Magnetic gear is an alternative to mechanical gear, where the magnetic gear has the advantages of no noise, minimum vibration, no maintenance required, increased reliability, overload protection capability, no physical contact between gears, and the resulting torque density is still below the mechanical gear torque density. In this research, the variation of the number of poles and air gap in the amount of torque density produced was carried out. The permanent magnet material used is Neodymium type with a gear ratio of 1:2. In the variation of the number of poles used by pairs of 4 and 8 poles, 8 and 16 poles, 10 and 20 poles, and 12 and 24 poles, in the variation of the air gap used, namely 1 mm, 1.2 mm, 1.3 mm, 1.4 mm and 1.5 mm. Magnetic gear performance can be seen through analysis simulation with the 3D finite element method using Finite Elements Software. The type of simulation used is the magnetostatic analysis method at the processing stage and the transient analysis method at the post-processing stage. From the simulation results, it is concluded that the greater the number of poles, the greater the torque density produced, and the closer the air gap distance will result in a greater torque density. The effect of the number of poles on the torque density is more significant than the effect of the air gap.

Jing Li, Chang-Chun Li, Jing Huang (2016), Transmission Efficiency Analysis and Experiment Research of Gear Box, Advances in Engineering Research (AER), Vol. 105.

Berna Balta, Fazil O. Sonmez, Abdulkadir Cengiz(2015), Speed Losses in V-ribbed belt drives, Mechanism and Machine Theory, Vol. 86, pp. 1-14.

Aleksey Egorov, Konstantin Kozlov, Vladimir Belogusev, (2015), A Method for Evaluation of The Chain Drive Efficiency, Journal of Applied Engineering Science, Vol.13 (4), 341,277-282.

Huibo Zhang, et (2018), Vibration Characteristics Analysis of Planetary Gears with a Multi-Clearance Coupling in Space Mechanism, Energies, 11(2687)

Chongqing Hu,et (2016), Development of a gear vibration indicator and its application in gear wear monitoring,

Mechanical Systems and Signal Processing, Vol. 76-77, pp. 319-366

P. M. Tlali ; R-J. Wang ; S. Gerber (2014), Magnetic gear technologies: A review, International Conference on Electrical Machines (ICEM), pp: 544 – 550.

Furlani, E. P (2000) . Analytical analysis of magnetically coupled multipole cylinders, Journal of Physics D: Applied Physics, Vol. 33, Issue 1, pp. 28-33.

Furlani, E. P. Permanent Magnet And Electormechanical devices. s.l. : Academic Press, 2001.

Yadhu Raj, et (2016), Magnetic Gearing System, International Journal for Innovative Research in Science & Technology (IJIRST), Vol. 2 (12).

Parker, R.J. (1990), Advances in Permanent Magnetism. New York : John Willey and Sons.

Lin Zhou, et (2014), Architecture and magnetism of alnico, Acta Materialia, vol. 74, pp 224–233.

Perdamean Sebayang, et (2011), Ferrite-based material as a permanent magnet for components of electrical generators, Advances in Natural Sciences: Nanoscience and Nano Technology 2.

Arnab Chakraborty, et (2020), Magnetic Properties of SmCo5 + 10 wt% Fe Exchange-Coupled Nanocomposites Produced from Recycled SmCo5, Nanomaterials, 10,1308.

N Menad and A Seron (2017), Characteristics of Nd-Fe-B Permanent Magnets Present in Electronic Components, International Journal of Waste Resources, Vol.7, Issue 1.

Wu, Y.-C., & Wang, C.-W. (2015), Transmitted Torque Analysis of Magnetic gear Mechanism with Rectanguler Magnets. Applied Mathematics & Information sciences, Vol.9,No.2.