Bourns Silicon Controlled Switches (SCS) 0

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Manufacturers
    • NXP Semiconductors
Trigger Device Type
    • PROGRAMMABLE UJT
    • SILICON CONTROLLED SWITCH
Package Style (Meter)
    • CYLINDRICAL
    • SMALL OUTLINE
Surface Mount
    • NO
    • YES
Terminal Position
    • BOTTOM
    • DUAL
Configuration
    • SINGLE
Case Connection
    • ANODE GATE
Package Body Material
    • METAL
    • PLASTIC/EPOXY
Terminal Form
    • GULL WING
    • WIRE
Package Shape
    • RECTANGULAR
    • ROUND
Maximum On-state Current
    • .175 A
No. of Elements
    • 1
Maximum DC Emitter Current (NPN)
    • .175 A
Maximum Emitter To Base Voltage Limit (PNP)
    • 50 V
    • 70 V
Maximum Anode To Cathode Voltage
    • 1.4 V
No. of Terminals
    • 4
Sub-Category
    • Other Trigger Devices
Maximum Operating Temperature
    • 150 Cel
Minimum Operating Temperature
    • -65 Cel
JESD-30 Code
    • O-MBCY-W4
    • R-PDSO-G4
Qualification
    • Not Qualified
Repetitive Peak Off-state Voltage
    • 70 V
Maximum Holding Current
    • 1 mA
JEDEC-95 Code
    • TO-72
Maximum Emitter To Base Voltage Limit (NPN)
    • 5 V
Maximum DC Emitter Current (PNP)
    • .175 A
Maximum Peak Current
    • .06 uA
Reset All
Part RoHS Manufacturer Trigger Device Type Package Style (Meter) Surface Mount Terminal Position Configuration Case Connection Package Body Material Terminal Form Package Shape Maximum On-state Current No. of Elements Maximum DC Emitter Current (NPN) Maximum Emitter To Base Voltage Limit (PNP) Maximum Anode To Cathode Voltage No. of Terminals Sub-Category Maximum Operating Temperature Minimum Operating Temperature JESD-30 Code Qualification Repetitive Peak Off-state Voltage Maximum Holding Current JEDEC-95 Code Maximum Emitter To Base Voltage Limit (NPN) Maximum DC Emitter Current (PNP) Maximum Peak Current
Silicon Controlled Switches (SCS)

Silicon Controlled Switches (SCS) are semiconductor devices that are used to control the flow of electrical current in high-power applications. They are similar to Silicon Controlled Rectifiers (SCRs) but have additional features that allow for greater control and flexibility.

SCSs consist of four layers of alternating p-type and n-type semiconductor material, forming three p-n junctions. The device has three terminals: the anode (A), the cathode (K), and the gate (G). The SCS is designed to conduct current only in one direction, from the anode to the cathode.

SCSs work by applying a positive voltage to the anode, which causes current to flow into the device. The gate terminal is used to control the flow of current by applying a voltage pulse to trigger the device. Once triggered, the SCS conducts current until the voltage across the device drops below a certain level, at which point it turns off.

SCSs have additional features such as the ability to control the turn-on and turn-off times of the device, allowing for greater control over the flow of current. They also have lower holding currents and faster turn-off times than SCRs, making them suitable for high-speed applications.

SCSs are commonly used in high-power applications such as motor control, lighting control, and power supplies. They are often used in conjunction with other components such as capacitors, inductors, and diodes to form complete electronic circuits.