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    4 、复杂环境振动微能源采集与应用

      物联网技术的发展使无线传感器广泛应用,其中一项重要的技术是设备实现无线、高效、长时间的稳定工作。本方向面向工业和社会生活中,不同复杂环境下的智能无线监测与传感,针对无线网络节点的长期、可靠供电难题,开展复合能量收集及微能源采集技术的研究与应用。重点围绕能量收集机理分析、MEMS器件设计、低功耗能源管理电路、智能能源管理算法优化、无线组网传输、5G通信等方面,研究能量高效采集、传感网络无线传输与自供电方法。

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      本研究方向由多种项目及经费支持,可提供丰富的资源及学习平台,拥有专业的测试及试验设备,鼓励学生积极参与各种国内外学术交流会议,不断提升个人能力,具有广阔的发展空间。

    学术交流及荣誉

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    相关论文:

            [1] Tingshan Liu, Juan Cui, Yongqiu Zheng, Shanming Bai, Congcong Hao, Chenyang Xue. A self-powered inert-gas sensor based on gas ionization driven by a triboelectric nanogenerator[J]. Nano Energy, 2023, 106:108083. (SCI一区,IF:19.069)

            [2] Shanming Bai, Juan Cui, Yongqiu Zheng, Gang Li, Tingshan Liu, Yabing Liu,Congcong Hao, Chenyang Xue. Electromagnetic-Triboelectric Energy Harvester Based on Vibration-to-Rotation Conversion for Human Motion Energy Exploitation[J]. Applied Energy, 2023, 329:120292. (SCI一区,IF:11.446)

            [3] Ru Wang, Juan Cui, Yabing Liu, Dan Liu, Chunhui Du, Shubin Yan, Yongqiu Zheng, Chenyang Xue. Multi-pulse triboelectric nanogenerator based on micro-gap corona[J]. Energy, 2021, 244:122588. (SCI一区,IF:8.857)

            [4] Gang Li, Juan Cui, Tingshan Liu, Yongqiu Zheng, Congcong Hao, Xiaojian Hao and Chenyang Xue. Triboelectric-Electromagnetic Hybrid Wind-Energy Harvester with a Low Startup Wind Speed in Urban Self-Powered Sensing[J]. micromachines, 2023, 14,298. (SCI三区,IF:3.523)

            [5] Yu Li, Juan Cui, Gang Li, Lu Liu, Yongqiu Zheng, Junbin Zang and Chenyang Xue. An Optimal Design Method for Improving the Efficiency of Ultrasonic Wireless Power Transmission during Communication[J]. sensors, 2022, 22,727. (SCI三区,IF:3.847

            [6] Xiaobin Xue, Zengxing Zhang, Bin Wu, Shanshan He, Qiang Wang, Wenjun Zhang, Ruiyu Bi, Juan Cui, Yongqiu Zheng, Chenyang Xue. Coil-levitated hybrid generator for mechanical energy harvesting and wireless temperature and vibration monitoring [J]. Science China Technological Sciences, 2020. (SCI二区,IF:3.572)

            [7] Congcong Hao, Jian He, Cong Zhai, Wei Jia, Linlin Song, Jundong Cho, Xiujian Chou, Chenyang Xue. Two-dimensional triboelectric-electromagnetic hybrid nanogenerator for wave energy harvesting [J]. Nano Energy, 2019, 58: 147-157. (SCI一区,IF:19.069)

            [8] CongZhai, Xiujian Chou, Jian He, Linlin Song, Zengxing Zhang, Tao Wen, Zhumei Tian, Xi Chen, Wendong Zhang, Zhichuan Niu, Chenyang Xue. An electrostatic discharge based needle-to-needle booster for dramatic performance enhancement of triboelectric nanogenerators [J]. Applied Energy, 2018, 231: 1346-1353.

            [9] Zengxing Zhang, Kang Du, Xi Chen, Chenyang Xue, Kaiying Wang. An air-cushion triboelectric nanogenerator integrated with stretchable electrode for human-motion energy harvesting and monitoring [J]. Nano Energy, 2018, 53: 108-115. (SCI一区,IF:19.069)

            [10] Zengxing Zhang, Jian He, Tao Wen, Jianqiang Han, Jiliang Mu, Wei Jia, Binzhen Zhang, Wendong Zhang, Xiujian Chou, Chenyang Xue. Magnetically levitated-triboelectric nanogenerator as a self-powered vibration monitoring sensor [J]. Nano Energy, 2017, 33: 88-97. (SCI一区,IF:19.069)

            [11] Chenyang Xue, Junyang Li, Qiang Zhang, Zhibo Zhang, Zhenyin Hai, Libo Gao, Ruiting Feng, Jun Tang, Jun Liu, Wendong Zhang, Dong Sun. A Novel Arch-Shape Nanogenerator Based on Piezoelectric and Triboelectric Mechanism for Mechanical Energy Harvesting [J]. Nanomaterials, 2015, 5: 36-46. (SCI一区,IF:5.719)

            [12] Zekun Wang, Juan Cui, Mingshuo Luan, Congcong Hao, Yongqiu Zheng and Chenyang Xue. Robotic pressure sensing sensor based on triboelectric nanogenerator[C]. The 2023 IEEE International Conference on Real-time Computing and Robotics, 2023. (IEEE国际学术会议)

            [13] Shanming Bai, Juan Cui, Zhidong Zhang, Yongqiu Zheng and Chenyang Xue. Manipulative Control Algorithm of Moxibustion Robot Based on 6-DOF Manipulator [C]. The 2022 IEEE International Conference on Real-time Computing and Robotics, 2022. (IEEE国际学术会议)

            [14] 白善明,崔娟,张志东,张天生,郑永秋,薛晨阳.基于六自由度机械臂的艾灸机器人手法控制算法[J].科学技术与工程,2023. (中文核心)

            [15] 崔娟,赵阳,李刚,张浩凌,郑永秋.面向航天地面测试环境监测的多源阵列传感器网络[J].兵器装备工程学报,2022. (中文核心)

            [16] 李刚,程博,崔娟,张成飞,郑永秋,郝晓剑,薛晨阳. 面向航天器地面测试的双参量同步采集与无线传输系统设计[J]. 测试技术学报,2022.

            [17] 张浩凌,崔娟,郑永秋,刘亚兵,杨路余,李刚,薛晨阳. 基于低功耗策略的自供电无线状态检测系统研究[J]. 传感技术学报,2022. (中文核心)

            [18] 薛晨阳,张浩凌,崔娟,刘丹,崔丹凤,郑永秋.基于复合振动能量采集器的自供电无线传感微系统研究[J]. 机械工程学报,2021. (中文EI)

    相关专利:

            [1] 刘丹,白善明,薛晨阳,郑永秋,崔娟,赵亚欣. 基于振动环境的旋转-悬浮复合式电磁发电装置: 21652634.7[P]. 2022-01-04.

            [2] 崔娟,郝聪聪,白善明,郑永秋,薛晨阳,李刚,刘亭杉. 一种抑振-俘能集成型能量采集系统: 20197573.8[P]. 2022-06-03.

            [3] 郑永秋,刘亚兵,崔娟,张益龙,杨路余,梁亚坤,薛晨阳,刘丹,张增星,高翔,王茹,张浩凌,李刚. 基于微间隙电晕放电的高输出性能多脉冲发电机及系统: 10626252.5[P]. 2022-10-25.

            [4] 崔娟,郑永秋,薛晨阳,高翔,郝聪聪,李刚. 一种磁路开关式悬臂梁结构压电-电磁复合振动发电装置: 10078123.1[P]. 

            [5] 崔娟,杨路余,薛晨阳,张益龙,郑永秋,刘亚兵,刘亭杉,李刚,白善明,高翔,祁博文. 基于磁悬浮电磁发电的振动能量采集装置及系统: 11345015.8[P].

    相关项目:

            [1] 国家高技术研究发展计划(“863”计划):面向重型采煤机械在线状态监测微纳系统的三维异质集成技术,2015-20181046万元。

            [2] 国家重点研发计划:高功率密度微纳振动能量收集器技术及矿井装备智能化应用研究,2020-20221229万元。

            [3] 装备重大基础研究项目:xxx结构振动抑制及能源采集研究,2021-202396万元。

            [4] 装备重大基础研究项目课题:xxx动态燃速测试,2021-2023149万元。

            [5] 国家自然科学基金:面向生物混合致动的骨骼肌组织仿生构建及功能诱导研究,2023-202530万元。

            [6] 山西省基础研究计划资助项目青年项目:基于微机器人跨尺度三维操作的仿生人工组织构建研究,2021-20245万元。    

            [7]  xxx高温谱线测试技术服务合同,2022-202360万元。

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