Triode For Alternating Current (TRIAC)
| Part | RoHS | Manufacturer | Trigger Device Type | Package Style (Meter) | Surface Mount | Terminal Position | Configuration | Case Connection | Maximum On-state Voltage | Package Body Material | Maximum DC Gate Trigger Current | Non Repetitive Peak On-state Current | Terminal Form | Package Shape | Maximum On-state Current | No. of Elements | Maximum Leakage Current | Repetitive Peak Reverse Voltage | Maximum Repetitive Peak Off-state Leakage Current | No. of Terminals | Sub-Category | Maximum Operating Temperature | Minimum Operating Temperature | Terminal Finish | Maximum RMS On-state Current | JESD-30 Code | Moisture Sensitivity Level (MSL) | Maximum DC Gate Trigger Voltage | Qualification | Repetitive Peak Off-state Voltage | Minimum Critical Rate of Rise of Commutation Voltage | Minimum Critical Rate of Rise of Off-state Voltage | Maximum Holding Current | Additional Features | JEDEC-95 Code | JESD-609 Code | Maximum Time At Peak Reflow Temperature (s) | Peak Reflow Temperature (C) | Reference Standard |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
|
Renesas Electronics |
TRIAC |
NO |
1.8 V |
10 mA |
1 mA |
TRIACs |
125 Cel |
-40 Cel |
5 A |
1.5 V |
400 V |
5 V/us |
10 |
260 |
||||||||||||||||||||||||
|
|
Renesas Electronics |
TRIAC |
NO |
1.4 V |
30 mA |
2 mA |
TRIACs |
125 Cel |
-40 Cel |
16 A |
1.5 V |
400 V |
10 V/us |
10 |
260 |
||||||||||||||||||||||||
|
|
STMicroelectronics |
TRIAC |
NO |
1.4 V |
10 mA |
.75 mA |
TRIACs |
110 Cel |
-40 Cel |
4 A |
2.5 V |
600 V |
1 V/us |
10 V/us |
25 mA |
||||||||||||||||||||||||
|
|
STMicroelectronics |
TRIAC |
NO |
1.4 V |
5 mA |
.75 mA |
TRIACs |
110 Cel |
-40 Cel |
4 A |
2.5 V |
700 V |
1 V/us |
10 V/us |
15 mA |
||||||||||||||||||||||||
|
|
STMicroelectronics |
TRIAC |
NO |
1.6 V |
50 mA |
.5 mA |
TRIACs |
110 Cel |
-40 Cel |
6 A |
2.5 V |
400 V |
10 V/us |
100 V/us |
50 mA |
||||||||||||||||||||||||
|
|
STMicroelectronics |
TRIAC |
NO |
1.6 V |
10 mA |
.75 mA |
TRIACs |
110 Cel |
-40 Cel |
6 A |
2.5 V |
600 V |
1 V/us |
10 V/us |
25 mA |
||||||||||||||||||||||||
|
|
STMicroelectronics |
TRIAC |
NO |
1.6 V |
25 mA |
.5 mA |
TRIACs |
8 A |
700 V |
5 V/us |
50 V/us |
50 mA |
|||||||||||||||||||||||||||
|
|
STMicroelectronics |
TRIAC |
NO |
1.7 V |
35 mA |
TRIACs |
150 Cel |
-40 Cel |
8 A |
1.5 V |
700 V |
4.5 V/us |
250 V/us |
35 mA |
|||||||||||||||||||||||||
|
|
STMicroelectronics |
TRIAC |
NO |
1.4 V |
50 mA |
.5 mA |
TRIACs |
110 Cel |
-40 Cel |
10 A |
2.5 V |
400 V |
10 V/us |
100 V/us |
50 mA |
||||||||||||||||||||||||
|
|
STMicroelectronics |
TRIAC |
NO |
1.4 V |
25 mA |
.5 mA |
TRIACs |
10 A |
400 V |
5 V/us |
50 V/us |
50 mA |
|||||||||||||||||||||||||||
|
|
STMicroelectronics |
TRIAC |
NO |
1.4 V |
50 mA |
.5 mA |
TRIACs |
110 Cel |
-40 Cel |
10 A |
2.5 V |
700 V |
10 V/us |
100 V/us |
50 mA |
||||||||||||||||||||||||
|
|
STMicroelectronics |
TRIAC |
NO |
1.5 V |
50 mA |
.5 mA |
TRIACs |
110 Cel |
-40 Cel |
12 A |
2.5 V |
700 V |
10 V/us |
100 V/us |
50 mA |
||||||||||||||||||||||||
|
|
STMicroelectronics |
TRIAC |
NO |
1.6 V |
50 mA |
.5 mA |
TRIACs |
125 Cel |
-45 Cel |
16 A |
2.5 V |
400 V |
.00001 V/us |
.0001 V/us |
50 mA |
||||||||||||||||||||||||
|
|
STMicroelectronics |
TRIAC |
NO |
1.7 V |
50 mA |
.01 mA |
TRIACs |
125 Cel |
-40 Cel |
25 A |
1.5 V |
700 V |
500 V/us |
75 mA |
|||||||||||||||||||||||||
|
STMicroelectronics |
TRIAC |
NO |
1.6 V |
50 mA |
3 mA |
TRIACs |
110 Cel |
-40 Cel |
25 A |
3 V |
400 V |
150 V/us |
80 mA |
||||||||||||||||||||||||||
|
|
STMicroelectronics |
TRIAC |
NO |
1.4 V |
5 mA |
.75 mA |
TRIACs |
110 Cel |
-40 Cel |
4 A |
2.5 V |
600 V |
1 V/us |
10 V/us |
15 mA |
||||||||||||||||||||||||
|
|
STMicroelectronics |
TRIAC |
NO |
1.7 V |
50 mA |
TRIACs |
150 Cel |
-40 Cel |
6 A |
1.5 V |
700 V |
5 V/us |
500 V/us |
50 mA |
|||||||||||||||||||||||||
|
|
STMicroelectronics |
TRIAC |
NO |
1.7 V |
50 mA |
TRIACs |
125 Cel |
-40 Cel |
8 A |
1.5 V |
700 V |
7 V/us |
500 V/us |
50 mA |
|||||||||||||||||||||||||
|
|
STMicroelectronics |
TRIAC |
NO |
1.8 V |
5 mA |
.01 mA |
TRIACs |
125 Cel |
-45 Cel |
.8 A |
1.5 V |
400 V |
10 mA |
||||||||||||||||||||||||||
|
|
Littelfuse |
ALTERNISTOR TRIAC |
YES |
50 mA |
6 mA |
TRIACs |
150 Cel |
-40 Cel |
MATTE TIN |
25 A |
1.3 V |
600 V |
20 V/us |
350 V/us |
80 mA |
e3 |
40 |
260 |
|||||||||||||||||||||
|
|
Littelfuse |
ALTERNISTOR TRIAC |
NO |
50 mA |
6 mA |
TRIACs |
150 Cel |
-40 Cel |
MATTE TIN |
25 A |
1.3 V |
600 V |
20 V/us |
350 V/us |
80 mA |
e3 |
40 |
260 |
|||||||||||||||||||||
|
|
Littelfuse |
TRIAC |
YES |
10 mA |
TRIACs |
125 Cel |
-40 Cel |
MATTE TIN |
16 A |
1.3 V |
600 V |
2 V/us |
150 V/us |
15 mA |
e3 |
40 |
260 |
||||||||||||||||||||||
|
|
Littelfuse |
TRIAC |
YES |
10 mA |
TRIACs |
125 Cel |
-40 Cel |
MATTE TIN |
16 A |
1.3 V |
600 V |
2 V/us |
150 V/us |
15 mA |
e3 |
40 |
260 |
||||||||||||||||||||||
|
|
Littelfuse |
ALTERNISTOR TRIAC |
NO |
10 mA |
TRIACs |
125 Cel |
-40 Cel |
MATTE TIN |
16 A |
1.3 V |
600 V |
2 V/us |
150 V/us |
15 mA |
e3 |
40 |
260 |
||||||||||||||||||||||
|
|
Littelfuse |
ALTERNISTOR TRIAC |
NO |
10 mA |
TRIACs |
125 Cel |
-40 Cel |
MATTE TIN |
16 A |
1.3 V |
800 V |
2 V/us |
100 V/us |
15 mA |
e3 |
40 |
260 |
||||||||||||||||||||||
|
|
Littelfuse |
4 QUADRANT LOGIC LEVEL TRIAC |
NO |
10 mA |
.5 mA |
TRIACs |
110 Cel |
-40 Cel |
MATTE TIN |
8 A |
1.3 V |
400 V |
10 mA |
e3 |
40 |
260 |
|||||||||||||||||||||||
|
|
Littelfuse |
4 QUADRANT LOGIC LEVEL TRIAC |
NO |
10 mA |
.5 mA |
TRIACs |
110 Cel |
-40 Cel |
MATTE TIN |
8 A |
1.3 V |
600 V |
10 mA |
e3 |
40 |
260 |
|||||||||||||||||||||||
|
|
Littelfuse |
TRIAC |
NO |
20 mA |
.5 mA |
TRIACs |
110 Cel |
-40 Cel |
MATTE TIN |
8 A |
1.3 V |
600 V |
20 mA |
e3 |
40 |
260 |
|||||||||||||||||||||||
|
|
Littelfuse |
4 QUADRANT LOGIC LEVEL TRIAC |
NO |
20 mA |
.5 mA |
TRIACs |
110 Cel |
-40 Cel |
MATTE TIN |
8 A |
1.3 V |
600 V |
20 mA |
e3 |
40 |
260 |
|||||||||||||||||||||||
|
|
Littelfuse |
TRIAC |
NO |
10 mA |
2 mA |
TRIACs |
110 Cel |
-40 Cel |
MATTE TIN |
8 A |
1.3 V |
400 V |
20 V/us |
75 V/us |
15 mA |
e3 |
40 |
260 |
|||||||||||||||||||||
|
|
Littelfuse |
ALTERNISTOR TRIAC |
NO |
10 mA |
2 mA |
TRIACs |
110 Cel |
-40 Cel |
MATTE TIN |
8 A |
1.3 V |
400 V |
20 V/us |
75 V/us |
15 mA |
e3 |
40 |
260 |
|||||||||||||||||||||
|
|
Littelfuse |
ALTERNISTOR TRIAC |
NO |
10 mA |
2 mA |
TRIACs |
110 Cel |
-40 Cel |
MATTE TIN |
8 A |
1.3 V |
600 V |
20 V/us |
50 V/us |
15 mA |
e3 |
40 |
260 |
|||||||||||||||||||||
|
|
Littelfuse |
TRIAC |
NO |
10 mA |
.5 mA |
TRIACs |
150 Cel |
-40 Cel |
MATTE TIN |
6 A |
1.3 V |
600 V |
10 mA |
e3 |
40 |
260 |
|||||||||||||||||||||||
|
|
Littelfuse |
ALTERNISTOR TRIAC |
NO |
10 mA |
3 mA |
TRIACs |
150 Cel |
-40 Cel |
MATTE TIN |
6 A |
1.3 V |
400 V |
20 V/us |
75 V/us |
15 mA |
e3 |
40 |
260 |
|||||||||||||||||||||
|
|
Littelfuse |
ALTERNISTOR TRIAC |
NO |
10 mA |
3 mA |
TRIACs |
150 Cel |
-40 Cel |
MATTE TIN |
6 A |
1.3 V |
600 V |
20 V/us |
50 V/us |
15 mA |
e3 |
40 |
260 |
|||||||||||||||||||||
|
|
NXP Semiconductors |
TRIAC |
NO |
25 mA |
.5 mA |
TRIACs |
150 Cel |
-40 Cel |
4 A |
1.5 V |
600 V |
15 mA |
|||||||||||||||||||||||||||
|
|
Littelfuse |
ALTERNISTOR TRIAC |
YES |
10 mA |
2 mA |
TRIACs |
110 Cel |
-40 Cel |
MATTE TIN |
8 A |
1.3 V |
600 V |
20 V/us |
50 V/us |
15 mA |
e3 |
40 |
260 |
|||||||||||||||||||||
|
|
NXP Semiconductors |
TRIAC |
YES |
5 mA |
.5 mA |
TRIACs |
150 Cel |
-40 Cel |
1 A |
1.3 V |
600 V |
.5 V/us |
10 V/us |
7 mA |
|||||||||||||||||||||||||
|
|
NXP Semiconductors |
TRIAC |
NO |
7 mA |
.5 mA |
TRIACs |
150 Cel |
-40 Cel |
1 A |
1.3 V |
800 V |
1 V/us |
20 V/us |
10 mA |
|||||||||||||||||||||||||
|
|
STMicroelectronics |
TRIAC |
SMALL OUTLINE |
YES |
DUAL |
SINGLE |
PLASTIC/EPOXY |
10 mA |
7.6 A |
FLAT |
RECTANGULAR |
.8 A |
1 |
3 |
TRIACs |
150 Cel |
-40 Cel |
Matte Tin (Sn) - annealed |
.8 A |
R-PDSO-F3 |
1 |
1 V |
600 V |
e3 |
30 |
260 |
|||||||||||||
|
|
Littelfuse |
TRIAC |
NO |
50 mA |
6 mA |
TRIACs |
150 Cel |
-40 Cel |
MATTE TIN |
25 A |
1.3 V |
600 V |
20 V/us |
350 V/us |
80 mA |
e3 |
40 |
260 |
|||||||||||||||||||||
|
|
Littelfuse |
TRIAC |
FLANGE MOUNT |
NO |
SINGLE |
SINGLE |
MAIN TERMINAL 2 |
PLASTIC/EPOXY |
10 mA |
THROUGH-HOLE |
RECTANGULAR |
1 |
.5 mA |
3 |
TRIACs |
110 Cel |
-40 Cel |
MATTE TIN |
6 A |
R-PSFM-T3 |
1.3 V |
600 V |
10 mA |
TO-220AB |
e3 |
40 |
260 |
||||||||||||
|
|
Littelfuse |
TRIAC |
FLANGE MOUNT |
NO |
SINGLE |
SINGLE |
MAIN TERMINAL 2 |
PLASTIC/EPOXY |
10 mA |
THROUGH-HOLE |
RECTANGULAR |
1 |
3 mA |
3 |
TRIACs |
125 Cel |
-40 Cel |
MATTE TIN |
6 A |
R-PSFM-T3 |
1.3 V |
600 V |
20 V/us |
75 V/us |
15 mA |
TO-220AB |
e3 |
40 |
260 |
||||||||||
|
|
Littelfuse |
TRIAC |
FLANGE MOUNT |
NO |
SINGLE |
SINGLE |
MAIN TERMINAL 2 |
PLASTIC/EPOXY |
10 mA |
THROUGH-HOLE |
RECTANGULAR |
1 |
3 mA |
3 |
TRIACs |
125 Cel |
-40 Cel |
MATTE TIN |
6 A |
R-PSFM-T3 |
1.3 V |
600 V |
20 V/us |
50 V/us |
15 mA |
TO-220AB |
e3 |
40 |
260 |
||||||||||
|
|
STMicroelectronics |
TRIAC |
NO |
SINGLE |
ISOLATED |
200 mA |
1 |
5 mA |
TRIACs |
125 Cel |
-40 Cel |
40 A |
1 |
2.5 V |
600 V |
.00001 V/us |
.0002 V/us |
UL RECOGNIZED |
|||||||||||||||||||||
|
|
STMicroelectronics |
TRIAC |
FLANGE MOUNT |
NO |
SINGLE |
SINGLE |
ISOLATED |
PLASTIC/EPOXY |
150 mA |
THROUGH-HOLE |
RECTANGULAR |
1 |
2 mA |
3 |
TRIACs |
125 Cel |
-40 Cel |
MATTE TIN |
25 A |
R-PSFM-T3 |
2.5 V |
1000 V |
10 V/us |
200 V/us |
e3 |
UL RECOGNIZED |
|||||||||||||
|
|
Renesas Electronics |
TRIAC |
YES |
10 mA |
.1 mA |
TRIACs |
150 Cel |
-55 Cel |
MATTE TIN |
1 A |
1 |
1.5 V |
400 V |
.5 V/us |
10 mA |
e3 |
|||||||||||||||||||||||
|
|
Renesas Electronics |
TRIAC |
NO |
10 mA |
1 mA |
TRIACs |
125 Cel |
-45 Cel |
5 A |
1.5 V |
400 V |
5 V/us |
10 |
260 |
A Triode for Alternating Current (TRIAC) is a semiconductor device that is used to control the flow of electrical current in AC circuits. It is a bidirectional device that can conduct current in both directions, making it useful for AC power control applications.
TRIACs consist of a bidirectional switching element that allows for the control of AC current in both directions. They are typically used in applications where AC voltage needs to be controlled, such as in lighting control, motor speed control, and power supplies.
TRIACs work by applying a small current or voltage to the gate terminal, which allows current to flow through the device. Once the current reaches a certain level, the TRIAC turns on and conducts current in both directions until the current drops below a certain threshold, at which point the TRIAC turns off.
TRIACs are commonly used in conjunction with other components such as capacitors, inductors, and diodes to form complete electronic circuits. They are often used in power control circuits that require precise control of AC voltage or current.