High Performance Graphene Enhanced Thermal Interface Materials
➢Unleash Efficient Heat Transfer➣
Key Features
• Unmatched Thermal Conductivity, Dimensionally Stable, No Preheating Required, Non-Silicone Oil Type (Ultra-Low Outgassing), Non-Corrosive, Room Temperature Storage, Excellent Electrical Insulation and more.
• Thermal conductivity(W/m.K): 5.8 or customizable.
• Thermal Impedance: 0.01 ℃-in²/W, Stable Dispensing.
• Outstanding heat dissipation performance, suitable for high computing products or equipment (Peak TDP >150W).
• Extensive burn-in testing confirms our grease's superior thermal management, resulting in longer-lasting electronics and enhanced performance.
• Proven long-term reliability (IP 142, ASTM D952) Ambient temperature during operation -40℃~85℃.
KappaX®
graphene
Industrial-grade
Efficient Heat Dissipation: By reducing thermal resistance, our Graphene Thermal Grease effectively dissipates heat, preventing overheating and ensuring optimal performance of electronic components.
Increased Component Lifespan: By keeping temperatures under control, the thermal grease helps extend the lifespan of electronic devices, reducing the risk of premature failures and enhancing overall reliability.
Our Graphene Thermal Grease is an innovative solution designed to optimize heat transfer and improve thermal management in electronic devices, ensuring optimal performance and reliability. Leveraging the remarkable properties of graphene, this advanced thermal interface material offers superior thermal conductivity, exceptional stability, and long-lasting performance.
Improved System Stability: By maintaining lower operating temperatures, our thermal grease contributes to improved system stability, reducing the likelihood of performance throttling or system shutdowns due to thermal issues.
Enhanced Energy Efficiency: Effective heat transfer allows for improved energy efficiency, as devices can operate at lower temperatures, reducing power consumption and optimizing overall system performance.
Easy Maintenance and Upkeep: Our Graphene Thermal Grease requires minimal maintenance, providing long-lasting thermal management without the need for frequent reapplication.
Durability and Longevity
Industrial computers typically have extended service lives and are subject to frequent usage and potential mechanical stress. Graphene-based thermal grease offers enhanced mechanical strength and durability compared to traditional thermal greases. It can withstand vibration, mechanical shocks, and thermal cycling, ensuring reliable and long-lasting performance in industrial environments.
Features
Thermal Conductivity
Oxidation Stability
Electrical Insulation
Mechanical Strength
Chemical Stability
Compatibility
Customizability
Traditional Thermal Grease
Moderate
May degrade over time
Adequate
Adequate
Standard
Broad range
Limited
Graphene Thermal Grease
Moderate
Enhanced oxidation resistance
Excellent electrical insulation
Enhanced mechanical properties
High chemical stability
Depends on specific formulation
Tailored formulations possible
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Ready to give these features a go?
Don't settle for second best. When it comes to thermal management, TiKOUS isn't just keeping pace – we're setting the pace. Choose TiKOUS, and leave the competition in the dust. TiKOUS Thermal Interface Materials: Cooler. Tougher. Longer-lasting. Simply superior.
Why is the thermal interface material crucial?
Thermal interface materials (TIMs) play a critical role in ensuring efficient heat transfer and thermal management in electronic devices. They are specifically designed to fill gaps and imperfections between heat-generating components, such as processors, graphics cards, or power electronics, and heat sinks, which are responsible for dissipating heat into the surrounding environment.
TIMs help minimize the thermal resistance between the heat source and the heat sink by eliminating air gaps and uneven surfaces. Air is a poor conductor of heat, and any air pockets present between the components can impede the transfer of heat, resulting in increased operating temperatures. The use of TIMs ensures intimate contact between the surfaces, facilitating efficient heat flow.
Source: internet
Thermal Paste FAQs
Why do high-performance industrial computers need a thermally stable, non-drying, and durable thermal paste?
High-performance industrial computers often run high-load computations for long periods, generating a lot of heat. These computers might operate 24/7, accumulating up to 8760 hours per year. A thermally stable thermal paste ensures effective heat dissipation, maintaining system efficiency. A non-drying, durable thermal paste can steadily conduct heat, preventing overheating, protecting components, and extending equipment lifespan. Additionally, such thermal paste reduces maintenance needs, lowering overall costs, and maintaining stable performance in harsh environments.
Why is effective heat dissipation important for electronic components?
Overheating can severely damage electronic components, shorten their lifespan, and even cause permanent damage. Research shows that for every 10°C increase in operating temperature, the lifespan of electronic components is halved. Using an efficient thermal paste like KappaX® can effectively conduct heat, preventing overheating, thus protecting components and extending their lifespan.
How important is the electrical insulation property of KappaX® thermal paste?
KappaX® graphene thermal paste, compounded with polymer materials, not only maintains high thermal conductivity but also provides excellent electrical insulation. This ensures that when used in electronic components, it won't cause short circuits or other electrical failures, thereby enhancing device safety.
What is the "Pump-Out" problem in thermal pastes, and how does KappaX® address it?
The "Pump-Out" problem refers to the separation or extrusion of thermal paste components during thermal cycling, causing the paste to dry out or lose thermal conductivity. KappaX® thermal paste's formulation prevents this issue, ensuring long-term thermal performance even in harsh environments, thus extending the lifespan of electronic devices and improving overall reliability.
How does KappaX® thermal paste improve energy efficiency?
KappaX® thermal paste features a low thermal resistance design, enhancing heat dissipation efficiency and keeping the system at lower operating temperatures. This helps improve overall stability, reducing the likelihood of performance limitations or system shutdowns due to heat issues. The long-lasting efficient heat transfer also allows devices to operate at lower temperatures, reducing power consumption and optimizing overall system performance.
Can KappaX® handle the harsh environments in which industrial computers often operate?
Yes, industrial computers often operate in harsh environments such as high temperatures (up to 80°C), high humidity (relative humidity up to 90%), or strong vibrations. KappaX® thermal paste, with its high thermal stability and durability, can maintain stable performance in these conditions, ensuring reliable operation of industrial computers.
How to Choose Thermal Paste Correctly?
Here are the five important indicators to consider when selecting thermal paste:
Thermal Conductivity (unit: W/m·K): Thermal conductivity is a key indicator of the thermal performance of the paste. It is typically measured in W/m·K, using either a metal wire or a disk method. The thermal conductivity measured with a wire is usually higher, but the disk method provides a more accurate representation of real-world conditions.
Thermal Resistance (unit: ℃-in²/W or K·in²/W): Thermal resistance is influenced by the compression rate and thickness of the thermal paste. Higher compression rates and lower thicknesses reduce thermal resistance, thus improving heat transfer efficiency.
Thickness: The thickness of the thermal paste can compensate for height differences between PCB components. For optimal thermal performance, it is generally recommended to use the thinnest possible layer of paste. Note: Please refer to point five (Breakdown Voltage) below.
Volume Resistivity (unit: Ohm·m): Volume resistivity measures the ability of the paste to prevent short circuits when in contact with conductive parts of the components. The higher the volume resistivity, the better the insulation performance of the thermal paste.
Breakdown Voltage (unit: V/mm): Breakdown voltage is the voltage at which an electric arc (short circuit) may occur. This parameter depends on the thickness of the thermal paste. Thinner paste layers pose a higher risk.
Understanding these indicators will help you make the best decision when selecting thermal paste, achieving an optimal balance of performance, cost, and quality.
Trust in...
...our Graphene Enhanced Thermal Grease delivers exceptional thermal conductivity, stability, and reliability, ensuring efficient heat dissipation for your electronic devices. Experience the benefits of enhanced thermal management and unleash the full potential of your systems with our advanced graphene-based solution.
Note: For detailed product specifications, application guidelines, and compatibility information, please refer to the product datasheet or contact our dedicated sales team.