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IRF7379TRPBF
Product Overview
Category: Power MOSFET
Use: Switching applications in power supplies, motor control, and other high current applications
Characteristics: High voltage, low on-resistance, small package size
Package: D2PAK
Essence: Power MOSFET for efficient switching
Packaging/Quantity: Tape & Reel, 800 units per reel
Specifications
- Voltage Rating: 75V
- Continuous Drain Current: 209A
- RDS(ON): 1.8mΩ
- Gate Charge (Qg): 150nC
- Operating Temperature Range: -55°C to 175°C
Detailed Pin Configuration
The IRF7379TRPBF has a standard D2PAK pin configuration with three pins: Gate (G), Drain (D), and Source (S).
Functional Features
- Low on-resistance for minimal power dissipation
- Fast switching speed for efficient operation
- High current handling capability for demanding applications
Advantages and Disadvantages
Advantages: - High voltage rating - Low on-resistance - Small package size
Disadvantages: - Higher gate charge compared to some alternative models - Limited operating temperature range
Working Principles
The IRF7379TRPBF operates based on the principle of field-effect transistors, where the voltage applied to the gate terminal controls the flow of current between the drain and source terminals.
Detailed Application Field Plans
This power MOSFET is suitable for a wide range of applications including: - Power supplies - Motor control - High current switching applications
Detailed and Complete Alternative Models
Some alternative models to IRF7379TRPBF include: - IRF7319 - IRF7343 - IRF7389
In conclusion, the IRF7379TRPBF is a high-performance power MOSFET suitable for various switching applications, offering high voltage ratings, low on-resistance, and fast switching speeds. Its compact package and high current handling capability make it an ideal choice for power supply and motor control applications. While it has certain limitations such as gate charge and operating temperature range, it remains a popular choice in the industry.
Enumere 10 preguntas y respuestas comunes relacionadas con la aplicación de IRF7379TRPBF en soluciones técnicas
What is the IRF7379TRPBF?
- The IRF7379TRPBF is a dual N-channel power MOSFET designed for use in various technical solutions requiring high efficiency and reliability.
What is the maximum voltage and current rating of the IRF7379TRPBF?
- The IRF7379TRPBF has a maximum voltage rating of 30V and a continuous drain current of 6.3A.
What are the typical applications of the IRF7379TRPBF?
- Typical applications include power management, battery protection, motor control, and other high-efficiency switching solutions.
What is the on-resistance of the IRF7379TRPBF?
- The on-resistance (RDS(on)) of the IRF7379TRPBF is typically around 20mΩ.
Is the IRF7379TRPBF suitable for use in automotive applications?
- Yes, the IRF7379TRPBF is designed to meet the requirements for automotive applications, including those with high temperature and reliability demands.
Does the IRF7379TRPBF require any external components for proper operation?
- The IRF7379TRPBF may require external components such as gate drivers and protection circuitry depending on the specific application requirements.
What is the thermal resistance of the IRF7379TRPBF?
- The thermal resistance of the IRF7379TRPBF is typically around 40°C/W, which is important for determining its heat dissipation capabilities.
Can the IRF7379TRPBF be used in parallel to increase current handling capability?
- Yes, the IRF7379TRPBF can be used in parallel to increase the overall current handling capability in high-power applications.
What are the key features that make the IRF7379TRPBF suitable for technical solutions?
- Key features include low on-resistance, fast switching speed, low gate charge, and high current handling capability, making it ideal for high-efficiency power management.
Are there any known limitations or considerations when using the IRF7379TRPBF in technical solutions?
- Some considerations include proper heat sinking and thermal management due to its power dissipation characteristics, as well as attention to gate drive requirements for optimal performance.