Thermal gap filler conductivity has increased dramatically over the last 10 years. The ever-increasing power and smaller area have driven the need for higher conductivity thermal gap fillers. In order to increase thermal conductivity, Fujipoly has explored various thermal fillers to achieve ultra-high thermal conductivity. One of those fillers is carbon fiber.
Overview
Thermal gap filler conductivity has increased dramatically over the last 10 years. The ever-increasing power and smaller area have driven the need for higher conductivity thermal gap fillers. In order to increase thermal conductivity, Fujipoly has explored various thermal fillers to achieve ultra-high thermal conductivity. One of those fillers is carbon fiber.
In this webinar, we will look at the need for higher conductivity materials and how carbon fiber-oriented thermal gap fillers can meet the demand for higher heat flux. Carbon fiber-oriented thermal gap fillers exhibit very low thermal resistance while still offering a highly compressible thermal gap filler. We will explore some of the properties of carbon fiber-oriented gap fillers as well as best practices for implementing them. We will discuss how they can be a great option when more conventional thermal gap fillers are not proving the thermal resistance or compliance needed. For more information, call (732) 969-0100 or visit us on the Web at click here!
For free samples and quote visit: click here!
Key Takeaways
- Understand why thermal interface materials are crucial for effective heat management.
- Explore the benefits of carbon fiber-based vs traditional ceramic-based gap fillers.
- Review advances made by Fujipoly in addressing thermal management challenges.
