Fan measurement chamber and claim
And since there is currently no source that offers realistic and usable data, even in comparison, we have invested a lot of time and money and simply developed our own fan measuring station with the advice of a cooling unit manufacturer and then calibrated it. Here the colleague Pascal Mouchel has done a great job and the result as the model “Sarcophagus I” can be seen in the meantime. The heavy and solid body made of thick MDF boards is screwed, glued and sound-insulated. How it all works and what we can and cannot measure in the end, you will learn in this article.
By now most of it has materialized really nicely, also with a lot of good feedback from the community and technical help from some industry partners. Of course, what we can measure from now on only meets semi-professional requirements, even though all measuring instruments have been calibrated in an elaborate and cost-intensive way. But that’s enough for all areas of what concerns the PC self-construction and -conversion. Of course, we are not a standardization company or the TÜV, but we try to measure everything as accurately as possible, which still remains within a reasonably affordable range.
A much simplified version with a long tube instead of the chamber would have been much cheaper, but it is so inaccurate due to the design that the values can only be considered as a rough estimate with many errors. The pressure drop is immense and a serious sound level measurement is simply impossible due to the resonance body thus created. Values below approx. 30 CFM can hardly be evaluated meaningfully and are then no longer particularly close to reality.
Tests as case fan and on radiators
Currently, there is always the question of what characteristics such a 120 or 140 mm fan really has. Not every model is suitable for all radiator thicknesses and many a supposed powerhouse loses so much pressure on radiators that it can hardly be called suitable. The data on volume flow (“throughput”) and static pressure in the data sheets are of no help if something works well on a slim radiator and fails completely on a 45 mm radiator.
In the picture we can see the middle partition between the two chambers, which supports the fan and also the radiator. Decoupling is of course very important, and we were fortunate to have expert help in calculating the volume for the chambers. Each of the chambers is also expediently lined with nubby foam and designed in terms of material technology so that there are hardly any disturbing influences.
The “honeycomb” behind the fan was recommended to us by Black Noise and the cooling manufacturer. This means that all coolers are equally well integrated, because each has a different exit angle and this is exactly what can be compensated for. However, due to the honeycomb, there is no tear-off edge and the airflow is directed directly to the outlet.
Radiators and fans are decoupled and screwed down with their own clamping device. On the picture you can see very nicely the improvised clamp with thick washers and insulation material as a base. The control is done by an Aquaero from Aqua Computer, which we bought, so we can control and test the fans by voltage (DC) or by PWM. Both are needed, because many fans, some people don’t know, can’t be brought to the lower and upper limits of the speed range with pure voltage regulation and also show other anomalies, about which we will write something at the appropriate place.
Volume flow
We measure the volume flow at the outlet of the second chamber where the air is blown out. This range is covered relatively accurately by comparative measurements in the measurement set-up of the refrigeration partner, so that our testo 410i now delivers quite reliable results to the electronic measurement data acquisition, which correspond quite well with the reference data of the professional measurement. What is important here is not the price of the equipment, but the appropriate positioning and the exact calibration with series of comparative measurements.
Static pressure
The measurement of the static pressure is carried out as usual as a differential pressure measurement. For this purpose, the special “bowl” is clamped on so that it closes airtight. Here too, of course, measurements were taken with borrowed, professional equipment and time-consuming calibrations were carried out. For this measurement we also use the 510i, a device we purchased ourselves from testo, and also collect the data wirelessly. Since many try to copy in the meantime, the angles in the 3D-graphics and also on the following two photos are of course not completely correct, because without knowledge of the exact dimensions of the funnel a copy is virtually senseless and it works also only in a quite small tolerance range really completely exactly. We have also made comparative measurement series for this once again. In practice, the whole thing looks like the two pictures below.
The installation is trouble-free and the pressure receptacle now also closes perfectly thanks to a special seal. The rest is just a matter of calibration, which we also did again. It’s unlikely to get much more accurate with semi-professional methods. However, especially in printing, mistakes are quickly possible, which above all are not immediately recognizable. Even if the deviations are small, we will still measure all previous fans again and prepare them for the database.
Noise emission
Measuring the noise level is a bit tricky, but works quite well in the evening hours at the measurement location. We decided to use dBA or dBC because values below one sone can hardly be measured reliably with still affordable and calibrated equipment and the software conversions of various software programs tend to confuse and become inaccurate in this low range. I’d rather use dBA then, especially since most people can do something with it. The measuring distance is 50 cm from the centre axis of the fan inlet.
We take two approaches to these measurements. For quick and plausibility tests we use a Voltcraft SL 451, which we calibrated according to ISO and whose microphone we placed decoupled from the body. The data acquisition takes place outside the measuring chamber. The Voltcraft SL 451 was kindly and uncomplicatedly provided to us by Conrad Elektronik. It is also the only component not acquired by ourselves. All other measuring instruments including accessories and electronics were purchased by us or provided from private stocks.
Our own purchases include a calibrated measurement microphone with XLR connector and low-noise USB interface. Measurements are taken in the evening and night hours in rural areas, so that one can already be quite satisfied with a basic level of below 26 dB(A). Since everything will be above this anyway during the measurement setup with a distance of 50 cm, this should not be a problem.
We also took the feedback from the community and evaluated the frequency band for each measurement, so you not only get the SPL values (sound pressure) in dB(A), but also a nice frequency analysis that helps to describe the sound character perfectly. Bearing or motor noise, vibrations or the tearing noise on the rotor – everything becomes mercilessly visible.
We will not go into certain details and approaches in this article, because there is still some foreign know-how in this structure and some things would probably be too far for the normal consumer. If you are interested and would like to build something like this, you are of course welcome to contact us. This also applies to all those who would like to contribute suggestions and tips, because we are still at the very beginning and can still correct or expand.
New metrics and graphics
Apart from the fact that we now also record the minimum and maximum values for the flowing currents and the power consumption, we have fulfilled two further wishes of the readers and extended the measurement series in this respect. In order to be able to assess the fans really objectively, we first graduated the resulting volume flow and measured the sound pressure level in many individual steps. The result for a fan then looks like this in comparison to the reference fan:
We see that the increase in the sound pressure level of our test fan is not as even compared to the reference, but the level is still lower at a comparable volume flow. In addition, the fan tested and compared here also delivers a significantly higher airflow due to a 50% higher maximum speed, which in the end is bought with a similar sound pressure level as the reference fan, but whose performance is significantly lower.
And because we just wrote about the rotational speeds, there are also new comparative graphics for this, at the express request of the reader, by showing which rotational speeds are necessary to achieve a certain volume flow. In practice, we can now also see where the dip in the upper graph comes from in terms of volume, because there is a speed range (rather a smaller window) where the fan doesn’t perform so perfectly and spins higher to reach the desired CFM than a more even rise in the curve would have led us to expect.
What we measure and how the result looks like, you can see on the next page by means of an exemplary selected fan, which however is anything but our reference. That’s exactly what we are still looking for 🙂
| Test setup | |
| Housing / measuring chamber | Two-chamber measuring set-up with sound insulation, fully air-conditioned room |
| Volume flow and flow velocity | testo 410i (calibrated) |
| Differential pressure measurement | testo 510i (calibrated) |
| Sound level measurement | Measuring microphone Class 2 and USB interface, Smaart 7, Voltcraft SL 451 (Conrad, permanent rental, calibrated), |
| Speed control and fan control | Aqua Computer Aquaero 6 Pro |
| Commissioning | March / April 2021 |
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