This is common knowledge for many PC builders, but exploring why cooling is an integral part of a build canbe useful, as is applying these principles to new builds. The basics are simple: demanding workloads (like gaming) result in hardware generating heat. Overheating components can result in performance issues. An ideal setup keeps all of your components sufficiently cool and allows you to get the best performance from your system.
How Heat Can Impact Performance
Heat is an inevitable byproduct of computer hardware operation, but too much heat can cause slowdown across your system.
If the CPU temperature is too high, for example, a mechanism will trigger that reduces performance in order to avoid damaging the processor. According to Mark Gallina, System Thermal & Mechanical Architect at Intel, “Intel® CPUs have very robust thermal management features that quickly adjust operating frequencies to reduce power when the system cooling solution is insufficient.”
This safety mechanism, sometimes referred to as dynamic frequency scaling, is useful in that it protects your processor from potential damage. However, this protection results in a performance cost when active. A better option is keeping the CPU cool enough that the mechanism doesn’t trigger in the first place.
Many laptops that use the latest Intel® Core™ processors utilize a feature called Dynamic Tuning. This process uses AI to predict workloads, and can increase or decrease CPU performance as needed in order to keep up with those workflows. This is all done automatically by the machine, without the need for any manual adjustment by the user.
How Processors Stay Cool
There are many ways to keep a CPU cool, from mineral oil to passive cooling, but by far the most popular solutions are air or liquid CPU coolers. These coolers offer a host of features and options for just about any use case, from desktops to portable systems. Laptops usually use sophisticated air cooling systems specifically designed for the smaller chassis and aren’t normally designed to be upgraded or replaced.
Correctly applied thermal paste is also a key part of any cooling solution, as it acts as a bridge between the CPU and the cooling plate of the CPU cooler.
Any component that uses electricity — meaning just about everything in a PC — creates heat when in use. Most have a cooling system of some kind already integrated. RAM usually comes with metal heatsinks designed to disperse heat, and power supplies usually have a fan designed for this purpose as well. Even motherboards have heatsinks for components that get hot, and modern options sometimes feature heat shields for M.2 storage in order to prevent potential slowdown caused by overheating.
But relocating heat away from a component is only half the battle. If all the components are dispersing heat into a small area, such as the inside of a PC case, the ambient temperature can quickly rise. If the case is not properly ventilated, the hot air can result in the system overheating, and performance can suffer as a result.
That’s where airflow comes in.
The Importance of Airflow
A good PC case should account for airflow, either by optimizing fan placement, or by providing airflow options to the builder. Many cases come with fans already installed, but even those that don’t will have areas to install fans — usually on the front, the back, or near the top. PC fans can vary drastically in design and size, from a common 120mm case fan to more specialized configurations with varying sizes, depths, noise levels, and aesthetic considerations.
Though PC case fans share a purpose, different fans are designed for different scenarios. Static pressure fans, for example, are designed to move small amounts of air shorter distances, like through a heatsink. Fans designed for higher airflow are more focused on the amount of air that can be moved.
Something to remember when installing an airflow solution: PC fans pull air past the motor housing, meaning that any sticker, wiring, branding, or protective grille is most likely on the back of the fan. This is the side that will expel air, so be sure to install accordingly.
Positive Airflow and Dust
When case fans pull in more air than they push out, it creates positive pressure in the case. When fans are pushing out more air than they are pulling in, the result is negative pressure. If a system has negative pressure, air will be pulled in through the small gaps and vents in the case. This can also pull in nearby dust, which means more frequent cleaning to keep the system running optimally.
A positive pressure configuration helps control dust, as air will be pushed out of any gaps and vents in the case. Dust may still be brought in by the air coming through the intake fans, but properly placed filters can help mitigate this. Positive air pressure is better for reducing dust overall by localizing it to areas with filters, which can then be cleaned before ever entering the PC.
That said, too much positive pressure can force the PC fans to work against one another as they push air into the limited space of the chassis. The ideal configuration is a balance, with a slight emphasis on positive pressure to prevent dust build up. Builders can experiment with positive and negative air pressure by changing the placement, orientation, and speed of the fans in a case to find the appropriate airflow setup for their hardware configuration.
Other Cooling Considerations
Though a well-implemented fan setup and the proper cooling hardware will do most of the heavy lifting, there are other factors that can impact system temperature.
- Hardware placement. Consider where the hardware is installed on the motherboard. For example, placing your M.2 SSD directly underneath your GPU wouldn’t be ideal, as it could put the storage device directly in the path of the hot air being ejected from the GPU. Your options may be limited by considerations such as the size of your motherboard, but try to factor in room for effective cooling when putting together a system.
- Cable management. Ensuring that cables are properly organized to prevent unnecessary blockages will not only make your build more aesthetically pleasing, but can also help with better airflow. This is especially true in small form factor builds, where space is at a premium. Take advantage of the cable management options provided by your case, and consider a modular power supply to further reduce cable clutter.
- Cleanliness. Large buildups of dust can cause issues, including blockages that stop your fans from operating at peak performance. Opening your case and carefully cleaning with compressed air every few months is recommended, along with utilizing positive air pressure as detailed above. Always consult relevant documentation for the best way to open your case, how to properly clean your system, and whether or not you are violating a warranty by doing so.
- Room temperature. It may not be practical to keep an air conditioner running at all times, but higher room temperature can contribute to a PC overheating. If you live somewhere hot, keep this in mind when choosing your cooling solution.
Proper cooling requires some forethought when putting together your system, but if you follow the guidance above, it doesn’t need to be difficult. An ideal cooling setup works to keep every component in a system at its optimal temperature, and should be designed to compliment the specific hardware configuration in that system.
Carefully planning your PC cooling isn’t just good practice. It’s also important for getting the best performance from your build, and for potentially increasing the lifespan of your components.