Planar-type micro-electromagnetic actuators using patterned thin film permanent magnets and mesh type coils

• Published in: Sensors and actuators. A. Physical. Vol. 220; pp. 365 - 372
• Main Authors: Zhi, Chao, Shinshi, Tadahiko, Saito, Mikiko, Kato, Kunio
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 01.12.2014
• Subjects: Electromagnetic actuation; Ferromagnetic material; MEMS; Segmentation; Thin film permanent magnet; Thin film permanent magnet; MEMS; Segmentation; Electromagnetic actuation; Ferromagnetic material
• ISSN: 0924-4247; 1873-3069
• DOI: 10.1016/j.sna.2014.10.012

•We proposed several high force density MEMS based electromagnetic actuators.•A high performance thin film permanent magnet is utilized.•The magnetic resistance of the thin film permanent magnet is effectively reduced by segmentation.•Permalloy is used to enhance the magnetic flux density generated by the magnet.•The actuator performance are simulated and experimentally measured. In this paper, we propose several types of planar micro-electromagnetic actuator that can be applied in micro-pumps and micro-valves. The various types each consist of a thin film permanent magnet (TFPM), a micro-coil and, in some cases, a ferromagnetic layer. The magnetic properties of a TFPM with a multilayered structure, comprising 300nm thick NdFeB and 10nm thick Ta layers deposited sequentially, are as high as bulk NdFeB magnets. Conventional micro-electromagnetic actuators consist of a bulk permanent magnet and a spiral micro-coil, whereas the actuators proposed in this paper consist of segmented patterns of TFPM, such as line/space and chessboard patterns, and mesh coils surrounding the segmented patterns. The TFPMs are segmented in order to reduce the demagnetization effect and to generate a large flux density. The proposed micro-coils possess a 2D structure and are easy to fabricate compared with spiral type micro-coils. The results of simulation show that the electromagnetic forces generated by actuators with segmented TFPMs are several times higher than one without segmentation. Furthermore, the actuation force performance is enhanced by covering the TFPM pattern with a ferromagnetic layer of Ni55Fe45 permalloy. The electromagnetic actuators are fabricated by a fully integrated MEMS process. The measured magnetic flux densities generated by the patterned TFPMs agree with the simulated results. The electromagnetic force between the patterned TFPM and the micro-coil is measured by an electronic force balance. Due to alignment errors between the micro-magnet and micro-coil, the experimentally measured forces are from 70% to 90% of the simulated ones.