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Prepared by: Mike Tyger Dept. of Electrical and Computer Engineering
ECE5320 Mechatronics Assignment#01: Literature Survey on Sensors and Actuators Topic: AC induction motor Prepared by: Mike Tyger Dept. of Electrical and Computer Engineering Utah State University 3/06/2009
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ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
Outline Reference List Explore Further Major applications Overview Basic working principles Typical Application Major specifications Limitations 4/14/2017 ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
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ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
Reference list Wikipedia, ‘Induction motor ’, en.wikipedia.org/wiki/AC_induction_motor. Wikipedia, ‘Squirrel-cage rotor’, en.wikipedia.org/wiki/Squirrel-cage_rotor. Wikipedia, ‘Slip Ring’, en.wikipedia.org/wiki/Slip_ring. 4/14/2017 ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
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To explore further (survival pointers of web references etc)
Animations of how an AC motor operates Physics of an AC motor 4/14/2017 ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
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ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
Major Applications Drive motor for small household appliances Fans Blenders Vacuums Drive motor for larger applications Pumps Compressors Treadmills Forced air heating system 4/14/2017 ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
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ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
Overview A polyphase sinusoidal voltage passed though the stators of a motor produces a rotating magnetic field. By placing conductive material in the rotor the rotating magnetic field will induce a current in the rotor which will in turn create a magnetic field in the rotor. The rotor magnetic field is opposed by the stator magnetic filed so a torque is generated. 4/14/2017 ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
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ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
Overview - General A 3-Phase power supply creates a rotating magnetic field in an induction motor. Illustration courtesy of wikipedia.org 4/14/2017 ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
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ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
Overview – Slip For a current to be induced the magnetic field in relation to the rotor must be changing so the speed of the rotor will never be the same as the rotational speed of the magnetic field. This difference is known as slip. F = supply frequency P = Number of Stator Poles Ns = speed of the rotating field S = slip 4/14/2017 ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
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Principle – General Operation
An AC induction motor does not have any direct supply onto the rotor. A secondary current is induced in the rotor. To achieve this, stator windings are arranged around the rotor so that when energized with a polyphase supply they create a rotating magnetic field pattern which sweeps past the rotor. This changing magnetic field pattern induces a current in the rotor conductors. These currents create a magnetic field which interacts with the rotating magnetic field created by the stator and the rotor will turn. 4/14/2017 ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
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ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
Principle – Slip For a current to be induced in the rotor, the speed of the rotor and the speed of the rotating magnetic field in the stator must be different. If the rotor reaches the speed of the rotating magnetic field the current will stop being induced and the rotor will slow slightly until a current is re-induced and then the rotor continues as before. The difference between the speed of the rotor and speed of the rotating magnetic field in the stator is called slip. It is the ratio between the relative speed of the magnetic field as seen by the rotor (the slip speed) to the speed of the rotating stator field. 4/14/2017 ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
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ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
Rotor Types Squirrel Cage Rotor Most common type of rotor Slip Ring Rotor Least common type of rotor Solid Core Rotor Simplest rotor to manufacture 4/14/2017 ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
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ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
Squirrel Cage Rotor The core of the rotor is built of a stack of iron laminations. The image above shows only three laminations of the stack but many more are used. Longitudinal conductive bars of aluminum or copper are set into grooves in the laminations and connected together at both ends by shorting rings forming a cage-like shape. 4/14/2017 ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
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ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
Slip Ring Rotor A slip ring rotor replaces the bars of the squirrel cage rotor with windings that are connected to slip rings. A slip ring is a conductive band mounted to and insulated from the motor shaft. If the slip rings are shorted to each other the rotor behaves similarly to the squirrel cage rotor. 4/14/2017 ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
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ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
Solid Core Rotor A solid core rotor uses a solid piece of mild steel for the rotor. The rotation is caused by the induced current 4/14/2017 ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
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Principle – Single Phase Starting
In a single phase induction motor a starting circuit must be used to start rotation of the rotor. A single phase induction motor can rotate in either direction. The starting circuit determines the rotational direction. For small motors it is usual to "shade" the stator poles by means of a single turn of heavy copper wire around one corner of the pole. The current induced in the single turn is out of phase with the supply current and so causes an out-of-phase component in the magnetic field. This imparts sufficient torque to start the motor. Starting torque is very low and efficiency is also reduced. 4/14/2017 ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
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Principle – Starting Larger Motors
Larger motors commonly have a second stator winding which is fed with an out-of-phase current to create a rotating magnetic field. The out-of-phase current may be obtained by putting a capacitor inline with the winding, or the winding may have different values of inductance and resistance from the main winding. 4/14/2017 ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
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ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
Typical Application Washing machine shaded pole pump motor 4/14/2017 ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
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ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
Major Specifications Poles Power (Horsepower or Watts) Voltage Drive Frequency 4/14/2017 ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
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ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
Limitations Speed is not synchronous to drive signal frequency High starting current 4/14/2017 ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
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ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
Cost and availability Cost AC induction motors are not complex to manufacture so cost is extremely reasonable availability Due to large demand AC induction motors are widely available 4/14/2017 ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
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ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
Nonlinearities ADC nonlinearities A High-performance ADC is required since ADC nonlinearity cannot be compensated for. Magnet nonlinearities The Hall elements of the array must be in the linear range of the magnetic field. This range is larger for larger diameter magnets but the field distribution curve is more shallow, resulting in a smaller differential signal. 4/14/2017 ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
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ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
Limitations Highly susceptible to stray magnetic fields Requires precise assembly Possible need for magnetic shielding 4/14/2017 ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
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ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
Limitations Sensors must be placed very accurately around the centerline of the rotational axis. Multiple sensors are typically contained in a single package Sensor must be very accurately placed on PCB Small tolerances of sensor PCB mounting fixtures can increase cost 4/14/2017 ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
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ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
Other Considerations Robustness The non-contact nature of a magnetic encoder makes it fairly robust. The CORDIC can be used to eliminate the effect of stray magnetic fields Hall effect sensors are used in a wide variety of applications 4/14/2017 ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
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ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
Other Considerations The ratio of sensor accuracy to sensor cost is very good for a hall effect rotary encoder 4/14/2017 ECE5320 Mechatronics. Assignment#1 Survey on sensors and actuators
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