THE INTERNATIONAL CONFERENCE ON ADVANCED MATERIAL AND TECHNOLOGY (ICAMT) 2021
This article introduces a simulation study on an innovative electromagnetic energy harvesting tec... more This article introduces a simulation study on an innovative electromagnetic energy harvesting technology which includes flexible planar membrane with planar arm for efficient electrical power generator. The study also includes a mechanism for capturing mechanical vibration by cantilever membrane and how that membrane adariyah oscillates along three axis directions of motion. The system consists of a flexible membrane with four planar spring arms on which a permanent magnet is attached. The membrane with attached permanent magnet will be oscillating above the coil and produces electromagnetic field coupling around the magnet which then induces the coil and generates an electric current. This result could produce electrical potential difference of low energy devices. The example of the devices that used this application is actuator and sensor. In this study, the design of the membrane having four spring arm is studied. The design approach has been simulated using FE analysis and discussed in detail in this article. The results show that the planar arm enables to move uniformly. The number of spring arm and the thickness of the membrane significantly affect the deformation capability of the membrane.
International Journal of Mechanical Engineering and Robotics Research, 2019
An electromagnetic (EM) micro-actuator with silicon membrane has been fabricated and characterize... more An electromagnetic (EM) micro-actuator with silicon membrane has been fabricated and characterized. The studied silicon based membrane is used as an actuator of a micropump system driven by magnetic force. The actuator consists of two main parts, namely, the electromagnetic part that generates electromagnetic field and the magneto mechanical part that enables the membrane deformation depending on the magnetic force strength on the silicon membrane. A standard Micro Electronic Mechanical System (MEMS) process was implemented to fabricate the actuator with an additional bonding between the actuator membrane and electromagnetic coil. The measurement results show that the 20 μm thin silicone membrane is capable of deformation with a maximum membrane deflection of approximately 4.5 μm which will be useful for a reliable fluids pump in a continuous drug delivery system.
THE INTERNATIONAL CONFERENCE ON ADVANCED MATERIAL AND TECHNOLOGY (ICAMT) 2021
This article introduces a simulation study on an innovative electromagnetic energy harvesting tec... more This article introduces a simulation study on an innovative electromagnetic energy harvesting technology which includes flexible planar membrane with planar arm for efficient electrical power generator. The study also includes a mechanism for capturing mechanical vibration by cantilever membrane and how that membrane adariyah oscillates along three axis directions of motion. The system consists of a flexible membrane with four planar spring arms on which a permanent magnet is attached. The membrane with attached permanent magnet will be oscillating above the coil and produces electromagnetic field coupling around the magnet which then induces the coil and generates an electric current. This result could produce electrical potential difference of low energy devices. The example of the devices that used this application is actuator and sensor. In this study, the design of the membrane having four spring arm is studied. The design approach has been simulated using FE analysis and discussed in detail in this article. The results show that the planar arm enables to move uniformly. The number of spring arm and the thickness of the membrane significantly affect the deformation capability of the membrane.
International Journal of Mechanical Engineering and Robotics Research, 2019
An electromagnetic (EM) micro-actuator with silicon membrane has been fabricated and characterize... more An electromagnetic (EM) micro-actuator with silicon membrane has been fabricated and characterized. The studied silicon based membrane is used as an actuator of a micropump system driven by magnetic force. The actuator consists of two main parts, namely, the electromagnetic part that generates electromagnetic field and the magneto mechanical part that enables the membrane deformation depending on the magnetic force strength on the silicon membrane. A standard Micro Electronic Mechanical System (MEMS) process was implemented to fabricate the actuator with an additional bonding between the actuator membrane and electromagnetic coil. The measurement results show that the 20 μm thin silicone membrane is capable of deformation with a maximum membrane deflection of approximately 4.5 μm which will be useful for a reliable fluids pump in a continuous drug delivery system.
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