ON Semiconductor FGP3440G2-F085 IGBT

The ON Semiconductor FGP3440G2-F085 is a state-of-the-art Insulated Gate Bipolar Transistor (IGBT) that offers high efficiency and fast switching speeds for a wide range of power applications. This IGBT is designed to handle significant power levels while maintaining a low on-state voltage drop, making it an ideal choice for high-performance power conversion systems.

Key Features:

• High Current Rating: The FGP3440G2-F085 is capable of supporting high continuous collector current up to 15 A, making it suitable for demanding power applications.
• Low Saturation Voltage: With a typical collector-emitter saturation voltage of 1.85 V, this IGBT ensures efficient operation, reducing power losses and improving overall system efficiency.
• Fast Switching Speed: The device features a fast switching speed, which is crucial for reducing switching losses, especially in high-frequency power converters.
• High Input Impedance: This IGBT has a high input impedance, which minimizes gate drive power and simplifies gate drive circuitry.
• Co-Packaged Free-Wheeling Diode: The inclusion of a fast and soft recovery diode in the package provides an efficient free-wheeling path during the off state of the IGBT, further enhancing the performance of the overall circuit.

Applications:

The FGP3440G2-F085 is well-suited for a variety of applications including:

• Uninterruptible Power Supplies (UPS)
• Power Factor Correction (PFC) circuits
• Induction heating systems
• Motor drives and inverters
• Solar inverters and renewable energy systems

Product Specifications:

• Package: TO-3P
• Collector-Emitter Voltage (Vces): 600V
• Collector Current (Ic): 15A
• Power Dissipation (Pd): 167W
• Operating Temperature Range: -55°C to +150°C

The FGP3440G2-F085 IGBT from ON Semiconductor is designed with the latest technology to provide reliable and high-performance solutions for a wide array of power electronic applications. Its robust design and advanced features ensure that it meets the stringent requirements of modern power systems.