A study of vortex-induced energy harvesting from water using PZT piezoelectric cantilever with cylindrical extension R Song, X Shan, F Lv, T Xie Ceramics International 41, S768-S773, 2015 | 156 | 2015 |
Enhancing the performance of an underwater piezoelectric energy harvester based on flow-induced vibration X Shan, H Li, Y Yang, J Feng, Y Wang, T Xie Energy 172, 134-140, 2019 | 100 | 2019 |
Novel energy harvesting: A macro fiber composite piezoelectric energy harvester in the water vortex X Shan, R Song, B Liu, T Xie Ceramics International 41, S763-S767, 2015 | 96 | 2015 |
A novel tunable multi-frequency hybrid vibration energy harvester using piezoelectric and electromagnetic conversion mechanisms Z Xu, X Shan, D Chen, T Xie Applied Sciences 6 (1), 10, 2015 | 84 | 2015 |
A curved panel energy harvester for aeroelastic vibration X Shan, H Tian, D Chen, T Xie Applied Energy 249, 58-66, 2019 | 78 | 2019 |
A novel piezoelectric energy harvester using the macro fiber composite cantilever with a bicylinder in water R Song, X Shan, F Lv, J Li, T Xie Applied Sciences 5 (4), 1942-1954, 2015 | 70 | 2015 |
A broadband piezo-electromagnetic hybrid energy harvester under combined vortex-induced and base excitations C Hou, C Li, X Shan, C Yang, R Song, T Xie Mechanical Systems and Signal Processing 171, 108963, 2022 | 67 | 2022 |
A 2DOF hybrid energy harvester based on combined piezoelectric and electromagnetic conversion mechanisms H Wang, L Tang, Y Guo, X Shan, T Xie Journal of Zhejiang University SCIENCE A 15 (9), 711-722, 2014 | 61 | 2014 |
Titanium wire drawing with longitudinal-torsional composite ultrasonic vibration C Yang, X Shan, T Xie The International Journal of Advanced Manufacturing Technology 83, 645-655, 2016 | 58 | 2016 |
Experimental study on titanium wire drawing with ultrasonic vibration S Liu, X Shan, K Guo, Y Yang, T Xie Ultrasonics 83, 60-67, 2018 | 57 | 2018 |
A new energy harvester using a piezoelectric and suspension electromagnetic mechanism X Shan, S Guan, Z Liu, Z Xu, T Xie Journal of Zhejiang University SCIENCE A 14 (12), 890-897, 2013 | 53 | 2013 |
Capturing flow energy from ocean and wind Y Gong, Z Yang, X Shan, Y Sun, T Xie, Y Zi Energies 12 (11), 2184, 2019 | 52 | 2019 |
An asymmetric bending-torsional piezoelectric energy harvester at low wind speed J Jia, X Shan, D Upadrashta, T Xie, Y Yang, R Song Energy 198, 117287, 2020 | 51 | 2020 |
Design and experimental evaluation of a novel stepping linear piezoelectric actuator W Chen, Y Liu, Y Liu, X Tian, X Shan, L Wang Sensors and Actuators A: Physical 276, 259-266, 2018 | 49 | 2018 |
Direction-adaptive energy harvesting with a guide wing under flow-induced oscillations Y Gong, X Shan, X Luo, J Pan, T Xie, Z Yang Energy 187, 115983, 2019 | 44 | 2019 |
Parametric analysis and experimental verification of a hybrid vibration energy harvester combining piezoelectric and electromagnetic mechanisms Z Xu, X Shan, H Yang, W Wang, T Xie Micromachines 8 (6), 189, 2017 | 43 | 2017 |
Energy-harvesting performances of two tandem piezoelectric energy harvesters with cylinders in water X Shan, R Song, M Fan, T Xie Applied Sciences 6 (8), 230, 2016 | 41 | 2016 |
A new mathematical model for a piezoelectric-electromagnetic hybrid energy harvester X Shan, Z Xu, R Song, T Xie Ferroelectrics 450 (1), 57-65, 2013 | 40 | 2013 |
An energy harvester combining a piezoelectric cantilever and a single degree of freedom elastic system H Wang, X Shan, T Xie Journal of Zhejiang University SCIENCE A 13 (7), 526-537, 2012 | 39 | 2012 |
Design and modeling of a magnetic-coupling monostable piezoelectric energy harvester under vortex-induced vibration C Hou, X Shan, L Zhang, R Song, Z Yang IEEE Access 8, 108913-108927, 2020 | 37 | 2020 |