2N6384 Transistor

Product Overview

The 2N6384 is a high-power NPN silicon transistor designed for general-purpose amplifier and switching applications. This transistor falls under the category of discrete semiconductor devices and is commonly used in electronic circuits for its high power handling capabilities and reliability.

Basic Information

Category: Discrete Semiconductor Device
Use: Amplification and Switching
Characteristics: High Power Handling, Reliable Performance
Package: TO-3 Metal Can
Essence: High-Power NPN Silicon Transistor
Packaging/Quantity: Typically sold individually or in small quantities

Specifications

Maximum Collector-Emitter Voltage (Vce): 100V
Maximum Collector Current (Ic): 15A
Power Dissipation (Pd): 150W
Transition Frequency (ft): 3MHz
Operating Temperature Range: -65°C to 200°C

Detailed Pin Configuration

The 2N6384 transistor has three pins: 1. Base (B): Input terminal for controlling the flow of current through the transistor. 2. Collector (C): Terminal connected to the positive supply voltage. 3. Emitter (E): Terminal through which the output current flows out of the transistor.

Functional Features

High power handling capacity
Low saturation voltage
Fast switching speed
Robust construction for reliable performance

Advantages and Disadvantages

Advantages

Suitable for high-power applications
Low saturation voltage reduces power loss
Fast switching speed for efficient operation

Disadvantages

Relatively large package size
Limited frequency response compared to smaller signal transistors

Working Principles

The 2N6384 operates based on the principles of amplification and control of current flow. When a small current is applied to the base terminal, it controls the larger current flowing between the collector and emitter terminals, allowing for amplification or switching of electrical signals.

Detailed Application Field Plans

The 2N6384 transistor finds application in various fields including: - Power amplifiers - Motor control circuits - High-power switching circuits - Audio amplifiers - Voltage regulators

Detailed and Complete Alternative Models

Some alternative models to the 2N6384 include: - TIP31C - MJ15003 - MJE3055T - 2SC5200

In summary, the 2N6384 transistor is a high-power NPN silicon transistor with versatile applications in amplification and switching circuits. Its robust construction and high power handling make it a popular choice for various electronic designs.

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技術ソリューションにおける 2N6384 の適用に関連する 10 件の一般的な質問と回答をリストします。

What is the 2N6384 transistor used for?
- The 2N6384 is a high-power NPN bipolar junction transistor (BJT) commonly used in power amplifier and switching applications.
What are the key specifications of the 2N6384 transistor?
- The 2N6384 has a maximum collector current of 20A, a maximum collector-emitter voltage of 400V, and a power dissipation of 250W.
How can the 2N6384 be used in power amplifier circuits?
- The 2N6384 can be used as the output transistor in audio amplifiers, RF amplifiers, and other high-power applications due to its high current and voltage ratings.
In what types of switching applications is the 2N6384 commonly employed?
- The 2N6384 is often used in high-power switching circuits such as motor control, power supplies, and inverters due to its ability to handle high currents and voltages.
What are the typical operating conditions for the 2N6384 transistor?
- The 2N6384 is typically operated at a collector current of 10A, a collector-emitter voltage of 200V, and a base current of 2A.
What are some common alternatives to the 2N6384 transistor?
- Alternatives to the 2N6384 include transistors with similar power ratings such as the MJ15003, 2SC5200, and MJE15030.
What are the thermal considerations when using the 2N6384 in a technical solution?
- Proper heat sinking and thermal management are crucial when using the 2N6384 in high-power applications to ensure that it operates within its temperature limits.
Can the 2N6384 be used in parallel to increase current handling capability?
- Yes, the 2N6384 can be used in parallel to increase the overall current handling capability in high-power applications.
What are the typical failure modes of the 2N6384 transistor?
- Common failure modes include thermal runaway due to inadequate heat dissipation, overvoltage stress leading to breakdown, and excessive current causing damage.
Are there any specific considerations for driving the 2N6384 in a technical solution?
- It's important to provide adequate base drive current and voltage to ensure proper saturation and switching speed, especially in high-frequency switching applications.