Electronic Troubleshooting - PowerPoint PPT Presentation

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Electronic Troubleshooting

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Electronic Troubleshooting Chapter 13 Power Control Devices – PowerPoint PPT presentation

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Title: Electronic Troubleshooting


1
Electronic Troubleshooting
  • Chapter 13
  • Power Control Devices

2
Power Control Devices
  • Characteristics
  • Bipolar and MOSFETs can be used to control large
    loads and motors
  • However they only can control DC Loads and Motors
  • Most large Loads and Motors are AC
  • Types of devices used to control them are
  • SCRs (Silicon Controlled Rectifiers)
  • TRIACs (TRIODE for AC - ??))
  • DIACs (Diode for AC - ??)
  • Ancillary Devices
  • Reed Switches
  • Opto-coupliers

3
Power Control Devices
  • Topics covered
  • SCRs
  • TRIACs
  • Ancillary Devices
  • Reed Switches
  • Opto-coupliers
  • Phase Control
  • Problems with TRIAC and SCR circuits
  • SCRs
  • Characteristics
  • Used to control current for AC Loads
  • Sometimes for DC loads

4
Power Control Devices
  • SCRs
  • Characteristics
  • Type of Thyristors
  • Acts like a switch not as a variable resistance
  • Key ratings
  • Maximum Voltage rating regardless of polarity
  • 30 to 3000V ratings are normal
  • Maximum voltage without damage or false
    activation
  • Maximum Current
  • 3000A
  • Construction
  • Uses alternating layers of P and N semiconductor
    materials like in bipolar transistors

5
Power Control Devices
  • SCRs
  • Characteristics
  • Construction
  • Uses 4 layers and three connections
  • Gate (G) ANODE (A) Cathode (K)
  • Functions as two transistors in the circuit shown
  • Typical packages

6
Power Control Devices
  • SCRs
  • Characteristics
  • Construction
  • Uses 4 layers and three connections
  • Gate (G) ANODE (A) Cathode (K)
  • Functions as two transistors in the circuit shown
  • Typical packages

7
Power Control Devices
  • SCRs
  • Basic DC operation
  • A simple SCR DC circuit is shown top right and
    the equivalent transistor circuit that will be
    analyzed bottom right
  • With E applied and Vin 0V
  • IG1 0V and Q1 is off
  • With Q1 off Q2 lacks base current and is off
  • With both transistors off the SCR appear like a
    reverse biased diode
  • Almost no current between
  • A and K or to the load
  • With E applied and Vin gt 0V
  • IG1 gt 0V and Q1 starts to turn on

8
Power Control Devices
  • SCRs
  • Basic DC operation
  • With E applied and Vin gt 0V
  • IC1 starts to flow and Q2 starts to conduct
  • IC2 starts to flow into the base of Q1 and Q1
    turns on harder
  • More IC1 flows, and Q2 turns on harder
  • The snowballing continues until both transistor
    are in saturation
  • Once the turn-on process starts the input voltage
    that started the process can be removed
  • The SCR will stay on until the
  • cathode voltage anode voltage

9
Power Control Devices
  • SCRs
  • Basic DC operation
  • Sample Circuit an Intrusion Alarm
  • With light (probably IR) striking the
    photoresistor it has a low value
  • The voltage divider formed by it and R1 yields a
    gate voltage too low to activate the SCR
  • Too low to make the sonic alarm output sound
  • When an intruder breaks the light
  • beam the photoresistor has a much
  • higher resistance and the
  • SCR turns on
  • The alarm will stay on
  • until S1 is opened
  • regardless s of the light beam

10
Power Control Devices
  • SCRs
  • Basic AC operation
  • Two modes of operation
  • Zero Voltage Switching
  • SCR is turned on when the AC voltage crosses a
    little above zero volts (instantaneous voltage
    not rms)
  • Phase Control (Covered after TRIACs)
  • The timing of the trigger that turns on the SCR
    is delayed from the zero crossing of the AC
    voltage
  • Characteristics
  • Current only flows during ½ of the AC voltage
    cycle
  • Sample circuit operation
  • See figure 13-5 on page 378 or on the next slide

11
Power Control Devices
  • SCRs
  • Basic AC operation
  • Sample circuit operation
  • With S1 open
  • All the line voltage drops across the SCR
  • Lamp is off
  • With S1 Closed
  • All the line voltage drops across the SCR only on
    the negative part of the cycle
  • During the positive part of the cycle the SCR is
    on and almost all the voltage is dropped across
    the lamp

12
Power Control Devices
  • SCRs
  • More Efficient AC
  • operation
  • Provides more power to
  • the device under control
  • Use a rectifier between the
  • AC source and the SCR
  • Will feed the SCR the full-wave rectified AC
    signal and the motor all the available AC power
    from the line not ½
  • TRIACs
  • Conducts AC in both directions
  • Acts like two SCRs in parallel, but facing in
    opposite directions

13
Power Control Devices
  • TRIACs
  • The symbol reflects the parallel SCR
  • description
  • Still has gate connection along with T1 and
  • T2 connections (some time MK1 and MK2)
  • The gate triggers operation when
  • With T2 positive with respect to T1 a positive
    gate with respect to T1 triggers operation
  • With T2 negative with respect to T1 a negative
    gate with respect to T1 triggers operation
  • Voltage and Current ranges available
  • Usually significantly less than for SCR
  • Reasonable values
  • 50-600V and 0.8-25 A

14
Power Control Devices
  • TRIACs
  • Ancillary Devices used to control the zero
    crossing mode with DC signals
  • Types covered Reed Switches Opto-coupliers
  • Reed Switches
  • Range of packaging
  • As shown
  • In a DIP for insertion on a PCB
  • Operation
  • When a current flows through the wire
  • The spring tensioned ferrous contacts are
    activated completing a circuit

15
Power Control Devices
  • TRIACs
  • Ancillary Devices used to control the zero
    crossing mode with DC signals
  • Opto-coupliers
  • Use either Light Activated SCRs (LASCR) or
    OptoTRIACs and a LED
  • Gates are either not shown
  • or shown not connected on circuits
  • Ancillary Device packaging
  • Can be obtained as discrete components and
    assembled
  • Or both types come as part of a Solid State Relay
    package

16
Power Control Devices
  • TRIACs
  • Sample Circuit Operation
  • Vin could be coming from
  • logic circuit
  • microcontroller
  • microprocessor, etc
  • With Vin 0V
  • The TRIAC is off and all the voltage is dropped
    across it
  • With Vin a logic one or higher voltage
  • The micro switch is activated
  • When the instantaneous AC voltage is high enough
    the TRIAC is activated

17
Power Control Devices
  • TRIACs
  • Sample Circuit Operation
  • With Vin a logic one --------
  • The TRIAC will continue to be activated on each
    positive and negative transition while the micro
    switch is activated
  • Sample w/Optocoupler
  • See Figure 13-11 on page 382 and on the next
    slide
  • The Q-NOT flip flop output goes low and the LED
    inside the optocoupler turns on
  • Activates internal Opto TRIAC

18
Power Control Devices
  • TRIACs
  • Sample w/Optocoupler
  • That activates the Power TRIAC
  • This repeats every 1/2cycle while the digital
    input is a Logic 0
  • For low current applications the internal TRIAC
    may be sufficient

19
Power Control Devices
  • Phase Control
  • Characteristics
  • Provides smooth control of amount of power
    delivered to a load instead of switching the
    power on and off using SCRs or TRIACs
  • Commonly used in lamp dimmers and motor speed
    controls
  • Ancillary Device A DIAC
  • Characteristics
  • Two terminal device that act like two diodes in
    parallel facing opposite directions
  • Or a TRIAC without a gate
  • Acts like a reversed polarity diode until a
    breakdown voltage is reached
  • Then it has a very small resistance
  • Not dependent on polarity

20
Power Control Devices
  • Phase Control
  • Ancillary Device A DIAC
  • Acts like a reversed polarity diode - continued
  • Breakdown voltage of 30 V is common but others
    such as 8 volts are available
  • Used to provide a triggering spike to the TRIAC
    to turn it on
  • Without the DIAC a slowly rising voltage would
    slowly turn the TRIAC on
  • Sample Circuit Operation
  • As the switch closes the
  • TRIAC is off and for simplicity
  • the AC is at zero crossing
  • The voltage on C1 slowly rises
  • due to the time constant from
  • R1, R2 and C1

21
Power Control Devices
  • Phase Control
  • Sample Circuit Operation
  • Switch closed - continued
  • After the breakdown voltage of the DIAC is
    reached on C1 the DIAC fires
  • The TRIAC conducts for the remainder of the ½
    cycle
  • By adjusting the POT you can vary the delay
    before the DIAC fires
  • Thus effecting the power delivered to a motor or
    lamp
  • Varies the motor speed
  • Varies the lamp intensity

22
Problems with TRIAC and SCR circuits
  • Slow Turn-On
  • SCRs and DIACs need a rapid rise in gate voltages
  • A slow rise in gate voltages result in slow
    activations of the SCR or TRIAC
  • DIACs provide a voltage spike for SCRs and TRIACs
  • After the voltage on the Cap reaches The DIACs
    breakdown voltage it provides a low impedance
    path for the Cap to discharge into the SCR/TRIAC
    gate
  • Inductive Loads
  • Sometimes SCRs and TRIACs
  • remain on past the point
  • when VAK or VT1-T2 0V
  • CEMF is the prime cause

23
Problems with TRIAC and SCR circuits
  • Inductive Loads
  • When a switch in series with an inductive load is
    opened
  • A CEMF instantaneously develops across the load
    to cause the current to continue flowing
  • For physical switches arcing can occur and
    sometimes damage switches
  • Some protection is needed - RC discharge path
  • Large rapid voltage swings across SCRs and TRIACs
    can cause them to turn on
  • Discharge path as shown
  • Resistor helps prevent a Tank circuit from
    consisting of the inductor and Cap
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