* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Download 3-d computer aided simulation
Skin effect wikipedia , lookup
Neutron magnetic moment wikipedia , lookup
Maxwell's equations wikipedia , lookup
Magnetometer wikipedia , lookup
Magnetic monopole wikipedia , lookup
Earth's magnetic field wikipedia , lookup
Giant magnetoresistance wikipedia , lookup
Magnetotactic bacteria wikipedia , lookup
Mathematical descriptions of the electromagnetic field wikipedia , lookup
Magnetoreception wikipedia , lookup
Electromotive force wikipedia , lookup
Magnetochemistry wikipedia , lookup
Multiferroics wikipedia , lookup
Friction-plate electromagnetic couplings wikipedia , lookup
Electric motor wikipedia , lookup
Magnetohydrodynamics wikipedia , lookup
Magnetotellurics wikipedia , lookup
Electricity wikipedia , lookup
Electromagnetic field wikipedia , lookup
Ferromagnetism wikipedia , lookup
Electromagnetism wikipedia , lookup
Electromagnet wikipedia , lookup
History of geomagnetism wikipedia , lookup
Force between magnets wikipedia , lookup
Lorentz force wikipedia , lookup
Superconducting magnet wikipedia , lookup
HOMOPOLAR MICROMOTOR WITH LIQUID METAL ROTOR Teimour Maleki and Babak Ziaie School of Electrical and Computer Engineering, Purdue University, West Lafayette, USA (Tel : +1-765-494-0725; E-mail: [email protected]) ADVISER:CHENG-HSIEN LIU 劉承賢 REPORTER:劉宗和、葉致成 ID:9733530、9733593 TRANDUCERS & EUROSENSORS’07 The 14th international Conference on Solid-State Sensor. Actuator and Microsystems, Lyon. France. June 10-14,2007 Outline Abstract Introduction Algorithm fabrication 3-D computer aided simulation Conclusion Reference Abstract GA homopolar motor concept model MEMS structure introduction First invented in 1821 by the famous ninetieth century English scientist Michael Faraday (1791-1867), he built a type of electric motor which nowadays is referred to as a homopolar motor. Michael Faraday introduction What is “Homopolar” ? -> Requiring only the same electric polarity for its operation, substituting the word “same” with its Greek equivalent homos one arrives at the name homopolar. introduction Homopolar motor Current, magnetic field and magnetic force directions. Here the exerted torque causes the disc to rotate in an anti-clockwise direction. introduction general DC motor introduction Homopolar DC motor compared with other DC motors Advantage Disadvantage simple high current requirement which is typically mitigated by using superconducting wires compact no force ripple do not require current or magnetic field controllers The liquid rotor simplifies electrical connection to the rotating part and reduces friction and power loss. Introduction • Homopolar Motor,made with drywall screw, alkaline cell, wire, and neodymium disk magnet. The screw and magnet contact the bottom of the battery cell and are held up by magnetic attraction. homopolar electric motor • The homopolar micromotor consists of a mercury droplet as the liquid rotor. Algorithm Faraday’s setup: magnet, disk and closing wire. Rotational torques acting on the magnet and on the closing wire. Algorithm Electric field(E) electric charge (q) Magnetic field(B)velocity of the particle (v) Algorithm the force on a point charge due to electromagnetic fields : Lorentz Force Equation Faraday’s law of induction : is the magnetic flux through the loop. is the electromotive force(EMF) experienced. Algorithm Moving charge motor (Ampere’s low) current Magnetic field generator Changing the magnetic field Algorithm B i F Algorithm Fabrication Mercury 2mm Highly doped silicon wafer (0.001 Ω-cm) Neodymium super magnet A micromachined circular hole with the diameter of 2mm. 200μm A small hole was created in Silicon nitride layer using RIE. Fabrication Fig. The optical image of the fabricated device showing the magnet , two layers of high doped silicon wafer ,a SU-8 cap and a Teflon rotor. 3-D COMPUTER AIDED SIMULATION Find the generated electromagnetic force. Ampere’s law Taking divergence of (1) COMSOL 3.3 3-D computer aided simulation The magnetic field in the location of the motor is mostly in z direction. Fig. Simulation result for magnetic field and current distribution in the micromotor 3-D computer aided simulation Fig. The magnetic flux density zFig. the current density distribution in the component magnitude on top of the rotor and top silicon part magnet. The magnet diameter should be as big as possible. The distance between the magnet surface and bottom of the mercury droplet should be kept at a minimum. Increasing the mass of the thickness of the top silicon does not change the electromagnetic force. Result Fig. Electromagnetic force vs. electric current. The output of electrostatic MEMS micromotor which is in the order of pN-m. The high-power MEMS electric induction motors needs power more than 100V . Fig. Measured output RPM vs. current. Because the measurement setup limitations.The author mention that the micromotor can rotate much faster than what is indicate in the figure(300 round per minute (rpm)) Conclusions Successfully simulated and fabricated a homopolar micromotor with a liquid rotor. The simulation result show that important parameters in designing the micromotor are the magnet diameter and the thickness of the bottom silicon which controls the distance between the surface and the bottom the magnet metal liquid. The other important parameter to increase both torque and rpm is the size of the hole in the top silicon which control the path length in the force equation. reference A SIMPLE ROLLING HOMOPOLAR MOTOR(Seán M. Stewart) D.K. Cheng, Field and Wave Electromagnetics, Addison Wesley, 1992. The homopolar motor: A true relativistic engine http://zh.wikipedia.org/wiki/Wiki Thanks of your attention About Silicon Nitride Key Properties High strength over a wide temperature range High fracture toughness High hardness Outstanding wear resistance, both impingement and frictional modes Good thermal shock resistance Good chemical resistance Typical Uses Rotating bearing balls and rollers Cutting tools Engine moving parts — valves, turbocharger rotors Engine wear parts — cam followers, tappet shims Turbine blades, vanes, buckets Metal tube forming rolls and dies Precision shafts and axles in high wear environments Weld positioners