20] 柳长昕等，基于多能互补的船舶余热利用发电系统:CN, 201721797058.9[P].2017.

[21] 柳长昕等，基于TEG-ORC联合循环的船舶余热梯级回收利用系统:CN, 201711387387.0[P].2017.

[22] 柳长昕等，热管式船舶主机废气余热利用温差发电装置:CN, 201721331991.7[P].2017.

[23] 柳长昕等，基于翅片换热的船舶焚烧炉高温废气余热温差发电装置:CN, 201721318987.7[P].2017.

[24] 柳长昕等，采用导热油结构的船舶主机废气余热利用温差发电装置:CN, 201721323099.4[P].2017.

团队项目：

（1）科技部重点研发计划“低频水波能收集的基础与应用研究， 2021YFA1201604”，2021.12-2026.11，2000万元。

（2）科技部重点研发计划“海洋环境安全保障”重点专项，“我国近海典型外来生物入侵灾害风险防控技术和装备研发，2017YFC14046”，2017.05 ~ 2022.04，1488万元。

（3）中央高校重点创新团队项目 “船舶动力系统低碳排放关键技术研究，3132019330”，2019.04 ~ 2022. 04，60万元。

（4）辽宁省自然科学基金项目“基于温差发电的船舶余热利用技术研究，201601063”，10万，2016.09~ 2018.09。

（5）中央高校基本科研业务费项目“基于TEG-ORC联合循环的船舶能效提升技术研究，3132018255”，6万，2018.01~ 2018.12。

（6）中央高校基本科研业务费项目“基于温差发电的船舶节能机理研究，3132016013”，6万，2016.01~ 2016.12。该项目主要开展船舶余热温差发电的机理研究。

（7）中央高校“十三五”重点科研团队项目“船舶综合能源柔性可再生应用创新理论及技术研究，3132016337”，45万，2016.01~ 2019.12。

（8） “中远集团船队综合节能策略研究，2014H0689”，40万，2014.12~ 2016.12。