1 final control introduction thyristors –scr –triac –diac stepping motors summary
TRANSCRIPT
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Final Control
• Introduction• Thyristors
–SCR–TRIAC–DIAC
• Stepping Motors• Summary
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•Thyristor SCR-Silicon Controlled Rectifier Triac Diac etc
A thyristor is a four-layer semiconductor device, consisting of alternating P type and N type materials (PNPN). A thyristor usually has three electrodes: an anode, a cathode, and a gate (control electrode). The most common type of thyristor is the silicon-controlled rectifier (SCR).
Thyristors are used in motor speed controls, light dimmers, pressure-control systems, and liquid-level regulators.
Hockey Puck SCRhttp://www.larkinpower.com/Thyristors.htm
SCR Symbol
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3SCR Origins
A commercially practical solid state rectifier has been operated by engineers at General Electric's Clyde, New York Rectifier Engineering Laboratory. This silicon-controlled rectifier operates in the same manner as a thyratron, and is capable of switching 1000 watts. A power rating of this magnitude is sufficient for most military and commercial applications. The device is expected to be first used in missiles.
The size of the silicon controlled rectifier is approximately twice that of a signal type transistor and 1/100 the size of a thyratron. The predicted life of the device is over 300,000 hours as compared to the 1000 hour life of a thyratron.
(Electronic Design, Jan. 8, 1958, p. 7) The first SCRs were compared to thyratrons because
that's what vacuum-tube era engineers understood. For today's engineer, we'd probably have to reverse the analogy--a thyratron, a gas-filled grid-controlled rectifier, was like an SCR.--Steve Scrupski
Thyratron Power Supply at Fermilab
Technical Papers
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Operation of an SCR
http://www.tpub.com/neets/book7/26c.htm
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SCR Characteristicshttp://www.nteinc.com/Web_pgs/SCR.html
Igate
(turn-on)
Imax
(Main)
Gate Controlled
turn-on time
0.8-25 mA .8-7 Amps
<2 usec
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SCR V-I curvehttp://www.tpub.com/neets/book7/26d.htm
V
I
VAK= 1-1.5 volts
Very HighReverse voltageto break it down
Very High
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SCR Circuit
Characteristics of 2N1595
Peak Reverse Blocking Voltage = 50 voltsRMS Forward Current (max) = 1.6 ampsTypical Gate Trigger Current= 2 mATypical Gate Trigger Voltage= .7 voltsTurn-on time = .8 usec Turn-off time=10 usec
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8SCR Output
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SCR for Overvoltage Protection
Vin
Computer
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Phase Control with an SCR
http://www.fairchildsemi.com/pf/1N/1N4148.html
Characteristics of 2N1595
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11SCR Phase Control
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Diacs andTriacs
• The Diac and Triac are bilateral thyristors, meaning that they conduct current in both directions
• The Diac is designed to conduct when breakdown occurs in both directions The triac is like two parallel SCR’s, with one in each direction.
• Triac’s have less current carrying ability than SCR’s
Diac Triac
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13A Triac Full-Wave Circuit
Τau = RC = .12 msec
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A Triac Full-Wave Circuit
Τau = RC = 3.8 msec
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15Diac-Triac Phase Control
Power Control with Thyristors and Triacs
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Diac-Triac Light Dimmer
http://www.geocities.com/tjacodesign/dimmer/dimmer.html
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Stepper Motors
A stepper motor system is an electro-mechanical rotary actuator that converts electrical pulses into unique shaft rotations. This rotation is directly related to the number of pulses. The speed is synchronous to the rate of pulsing.
Stepper motors feature bi-directional control, built-in braking, variable torque, power control, precision accuracy, high resolution, open-loop control, and direct interface to digital systems. Stepper Motors - General Description
A step motor converts electrical energy into discrete motions or steps. The motor consists of multiple electrical windings wrapped in pairs (phases)
around the outer stationary portion of the motor (stator). The inner portion (rotor) consists of iron or magnetic disks mounted on a shaft
and suspended on bearings. The rotor has projecting teeth which align with the magnetic fields of the
windings. When the coils are energized in sequence by direct current, the teeth follow the sequence and rotate a discrete distance necessary to re-align with
the magnetic field.The number of coil combinations (phases) and the number of teeth determine the
number of steps (resolution) of the motor. For example, a 200 step per rev (spr) motor has 50 rotor teeth times 4 coil combinations to equal 200 spr.
There are no brushes between the rotor and stator assembly; a stepper motor is a multipole (polyphase) brushless DC motor.
These multiple coil pairs can be connected either positive or negative resulting in four unique full steps. When the coils are sequenced correctly, the motor rotates for- ward. When the sequence is reversed, the motor rotates in reverse.
http://www.cs.uiowa.edu/~jones/step/#introduction http://www.doc.ic.ac.uk/~ih/doc/stepper/
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18A Stepper Motor
In the KP4M4-001 stepper motor, the permanent magnet lies North - South along the shaft. It is encased in two "stacks" each with 25 teeth round the rim. The teeth on the South stack are out of phase with the teeth on the North stack by half the gap between teeth as can be seen in the photo of the shaft shown above.
http://www.doc.ic.ac.uk/~ih/doc/stepper/kp4m4/
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SimpleStepper Operation
http://www.st.com/stonline/books/ascii/docs/1679.htm
Permanent Magnet or can also be switched
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Summary
• Introduction• Thyristors
– SCR– TRIAC– DIAC
• Stepping Motors• Summary