Testing Methodology

Although the testing of a cooler appears to be a simple task, that could not be much further from the truth. Proper thermal testing cannot be performed with a cooler mounted on a single chip, for multiple reasons. Some of these reasons include the instability of the thermal load and the inability to fully control and or monitor it, as well as the inaccuracy of the chip-integrated sensors. It is also impossible to compare results taken on different chips, let alone entirely different systems, which is a great problem when testing computer coolers, as the hardware changes every several months. Finally, testing a cooler on a typical system prevents the tester from assessing the most vital characteristic of a cooler, its absolute thermal resistance.

The absolute thermal resistance defines the absolute performance of a heatsink by indicating the temperature rise per unit of power, in our case in degrees Celsius per Watt (°C/W). In layman's terms, if the thermal resistance of a heatsink is known, the user can assess the highest possible temperature rise of a chip over ambient by simply multiplying the maximum thermal design power (TDP) rating of the chip with it. Extracting the absolute thermal resistance of a cooler however is no simple task, as the load has to be perfectly even, steady and variable, as the thermal resistance also varies depending on the magnitude of the thermal load. Therefore, even if it would be possible to assess the thermal resistance of a cooler while it is mounted on a working chip, it would not suffice, as a large change of the thermal load can yield much different results.

Appropriate thermal testing requires the creation of a proper testing station and the use of laboratory-grade equipment. Therefore, we created a thermal testing platform with a fully controllable thermal energy source that may be used to test any kind of cooler, regardless of its design and or compatibility. The thermal cartridge inside the core of our testing station can have its power adjusted between 60 W and 340 W, in 2 W increments (and it never throttles). Furthermore, monitoring and logging of the testing process via software minimizes the possibility of human errors during testing. A multifunction data acquisition module (DAQ) is responsible for the automatic or the manual control of the testing equipment, the acquisition of the ambient and the in-core temperatures via PT100 sensors, the logging of the test results and the mathematical extraction of performance figures.

Finally, as noise measurements are a bit tricky, their measurement is being performed manually. Fans can have significant variations in speed from their rated values, thus their actual speed during the thermal testing is being recorded via a laser tachometer. The fans (and pumps, when applicable) are being powered via an adjustable, fanless desktop DC power supply and noise measurements are being taken 1 meter away from the cooler, in a straight line ahead from its fan engine. At this point we should also note that the Decibel scale is logarithmic, which means that roughly every 3 dB(A) the sound pressure doubles. Therefore, the difference of sound pressure between 30 dB(A) and 60 dB(A) is not "twice as much" but nearly a thousand times greater. The table below should help you cross-reference our test results with real-life situations.

The noise floor of our recording equipment is 30.2-30.4 dB(A), which represents a medium-sized room without any active noise sources. All of our acoustic testing takes place during night hours, minimizing the possibility of external disruptions.

<35dB(A) Virtually inaudible
35-38dB(A) Very quiet (whisper-slight humming)
38-40dB(A) Quiet (relatively comfortable - humming)
40-44dB(A) Normal (humming noise, above comfortable for a large % of users)
44-47dB(A)* Loud* (strong aerodynamic noise)
47-50dB(A) Very loud (strong whining noise)
50-54dB(A) Extremely loud (painfully distracting for the vast majority of users)
>54dB(A) Intolerable for home/office use, special applications only.

*noise levels above this are not suggested for daily use

Introduction & the Cooler Testing Results
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  • Leeea - Friday, August 27, 2021 - link

    I have found direct heat pipe coolers to not be particularly flat on the bottom.

    On a silverstone cooler I had, I perceived the problem seemed to get worse with time. Gave me a real dislike for that design.
    Reply
  • edwardhchan - Thursday, August 26, 2021 - link

    So it's an expensive Hyper 212? Reply
  • Threska - Thursday, August 26, 2021 - link

    The clips are better than the plastic for holding the fans on. Reply
  • TrevorH - Friday, August 27, 2021 - link

    I looked at this and sadly it appears that it's just too tall to fit inside my case. Went for the Scythe Fuma 2 instead which costs a bit more but is about 3cm shorter and seems to get better reviews (everywhere except Anandtech which seems to have missed it altogether). Reply
  • sonny73n - Saturday, August 28, 2021 - link

    Noctua has smaller models like the NH-U9S which I have along with the U12S. Or you can get the Zalman CNPS9500 which performs better than the U9S. I have the Zalman in my old i5-2500K system. It's been working extremely well since 2011. Yup, it's been 10 years and I repasted it twice (every 4-5 years or so) even though the old paste did not cause any degrade in performance. Reply
  • lau808 - Sunday, August 29, 2021 - link

    Why isn’t the hyper 212 part of the test group? Reply
  • Jamesanderson03 - Thursday, September 2, 2021 - link

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  • dicobalt - Saturday, September 11, 2021 - link

    I see a bunch of coolers I've never heard of but the very popular Hyper 212 isn't there. Considering the very low price that's probably why, but the performance is still good, at least for me on a 5600X. The 212 would provide a good base reference point for aftermarket price performance and put the rest of the coolers into perspective. Reply

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