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Thyristor Product Catalog
Littelfuse, Inc. 1800 Hurd Drive Irving, Texas 75038 United States of America Phone: +1 972-580-7777 Fax: +1 972-550-1309 Website: http://www.littelfuse.com E-mail: techsalespower@littelfuse.com
Thyristor Product Catalog
Littelfuse, Inc. 1800 Hurd Drive Irving, Texas 75038 United States of America Phone: +1 972-580-7777 Fax: +1 972-550-1309 Website: http://www.littelfuse.com E-mail: techsalespower@littelfuse.com
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Teccor Electronics reserves the right to make changes at any time in order to improve designs and to supply the best products possible. The information in this catalog has been carefully checked and is believed to be accurate and reliable however, no liability of any type shall be incurred by Teccor for the use of the circuits or devices described in this publication. Furthermore, no license of any patent rights is implied or given to any purchaser. Teccor Electronics is the proprietor of the QUADRAC® trademark. is a registered trademark of Underwriters Laboratories, Inc. All other brand names may be trademarks of their respective companies. To conserve space in this catalog, the trademark sign (®) is omitted.
Contents
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Product Selection Guide
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Product Descriptions
Thyristors
A thyristor is any semiconductor switch with a bi-stable action depending on p-n-p-n regenerative feedback. Thyristors are normally two- or three-terminal devices for either unidirectional or bidirectional circuit configurations. Thyristors can have many forms, but they have certain commonalities. All thyristors are solid state switches that are normally open circuits (very high impedance), capable of withstanding rated blocking / off-state voltage until triggered to on state. When triggered to on state, thyristors become a low-impedance current path until principle current either stops or drops below a minimum holding level. After a thyristor is triggered to on-state condition, the trigger current can be removed without turning off the device. Thyristors are used to control the flow of electrical currents in applications including: · Home appliances (lighting, heating, temperature control, alarm activation, fan speed) · Electrical tools (for controlled actions such as motor speed, stapling event, battery charging) · Outdoor equipment (water sprinklers, gas engine ignition, electronic displays, area lighting, sports equipment, physical fitness)
Sensitive SCRs
Sensitive Triacs
Rectifiers
Teccor manufactures 15 A to 25 A rms rectifiers with voltages rated from 200 V to 1000 V. Due to the electrically isolated TO-220 package, these rectifiers may be used in common anode or common cathode circuits using only one part type, thereby simplifying stock requirements.
Triacs
Diacs
Diacs are trigger devices used in phase control circuits to provide gate pulses to a triac or SCR. They are voltage-triggered bidirectional silicon devices housed in DO-35 glass axial lead packages and DO-214 surface mount packages. Diac voltage selections from 27 V to 70 V provide trigger pulses closely matched in symmetry at the positive and negative breakover points to minimize DC component in the load circuit. Some applications include gate triggers for light controls, dimmers, power pulse circuits, voltage references in AC power circuits, and triac triggers in motor speed controls.
Quadrac
Quadrac devices, originally developed by Teccor, are triacs and alternistor triacs with a diac trigger mounted inside the same package. These devices save the user the expense and assembly time of buying a discrete diac and assembling in conjunction with a gated triac. The Quadrac is offered in capacities from 4 A to 15 A rms and voltages from 200 V ac to 600 V ac.
Sidacs
Sidacs represent a unique set of thyristor qualities. The sidac is a bidirectional voltage triggered switch. Some characteristics of this device include a normal 95 V to 330 V switching point, negative resistance range, latching characteristics at turn-on, and a low onstate voltage drop. One-cycle surge current capability up to 20 A makes the sidac an ideal product for dumping charged capacitors through an inductor in order to generate high-voltage pulses. Applications include light controls, high-pressure sodium lamp starters, power oscillators, and high-voltage power supplies.
Alternistor Triacs
The Teccor alternistor is specifically designed for applications required to switch highly inductive loads. The design of this special chip effectively offers the same performance as two thyristors (SCRs) wired inverse parallel (back-to-back). This new chip construction provides the equivalent of two electrically-separate SCR structures, providing enhanced dv / dt characteristics while retaining the advantages of a single-chip device. Teccor manufactures 6 A to 40 A alternistors with blocking voltage rating from 200 V to 1000 V. Alternistors are offered in TO-220, TO-218, and TO-218X packages with isolated and non-isolated versions. http://www.littelfuse.com P-2 +1 972-580-7777
Circuit Requirement Diagram
BILATERAL VOLTAGE SWITCH RECTIFIER REVERSE BLOCKING THYRISTOR BIDIRECTIONAL THYRISTOR BILATERAL VOLTAGE TRIGGER
SIDAC
RECTIFIER
GATE CURRENT 12-500 µA 10-50 mA
GATE CONTROL DIAC TRIGGER DIRECT
OPTIONS SCR (Sensitive) SCR INTERNAL EXTERNAL
QUADRANT OPERATION (See Quadrant Chart on Data Sheet) I II III I II III IV
DIACS QUADRAC
GATE CURRENT 10-100 mA
GATE CURRENT 3-20 mA
ALTERNISTOR TRIAC For detailed information, see specific data sheet in product catalog.
TRIAC
SENSITIVE TRIAC
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Product Packages
Isolated Mounting Tab Package Code
Product Type Sensitive Triac
Current (Amps)
DO-15
DO-35
DO-214
Compak
TO-220
TO-218
TO-218X
TO-3 Fastpak
Triac
Quadrac
Alternistor
Sensitive SCR
Rectifier Diac Sidac
No center lead on TO-92 Sidacs.
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Product Packages
Non-isolated Mounting Tab
Package Code
TO-202
TO-220
TO-218
TO-218X
TO-252 D-Pak
TO-251 V-Pak
TO-263 D2Pak
Current (Amps)
Product Type Sensitive Triac
Triac
Quadrac
Alternistor
Sensitive SCR
Rectifier Diac Sidac
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Description of Part Numbers
Sensitive Triac
Triac and Alternistor
Quadrac
Sensitive SCR
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Description of Part Numbers
Sidac
Rectifier
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Quality and Reliability
Quality Assurance
Incoming Material Quality
Teccor "Vendor Analysis" programs provide stringent requirements before components are delivered to Teccor. In addition, purchased materials are tested rigidly at incoming inspection for specification compliance prior to acceptance for use.
Process Controls
From silicon slice input through final testing, we use statistical methods to control all critical processes. Process audits and lot inspections are performed routinely at all stages of the manufacturing cycle.
Parametric Testing
Final Inspection
Each completed manufacturing lot is sampled and tested for compliance with electrical and mechanical requirements.
Reliability Testing
Random samples are taken from various product families for ongoing reliability testing.
Finished Goods Inspection
Product assurance inspection is performed immediately prior to shipping.
Design Assurance
Quality and Reliability
Reliability Stress Tests
The following table contains brief descriptions of the reliability tests commonly used in evaluating Teccor product reliability on a periodic basis. These tests are applied across product lines depending on product availability and test equipment capacities. Other tests may be performed when appropriate.
Test Type High Temperature AC Blocking High Temperature Storage Life Temperature and Humidity Bias Life
Typical Conditions
Test Description
Evaluation of the reliability of product under bias conditions and elevated temperature Evaluation of the effects on devices after long periods of storage at high temperature
Standards
MIL-STD-750, M-1040
MIL-STD-750, M-1031
Evaluation of the reliability of non- EIA / JEDEC, JESD22-A101 hermetic packaged devices in humid environments
Temperature Cycle Air to Air
MIL-STD-750, M-1051, EIA / JEDEC, JESD22-A104
Thermal Shock Liquid to Liquid Autoclave Resistance to Solder Heat Solderability
Flammability Test
For the UL 94V0 flammability test, all epoxies used in Teccor encapsulated devices are recognized by Underwriters Laboratories
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Standard Terms and Conditions
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Standard Terms and Conditions
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Notes
Data Sheets
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V-I Characteristics of Thyristor Devices
Voltage Drop (VT) at Specified Current (iT)
Latching Current (IL)
Off-state Leakage Current - (IDRM) at Specified VDRM Minimum Holding Current (IH)
IS IDRM IBO +V VBO VS VDRM
Specified Minimum Off-state Blocking Voltage (VDRM)
(VBO - VS) (IS - IBO)
V-I Characteristics of Triac Device
Breakover Voltage
V-I Characteristics of Sidac Device with Negative Resistance
Voltage Drop (VT) at Specified Current (iT)
Latching Current (IL)
Reverse Leakage Current - (IRRM) at Specified VRRM
Off - State Leakage Current - (IDRM) at Specified VDRM
Minimum Holding Current (IH)
Breakover Current IBO
Specified Minimum Reverse Blocking Voltage (VRRM)
Specified Minimum Off - State Blocking Voltage (VDRM)
Breakover Voltage VBO
Reverse Breakdown Voltage
Forward Breakover Voltage
V-I Characteristics of SCR Device V-I Characteristics of Bilateral Trigger Diac
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Electrical Parameter Terminology
Thyristor
di / dt (Critical Rate-of-rise of On-state Current) - Maximum
value of the rate-of-rise of on-state current which a thyristor can withstand without deleterious effect
tgt (Gate-controlled Turn-on Time) - Time interval between
dV / dt (Critical Rate-of-rise of Off-state Voltage or Static dv / dt) - Minimum value of the rate-of-rise of principal voltage
which will cause switching from the off state to the on state
dV / dt(c) (Critical Rate-of-rise of Commutation Voltage of a Triac (Commutating dv / dt)) - Minimum value of the rate-of-rise
of principal voltage which will cause switching from the off state to the on state immediately following on-state current conduction in the opposite quadrant
tq (Circuit-commutated Turn-off Time) - Time interval between the instant when the principal current has decreased to zero after external switching of the principal voltage circuit and the instant when the SCR is capable of supporting a specified principal voltage without turning on
point
VBO (Breakover Voltage) - Principal voltage at the breakover VDRM (Repetitive Peak Off-state Voltage) - Maximum allow-
dVq / dt (Critical Rate-of-rise of Turn-off Voltage at 8 kHz) -
Minimum value of the rate-of-rise of turn-off voltage during operation at 8 kHz.
able instantaneous value of repetitive off-state voltage that may be applied across a bidirectional thyristor (forward or reverse direction) or SCR (forward direction only) produce the gate trigger current
VGT (Gate Trigger Voltage) - Minimum gate voltage required to VRRM (Repetitive Peak Reverse Voltage) - Maximum allowable instantaneous value of a repetitive reverse voltage that may be applied across an SCR without causing reverse current avalanche VS (Switching Voltage) - Voltage point after VBO when a sidac switches from a clamping state to on state
the on state
I2t (RMS Surge (Non-repetitive) On-state Fusing Current) -
Measure of let-through energy in terms of current and time for fusing purposes point
IBO (Breakover Current) - Principal current at the breakover IDRM (Repetitive Peak Off-state Current) - Maximum leakage
current that may occur under the conditions of VDRM
IGT (Gate Trigger Current) - Minimum gate current required to
switch a thyristor from the off state to the on state
VT (On-state Voltage) - Principal voltage when the thyristor is in
IH (Holding Current) - Minimum principal current required to
maintain the thyristor in the on state duration and specified waveshape
Diode Rectifiers
IF(AV) (Average Forward Current) - Average forward conduction current
IPP (Peak Pulse Current) - Peak pulse current at a short time IRRM (Repetitive Peak Reverse Current) - Maximum leakage current that may occur under the conditions of VRRM
from the clamping state to on state
leakage current that may occur at rated VRRM rent
IFM (Maximum (Peak) Reverse Current) - Maximum reverse IF(RMS) (RMS Forward Current) - RMS forward conduction cur-
IS (Switching Current) - Current at VS when a sidac switches IT(RMS) (On-state Current) - Anode cathode principal current
that may be allowed under stated conditions, usually the fullcycle RMS current
IFSM (Maximum (Peak) Forward (Non-repetitive) Surge Current) - Maximum (peak) forward single cycle AC surge current allowed for specified duration
cycle AC current pulse allowed
ITSM (Surge (Non-repetitive) On-state Current) - Peak single PG(AV) (Average Gate Power Dissipation) - Value of gate
VFM (Maximum (Peak) Forward Voltage Drop) - Maximum
(peak) forward voltage drop from the anode to cathode at stated conditions
power which may be dissipated between the gate and main terminal 1 (or cathode) average over a full cycle may be dissipated between the gate and main terminal 1 (or cathode) for a specified time duration
VR (Reverse Blocking Voltage) - Maximum allowable DC
reverse blocking voltage that may be applied to the rectifier
PGM (Peak Gate Power Dissipation) - Maximum power which
VRRM (Maximum (Peak) Repetitive Reverse Voltage) - Maximum peak allowable value of a repetitive reverse voltage that may be applied to the rectifier
RJA (Thermal Resistance, Junction-to-ambient) - Temperature difference between the thyristor junction and ambient divided by the power dissipation causing the temperature difference under conditions of thermal equilibrium
Note: Ambient is defined as the point where temperature does not change as a result of the dissipation.
RJC (Thermal Resistance, Junction-to-case) - Temperature difference between the thyristor junction and the thyristor case divided by the power dissipation causing the temperature difference under conditions of thermal equilibrium
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Notes
TO-92 TO-220 Isolated
3-lead Compak
TO-252 D-Pak TO-202 TO-251 V-Pak
Sensitive Triacs
General Description
Variations of devices covered in this data sheet are available for custom design applications. Consult factory for more information.
Features
· · · · · · RoHS Compliant Electrically-isolated packages Glass-passivated junctions ensure long device reliability and parameter stability Voltage capability - up to 600 V Surge capability - up to 80 A Four-quadrant gating guaranteed
Compak Sensitive Gate Triac
· · · · Surface mount package - 0.8 A and 1 A series New small profile three-leaded Compak package Packaged in embossed carrier tape with 2, 500 devices per reel Can replace SOT-223
Sensitive Triacs
Data Sheets
Part No. IT(RMS)
Isolated
Non-isolated
MT1 G MT2
MT1 MT2
TO-92 MAX L2X8E3 L4X8E3 L6X8E3 L2X8E5 L4X8E5 L6X8E5 L2X8E6 L4X8E6 L6X8E6 L2X8E8 L4X8E8 L6X8E8 L201E3 L401E3 L601E3 L201E5 L401E5 L601E5 L201E6 L401E6 L601E6 L201E8 L401E8 L601E8
Compak
TO-220
TO-252 D-Pak
TO-202
TO-251 V-Pak
See "Package Dimensions" section for variations. (12) L2X3 L4X3 L6X3 L2X5 L4X5 L6X5
L2N3 L4N3 L6N3 L2N5 L4N5 L6N5
L2004L3 L4004L3 L6004L3 L2004L5 L4004L5 L6004L5 L2004L6 L4004L6 L6004L6 L2004L8 L4004L8 L6004L8
L2004D3 L4004D3 L6004D3 L2004D5 L4004D5 L6004D5 L2004D6 L4004D6 L6004D6 L2004D8 L4004D8 L6004D8
L2004F31 L4004F31 L6004F31 L2004F51 L4004F51 L6004F51 L2004F61 L4004F61 L6004F61 L2004F81 L4004F81 L6004F81
L2004V3 L4004V3 L6004V3 L2004V5 L4004V5 L6004V5 L2004V6 L4004V6 L6004V6 L2004V8 L4004V8 L6004V8
See "General Notes" on page E1 - 4 and "Electrical Specification Notes" on page E1 - 5.
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Data Sheets
Sensitive Triacs
PG(AV)
dv / dt(c)
Amps mAmps MAX 5 5 5 10 10 10 10 10 10 15 15 15 5 5 5 10 10 10 10 10 10 15 15 15 5 5 5 10 10 10 10 10 10 15 15 15 Amps 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1.2 1.2 1.2 1.2 1.2 1.2 1.2 1.2 1.2 1.2 1.2 1.2 Watts 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 15 15 15 15 15 15 15 15 15 15 15 15 Watts 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.2 0.3 0.3 0.3 0.3 0.3 0.3 0.3 0.3 0.3 0.3 0.3 0.3 60 / 50 Hz 10 / 8.3 10 / 8.3 10 / 8.3 10 / 8.3 10 / 8.3 10 / 8.3 10 / 8.3 10 / 8.3 10 / 8.3 10 / 8.3 10 / 8.3 10 / 8.3 20 / 16.7 20 / 16.7 20 / 16.7 20 / 16.7 20 / 16.7 20 / 16.7 20 / 16.7 20 / 16.7 20 / 16.7 20 / 16.7 20 / 16.7 20 / 16.7 40 / 33 40 / 33 40 / 33 40 / 33 40 / 33 40 / 33 40 / 33 40 / 33 40 / 33 40 / 33 40 / 33 40 / 33 Volts / µSec TYP 0.5 0.5 0.5 1 1 1 1 1 1 2 2 2 0.5 0.5 0.5 1 1 1 1 1 1 1 1 1 0.5 0.5 0.5 1 1 1 1 1 1 2 2 2
µSec TYP 2.8 2.8 2.8 3 3 3 3 3 3 3.2 3.2 3.2 2.8 2.8 2.8 3 3 3 3 3 3 3.2 3.2 3.2 2.8 2.8 2.8 3 3 3 3 3 3 3.2 3.2 3.2
Amps2Sec 0.41 0.41 0.41 0.41 0.41 0.41 0.41 0.41 0.41 0.41 0.41 0.41 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 6.6 6.6 6.6 6.6 6.6 6.6 6.6 6.6 6.6 6.6 6.6 6.6
Amps / µSec 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 50 50 50 50 50 50 50 50 50 50 50 50
See "General Notes" on page E1 - 4 and "Electrical Specification Notes" on page E1 - 5.
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Sensitive Triacs
Data Sheets
Part No. IT(RMS)
Isolated
Non-isolated
G MT2 MT1
MT1 MT2
TO-220 MAX
TO-252 D-Pak
TO-251 V-Pak
Volts MIN 200 400 600 200 400 600 200 400 600 200 400 600 200 400 600
See "Package Dimensions" section for variations. (12) L2006L5 L2006D5 L2006V5 L4006L5 L4006D5 L4006V5 L6006L5 L6006D5 L6006V5 L2006L6 L2006D6 L2006V6 L4006L6 L4006D6 L4006V6 L6006L6 L6006D6 L6006V6 L2006L8 L2006D8 L2006V8 L4006L8 L4006D8 L4006V8 L6006L8 L6006D8 L6006V8 L2008L6 L2008D6 L2008V6 L4008L6 L4008D6 L4008V6 L6008L6 L6008D6 L6008V6 L2008L8 L2008D8 L2008V8 L4008L8 L4008D8 L4008V8 L6008L8 L6008D8 L6008V8
Specified Test Conditions
General Notes
· · · All measurements are made with 60 Hz resistive load and at an ambient temperature of +25 °C unless otherwise specified. Operating temperature range (TJ) is -65 °C to +110 °C for TO-92 devices and -40 °C to +110 °C for all other devices. Storage temperature range (TS) is -65 °C to +150 °C for TO-92 devices, -40 °C to +150 °C for TO-202 devices, and -40 °C to +125 °C for TO-220 devices. Lead solder temperature is a maximum of 230 °C for 10 seconds maximum at a minimum of 1 / 16" (1.59 mm) from case. The case or lead temperature (TC or TL) is measured as shown on dimensional outline drawings. See "Package Dimensions" section of this catalog.
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Data Sheets
Sensitive Triacs
PG(AV)
dv / dt(c)
mAmps MAX 10 10 10 10 10 10 20 20 20 10 10 10 20 20 20
Amps 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6 1.6
Watts 18 18 18 18 18 18 18 18 18 18 18 18 18 18 18
Watts 0.4 0.4 0.4 0.4 0.4 0.4 0.4 0.4 0.4 0.4 0.4 0.4 0.4 0.4 0.4
Amps2Sec 15 15 15 15 15 15 15 15 15 26.5 26.5 26.5 26.5 26.5 26.5
Amps / µSec 70 70 70 70 70 70 70 70 70 70 70 70 70 70 70
Electrical Specification Notes
(1) (2) (3) (4) (5) (6) (7) (8) (9) For either polarity of MT2 with reference to MT1 terminal For either polarity of gate voltage VGT with reference to MT1 terminal See Gate Characteristics and Definition of Quadrants. See Figure E1.4 for iT versus vT. See Figure E1.6 for VGT versus TC. See Figure E1.7 for IGT versus TC. See Figure E1.5 for IH versus TC. See Figure E1.9 for surge rating and specific duration. See Figure E1.8 for tgt versus IGT.
Gate Characteristics
Teccor triacs may be turned on between gate and MT1 terminals in the following ways: · · In-phase signals (with standard AC line) using Quadrants I and III Application of unipolar pulses (gate always positive or negative), using Quadrants II and III with negative gate pulses and Quadrants I and IV with positive gate pulses
When maximum surge capability is required, pulses should be a minimum of one magnitude above IGT rating with a steep rising waveform (1 µs rise time).
ALL POLARITIES ARE REFERENCED TO MT1 MT2 POSITIVE (Positive Half Cycle)
MT2 IGT GATE
IGT GATE MT1
REF MT2 IGT GATE MT1 REF
QII QI QIII QIV
MT2 IGT GATE MT1 REF
MT2 NEGATIVE (Negative Half Cycle)
Definition of Quadrants
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Sensitive Triacs
Data Sheets
Electrical Isolation
Electrical Isolation from Leads to Mounting Tab
V AC RMS 2500 UL Recognized File #E71639 TO-220 Standard
Thermal Resistance (Steady State) Junction to Mounting Tab and Junction to Ambient RJC RJA °C / W (TYP)
Package Code E C F L F2 D V
TO-92 Plastic 0.8 A 1A 4A 6A 8A 60 135 50 95
Compak 60 40
TO-202 Type 1
TO-220 Isolated
TO-202 Type 2
TO-252 D-Pak
TO-251 V-Pak
Mounted on 1 cm2 copper foil surface two-ounce copper foil
Maximum Allowable Ambient Temperature (TA) - °C
Maximum Allowable Case Temperature (TC) - °C
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360° FREE AIR RATING - NO HEATSINK TO-220 and TYPE 1 and 3 TO-202
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360° CASE TEMPERATURE: Measured as shown on Dimensional Drawings
TYPE 2 and 4 TO-202 and TO-251
1 A TO-92
0.8 A TO-92
RMS On-State Current IT(RMS) - Amps
RMS On-State Current IT(RMS) - Amps
Figure E1.1 Maximum Allowable Ambient Temperature versus On-state Current
Figure E1.2 Maximum Allowable Case Temperature versus On-state Current (0.8 A and 1 A)
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Data Sheets
Sensitive Triacs
Maximum Allowable Case Temperature (TC) - °C
4 A TYPE 2 and 4 TO-202 4 A TO-251 4 A TYPE 1 and 3 TO-202 4 A TO-220 (Isolated) 4 A TO-252
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360° CASE TEMPERATURE: Measured as shown on Dimensional Drawings
TO TO -25 8A 1a -22 nd TO 0( TO -22 Iso -25 0( 2 lat Iso ed late ) d)
6 A TO-251 6 A TO-252
Ratio of
RMS On-State Current IT(RMS) - Amps
Case Temperature (TC) - ° C
Figure E1.3 Maximum Allowable Case Temperature versus On-state Current (4 A, 6 A, and 8 A)
Figure E1.6 Normalized DC Gate Trigger Voltage for All Quadrants versus Case Temperature
Positive or Negative Instantaneous On-state Current (iT) - Amps
Ratio of
Positive or Negative Instantaneous On-state Voltage (vT) - Volts
Case Temperature (TC) - °C
Figure E1.4 On-state Current versus On-state Voltage (Typical)
Figure E1.7 Normalized DC Gate Trigger Current for All Quadrants versus Case Temperature
Turn-On Time (tgt) - µSec
Ratio of
Case Temperature (TC) - °C
DC Gate Trigger Current (IGT) - mA
Figure E1.5 Normalized DC Holding Current versus Case Temperature
Figure E1.8 Turn-on Time versus Gate Trigger Current (Typical)
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Sensitive Triacs
Data Sheets
SUPPLY FREQUENCY: 60 Hz Sinusoidal LOAD: Resistive RMS On-state Current: IT(RMS): Maximum Rated Value at Specified Case Temperature
Peak Surge (Non-Repetitive) On-State Current (ITSM) - Amps
NOTES: 1) Gate control may be lost during and immediately following surge current interval. 2) Overload may not be repeated until junction temperature has returned to steady-state rated value.
Surge Current Duration - Full Cycles
Figure E1.9 Peak Surge Current versus Surge Current Duration
Average On-state Power Dissipation PD(AV) - Watts
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360°
0.8 A 0.5 1A
RMS On-state Current IT(RMS) - Amps
Figure E1.10 Power Dissipation (Typical) versus RMS On-state Current (0.8 A and 1 A)
Figure E1.11 Power Dissipation (Typical) versus RMS On-state Current (4 A, 6 A, and 8 A)
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TO-92 TO-202 TO-220
3-lead Compak
TO-263 D2Pak
TO-252 D-Pak TO-251 V-Pak
TO-3 Fastpak
Triacs
(0.8 A to 35 A)
General Description
Features
· · · · · RoHS Compliant Electrically-isolated packages Glass-passivated junctions Voltage capability - up to 1000 V Surge capability - up to 200 A
Compak Package
· · · · Surface mount package - 0.8 A and 1 A series New small profile three-leaded Compak package Packaged in embossed carrier tape with 2, 500 devices per reel Can replace SOT-223
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Triacs
Data Sheets
Part Number IT(RMS)
Isolated
Non-isolated
MT2 G MT2
G MT2 MT1
MT1 MT2
Volts TO-92 MAX TO-220 Compak Q2X3 Q4X3 Q6X3 Q2X4 Q4X4 Q6X4 Q2N3 Q4N3 Q6N3 Q2N4 Q4N4 Q6N4 Q2004L3 Q4004L3 Q6004L3 Q2004L4 Q4004L4 Q6004L4 Q8004L4 QK004L4 Q2004F31 Q4004F31 Q6004F31 Q2004F41 Q4004F41 Q6004F41 Q2004D3 Q4004D3 Q6004D3 Q2004D4 Q4004D4 Q6004D4 Q8004D4 QK004D4 Q2006F41 Q4006F41 Q6006F51 Q2006R4 Q4006R4 Q6006R5 Q8006R5 QK006R5 Q2008F41 Q4008F41 Q6008F51 Q2008R4 Q4008R4 Q6008R5 Q8008R5 QK008R5 Q2004V3 Q4004V3 Q6004V3 Q2004V4 Q4004V4 Q6004V4 Q8004V4 QK004V4 Q2006N4 Q4006N4 Q6006N5 Q8006N5 QK006N5 Q2008N4 Q4008N4 Q6008N5 Q8008N5 QK008N5 TO-202 TO-220 TO-252 D-Pak TO-251 V-Pak TO-263 D2Pak MIN 200 400 600 200 400 600 200 400 600 200 400 600 200 400 600 200 400 600 800 1000 200 400 600 800 1000 200 400 600 800 1000 10 10 10 25 25 25 10 10 10 25 25 25 10 10 10 25 25 25 25 25 25 25 50 50 50 25 25 50 50 50 QI QII 10 10 10 25 25 25 10 10 10 25 25 25 10 10 10 25 25 25 25 25 25 25 50 50 50 25 25 50 50 50
mAmps QIII QIV 10 10 10 25 25 25 10 10 10 25 25 25 10 10 10 25 25 25 25 25 25 25 50 50 50 25 25 50 50 50 QIV TYP 25 25 25 50 50 50 25 25 25 50 50 50 25 25 25 50 50 50 50 50 50 50 75 75 75 50 50 75 75 75
See "Package Dimensions" section for variations. (11) Q2X8E3 Q4X8E3 Q6X8E3 Q2X8E4 Q4X8E4 Q6X8E4
Q201E3 Q401E3 Q601E3 Q201E4 Q401E4 Q601E4
Q2006L4 Q4006L4 Q6006L5 Q8006L5 QK006L5
Q2008L4 Q4008L4 Q6008L5 Q8008L5 QK008L5
See "General Notes" on page E2 - 4 and "Electrical Specification Notes" on page E2 - 5.
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Data Sheets
Triacs
PG(AV)
dv / dt(c)
See "General Notes" on page E2 - 4 and "Electrical Specification Notes" on page E2 - 5.
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Triacs
Data Sheets
Part Number IT(RMS)
Isolated
Non-isolated
G MT2 MT1
MT1 MT2
TO-3 Fastpak MAX
TO-220 Q2010L4 Q4010L4 Q6010L4 Q8010L4
TO-202
TO-220 Q2010R4 Q4010R4 Q6010R4 Q8010R4 QK010R4
See "Package Dimensions" section for variations. (11)
QK010L4 Q2010L5 Q4010L5 Q6010L5 Q8010L5 QK010L5 Q2015L5 Q4015L5 Q6015L5 Q8015L5 QK015L5 Q2010F51 Q4010F51 Q6010F51
Q2010R5 Q4010R5 Q6010R5 Q8010R5 QK010R5 Q2015R5 Q4015R5 Q6015R5 Q8015R5 QK015R5 Q2025R5 Q4025R5 Q6025R5
Q6025P5 Q8025P5
Q8025R5 QK025R5
Q6035P5 Q8035P5
Specific Test Conditions
General Notes
· · All measurements are made at 60 Hz with a resistive load at an ambient temperature of +25 °C unless specified otherwise. Operating temperature range (TJ) is -65 °C to +125 °C for TO-92, -25 °C to +125 °C for Fastpak, and -40 °C to +125 °C for all other devices. Storage temperature range (TS) is -65 °C to +150 °C for TO-92, -40 °C to +150 °C for TO-202, and -40 °C to +125 °C for all other devices. Lead solder temperature is a maximum of 230 °C for 10 seconds, maximum 1 / 16" (1.59 mm) from case. The case temperature (TC) is measured as shown on the dimensional outline drawings. See "Package Dimensions" section of this catalog.
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Data Sheets
Triacs
PG(AV)
dv / dt(c)
Amps 60 / 50 Hz 120 / 100 120 / 100 120 / 100 120 / 100 120 / 100 120 / 100 120 / 100 120 / 100 120 / 100 120 / 100 200 / 167 200 / 167 200 / 167 200 / 167 200 / 167 200 / 167 200 / 167 200 / 167 200 / 167 200 / 167 250 / 220 250 / 220 350 / 300 350 / 300 Volts / µSec TYP 2 2 2 2 2 4 4 4 4 4 4 4 4 4 4 5 5 5 5 5 5 5 5 5
Electrical Specification Notes
(1) (2) (3) (4) (5) (6) (7) (8) (9) For either polarity of MT2 with reference to MT1 terminal For either polarity of gate voltage (VGT) with reference to MT1 terminal See Gate Characteristics and Definition of Quadrants. See Figure E2.1 through Figure E2.7 for current rating at specific operating temperature. See Figure E2.8 through Figure E2.10 for iT versus vT. See Figure E2.12 for VGT versus TC. See Figure E2.11 for IGT versus TC. See Figure E2.14 for IH versus TC. See Figure E2.13 for surge rating with specific durations.
Gate Characteristics
Teccor triacs may be turned on between gate and MT1 terminals in the following ways: · · In-phase signals (with standard AC line) using Quadrants I and III Application of unipolar pulses (gate always positive or negative), using Quadrants II and III with negative gate pulses and Quadrants I and IV with positive gate pulses However, due to higher gate requirements for Quadrant IV, it is recommended that only negative pulses be applied. If positive pulses are required, see "Sensitive Triacs" section of this catalog or contact the factory. Also, see Figure AN1002.8, "Amplified Gate" Thyristor Circuit.
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Triacs
Data Sheets
In all cases, if maximum surge capability is required, pulses should be a minimum of one magnitude above IGT rating with a steep rising waveform (1 µs rise time).
ALL POLARITIES ARE REFERENCED TO MT1 MT2 POSITIVE (Positive Half Cycle)
Electrical Isolation
Electrical Isolation from Leads to Mounting Tab
IGT GATE MT1
V AC RMS 2500
TO-220 Isolated Standard Optional
Fastpak Isolated Standard N / A
REF MT2 IGT GATE MT1 REF
QII QI QIII QIV
MT2 IGT GATE MT1 REF
UL Recognized File E71639 For 4000 V isolation, use V suffix in part number.
MT2 NEGATIVE (Negative Half Cycle)
Definition of Quadrants
Thermal Resistance (Steady State) R JC R JA (TYP.) °C / W
TO-3 Fastpak 0.8 A 1A 4A 6A 8A 10 A 15 A 25 A 35 A 1.6 1.5
TO-92 60 135 50 95
Compak 60 40
TO-202 Type 1
TO-202 Type 2
TO-220 Isolated
TO-220 Non-isolated
TO-252 D-Pak
TO-251 V-Pak
TO-263 D2Pak
Mounted on 1
copper foil surface two-ounce copper foil
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Data Sheets
Triacs
Maximum Allowable Case Temperature (TC) - °C
130 120 110 100 90 80 70 60 0 0 2 4 6 8 10 12 14 CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360 CASE TEMPERATURE: Measured as shown on Dimensional Drawing 10 A TO-202 10 A TO-220 (Non-isolated) 10 A D2Pak
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360° CASE TEMPERATURE: Measured as shown on Dimensional Drawing
RMS On-state Current lT(RMS) - AMPS
RMS On-state Current lT(RMS) - Amps
Figure E2.1 Maximum Allowable Case Temperature versus On-state Current (0.8 A and 1 A)
Figure E2.4 Maximum Allowable Case Temperature versus On-state Current (10 A)
Maximum Allowable Case Temperature (TC) - °C
130 120 110 100 90 80 70 60 0 0 1 2 3 4 A TO-202 (TYPE 2 and 4) 4 A TO-251 4 A TO-220 (Isolated) 4 A TO-202 (Type 1 and 3) 4 A TO-252 6 A TO-220 (Non-isolated) 6 A D2Pak 6 A TO-220 (Isolated) 6 A TO-202
15 A TO-220 (Non-isolated) 15 A D2Pak
15 A TO-220 (Isolated)
90 80 70 60 0 0 5 10 15 CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360 CASE TEMPERATURE: Measured as shown on Dimensional Drawing
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360 CASE TEMPERATURE: Measured as shown on Dimensional Drawing
RMS On-state Current lT(RMS) - Amps
RMS On-state Current lT(RMS) - AMPS
Figure E2.2 Maximum Allowable Case Temperature versus On-state Current (4 A and 6 A)
Figure E2.5 Maximum Allowable Case Temperature versus On-state Current (15 A)
Maximum Allowable Case Temperature (TC) - °C
130 10 A TO-220 (Isolated) 120 110 100 90 80 70 60 0 0 2 4 6 8 10 12 14 CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360 CASE TEMPERATURE: Measured as shown on Dimensional Drawing 8 A TO-202 8 A TO-220 (Isolated) 8 A TO-220 (Non-isolated) 8 A D2Pak
Maximum Allowable Case Temperature (TC) - °C
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360° CASE TEMPERATURE: Measured as shown on Dimensional Drawing
110 25 A TO-220 (Non-isolated) 25 A D2Pak
90 25 A TO-3 Fastpak 35 A TO-3 Fastpak
RMS On-state Current lT(RMS) - AMPS
RMS On-state Current lT(RMS) - Amps
Figure E2.3 Maximum Allowable Case Temperature versus On-state Current (8 A and 10 A)
Figure E2.6 Maximum Allowable Case Temperature versus On-state Current (25 A and 35 A)
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Triacs
Data Sheets
Maximum Allowable Ambient Temperature (TA) - °C
Positive or Negative Instantaneous On-state Current (iT) - Amps
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360° FREE AIR RATING - NO HEATSINK
TO-202 (TYPE 2 and 4) TO-251 TO-220 Devices and TO-202 (Type 1 and 3)
25 A and 35 A Fastpak
1 A TO-92 40 0.8 A TO-92 25 20 0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0
RMS On-state Current IT (RMS) - Amps
Positive or Negative Instantaneous On-state Voltage (vT) - Volts
Figure E2.7 Maximum Allowable Ambient Temperature versus On-state Current
Figure E2.10 On-state Current versus On-state Voltage (Typical) (15 A and 25 A)
Positive or Negative Instantaneous On-state Current (iT) - Amps
Ratio of
Positive or Negative Instantaneous On-state Voltage (vT) - Volts
Case Temperature (TC) - °C
Figure E2.8 On-state Current versus On-state Voltage (Typical) (0.8 A and 1 A)
Figure E2.11 Normalized DC Gate Trigger Current for All Quadrants versus Case Temperature
Positive or Negative Instantaneous On-state Current (iT) - Amps
6-10 A
Ratio of
Positive or Negative Instantaneous On-state Voltage (vT) - Volts
Case Temperature (TC) - °C
Figure E2.9 On-state Current versus On-state Voltage (Typical) (4 A, 6 A, 8 A, and 10 A)
Figure E2.12 Normalized DC Gate Trigger Voltage for All Quadrants versus Case Temperature
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Data Sheets
Triacs
SUPPLY FREQUENCY: 60 Hz Sinusoidal LOAD: Resistive RMS ON-STATE CURRENT lT(RMS): Maximum Rated Value at Specified Case Temperature
NOTES:
Peak Surge (Non-repetitive) On-state Current (l
1) Gate control may be lost during and immediately following surge current interval. 2) Overload may not be repeated until junction temperature has returned to steady-state rated value.
Surge Current Duration - Full Cycles
Figure E2.13 Peak Surge Current versus Surge Current Duration
Typical Turn-on Time (tgt) - µSec
Ratio of
Case Temperature (TC) - °C
DC Gate Trigger Current (lGT) - mA
Figure E2.14 Normalized DC Holding Current versus Case Temperature
Figure E2.15 Turn-on Time versus Gate Trigger Current (Typical)
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Triacs
Data Sheets
Average On-state Power Dissipation PD(AV) - Watts
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360°
4A 1.0
RMS On-state Current IT(RMS) - Amps
Figure E2.16 Power Dissipation (Typical) versus On-state Current (0.8 A and 1 A)
Average On-state Power Dissipation PD(AV) - Watts
Figure E2.19 Power Dissipation (Typical) versus RMS On-state Current (4 A)
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360°
RMS On-state Current lT(RMS) - Amps
Figure E2.17 Power Dissipation (Typical) versus On-state Current (6 A to 10 A and 15 A)
Average On-state Power Dissipation PD(AV) - Watts
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360°
25 A - 35 A Fastpaks
RMS On-state Current lT(RMS) - Amps
Figure E2.18 Power Dissipation (Typical) versus On-state Current (25 A to 35 A)
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TO-220
Quadrac
Internally Triggered Triacs (4 A to 15 A)
General Description
Features
· · · · · · RoHS Compliant Glass-passivated junctions Electrically-isolated package Internal trigger diac High surge capability - up to 200 A High voltage capability - 200 V to 600 V
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Quadrac
Data Sheets
Part No. IT(RMS)
(5) Isolated
Trigger Diac Specifications (T-MT1) VDRM
VBO (7)
VBO (6)
CT (11)
TO-220 See "Package Dimensions" section for variations. (12)
Q2004LT Q4004LT Q6004LT Q2006LT Q4006LT
Q6006LT Q4006LTH Q6006LTH Q2008LT Q4008LT
Q6008LT Q4008LTH Q6008LTH Q2010LT Q4010LT
Q6010LT Q4010LTH Q6010LTH Q2015LT Q4015LT
Q6015LT Q4015LTH Q6015LTH
Specific Test Conditions
VDRM - Repetitive peak blocking voltage V - Peak on-state voltage at maximum rated RMS current
General Notes
· · · · · All measurements are made at 60 Hz with resistive load at an ambient temperature of +25 °C unless otherwise specified. Operating temperature range (TJ) is -40 °C to +125 °C. Storage temperature range (TS) is -40 °C to +125 °C. Lead solder temperature is a maximum of +230 °C for 10 seconds maximum 1 / 16" (1.59 mm) from case. The case temperature (TC) is measured as shown on dimensional outline drawings. See "Package Dimensions" section of this catalog.
Electrical Specification Notes
(1) (2) (3) (4) For either polarity of MT2 with reference to MT1 See Figure E3.1 for IH versus TC. See Figure E3.4 and Figure E3.5 for iT versus vT. See Figure E3.9 for surge ratings with specific durations.
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Data Sheets
Quadrac
dv / dt(c)
Electrical Isolation
All Teccor isolated Quadrac packages withstand a minimum high potential test of 2500 V ac rms from leads to mounting tab over the operating temperature range of the device. The following isolation table shows standard and optional isolation ratings.
Electrical Isolation from Leads to Mounting Tab
V AC RMS 2500 4000 TYPE Standard Optional
UL Recognized File #E71639 For 4000 V isolation, use "V" suffix in part number.
Thermal Resistance (Steady State) RJC RJA °C / W (TYP)
TYPE 4A 6A 8A 10 A 15 A Isolated TO-220 3.6 50 3.3 2.8 2.6 2.1
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Quadrac
Data Sheets
Positive or Negative Instantaneous On-state Current (iT) - Amps
Ratio of
Case Temperature (TC) - °C
Positive or Negative Instantaneous On-state Voltage (vT) - Volts
Figure E3.1 Normalized DC Holding Current versus Case Temperature
Figure E3.4 On-state Current versus On-state Voltage (Typical) (4 A to 10 A)
Positive or Negative Instantaneous On-state Current (iT) - Amps
D.U.T.
Positive or Negative Instantaneous On-state Voltage (vT) - Volts
Figure E3.2 Test Circuit
Figure E3.5 On-state Current versus On-state Voltage (Typical) (15 A)
VC +VBO V+
Maximum Allowable Ambient Temperature (TA) - °C
V-VBO
RMS On-state Current IT(RMS) - Amps
Figure E3.3 Test Circuit Waveforms
Figure E3.6 Maximum Allowable Ambient Temperature versus On-state Current
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Data Sheets
Quadrac
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360 CASE TEMPERATURE: Measured as shown on Dimensional Drawings
Average On-state Power Dissipation PD(AV) - Watts
Maximum Allowable Case Temperature (TC) - °C
3.0 4A
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360°
RMS On-state Current IT(RMS) - Amps
Figure E3.7 Maximum Allowable Case Temperature versus On-state Current (4 A)
Figure E3.10 Power Dissipation (Typical) versus On-state Current (4 A)
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360 CASE TEMPERATURE: Measured as shown on Dimensional Drawings
Average On-state Power Dissipation PD(AV) - Watts
Maximum Allowable Case Temperature (TC) - °C
100 6A
CURRENT WAVEFORM: Sinusoidal LOAD: Resistive or Inductive CONDUCTION ANGLE: 360°
RMS On-state Current IT(RMS) - Amps
Figure E3.8 Maximum Allowable Case Temperature versus On-state Current (6 A to 15 A)
Figure E3.11 Power Dissipation (Typical) versus On-state Current (6 A to 10 A and 15 A)
Peak Surge (Non-repetitive) On-state Current (ITSM) - Amps
NOTES: 1) Gates control may be lost during and immediately following surge current interval. 2) Overload may not be repeated until junction temperature has returned to steady state rated value.
SUPPLY FREQUENCY: 60 Hz Sinusoidal LOAD: Resistive RMS ON-STATE CURRENT IT(RMS): Maximum Rated Value at Specified Case Temperature
Surge Current Duration - Full Cycles
Junction Temperature (TJ) - °C
Figure E3.12 Normalized diac VBO versus Junction Temperature
Figure E3.9 Peak Surge Current versus Surge Current Duration
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Notes
TO-220 TO-218X
TO-218
TO-252 D-Pak TO-263 D 2 Pak TO-251 V-Pak
MT2 MT1
Alternistor Triacs
General Description
Features
· · · · · · RoHS Compliant High surge current capability Glass-passivated junctions 2500 V ac isolation for L, J, and K Packages High commutating dv / dt High static dv / dt
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Alternistor Triacs
Data Sheets
Part Number IT(RMS)
Isolated
Non-isolated
G MT2 MT1
MT1 MT2
T0-220 MAX
TO-220
TO-251 V-Pak Q2006VH3 Q4006VH3 Q6006VH3 Q2006VH4 Q4006VH4
See "Package Dimensions" section for variations. (11)
Q2006LH4 Q4006LH4 Q6006LH4 Q8006LH4 QK006LH4 Q2006RH4 Q4006RH4 Q6006RH4 Q8006RH4 QK006RH4
Q6006VH4 Q8006VH4 QK006VH4
Q2008VH3 Q4008VH3 Q6008VH3 Q2008VH4 Q4008VH4
Q2008DH3 Q4008DH3 Q6008DH3 Q2008DH4 Q4008DH4 Q6008DH4 Q8008DH4 QK008DH4
Q2008LH4 Q4008LH4 Q6008LH4 Q8008LH4 QK008LH4 Q2010LH5 Q4010LH5 Q6010LH5 Q8010LH5 QK010LH5 Q2012LH5 Q4012LH5 Q6012LH5 Q8012LH5 QK012LH5 Q2008RH4 Q4008RH4 Q6008RH4 Q8008RH4 QK008RH4 Q2010RH5 Q4010RH5 Q6010RH5 Q8010RH5 QK010RH5 Q2012RH5 Q4012RH5 Q6012RH5 Q8012RH5 QK012RH5
Q6008VH4 Q8008VH4 QK008VH4
See "General Notes" and "Electrical Specification Notes" on page E4 - 5.
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Data Sheets
Alternistor Triacs
PG(AV)
dv / dt(c)
See "General Notes" and "Electrical Specification Notes" on page E4 - 5.
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Alternistor Triacs
Data Sheets
Part Number IT(RMS)
Isolated
Non-isolated
G MT2 MT1
MT1 MT2
G MT1 MT2
MT1 G MT2
mAmps TO-263 D2Pak Q2016NH3 Q4016NH3 Q6016NH3 Q8016NH3 QK016NH3 Q2016NH4 Q4016NH4 Q6016NH4 Q8016NH4 QK016NH4 Q2016NH6 Q4016NH6 Q6016NH6 Q8016NH6 QK016NH6 Q2025NH6 Q4025NH6 Q6025NH6 Q8025NH6 QK025NH6 Volts 200 400 600 800 1000 200 400 600 800 1000 200 400 600 800 1000 200 400 600 800 1000 200 400 600 QI 20 20 20 20 20 35 35 35 35 35 80 80 80 80 80 80 80 80 80 80 50 50 50 50 50 50 100 100 100 100 100 QII MAX 20 20 20 20 20 35 35 35 35 35 80 80 80 80 80 80 80 80 80 80 50 50 50 50 50 50 100 100 100 100 100 20 20 20 20 20 35 35 35 35 35 80 80 80 80 80 80 80 80 80 80 50 50 50 50 50 50 100 100 100 100 100 QIII
T0-220 MAX Q2016LH3 Q4016LH3 Q6016LH3 Q8016LH3 QK016LH3 Q2016LH4 Q4016LH4
TO-218 (16)
TO-218X
TO-220 Q2016RH3 Q4016RH3 Q6016RH3 Q8016RH3 QK016RH3 Q2016RH4 Q4016RH4 Q6016RH4 Q8016RH4 QK016RH4 Q2016RH6 Q4016RH6 Q6016RH6 Q8016RH6 QK016RH6
See "Package Dimensions" section for variations. (11)
Q6016LH4 Q8016LH4 QK016LH4 Q2016LH6 Q4016LH6 Q6016LH6 Q8016LH6 QK016LH6 Q2025L6 Q2025K6 Q4025K6 Q6025K6 Q8025K6 QK025K6 Q2025J6 Q4025J6 Q6025J6 Q8025J6 Q4025L6 Q6025L6 Q8025L6 QK025L6 Q2030LH5
Q2025R6 Q4025R6 Q6025R6 Q8025R6 QK025R6
Q4030LH5 Q6030LH5 Q2035RH5 Q2035NH5 Q4035NH5 Q6035NH5
Q2040K7 Q4040K7 Q2040J7 Q4040J7 Q6040J7 Q8040J7
Q4035RH5 Q6035RH5
Q6040K7 Q8040K7 QK040K7
See "General Notes" and "Electrical Specification Notes" on page E4 - 5.
Test Conditions
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Data Sheets
Alternistor Triacs
PG(AV)
dv / dt(c)
Amps 60 / 50 Hz 200 / 167 200 / 167 200 / 167 200 / 167 200 / 167 200 / 167 200 / 167 200 / 167 200 / 167 200 / 167 200 / 167 200 / 167 200 / 167 200 / 167 200 / 167 250 / 208 250 / 208 250 / 208 250 / 208 250 / 208 350 / 290 350 / 290 350 / 290 350 / 290 350 / 290 350 / 290 400 / 335 400 / 335 400 / 335 400 / 335 400 / 335 Volts / µSec MIN 20 20 20 20 20 25 25 25 25 25 30 30 30 30 30 30 30 30 30 30 20 20 20 20 20 20 50 50 50 50 50
General Notes
· · · · · All measurements are made at 60 Hz with a resistive load at an ambient temperature of +25 °C unless specified otherwise. Operating temperature range (TJ) is -40 °C to +125 °C. Storage temperature range (TS) is -40 °C to +125 °C. Lead solder temperature is a maximum of 230 °C for 10 seconds maximum 1 / 16" (1.59 mm) from case. The case temperature (TC) is measured as shown in the dimensional outline drawings. See "Package Dimensions" section.
Electrical Specification Notes
(1) (2) (3) (4) For either polarity of MT2 with reference to MT1 terminal For either polarity of gate voltage (VGT) with reference to MT1 terminal See Gate Characteristics and Definition of Quadrants. See Figure E4.1 through Figure E4.4 for current rating at specific operating temperature and Figure 4.16 for free air rating (no heat sink). See Figure E4.5 and Figure E4.6 for iT and vT. See Figure E4.7 for VGT versus TC. See Figure E4.8 for IGT versus TC. See Figure E4.9 for IH versus TC. See Figure E4.10 and Figure E4.11 for surge rating with specific durations.
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Alternistor Triacs
Data Sheets
ALL POLARITIES ARE REFERENCED TO MT1 MT2 POSITIVE (Positive Half Cycle)
IGT GATE MT1
IGT GATE
REF MT2
QII QI QIII QIV
MT2 IGT GATE MT1
MT1 REF
Gate Characteristics
Teccor triacs may be turned on in the following ways: · · In-phase signals (with standard AC line) using Quadrants I and III Application of unipolar pulses (gate always negative), using Quadrants II and III with negative gate pulses
Definition of Quadrants
REF MT2 NEGATIVE (Negative Half Cycle) NOTE: Alternistors will not operate in QIV
Electrical Isolation
In all cases, if maximum surge capability is required, gate pulses should be a minimum of one magnitude above minimum IGT rating with a steep rising waveform (1 µs rise time). If QIV and QI operation is required (gate always positive), see Figure AN1002.8, "Amplified Gate" Thyristor Circuit.
from Leads to Mounting Tab
V AC RMS 2500 4000
TO-218 Isolated
Standard N / A
TO-220 Isolated
Standard Optional
TO-218X Isolated
Standard N / A
UL Recognized File E71639 For 4000 V isolation, use V suffix in part number.
Thermal Resistance (Steady St
|
