Sage Journals: Discover world-class research

Abstract

In this paper, the levitation characteristics of the floating magnet in an airflow energy harvester based on diamagnetic levitation structure is studied by theoretical analysis and simulation calculation. According to the simulation with COMSOL Multiphysics, we obtained the relationship between the inductive voltage and the values of the notch radius, the floating magnet radius and the floating magnet thickness. At the same time, the coil parameters, including inner diameter, outer diameter, wire diameter and coil layer, were analyzed to study the influence of energy conversion factor (ECF) and energy conversion efficiency of the airflow energy harvester. Based on the analysis results, corresponding parameters are selected for experiment. And the results show that the peak voltage is 1.892 V, and the average power is 94.70 mW when the left and right nozzles’ gas flow rate is 3000 sccm. The simulation analysis provides a good reference for parameters selection of the floating magnet and the coil in the diamagnetic airflow energy harvester, which can increase the energy harvesting efficiency of the harvester.

Keywords

Diamagnetic levitation structure energy harvester floating magnet gas flow

Get full access to this article

View all access options for this article.

References

Jeyaraj

Balasubramaniam

Kumara

MAA

, et al. Resource management in cloud and cloud-influenced technologies for internet of things applications. ACM Comput Surv 2023; 55: 1–37.

Abdulkarem

Samsudin

Rokhani

, et al. Wireless sensor network for structural health monitoring: a contemporary review of technologies, challenges, and future direction. Struct Health Monit 2020; 19: 693–735.

Hernandez-Benitez

Balam

Vazquez-Castillo

, et al. An ultra-low-power strain sensing node for long-range wireless networks in carbon nanotube-based materials. IEEE Sensors J 2022; 22: 9778–9786.

Song

Han

, et al. Portable and wearable self-powered systems based on emerging energy harvesting technology. Microsyst Nanoeng 2021; 7: 25.

Guo

Zhang

Fan

, et al. A comprehensive study of non-linear air damping and “pull-in” effects on the electrostatic energy harvesters. Energy Convers Manage 2020; 203: 112264.

Hasan

Muktadir

Alam

. Comparative study of tapered shape bimorph piezoelectric energy harvester via finite element analysis. Forces Mech 2022; 9: 100131.

Wang

Zhang

Wei

, et al. Design and numerical investigation of an ultra-wide bandwidth rolling magnet bistable electromagnetic harvester. Energy 2022; 261: 125311.

Liu

Zhao

, et al. Design and characteristic analysis of magnetostrictive vibration harvester with double-stage rhombus amplification mechanism. Machines 2022; 10: 848.

Liu

Bao

Chen

, et al. Passively adaptive wind energy harvester featuring a double-airfoil bluff body with adjustable attack angles. Mech Syst Signal Process 2023; 185: 109814.

10.

Hou

Shan

, et al. A novel seesaw-like piezoelectric energy harvester for low frequency vibration. Energy 2022; 261: 125241.

11.

Wang

Chen

, et al. Vortex-induced piezoelectric cantilever beam vibration for ocean wave energy harvesting via airflow from the orifice of oscillation water column chamber. Nano Energy 2022; 104: 107870.

12.

Liu

, et al. Experimental study on magnetic coupling piezoelectric-electromagnetic composite galloping energy harvester. Sensors 2022; 22: 8241.

13.

Cao

Tang

Zhang

, et al. A magnetic coupling wind energy harvester for unmanned surface vehicles. Int J Mech Sci 2023; 257: 108543.

14.

Gong

Zhang

, et al. A diamagnetic-airflow hybrid levitation structure. Int J Appl Electromagnet Mech 2020; 62: 341–354.

15.

Cheng

Wang

, et al. Levitation characteristics analysis of a diamagnetically stabilized levitation structure. Micromachines (Basel) 2021; 12: 982.

16.

Zhang

Gong

, et al. A miniaturized gas flow energy harvester using diamagnetically stabilized levitation. Eur Phys J Appl Phys 2020; 92: 10903.

17.

Shao

Wang

, et al. Optimal analysis on coil and rotor in a diamagnetically airflow energy harvester. Int J Appl Electromagnet Mech 2023; 71: 169–181.

18.

Shao

Cheng

, et al. Comparative analysis and experiment verification of diamagnetically stable levitation structure. IEEE Sensors J 2023; 23: 11469–11481.

19.

Simon

Geim

. Diamagnetic levitation: flying frogs and floating magnets. J Appl Phys 2000; 87: 6200–6204.

Geometric decision of the floating magnet and the coil for airflow energy harvester based on push-pull diamagnetic levitation structure

Abstract

Keywords

Get full access to this article

References