ホーム ニュース&イベント 技術関連記事 What are heatsinks? Why Fanless Industrial Computers Use Them?
    技術関連記事
    23.May.2022

    What are heatsinks? Why Fanless Industrial Computers Use Them?

    What are heatsinks? Why fanless industrial computers use them?

    What are heatsinks?

    Heatsinks are thermal dissipaters that regulate and manage the temperature of essential computer components. They keep computers cool by pulling heat generated by the component and radiating it into the air. As computers become more advanced and drive higher performance, thermal regulation becomes a key element. Refusing to accommodate high temperature components can result in a shorter product lifespan, system failure, and eventually permanent damage to the computer.
     

    Why is fanless design important for industrial applications?

    The fanless design is significant in industrial applications because of its already hardened and ruggedized form factor. With a fully enclosed system, external conditions will not come in contact with sensitive components within. An example is the deployment of our industrial computer in a factory where corrosive elements and debris are found in the air. These corrosive particles and debris can damage the internals of the computer and eventually destroy it. However, with our fanless design, the computer can sustainably operate reliably in these harsh conditions. The fanless passive-cooling design is a pivotal feature that Edge Computers have, compared to traditional desktop computers.
    Learn more about the 6 steps to build a Fanless PC

     

    industrial computer wide temperature with passive cooling
     

    How do heatsinks cool down computers?

    Heatsinks are made of conductive materials like copper and aluminum that can effectively absorb and distribute heat rapidly. Most heatsinks are fin-shaped to maximize surface area to distribute as much heat into the air as possible and are capable of ‘natural convection’. Natural convection is the passive movement of heat distribution to radiation into the air.
     

    active cooling vs passive cooling
     

    What are the different types of heatsinks? (Active-cooling vs passive-cooling)

    Because some computer components, like GPUs generate great amounts of heat, the addition of a fan to actively cool the component is needed. Heatsinks move the heat away from these components and a fan blows the heat out of the entire system. However, passive cooling relies solely on the heatsink to disperse heat away from the components without the need of a fan. For industrial purposes, computers are built with a fanless design. The computer is fully enclosed therefore generated heat would be trapped within the system; however, C&T has designed a heatsink chassis where heat would be spread throughout the chassis of the system and dissipated to the air outside. That way any heat built within the system is properly radiated out through the heatsink chassis. 
     

    Popular critical components that require heatsinks

    There are three main components on a computer that generate the most amount of heat. Without any thermal regulators incorporated onto these parts, the computer system will ultimately fail and be in-operatable.
     

    CPU (Central Processing Unit)

    CPU is the ‘brain’ of the whole computer and is where nearly all data processing takes place. When looking inside a computer, the large set of fins and copper rods that sits on the motherboard is the heatsink for the CPU. Desktop computers use active cooling to regulate the temperature of the CPU, however, industrial computers remain fanless and use passive cooling with the chassis heatsink design. It is important to note that passive cooling is only compatible with certain CPUs with set TDP (Thermal Design Power). Overclocking and CPUs with high heat loads cannot be passively cooled properly.
     

    Premio Chassis Heatsink Design passively cools CPU
    • C&T’s 10th Gen Intel AI Edge Inference Computer (RCO-6000-CMLis passively cooled with a finned aluminum chassis design. Copper rods are in contact with the CPU and spread across the chassis to evenly distribute heat while the aluminum radiates the heat into the air. This design serves as both a heatsink to cool the vital components within and a chassis to protect the internals from extraneous elements. This design is capable of passively cooling both 10th Gen Intel Core and Xeon W Processors.
       
    CPU Passive Cooling Solution
    Asset credits to Noctua 
     
    • Passive cooling solutions for CPUs will typically look like Noctua’s NH-P1. In order to distribute and radiate heat effectively, perfectly sized and precisely spread fins are needed to optimize natural convection. The NH-P1 can handle most CPUs up to 12th Gen Intel Core and Intel Xeon E Processors.
    Learn more about CPU wattage and how it affect cooling
     

    M.2 NVMe

    M.2 NVMe, although miniscule in size, requires a heatsink due to the amount of data rapidly being processed and stored. Unlike the CPU, M.2 NVMe do not need a chassis sized heatsink to cool down, an aluminum finned heatsink is enough to dissipate the heat.
     

    M.2 NVMe heatsink cooling solution
    Asset credits to Corsair
     
    • M.2 NVMe can reach up to 100°C when under load. However, with a heatsink, temperatures will only reach 60°C-70°C. This dramatic decrease in temperature shows how effective heatsinks are and the importance of component cooling to ensure reliability and system integrity.
    Learn more about M.2 expansion slot and the future of robust and compact interface
     

    GPU (Graphics Processing Unit)

    GPU is a performance accelerator that enables AI inferencing and other data intensive applications to operate seamlessly for machine learning workloads . GPUs are large components and require a long arrangement of fins throughout its structure and sometimes multiple fans.
     

    GPU blower fan cooling solution
    Asset credits to Nvidia
      
    •  Nvidia introduced the RTX A4000, a single-slot GPU that bring high-performance processing power, real-time data analysis, and AI-accelerated compute. With so much performance driving this GPU, a blower fan is built in to actively cool and regulate its temperature.
       
    GPU passive cooling solution
    Asset credits to Nvidia
    • Nvidia’s T4 GPU with 320 Turing Tensor Cores enable seamless AI Inferencing and Deep Machine Learning. Nvidia T4 is revolutionizing edge computing because it has a low-profile form factor, is powered through the motherboard, and most importantly is passively cooled (no longer needing a blower fan) with rows of copper fins along the whole card.
    Learn more about indsutrial computers with NVIDIA GPUs
     

    computer-manufacturer

    Find Product
    Product Finder