33 W Power Bipolar Junction Transistors (BJT) 8

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Part	Manufacturer	Polarity or Channel Type	Configuration	Surface Mount	Nominal Transition Frequency (fT)	Maximum Power Dissipation (Abs)	Maximum Collector Current (IC)	Package Body Material	Transistor Application	Maximum VCEsat	Terminal Form	Package Shape	No. of Elements	No. of Terminals	Package Style (Meter)	Sub-Category	Maximum Power Dissipation Ambient	Minimum DC Current Gain (hFE)	Maximum Operating Temperature	Transistor Element Material	Maximum Collector-Emitter Voltage	Maximum Turn On Time (ton)	Maximum Turn Off Time (toff)	Terminal Finish	Terminal Position	JESD-30 Code	Moisture Sensitivity Level (MSL)	Case Connection	Qualification	Additional Features	JEDEC-95 Code	JESD-609 Code	Maximum Time At Peak Reflow Temperature (s)	Peak Reflow Temperature (C)
NSS1C300ET4G	Onsemi	PNP	SINGLE	YES	100 MHz	33 W	3 A	PLASTIC/EPOXY	SWITCHING		GULL WING	RECTANGULAR	1	2	SMALL OUTLINE	Other Transistors		50	150 Cel	SILICON	100 V			MATTE TIN	SINGLE	R-PSSO-G2	1	COLLECTOR				e3	30	260
NSS1C301ET4G	Onsemi	NPN	SINGLE	YES	120 MHz	33 W	3 A	PLASTIC/EPOXY	SWITCHING		GULL WING	RECTANGULAR	1	2	SMALL OUTLINE	Other Transistors		80	150 Cel	SILICON	100 V			MATTE TIN	SINGLE	R-PSSO-G2	1	COLLECTOR				e3	30	260
NSV1C300ET4G	Onsemi	PNP	SINGLE	YES		33 W	3 A						1			Other Transistors		120	150 Cel					MATTE TIN			1					e3	30	260
NSV1C301ET4G	Onsemi	NPN	SINGLE	YES		33 W	3 A						1			Other Transistors		120	150 Cel					MATTE TIN			1					e3	30	260
BUL138FP	STMicroelectronics	NPN	SINGLE	NO		33 W	5 A	PLASTIC/EPOXY	SWITCHING		THROUGH-HOLE	RECTANGULAR	1	3	FLANGE MOUNT	Other Transistors		8	150 Cel	SILICON	400 V			MATTE TIN	SINGLE	R-PSFM-T3		ISOLATED	Not Qualified			e3
BUT18F	NXP Semiconductors	NPN	SINGLE	NO		33 W	6 A	PLASTIC/EPOXY	SWITCHING	1.5 V	THROUGH-HOLE	RECTANGULAR	1	3	FLANGE MOUNT	Other Transistors	33 W	10	150 Cel	SILICON	400 V	1000 ns	4800 ns		SINGLE	R-PSFM-T3		ISOLATED	Not Qualified	FORMED LEAD OPTIONS ARE AVAILABLE	TO-220AB
BUT12XI	NXP Semiconductors	NPN	SINGLE	NO		33 W	8 A	PLASTIC/EPOXY	SWITCHING	1.5 V	THROUGH-HOLE	RECTANGULAR	1	3	FLANGE MOUNT	Other Transistors	33 W	14	150 Cel	SILICON	450 V	1000 ns	4800 ns		SINGLE	R-PSFM-T3		ISOLATED	Not Qualified
BUT18AF	NXP Semiconductors	NPN	SINGLE	NO		33 W	6 A	PLASTIC/EPOXY	SWITCHING	1.5 V	THROUGH-HOLE	RECTANGULAR	1	3	FLANGE MOUNT	Other Transistors	33 W	10	150 Cel	SILICON	450 V	1000 ns	4800 ns		SINGLE	R-PSFM-T3		ISOLATED	Not Qualified	FORMED LEAD OPTIONS ARE AVAILABLE	TO-220AB

Power Bipolar Junction Transistors (BJT)

Power Bipolar Junction Transistors (BJT) are electronic devices used in power electronics to control and switch high current and voltage levels. They are commonly used in applications such as power supplies, motor drives, and welding equipment.

The Power BJT is a three-layer device that consists of an emitter, base, and collector region. The emitter and collector are heavily doped, while the base region is lightly doped. The power BJT works by controlling the flow of majority charge carriers (electrons or holes) from the emitter to the collector region through the base region. When a voltage is applied to the base-emitter junction, a current flows through the base, allowing a larger current to flow from the emitter to the collector.

Power BJTs are designed to handle high current and voltage levels, and have a low on-resistance and high gain. They are typically used in applications that require efficient and precise control of power, such as motor drives and power supplies.

Power BJTs are available in various types and configurations, including NPN and PNP bipolar transistors, and can handle power levels ranging from a few watts to several kilowatts. They are subject to various standards and regulations, such as UL (Underwriters Laboratories) and CE (Conformité Européenne), to ensure their safety and performance.

Proper selection and use of Power BJTs are critical to ensure safe and reliable operation of power electronics systems. Power BJTs are often used in conjunction with other components, such as diodes and capacitors, to form complete power electronics circuits.