新能源与自驱动智能传感:
57. Shizhong Zhao, Kangqi Fan*, Zewei Ren, Jiuling Zhu, Cheng Li, Xuan Zhang, Hua He, Zehao Hou. Robust maglev hybrid nanogenerator with an airflow-based motion conversion mechanism for exploiting low-frequency mechanical energy. Nano Energy, 2024, 130: 110131. (影响因子 16.3; 中科院 一区; Top Journal)
56. Wang Zhen, Fan Kangqi*, Zhao Shizhong, Wu shuxin, Zhang Xuan, Zhai Kangjia, Li Zhiqi, He Hua. Archery-inspired catapult mechanism with controllable energy release for efficient ultralow-frequency energy harvesting. Applied Energy, 2024, 356: 122400. (影响因子 10.1; 中科院 一区; Top Journal)
55. Shanghao Gu, Weihan Xu, Kunling Xi, Anxin Luo, Kangqi Fan*, Fei Wang. High-performance piezoelectric energy harvesting system with anti-interference capability for smart grid monitoring. Renewable Energy, 2024, 221: 119742. (影响因子 8.1 中科院 一区; Top Journal)
54. Chao Zhang, Boren Zhang, Tao Wen, Kangqi Fan*. An efficient harvester with an autoregulatory driving arm to capture random wind energy. Sensors and Actuators A: Physical, 2024, 368: 115125. (影响因子 4.0; 中科院 二区)
53. Ma Xiaoyu, Fan Kangqi*, Zhang Xuan, Zhao Shizhong, He Hua, Zhang Chao, Tao Kai. A snap-through vibration-rotation modulation mechanism for high-performance low frequency enegry harvester. Mechanical Systems and Signal Processing. 2023, 202: 110717. (中科院 一区; Top Journal)
52. Li Rongchun, Fan Kangqi*, Ma Xiaoyu, Wen Tao, Liu Qingli, Gao Xianming, Zhu Jiuling, Zhang Yan. A rotational energy harvester with a semi-flexible one-way clutch for capturing low-frequency vibration energy. Energy, 2023, 281: 128266. (中科院 一区; Top Journal)
51. Tan Qinxue, Li Rongchun, Ma Xiaoyu, Zhao Hongyuan, Zhao Shizhong, Fan Kangqi*, Zhang Chao, Zhu Zhaofei. A finger-snapping inspired bistable mechanism for converting low-frequency vibrations to high-speed rotation. Smart Materials and Structures, 2023, Online. (中科院 二区)
50. Fan Kangqi*, Wang Chenyu, Zhang Yan, Guo Jiyuan, Li Rongchun, Wang Fei, Tan Qinxue. Modeling and experimental verification of a pendulum-based low-frequency vibration energy harvester. Renewable Energy, 2023, 211: 100-111. (中科院 一区; Top Journal)
49. Tao Kai, Zhao Zhe, Mao Xinhui, Shen Weihe, Qiu Changquan, Qi Huan, Ye Tao, Zhang Xingxu, Wu Jin, Fan Kangqi*, Chang Honglong, Yuan Weizheng. Direct-current long-lasting and highly efficient electret energy harvesting from ultra-low-frequency motions using toothed clutch mechanism. Nano Energy, 2023, 105: 107998. (IF 19.069; 中科院 一区; Top Journal)
48. Zhang Yan, Fan Kangqi*, Zhu Jiuling, Wu Shuxin, Zhang Sheng, Cheng Tinghai, Wang Zhong Lin. Multi-purpose triboelectric-electromagnetic hybrid nanogenerator with a mechanical motion-controlled switch for harvesting low-frequency energy. Nano Energy, 2022, 104: 107867. (IF 19.069; 中科院 一区; Top Journal)
47. Zhang Sheng, Jing Zhaoxu, Wang Xinxian, Fan Kangqi, Zhao Hongwei, Wang Zhong Lin. Enhancing Low-Velocity Water Flow Energy Harvesting of Triboelectric–Electromagnetic Generator via Biomimetic-Fin Strategy and Swing-Rotation Mechanism. ACS Energy Letters, 2022, 7: 4282-4289. (IF 23.991;中科院 一区; Top Journal)
46. Fan Kangqi*, Chen Chenggen, Zhang Baosheng, Li Xiang, Wang Zhen, Cheng Tinghai, Wang Zhong Lin. Robust triboelectric-electromagnetic hybrid nanogenerator with maglev-enabled automatic mode transition for exploiting breeze energy. Applied Energy, 2022, 328: 120218. (IF 11.446; 中科院 一区; Top Journal)
45. Fan Kangqi*, Xia Pengwei, Li Rongchun, Guo Jiyuan, Tan Qinxue, Wei Danmei. An innovative energy harvesting backpack strategy through a flexible mechanical motion rectifier. Energy Conversion and Management, 2022, 264: 115731. (IF 11.533; 中科院 一区; Top Journal)
44. Wu Yipeng, Li Sen, Fan Kangqi, Ji Hongl, Qiu Jinhao. Investigation of an ultra-low frequency piezoelectric energy harvester with high frequency up-conversion factor caused by internal resonance mechanism. Mechanical Systems and Signal Processing, 2022, 162: 108038. (IF 8.934; 中科院 一区; Top Journal)
43. Fan Kangqi, Wei Danmei, Zhang Yan, Wang Peihong, Tao Kai, Yang Rusen. A whirligig-inspired intermittent-contact triboelectric nanogenerator for efficient low-frequency vibration energy harvesting. Nano Energy, 2021, 90, 106576. (IF 17.881; 中科院 一区; Top Journal)
42. Fan Kangqi, Liu Jin, Wei Danmei, Zhang Daxing, Zhang Yun, Tao Kai. A cantilever-plucked and vibration-driven rotational energy harvester with high electric outputs. Energy Conversion and Management, 2021, 244: 114504. (IF 9.709; 中科院 一区; Top Journal)
41. Fan Kangqi, Wang Chenyu, Chen Chenggen, Zhang Yan, Wang Peihong, Wang Fei. A pendulum-plucked rotor for efficient exploitation of ultralow-frequency mechanical energy. Renewable Energy, 2021, 179: 339-350. (IF 8.001; 中科院 一区; Top Journal)
40. Tan Qinxue, Fan Kangqi, Guo Jiyuan, Wen Tao, Gao Libo, Zhou Shengxi. A cantilever-driven rotor for efficient vibration energy harvesting. Energy, 2021, 235: 121326. (IF 7.147; 中科院 一区; Top Journal)
39. Fan Kangqi , Hao Jiayu, Wang Chenyu, Zhang Chao, Wang Weidong, Wang Fei. An eccentric mass-based rotational energy harvester for capturing ultralow-frequency mechanical energy. Energy Conversion and Management, 2021, 241: 114301. (IF 9.709; 中科院 一区; Top Journal)
38. Fan Kangqi, Xia Pengwei, Zhang Yiwei, Qu Hengheng, Liang Geng, Wang Fei, Zuo Lei. Achieving high electric outputs from low-frequency motions through a double-string-spun rotor. Mechanical Systems and Signal Processing, 2021, 155: 107648. (IF 6.823; 中科院 一区; Top Journal)
37. Wu Yipeng, Li Sen, Fan Kangqi, Ji Hongl, Qiu Jinhao. Investigation of an ultra-low frequency piezoelectric energy harvester with high frequency up-conversion factor caused by internal resonance mechanism. Mechanical Systems and Signal Processing, 2021, 162: 108038. (IF 6.823; 中科院 一区; Top Journal)
36. Tao K, Chen Z, Yi H, Zhang R, Shen Q, Wu J, Fan K, et al. Hierarchical Honeycomb-Structured Electret/Triboelectric Nanogenerator for Biomechanical and Morphing Wing Energy Harvesting. Nano-Micro Letters, 2021, 13(1): 1-16. (IF 16.419; 中科院 一区; Top Journal)
35. Fan Kangqi, Liang Geng, Wei Danmei, Wang Weidong, Zhou Shengxi, Tang Lihua. Achieving high-speed rotations with a semiflexible rotor driven by ultralow-frequency vibrations. Applied Physics Letters, 2020, 117: 223901. (中科院 二区, Top Journal, Editor's Pick)
34. Fan Kangqi, Liu Jin, Cai Meiling, Zhang Mingming, Qiu Tian, Tang Lihua. Exploiting ultralow-frequency energy via vibration-to-rotation conversion of a rope-spun rotor. Energy Conversion and Management, 2020, 225: 113433. (IF 9.709; 中科院 一区; Top Journal)
33. Luo Anxin, Zhang Yulong, Dai Xiangtian, Wang Yifan, Xu Weihan, Lu Yan, Wang Min, Fan Kangqi*, Wang Fei*. An inertial rotary energy harvester for vibrations at ultra-low frequency with high energy conversion efficiency. Applied Energy, 279: 115762. (IF 8.426; 中科院 一区; Top Journal)
32. Tan Qinxue, Fan Kangqi*, Tao Kai, Zhao Liya, Cai Meiling. A two-degree-of-freedom string-driven rotor for efficient energy harvesting from ultra-low frequency excitations. Energy, 2020, 196: 117107. (IF 7.147; 中科院 一区; Top Journal)
31. Fan Kangqi, Qu Hengheng, Cai Meiling. A twisting vibration based energy harvester for ultra-low frequency excitations. International Journal of Applied Electromagnetics and Mechanics. 2020, 64: 693-700.
30. Fan Kangqi, Qu Hengheng, Wu Yipeng, Wen Tao, Wang Fei. Design and development of a rotational energy harvester for ultralow frequency vibrations and irregular human motions. Renewable Energy. 2020, 156: 1028-1039.(IF 8.001; 中科院 一区; Top Journal)
29. Xinge Guo, Yulong Zhang, Kangqi Fan, Chengkuo Lee, Fei Wang. A comprehensive study of non-linear air damping and “pull-in” effects on the electrostatic energy harvesters. Energy Conversion and Management, 2020, 203: 112264. (IF 7.181; 中科院 一区; Top Journal)
28. Fan Kangqi, Zhang Yiwei, E Shiju, Tang Lihua, Qu Hengheng. A string-driven rotor for efficient energy harvesting from ultra-low frequency excitations. Applied Physics Letters, 2019, 115: 203903. (IF 3.521; 中科院 二区; Top Journal)
27. Zhengqiu Xie, Baorui Huang, Kangqi Fan, Shengxi Zhou, Wenbin Huang. A magnetically coupled nonlinear T-shaped piezoelectric energy harvester with internal resonance. Smart Materials and Structures, 2019, 28: 11LT01. (IF 3.543; 中科院 二区)
26. Fan Kangqi, Cai Meiling, Wang Fei, et al. A string-suspended and driven rotor for efficient ultra-low frequency mechanical energu harvesting. Energy Conversion and Management, 2019, 198: 111820. (IF 7.181; 中科院 一区; Top Journal)
25. Fan Kangqi, Liang Geng, Zhang Yiwei, Tan Qinxue. Hybridizing linear and nonlinear couplings for constructuring two-degree-of-freedom electromagnetic energy harvesters. International Journal of Energy Research. 2019, 8: 1-16. (IF 3.343; 中科院 三区)
24. Fan Kangqi, Hao Jiayu, Tan Qinxue, Cai Meiling. A monostable hybrid energy harvester for capturing energy from low-frequency excitations. Journal of Intelligent Material Systems and Structures. 2019: 1-17. (IF 2.582; 中科院 三区
23. Fan Kangqi, Cai Meiling, Liu Haiyan, Zhang Yiwei. Capturing energy from ultra-low frequency vibrations and human motion through a monostable electromagnetic energy harvester. Energy, 2019, 169: 356-368. (IF 5.537; 中科院 一区; Top Journal)
22. Fan Kangqi, Tan Qinxue, Liu Haiyan, Zhang Yiwei, Cai Meiling. Improved energy harvesting from low-frequency small excitations through a monostable piezoelectric energy harvester. Mechanical Systems and Signal Processing, 2019, 117: 594-608. (IF 5.005; 中科院 一区; Top Journal)
21. Fan Kangqi, Zhang Yiwei, Liu Haiyan, Cai Meiling, Tan Qinxue. A nonlinear two-degree-of-freedom electromagnetic energy harvester for ultra-low frequency vibrations and human body motions. Renewable Energy, 2019, 138: 292-302. (IF 5.439; 中科院 一区; Top Journal)
20. Fan Kangqi, Tan Qinxue, Liu Haiyan, Cai Meiling, Qu Hengheng. Harvesting energy from twisting vibration of a rotor suspended by a piece of string. Smart Materials and Structures (Letter), 2019, 28: 07LT01. (IF 3.543; 中科院 二区)
19. Fan Kangqi, Liu Shaohua, Liu Haiyan, Zhu Yingmin, Wang Weidong, Zhang Daxing. Scavenging energy from ultra-low frequency mechanical excitations through a bi-directional hybrid energy harvester. Applied Energy, 2018, 216: 8-20.(IF 8.426; 中科院 一区; Top Journal,高被引论文)
18. Fan Kangqi, Tan Qinxue, Liu Haiyan, Zhu Yingmin, Wang Weidong, Zhang Daxing. Hybrid piezoelectric-electromagnetic energy harvester for scavenging energy from low-frequency excitations. Smart Materials and Structures, 2018, 27: 085001.(IF 3.543; 中科院 二区)
17. Fan Kangqi, Tan Qinxue, Zhang Yiwei, Liu Shaohua, Cai Meiling, Zhu Yingmin. A monostable piezoelectric energy harvester for broadband low-level excitations. Applied Physics Letters, 2018, 112: 123901.(IF 3.521; 中科院 二区; Top Journal,高被引论文)
16. Fan Kangqi, Liu Zhaohui, Liu Haiyan, Wang Liansong, Zhu Yingmin, Yu Bo. Scavenging energy from human walking through a shoe-mounted piezoelectric harvester. Applied Physics Letters, 2017, 110: 143902.(IF 3.521; 中科院 二区; Top Journal)
15. Fan Kangqi, Liu Zhaohui, Wang Liansong, Yu Bo. Shoe-mounted piezoelectric energy harvester for collecting energy from human walking. Optics and Precision Engineering, 2017, 25(5): 1272-1280. (In Chinese)
14. Fan Kangqi, Wang Liansong, Zhu Yingmin, Liu Zhaohui, Yu Bo. Performance of a multi-purpose piezoelectric energy harvester. International Journal of Modern Physics B, 2017, 30: 1741007
13. Fan Kangqi, Yu Bo, Zhu Yingmin, Liu Zhaohui, Wang Liansong. Scavenging energy from the motion of human lower limbs via a piezoelectric energy harvester. International Journal of Modern Physics B, 2017, 30: 1741011.
12. Fan Kangqi, Pedrycz Witold. Evolution of public opinions in closed societies influenced by broadcast media. Physica A, 2017, 472: 53~66. (IF 3.263; 中科院 二区)
11. Fan Kangqi, Witold Pedrycz. Opinion evolution influenced by informed agents. Physica A, 2016,462:431-441. (IF 3.263; 中科院 二区)
10. Fan Kangqi, Chang Jianwei, Witold Pedrycz, Liu Zhaohui, Zhu Yingmin. A nonlinear piezoelectric energy harvester for various mechanical motions. Applied Physics Letters, 2015, 106: 223902. (IF 3.521; 中科院 二区; Top Journal)
9. Fan Kangqi, Chang Jianwei, Chao Fengbo. Witold Pedrycz. Design and development of a multipurpose piezoelectric energy harvester. Energy Conversion and Management, 2015, 96: 430-439. (IF 7.181; 中科院 一区; Top Journal)
8. Fan Kangqi, Witold Pedrycz. Emergence and spread of extremist opinions. Physica A, 2015, 436: 87-97. (IF 3.263; 中科院 二区)
7. Fan Kangqi, Xu Chunhui, Wang Weidong. Complete charging for piezoelectric energy harvesting system. Transactions of Tianjin University, 2014, 20(6): 407-414.
6. Fan Kangqi, Xu Chunhui. Transient Charging Behavior of an Energy Harvesting System Using SSHI Interface. Integrated Ferroelectrics, 2014, 154(1): 1-13.
5. Fan Kangqi, Xu Chunhui, Wang Weidong, Fang Yang. Broadband energy harvesting via magnetic coupling between two movable magnets. Chinese Physics B, 2014, 23(8): 084501. (中科院 三区)
4. Fan Kangqi, Chao Fengbo, Zhang Jianguo, Wang Weidong, Che Xiaohuan. Design and experimental verification of a bi-directional nonlinear piezoelectric energy harvester. Energy Conversion and Management, 2014, 86: 561-567.(IF 7.181; 中科院 一区; Top Journal)
3. Kangqi Fan, Zhengfeng Ming, Chunhui Xu, Fengbo Chao. The dynamic characteristics of harvesting energy from mechanical vibration via piezoelectric conversion, Chinese Physics B, 2013, 22(10): 104502. (中科院 三区)
2. Kangqi Fan, Pengfei Zhang, Zhijian Pei. An assessment modelfor collecting and transporting cellulosic biomass, Renewable Energy, 2013, 50(2): 786-794. (IF 5.439; 中科院 一区; Top Journal)
1. Fan Kangqi, Zhang Pengfei, PeiZ J. Ultrasonic vibration-assisted pelletingof wheat straw: a predictive model for pellet density using response surface method. Biofuels, 2012, 3(3): 259-267.
微机电系统研究领域:
11. Fan Kangqi, Jia Jianyuan, Zhu yingmin, and Zhang Xiuyan. Adhesive contact: from atomistic model to continuum model. Chinese Physics B, 2011, 20(4): 043401. (中科院 三区)
10. Fan Kangqi, Wang Weidong, Zhu Yingmin, and Zhang Xiuyan. A multiscale modeling approach to adhesive contact. Science China: Physics, Mechanics & Astronomy. 2011, 54(9): 1680-1686. (中科院 一区)
9. 王卫东, 樊康旗, 贾建援. 一阶速度滑移边界条件下Stokes第二问题的研究. 纳米技术与精密工程, 2012, 10(1): 68-72.
8. 樊康旗, 霍海东, 王波. 球体-平面粘附模型分析. 西安交通大学学报,2011, 45(11): 106-111.
7. 樊康旗, 贾建援, 朱应敏, 刘小院. 原子力显微镜在轻敲模式下的动力学模型. 物理学报, 2007, 56(11): 171-177.
6. Huang Xin-bo, Fan Kang-qi, Sun Qing-dong et al. Influence of interfacial diffusion on mechanical property of vacuum fusion sinter (VFS) WC-Co composite coating. Journal of Iron and Steel Research, 2006, 13(2): 69-72.
5. 樊康旗, 贾建援, 朱应敏, 陈光焱. 基于Hamaker假设的黏着接触弹性模型. 西安交通大学学报, 2007, 41(5): 606-610.
4. 樊康旗, 贾建援. 微机械黏着接触问题的建模和分析. 西安交通大学学报, 2006, 40(11): 1280-1284.
3. 樊康旗, 贾建援, 王卫东. AFM针尖“突跳”研究. 中国机械工程, 2007, 18(3): 339-343.
2. 樊康旗, 贾建援, 朱应敏. 轻敲模式下原子力显微镜的能量耗散机理研究. 西安电子科技大学学报,2007, 34(6): 947-952.
1. 贾建援, 樊康旗, 王洪喜, 朱应敏. 基于两态稳定性原子级存储方式的分子动力学模拟. 西安电子科技大学学报, 2005, 3(25):729-732.