onsemi

onsemi

ON Semiconductor is a leading provider of power management and semiconductor solutions for a wide range of applications, including automotive, industrial, consumer, and communications. The company's comprehensive portfolio encompasses products such as power semiconductors, analog ICs, sensors, and imaging technologies. ON Semiconductor's innovative solutions enable efficient power management, enhance system performance, and facilitate the development of advanced electronic devices. With a commitment to sustainability, the company focuses on delivering energy-efficient solutions that help customers reduce their environmental impact. ON Semiconductor's dedication to quality and reliability has established it as a trusted partner for design engineers and manufacturers worldwide, supporting the development of cutting-edge technologies across various industries.

DIACs, SIDACs

Results:
13
Series
Voltage - Breakover
Package / Case
Current - Breakover
Current - Peak Output
Supplier Device Package
Operating Temperature
Current - Hold (Ih) (Max)
Results remaining13
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ImageProduct DetailPriceAvailabilityECAD ModelSeriesSupplier Device PackageOperating TemperaturePackage / CaseVoltage - BreakoverCurrent - Hold (Ih) (Max)Current - BreakoverCurrent - Peak Output
SMT10001T3
THY SMB SPECIAL SURGE
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Quantity
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PCB Symbol, Footprint & 3D Model
*
-
-
-
-
-
-
-
MKP1V130RL
SIDAC 120-140V 900MA AXIAL
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Quantity
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PCB Symbol, Footprint & 3D Model
-
Axial
-40°C ~ 125°C (TJ)
DO-204AL, DO-41, Axial
120 ~ 140V
100 mA
35 µA
900 mA
MKP1V160RL
SIDAC 150-170V 900MA AXIAL
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Quantity
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PCB Symbol, Footprint & 3D Model
-
Axial
-40°C ~ 125°C (TJ)
DO-204AL, DO-41, Axial
150 ~ 170V
100 mA
200 µA
900 mA
MKP1V160
SIDAC 150-170V 900MA AXIAL
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Quantity
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PCB Symbol, Footprint & 3D Model
-
Axial
-40°C ~ 125°C (TJ)
DO-204AL, DO-41, Axial
150 ~ 170V
100 mA
200 µA
900 mA
MKP1V240RL
SIDAC 220-250V 900MA AXIAL
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Quantity
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PCB Symbol, Footprint & 3D Model
-
Axial
-40°C ~ 125°C (TJ)
DO-204AL, DO-41, Axial
220 ~ 250V
100 mA
35 µA
900 mA
MKP9V160RL
SIDAC 150-170V 900MA AXIAL
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Quantity
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PCB Symbol, Footprint & 3D Model
-
Axial
-40°C ~ 125°C (TJ)
DO-204AL, DO-41, Axial
150 ~ 170V
100 mA
200 µA
900 mA
MKP3V240RL
SIDAC 220-250V 1A AXIAL
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Quantity
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PCB Symbol, Footprint & 3D Model
-
Axial
-40°C ~ 125°C (TJ)
DO-201AA, DO-27, Axial
220 ~ 250V
100 mA
200 µA
1 A
MKP3V240
SIDAC 220-250V 1A AXIAL
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Quantity
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PCB Symbol, Footprint & 3D Model
-
Axial
-40°C ~ 125°C (TJ)
DO-201AA, DO-27, Axial
220 ~ 250V
100 mA
200 µA
1 A
DB3
DIAC 28-36V 2A DO35
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Quantity
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PCB Symbol, Footprint & 3D Model
-
DO-35
-40°C ~ 125°C (TJ)
DO-204AH, DO-35, Axial
28 ~ 36V
-
100 µA
2 A
DB3TG
DIAC 30-34V 2A DO35
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Quantity
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PCB Symbol, Footprint & 3D Model
-
DO-35
-40°C ~ 125°C (TJ)
DO-204AH, DO-35, Axial
30 ~ 34V
-
15 µA
2 A
SMT10002T3
THYRISTOR SURGE PROTECTION DEVIC
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Quantity
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PCB Symbol, Footprint & 3D Model
*
-
-
-
-
-
-
-
MKP1V120RL
SIDAC 110-130V 900MA AXIAL
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Quantity
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PCB Symbol, Footprint & 3D Model
-
Axial
-40°C ~ 125°C (TJ)
DO-204AL, DO-41, Axial
110 ~ 130V
100 mA
35 µA
900 mA
MKP3V120G
SIDAC, 130V MAX
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Quantity
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PCB Symbol, Footprint & 3D Model
-
Axial
-40°C ~ 125°C (TJ)
DO-201AD, Axial
110 ~ 130V
100 mA
200 µA
1 A

About  DIACs, SIDACs

DIAC and SIDAC devices belong to a family of two-terminal components that find widespread use as triggering mechanisms in AC phase control applications. Their primary function is to regulate the flow of current until a specific voltage threshold is reached, at which point they allow a significant increase in current flow. The key distinction between DIACs (Diodes for Alternating Current) and SIDACs (Silicon Diode for Alternating Current) lies in their characteristic curves. DIACs typically exhibit higher forward voltages in their conductive mode compared to SIDACs. As a result, when applications require substantial current flow, SIDACs are generally more suitable due to their lower forward voltage drop. In AC phase control applications, these devices play a critical role in achieving precise control over the flow of alternating current. By serving as triggering mechanisms, DIACs and SIDACs enable the regulation of power levels and facilitate the proper functioning of electronic circuits. It is important to select the appropriate device based on the specific requirements of the application. If the application demands higher current flow, SIDACs are generally preferred due to their lower forward voltage drop. However, if the application allows for higher forward voltages, DIACs can also be used effectively. In summary, DIACs and SIDACs are two-terminal devices commonly used as triggering mechanisms in AC phase control applications. They regulate current flow until a specific voltage threshold is reached. While DIACs exhibit higher forward voltages in their conductive mode, making them less suitable for high-current applications, SIDACs offer a lower forward voltage drop, making them more favorable in such scenarios. Proper selection between DIACs and SIDACs is crucial for achieving optimal performance in AC phase control applications.