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。
