Allicdata Part #: | 2SC4620TV2P-ND |
Manufacturer Part#: |
2SC4620TV2P |
Price: | $ 0.00 |
Product Category: | Discrete Semiconductor Products |
Manufacturer: | ROHM Semiconductor |
Short Description: | TRANS NPN 400V 0.1A ATV |
More Detail: | Bipolar (BJT) Transistor NPN 400V 100mA 20MHz 1W T... |
DataSheet: | 2SC4620TV2P Datasheet/PDF |
Quantity: | 1000 |
1 +: | 0.00000 |
Series: | -- |
Packaging: | Tape & Reel (TR) |
Part Status: | Obsolete |
Transistor Type: | NPN |
Current - Collector (Ic) (Max): | 100mA |
Voltage - Collector Emitter Breakdown (Max): | 400V |
Vce Saturation (Max) @ Ib, Ic: | 500mV @ 1mA, 10mA |
Current - Collector Cutoff (Max): | 10µA (ICBO) |
DC Current Gain (hFE) (Min) @ Ic, Vce: | 82 @ 10mA, 10V |
Power - Max: | 1W |
Frequency - Transition: | 20MHz |
Operating Temperature: | 150°C (TJ) |
Mounting Type: | Through Hole |
Package / Case: | 3-SIP |
Supplier Device Package: | ATV |
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2SC4620TV2P is a high-current transistor with a collector current rating of up to 12A. It is classified as a single bipolar transistor, and is commonly used in applications such as switching, small signal amplifiers, linear power amplifiers, audio amplifiers, and other medium- to high-power applications. This transistor is designed to operate within a wide range of voltages, and can work well over a temperature range of -10 ~ 125 C.
The 2SC4620TV2P is designed to take advantage of the bipolar junction transistor, or BJT, current gain property. The way this works is that, with a small base current, the transistor can handle much larger collector and emitter currents. The gain of the transistor, or the ratio of collector current to base current, is what gives it its capability for amplifying signals, and for driving high-current loads. The current gain of this transistor, typically known as the “beta” or hfe parameter, typically ranges from 80 to 900.
Bipolar transistors operate in three distinct regions, which are known as cut-off, active, and saturation. These terms refer to the types of current flow through the transistor, and to the voltages on the various terminals. In cut-off mode, the transistor behaves like an open switch, with no current flowing through it, and the voltages are such that electrons are not able to cross between the collector and emitter terminals. In active mode, the transistor is turned on, and current can flow between the collector and emitter, with the current gain property of the transistor coming into play as the base current is amplified by the collector current. In saturation mode, the transistor is fully turned on, and the collector current is limited only by the amount of base current that is applied.
In operation, the 2SC4620TV2P transistor will switch quite quickly and predictably, making it ideal for many types of electronic switching applications. Its current gain also allows for it to be used in linear and audio amplifier circuits, as it provides a consistent and strong signal amplification. This transistor is also capable of handling large current levels, making it a good choice for small power and medium- to high-power applications.
Due to the nature of the transistor, it is important to consider the maximum current and voltage ratings of the model when choosing the right transistor for the job. The collector-emitter voltage rating, or VCEO, should never be exceeded, and it is important to ensure that the base current level, and consequently the collector current, is within the limits of the model as well. Additionally, it is important to pay attention to the thermal ratings of the transistor, as some models have ratings that limit the amount of heat generated in operation.
Overall, the 2SC4620TV2P transistor is a reliable and versatile device, capable of handling a large range of power levels and switching requirements. With its high current ratings and relatively low temperature operation, it is a popular choice for many applications. It’s important to pay attention to the ratings of the model when choosing the right transistor for the job, and also to consider the thermal ratings of the device.
The specific data is subject to PDF, and the above content is for reference
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