Thermal conductive gel: a technology pioneer in optimizing the performance of intelligent driving controllers

In the rapidly developing field of intelligent driving, as the core brain of the system, the stability and effectiveness of the controller performance is directly related to the safety and driving experience of the vehicle. With the wide application of high-performance processors and chips, intelligent driving controller will generate a lot of heat in the process of operation.If the heat cannot be timely and effectively dissipated, the performance of the equipment will be seriously affected and even lead to faults.

Thermal conductive gel, also known as thermal conductive putty, stands out for its excellent thermal conductivity. It has the advantages of both thermal gasket and thermal silicone grease, strong plasticity, can flexibly adapt to various shapes and sizes of heat dissipation components, without special consideration of tolerance limits. This paste feature enables the thermal conductive gel to closely fit the heat source and heat dissipation element inside the controller, significantly reducing thermal resistance and improving heat transfer efficiency. At the same time, the thermal conductivity gel also has excellent weather resistance, high and low temperature resistance and insulation, to ensure that it can work stably in bad environment.

Characteristics of Ziitek thermal conductive gel:
Thermal conductivity: 1.5~5.0W/mK
Operating temperature: -45℃ to 200℃
Two component material, easy to store
Curing time can be adjusted according to temperature
Excellent high and low temperature mechanical properties and chemical stability
Easy to use in automated dispensing systems
The thickness can be adjusted by automatic equipment

In the intelligent driving controller, the application of heat conduction gel greatly optimizes the heat dissipation design. By quickly transferring the heat inside the controller to the heat dissipation components, the thermal conductive gel effectively reduces the heat source temperature, avoiding the risk of performance degradation and failure due to high temperatures. This not only improves the stability and reliability of the controller, but also extends its service life, providing a strong guarantee for the long-term stable operation of intelligent driving system. However, the complex internal structure of intelligent driving controller puts forward higher requirements for thermal management materials. With its plasticity and good fluidity, thermally conductive gels can easily cope with various irregular interface and gap filling requirements. Whether it is a flat PCB board or a complex component corner, the thermal gel ensures good contact and heat transfer. In addition, the thermal conductive gel also has certain adhesion, not easy to oil out and dry, which further enhances its advantage in reliability.