Thyristors and Optical Devices

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Presentation transcript:

Thyristors and Optical Devices Chapter 33 Thyristors and Optical Devices

Introduction to Thyristors Switch On-state, off-state Unilateral or bilateral Latching High power

Introduction to Thyristors Sinusoidal Firing angle Conduction angle

Triggering Devices Used to pulse switching devices Diac 3-layer Bi-directional conduction Breakover voltage Blocking region Symbols

Triggering Devices Unijunction Transistor (UJT) 3-terminal device Intrinsic standoff ratio n E B2 B1 B2 E B1 Symbol P

Triggering Devices UJT 0.5 < η < 0.9 Emitter region heavily doped VE – B1 = 0, p-n junction reverse biased Increase VE – B1, reach peak point (maximum current)

Triggering Devices UJT Continue increase, reach valley point Further increase VE – B1, UJT is saturated

Triggering Devices UJT relaxation oscillator - +VBB RE + vout CE ___

Silicon Controlled Rectifiers (SCRs) 4-layer device, p-n-p-n Anode (A) Cathode (K) Gate (G) Unidirectional

Silicon Controlled Rectifiers (SCRs) High-power (I up to 2500 A, V up to 2500 V) Phase control Small VAK when On

SCRs

SCRs Operation IG = 0, no anode current IG > IGT → regenerative feedback → high IAK IAK < IH → turn off → IAK = 0

SCRs Can cause SCR turn-on High temperature High ∆V/∆t (noise) Radiation

SCRs Specifications VDRM or VRRM Peak Repetitive Off-state Voltage IT(RMS) On-State RMS current (maximum) ITSM Peak Non-Repetitive Surge current IGT Gate trigger current IL Latching current IH Holding current

SCRs SCR phase control

SCRs Small R1 Large R1 Short RC time constant SCR turns on rapidly, close to 0° Large R1 long RC time constant SCR turns on slowly, close to 180°

SCRs Too large R1 SCR does not turn on

Triacs 3-terminal switch Bi-directional current Symbol Gate trigger may be either + or – pulse I MT1 or Anode (A) MT2 G

Triacs Characteristics Direct replacement for mechanical relays Trigger circuit for full-wave control 4 modes Remains on in either direction until I < IH Blocking region, I ≈ μamps Small voltage across Triac when On

Triacs Specifications Similar to SCR PGM Peak Gate Power PG(AV) Average Gate Power VGM Peak Gate Voltage VGT Gate trigger voltage tgt Turn-On Time

Triacs Phase control light dimmer

Triacs Circuit operation Turn-off due to small load current Capacitor charges/discharges through load DIAC is bi-directional RC time constant → 0° to 180° turn on in each direction

Power Control Fundamentals Review equations Control Lamp intensity Heat from a resistive heater Speed of a motor

Power Control Fundamentals

Power Control Fundamentals Delayed turn-on, full-wave signal Delayed turn-on, half-wave signal

Power Control Fundamentals V and P curves for full-wave control

Introduction to Optical Devices Opto-electronic devices λ = wavelength Current → light Light → current c = speed of light in a vacuum c = 3 x 108 m/s

Introduction to Optical Devices Electromagnetic spectrum Visible (380 < λ(nm) < 750) Infrared region (750 < λ(nm) < 1000) 1 Å = 1  10–10 m = 0.1 nm

Introduction to Optical Devices LED is a diode When forward biased Electron-hole recombination energy Photons released: E = hf , h is Planck’s constant h = 6.626  10–34 Joules∙seconds High energy → visible spectrum Lower energy → IR spectrum

Introduction to Optical Devices LED advantages Low voltage Rapid change in light output with input V change Long life LED output can be matched to photodetector

Introduction to Optical Devices LED disadvantages Easily damaged Brightness dependent on temperature Chromatic dispersion Inefficient compared to LCDs

Photodetectors R varies with light intensity Photoresistors Voltage or current varies with light intensity Photodiodes Phototransistors Light-Activated SCRs (LASCRs)

Photodetectors Photodiodes Reverse biased Low ambient light → very small current, ID (small leakage current) High ambient light → increased current, ID (increase in minority carriers)

Photodetectors Photodiodes Symbol

Photodetectors Phototransistor Base open Light on reverse-biased CB junction Increase minority carriers Increase IC

Photodetectors Phototransistor Usually used as a switch Off → IC = 0 On → IC > 0

Photodetectors LASCR Light-Activated SCR or photo-SCR Symbol Light turns LASCR on Open gate or resistor on gate to control sensitivity

Optocouplers Couple two circuits Electrical isolation LED and Photodetector in single circuit Electrical isolation Medical equipment High voltage circuit to digital circuit

Optocouplers Use as Linear device Digital buffer

Optocouplers Phototransistor optocoupler

Optocouplers Current transfer ratio 0.1 < CTR < 1

Optocouplers Operation High diode current in input circuit yields High diode light output which yields High collector current in output circuit

Semiconductor LASERs Light Amplification through Stimulated Emission of Radiation Operation Similar to LEDs Monochromatic (same frequency) Coherent (same phase) output Small pulse dispersion