Fabrication and Performance of Silicon-Embedded Permanent-Magnet Microgenerators

Herrault, Florian; Yen, B.; Ji, Chang-Hyeon; Spakovszky, Z. S.; Lang, Jeffrey H.; Allen, Mark G.

doi:10.1109/jmems.2009.2036583

Cited by 24 publications

(16 citation statements)

References 25 publications

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“…The generator exhibited up to 6.6 mW of alternating current (AC) electrical power across a resistive load at a rotation speed of 392 kr/min. In the following year, the same research group fabricated a generator with a laminated magnetic stator core to obtain power of 1.05 W at 200 kr/min [5]. Sun et al presented a three-phase stator coil which delivered 357.3 μW at 10 kr/min with a 0.23 Ω resistor load [6].…”

Section: Introductionmentioning

confidence: 99%

Miniaturized Air-Driven Planar Magnetic Generators

Zhao

Shi

2015

Energies

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This paper presents the design, analysis, fabrication and testing of two miniaturized air-driven planar magnetic generators. In order to reduce the magnetic resistance torque, Generator 1 establishes a static magnetic field by consisting a multilayer planar coil as the stator and two multi-pole permanent-magnet (PM) rotors on both sides of the coil. To further decrease the starting torque and save more space, Generator 2 adopts the multilayer planar coil as the rotor and the multi-pole PMs as the stator, eliminating the casing without compromising the magnetic structure or output performance. The prototypes were tested gathering energy from wind which can work at a low wind speed of 1~2 m/s. Prototype of Generator 1 is with a volume of 2.61 cm 3 and its normalized voltage reaches 485 mV/krpm. Prototype of Generator 2 has a volume of 0.92 cm 3 and a normalized voltage as high as 538 mV/krpm. Additionally, output voltage can be estimated at better than 96% accuracy by the theoretical model developed in this paper. The two micro generators are capable of producing substantial electricity with little volume to serve as compact power conversion devices.

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Section: Introductionmentioning

confidence: 99%

Miniaturized Air-Driven Planar Magnetic Generators

Zhao

Shi

2015

Energies

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“…However, high temperature process is usually not compatible with most of the MEMS technology. For screen printing [2] and electroplating [3] techniques, the control of magnetization direction is a major concern [4].…”

Section: Introductionmentioning

confidence: 99%

Formation and integration of tunable anisotropic magnetic polymer composites by two stages solidification process

Hsu

Chen

et al. 2013

2013 Transducers &Amp; Eurosensors XXVII: The 17th International Conference on Solid-State Sensors, Actuators and Microsystems

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This study exploits a novel two-stage solidification technology to realize anisotropic magnetic polymer composites (MPC, polymer with magnetic powders). The merits of the presented process technology are as follows: (1) magnetic strength of MPC is controlled by weight fraction of magnetic powder, (2) volume of liquid MPC is controlled by pneumatic system, (3) surface of liquid MPC is solidified by UV, and (4) magnetization and solidification of MPC inside the solidified surface. In applications, the polymer-NdFeB composites magnetic structures are realized respectively in liquid and air medium, and further integrate with MEMS structures. The discrete NiFeB-MPC balls (Diameter:500m-3200m) with anisotropic magnetization are achieved. Performances enhancement of NiFeB-MPC (30wt%) by anisotropic magnetization during two-stage solidification are: coercivity force (356%), remanence (61%), and saturation magnetization (75%). Assembly of MPC on MEMS structures and the following driving tests are also demonstrated.

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“…Therefore, the electromagnetic induction type is more desirable than electrostatic type even in the miniaturized generator. Some outstanding studies were reported [3][4][5][6][7][8][9][10][11][12]. Among these studies, milli-watt to watt class generators were achieved.…”

Section: Introductionmentioning

confidence: 99%

Millimeter Scale MEMS Air Turbine Generator by Winding Wire and Multilayer Magnetic Ceramic Circuit

Iizuka¹,

Takato²,

Kaneko³

et al. 2012

MME

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This paper provides a new system and concept concerning to MEMS air turbine power generator. The generator was composed of the MEMS air turbine and the magnetic circuit. The magnetic circuit was fabricated by multilayer magnetic ceramic technology and achieved monolithic structure which included high permeability material and three di-mensional helical conductor patterns inside. Although the output power was micro watt class, some features were extracted by comparing to the simple winding wire type magnetic circuit. In the power density measurement, almost same output power density was extracted though the turn number of the winding wire type was more than that of monolithic type. Also the resistance of the conductor was quarter of the winding type. The maximum output voltage and the maximum power of the monolithic generator was 6.2 mV and 1.92 µVA respectively. The DC conductor resistance was 1.2 Ω. The energy density was 0.046 µVA/mm3. The appearance size of the monolithic type was 3.6, 3.4, 3.5 mm, length, width and height respectively

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Fabrication and Performance of Silicon-Embedded Permanent-Magnet Microgenerators

Cited by 24 publications

References 25 publications

Miniaturized Air-Driven Planar Magnetic Generators

Miniaturized Air-Driven Planar Magnetic Generators

Formation and integration of tunable anisotropic magnetic polymer composites by two stages solidification process

Millimeter Scale MEMS Air Turbine Generator by Winding Wire and Multilayer Magnetic Ceramic Circuit

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