FQB6N90TM_AM002
Product Overview
Category
The FQB6N90TM_AM002 belongs to the category of power MOSFETs.
Use
It is used as a high-voltage, fast-switching N-channel enhancement-mode power MOSFET.
Characteristics
- High voltage capability
- Fast switching speed
- Low on-resistance
- Enhanced ruggedness and reliability
Package
The FQB6N90TM_AM002 is typically available in TO-263 packaging.
Essence
This MOSFET is essential for power management and control in various electronic applications.
Packaging/Quantity
It is usually packaged in reels or tubes, with quantities varying based on manufacturer specifications.
Specifications
- Drain-Source Voltage (VDS): 900V
- Continuous Drain Current (ID): 6A
- On-Resistance (RDS(on)): 1.8Ω
- Gate-Source Voltage (VGS): ±30V
- Total Gate Charge (Qg): 18nC
- Operating Temperature Range: -55°C to 150°C
Detailed Pin Configuration
The FQB6N90TM_AM002 has a standard pin configuration with three pins: gate, drain, and source.
Functional Features
- High voltage capability allows for use in high-power applications.
- Fast switching speed enables efficient power control.
- Low on-resistance minimizes power loss and heat generation.
Advantages
- Suitable for high-voltage applications
- Fast and efficient switching
- Low power dissipation
Disadvantages
- Sensitive to static electricity
- Requires careful handling during installation
Working Principles
The FQB6N90TM_AM002 operates based on the principles of field-effect transistors, utilizing the control of electric fields to modulate the conductivity of the channel between the drain and source.
Detailed Application Field Plans
The FQB6N90TM_AM002 is commonly used in: - Switching power supplies - Motor control - Inverters - LED lighting - Audio amplifiers
Detailed and Complete Alternative Models
Some alternative models to the FQB6N90TM_AM002 include: - IRF840 - STP16NF06 - FQP50N06L - IRL540
In conclusion, the FQB6N90TM_AM002 power MOSFET offers high-voltage capability, fast switching speed, and low on-resistance, making it suitable for various power management applications across different industries.
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Lista 10 Vanliga frågor och svar relaterade till tillämpningen av FQB6N90TM_AM002 i tekniska lösningar
What is the FQB6N90TM_AM002?
- The FQB6N90TM_AM002 is a power MOSFET designed for various technical solutions requiring high efficiency and reliability.
What are the key features of FQB6N90TM_AM002?
- The key features include a low on-resistance, high current capability, fast switching speed, and a rugged design suitable for demanding applications.
In what technical solutions can FQB6N90TM_AM002 be used?
- FQB6N90TM_AM002 can be used in applications such as power supplies, motor control, lighting, and other power management systems.
What is the maximum voltage and current rating of FQB6N90TM_AM002?
- The maximum voltage rating is 900V, and the maximum continuous drain current is 6A.
Does FQB6N90TM_AM002 require any special heat dissipation considerations?
- Yes, due to its high current capability, proper heat sinking or thermal management may be necessary to ensure optimal performance and reliability.
Is FQB6N90TM_AM002 suitable for high-frequency switching applications?
- Yes, it has a fast switching speed and can be used in high-frequency applications with appropriate circuit design considerations.
What are the typical thermal characteristics of FQB6N90TM_AM002?
- The device has a low thermal resistance and is designed to efficiently dissipate heat when properly mounted on a heatsink.
Are there any recommended driver ICs or gate drivers for FQB6N90TM_AM002?
- While specific recommendations may vary based on the application, using a gate driver to properly drive the MOSFET can improve overall performance and efficiency.
Can FQB6N90TM_AM002 be used in automotive applications?
- Yes, it can be used in automotive systems, but it's important to ensure that it meets the necessary automotive-grade standards and requirements.
What are the typical failure modes of FQB6N90TM_AM002 and how can they be mitigated?
- Common failure modes include overcurrent, overvoltage, and thermal stress. These can be mitigated by implementing appropriate protection circuits, ensuring proper voltage and current ratings, and managing thermal conditions effectively.