The TDH35P2R00JE-TR is a thick film, non-inductive power resistor manufactured by Ohmite. It's designed to handle high power dissipation in a compact size, making it suitable for various industrial and electronic applications.

Applications:

• Power Supplies: Used as a bleeder resistor, current limiting resistor, or load resistor in power supply circuits.
• Motor Drives: Employed as braking resistors in motor control applications.
• Inverters: Utilized as load resistors for testing and calibration of inverters.
• RF Amplifiers: Used as termination resistors in RF amplifier circuits.
• Testing Equipment: Found in test and measurement equipment for load simulation.

Features:

• High Power Rating: Capable of dissipating a significant amount of power.
• Non-Inductive Design: Minimizes inductance for high-frequency applications.
• Thick Film Construction: Provides good thermal stability and reliability.
• Compact Size: Small footprint for high power density.
• RoHS Compliant: Meets environmental regulations.
• Tape and Reel Packaging: Suitable for automated assembly.

Benefits:

• Reliable Performance: Provides stable resistance values under high power conditions.
• Reduced Component Count: High power handling capability reduces the need for multiple resistors.
• Improved System Efficiency: Non-inductive design minimizes energy losses at high frequencies.
• Simplified Assembly: Tape and reel packaging facilitates automated assembly.
• Environmentally Friendly: RoHS compliance ensures environmental safety.

Additional Details:

The TDH35P2R00JE-TR has a resistance value of 2 Ohms and a power rating of 35 Watts. It's important to ensure adequate heat sinking to prevent overheating when operating at high power levels. The operating temperature range is typically specified in the datasheet. The resistor is designed for surface mounting and requires proper soldering techniques. The “-TR” suffix indicates that the part is supplied in tape and reel packaging. Derating curves should be consulted in the datasheet to determine the maximum power dissipation at a given ambient temperature.