MSI MEG Silent Gale P12: A dominant all-rounder for a price

Ľubomír Samák

2 years ago

Results: Frequency response of sound with a dust filter

While the Silent Gale P12 isn’t the first fan in MSI’s lineup (like the Strix XF120 from Asus), it beats anything previous from the company by a mile. This is by the efficiency of the rotor, which is suitable for radiators as well as for a case, but also by the overall robust design. There’s a big, powerful but quiet motor, and you won’t even know about the hydrodynamic bearings.

We reported on the release of the MEG Silent Gale P12 fan quite recently, but now we’re going to properly put it to the test. Compared to MSI’s Torx fan, this should be a serious step up in all directions, even price-wise. From the price of over thirty euros, it’s clear that MSI believes in the fan.


Brand and model of fan	Paper specicifations *									Price [EUR]
	Format (and thickness) in mm	Connecting		Speed [rpm]	Airflow [m³/h]	Static pressure [mm H₂O]	Noise level [dBA]	Bearings	MTBF [h]
		Motor	RGB LED
MSI MEG Silent Gale P12	120 (25)	4-pin (PWM)	N/A	0–2000	95.48	2.21	22.7	hydrodynamic	50 000	31
Asus ROG Strix XF120	120 (25)	4-pin (PWM)	N/A	1800	106.19	3.07	22.5	„MagLev“	400 000	23
Akasa Vegas X7	120 (25)	4-pin (PWM)	4-pin (12 V)	1200	71.19	N/A	23.2	fluid	40 000	11
Reeven Coldwing 12	120 (25)	4-pin (PWM)	N/A	300–1500	37.54–112.64	0.17–1.65	6.5–30.4	sleeve	30 000	12
Reeven Kiran	120 (25)	4-pin (PWM)	shared	400–1500	110.10	2.95	33.6	fluid	120 000	17
SilentiumPC Sigma Pro 120 PWM	120 (25)	4-pin (PWM)	N/A	500–1600	79.00	N/A	15.0	hydraulic	50 000	7
SilentiumPC Sigma Pro Corona RGB 120	120 (25)	4-pin (PWM)	4-pin (12 V)	1500	56.58	N/A	N/A	hydraulic	50 000	12
SilverStone SST-AP121	120 (25)	3-pin (DC)	N/A	1500	60.08	1.71	22.4	fluid	50 000	18
SilverStone SST-FQ121	120 (25)	7-pin (PWM)	N/A	1000–1800	114.68	0.54–1.82	16.4–24.0	PCF (fluid)	150 000	20
Xigmatek XLF-F1256	120 (25)	3-pin (DC)	N/A	1500	103.64	N/A	20.0	„long-life“	50 000	16

/* Here you can add custom CSS for the current table */ /* Lean more about CSS: https://en.wikipedia.org/wiki/Cascading_Style_Sheets */ /* To prevent the use of styles to other tables use "#supsystic-table-1169" as a base selector for example: #supsystic-table-1169 { ... } #supsystic-table-1169 tbody { ... } #supsystic-table-1169 tbody tr { ... } */

* When reading performance values, a certain amount of tolerance must always be taken into account. For maximum speeds, ±10 % is usually quoted, minimum speeds can vary considerably more from piece to piece, sometimes manufacturers will overlap by as much as ±50 %. This must then also be adequately taken into account for air flow, static pressure and noise levels. If only one value is given in a table entry, this means that it always refers to the situation at maximum speed, which is achieved at 12 V or 100 % PWM intensity. The manufacturer does not disclose the lower limit of the performance specifications in its materials in that case. The price in the last column is always approximate.

The Silent Gale P12’s high weight is the first thing above standard. You won’t find many fans that exceed 209 g. The body is extremely robust and the rotor is made of liquid crystal polymer (LCP). And if MSI claims that the frame can withstand the effects of super-high pressure, we confirm it.

The frame will only start to deform under enormous force and you can’t just wiggle it in your hands. In this respect Silent Gale P12 will not find many rivals, but the importance of such a feature for a fan that does not encounter high mechanical forces in practice is of course questionable. But it’s an excellent showcase of strength, that’s a fact.

The engine is also solid. Its housing has a diameter of 51.5 mm and, among other things, it also hides hydrodynamic bearings. Their operation is virtually noiseless and the fan is characterized by a purely aerodynamic sound. MSI’s remark about friction noise reduction is thus justified. The rubber pads in the corners of the fan thus primarily dampen vibrations from turbulence.

The rotor blades are long, curved – the shape is inspired by the Gentle Typhoon fan. The Noctua NF-A12x25 is similar, but with the difference that MSI doesn’t go into so much detail with it and stays with relative simplicity.

Neither the blades nor the frame contain any, shall we say, micro-details that could be dissected. The finish is “dirty” (perhaps even speckled), but deliberately so. MSI breaks up the boring look of monochromatic black fans with this, and it makes the Silent Gale P12 visually appealing as well.

There are more than enough differences from the Noctua sterrox fan, for example the gap between the tips of the blades and the frame is bigger. It’s respectable that MSI makes no secret of the lower efficiency in the specs. Still, this should be an attractive fan that combines high speeds (and a wide speed range overall) with passive mode at low PWM intensity.

Accessories include a 30-cm extension cable (the built-in fan cable is already quite long at 35 cm), pins with soft anti-vibration grommets for mounting in a case and a set of self-tapping screws.

To write that we have something mapped out to the last detail is perhaps too bold, but after proper preparation, few pieces of hardware are as easy to evaluate as fans. Of course, this had to be preceded by long preparations, developing a methodology, but you already know the story. What you don’t know yet is the first fruit, or rather the results of Akasa, SilentiumPC, SilverStone, Xigmatek or more exotic Reeven fans.

The basis of the methodology, the wind tunnel

Before you start reading the methodology with all the details, take a look at the test tunnel as a whole. This is the heart of the whole system, to which other arteries are connected (manometer, vibrometer, powermeter, …). The only solid part of the tunnel from the measuring instruments is the anemometer.

The shape of the wind tunnel is inspired by the Venturi tube, which has long been used to measure the flow of liquids and gasses. The Venturi effect for wind speed measuring is also known from the aerospace industry. However, the design for measuring computer fans has its own specificities, which this proposal of ours reflects.

The individual parameters of the HWC wind tunnel for fan tests are the result of physical simulations and practical debugging. All the details (folds, material or finish used) have a rationale behind them and are designed this way for a specific reason. We will discuss the individual design details in turn in the description of the sub-variable measurements.

Now we will briefly elaborate on some things that do not fit thematically into the text of the following chapters. Namely, for example, that the skeleton of the wind tunnel is the work of a 3D printer (PLA). The rough print was, of course, then thoroughly machined by grinding, fusing, polishing and varnishing. Especially important is the smooth finish of the interior walls.

When joining the individual parts, the emphasis was on making sure that they fit together flawlessly, that they were sealed flawlessly (we will come back to this when we describe the test procedures for pressure measurement), but also that the joints were not loosened by use. Everything is disassemblable for servicing purposes, but it is ensured that the properties are maintained during use and, for example, even under the stress of vibration. The threads are secured with either lock nuts or thread-locking fluid. It depends on which is more suitable in which place.

When the wind tunnel is not in use, it is enclosed in a dust-tight chamber. In addition to the technical equipment and its correct storage, it is also important for objective outputs that all measuring instruments are calibrated according to the standard. Without this, it would be impossible to stand behind your results and rely on the manufacturers’ specifications. Calibration protocols are therefore an important part of the methodology. Testing is carried out at an ambient air temperature of 21–21.3 °C, humidity is approximately 45 % (± 2 %).

Fans come to us for testing in at least two pieces of the same model. If the deviations of any of the measured values are greater than 5 %, we also work with a third or fourth sample and the average value is formed by the results of the fans that came out the most similar and the differences between them fit under 5 %.

The introduction to this article has been rewritten several times. The original versions resorted to describing the adverse events that caused the long-announced fan testing to be so dramatically delayed. But the text was always dreadfully boring… the important thing is that everything managed to make it to the start. But before the starting gun, come take a thorough walk around the track where the measurements will take place.

Mounting and vibration measurement

Naturally, each tested fan must first be properly mounted. With all that we want to measure, and with the kind of precision that is required for relevant measurements, even the smallest details matter. The whole mounting system is quite complex and we are happy to have fine-tuned it to maximum satisfaction. Even if it meant hundreds of hours of tinkering. What’s so complicated about it? There’s more.

The fans are installed to the multi-purpose bracket. The substrate is a 2 mm thick metal plate to which the fan is attached, or the fan is attached together with an obstacle (e.g. a filter, hexagonal grille or liquid cooler radiator).

Bracket for installing the fan and vibrometer sensor

For correct and always equal pressure, the fans are always tightened with the same force with a torque screwdriver. If this were not the case, joints and clearances in the assembly could arise, in short, uneven conditions with undesirable distortion. For example, also for vibration measurement. On top of the fan mount there is also a bracket for the three-axis vibrometer sensor. The latter is magnetically attached via a steel insert, on which the sensor exerts a force of one kilogram and, thanks to the stop, is also always in the same place and in the same contact with the rest of the structure. These are the basics in terms of repeatability of measurements.

In order to capture the intensity at the highest possible resolution, the tray of the holder cannot be too heavy and at the same time it must be strong enough not to twist. This would again cause various distortions. Therefore, we used a hard (H19) aluminium (AL99.5) plate for the construction of the holder, whose weight is just enough so that free movement is not significantly restricted.

To achieve the finest possible resolution for vibration measurement, soft rubber inserts are provided in the mounting holes through which the bracket is installed to the tunnel. And just behind these inserts are silent blocks with a very low hardness of 30 Shore. These are also used so that the vibrations of the fans don’t spread to the tunnel skeleton. If this were to happen, then for fans with more intense vibrations, this secondary noise component, which is not related to the aerodynamic sound of the fan, would also be reflected in the noise measurement results.

Sensitive mounting mechanism allows high-resolution vibration measurement while preventing vibrations from traversing to the wind tunnel skeleton

This is where it is good to have ideal conditions, even though they are unattainable in practice, because fan vibrations will always be transmitted to the case skeleton to some degree. But each cabinet will react differently to them, or rather the final noise level will depend on a number of factors, starting with the materials used. Therefore, it is a good idea to filter out this extra noise component in tests and in practice take into account the measured vibration intensities. The higher these vibrations are, the higher the noise addition has to be taken into account.

The silent blocks are naturally formatted to offset the bracket a bit from the rest of the tunnel, otherwise they wouldn’t make sense. This creates a gap that is sealed across the entire surface with a soft foam seal with closed cell structure (i.e., it’s airtight).

To prevent vibrations from passing through to the wind tunnel structure, there is a small gap between the fan bracket and the leading edge of the tunnel, which is sealed by a soft foam collar

To properly center the fan rotor in relation to the other elements, the bracket includes a protruding frame that follows the inner contour of the seal. And to make matters even more complicated, the frame with the tested fan is pressed against this seal by a small force of compression springs, which in turn is set with the highest possible resolution for vibration measurement in mind and at the same time so that sufficient pressure is generated to maintain a flawless seal.

Vibration is measured with a Landtek VM-6380 vibration meter. It records the vibration speed (in mm) per second in all axes (X, Y, Z). For quick orientation, we calculate a 3D vector from the measured values and graph the “total” vibration intensity. But you can also find your results if you are only interested in a specific axis.

The most complicated part of the tunnel is behind us, and we’ll move on in the next chapter. But we will still stay at the beginning of the tunnel, we will just turn to the peripheries on the sides.

Initial warm-up…

Before we even start measuring anything, we let the fans run “idle” for a few minutes after plugging them in. This is because immediately after a cold start the fans reach different parameters than after a certain amount of short-term operation.

Until the operating temperature of the lubricant is stabilized, a typically lower maximum performance is achieved. This is because at lower temperatures the lubricant is denser, which is associated with higher friction. Therefore, the fans do not reach maximum speed immediately, but only after the first few seconds. Before the first measurements, we therefore leave the fans running for at least 300 seconds at 12 V, or 100 % PWM intensity.

…and speed recording

The speed of the fans is monitored using a laser tachometer, which reads the number of revolutions from a reflective sticker on the rotor. For this purpose, we use the UNI-T UT372 device, which also allows real-time averaging of samples. Thus, we do not record the peak value in the graphs, but the average speed value from a 30-second time period.

However, the speed itself is a relatively unimportant parameter that is often given more attention than is appropriate. This is the case even in many fan or cooler tests, where speed is used to normalize the different modes in which other variables are measured.

We monitor the speed of the fans with a laser tachometer

However, hyper-focusing on a specific speed is a rather unfortunate decision if only because the fans don’t gain any commonality. At the same speed all other variables are different, there is no intersection. It can be noted that a better normalization would have been by any other variable, whether it be static pressure, flow or noise level, which wins in our case. But more on that in the next chapter.

We only measure the speed so that you can associate a particular parameter (such as the amount of static pressure or some noise level) with something according to which you can adjust the fan yourself. Perhaps for that alone, the information about the achieved speed is useful. As part of the fan analysis, we will also indicate what the fans’ starting and minimum speeds are. Start-up speeds tend to be higher than minimum speeds because more force is required to get the rotor moving than once the fan rotor is spinning, and a minimum power intensity is sought at which the fan does not stall.

Base 7 equal noise levels

There are several options by which to normalize the test modes for fans. In the previous chapter, we wrote that perhaps the least appropriate option is equal speed.
Settings according to the same static pressure or flow are for consideration, but we find it most sensible in the long term to normalize the measurement modes according to the same noise levels. Firstly because decibels are a logarithmic unit and all others scale linearly, but mainly because you can orientate fastest by the same noise levels. The easiest way to compare the efficiency of fans is just by how they perform at the same sound pressure level. Of all the options, this is the one that most people can best imagine and bounce off of when considering other variables.

The individual noise level modes are adjusted from low levels continuously to higher levels. All users will find their results in the tests, regardless of whether they prefer very quiet operation at the limit of audibility or whether high performance is paramount.
The quietest mode corresponds to 31.5 dBA, followed by 33 dBA, and for each additional mode we add 3 dBA, which always doubles the noise level (36, 39, 42 and 45 dBA). Finally, we measure the fans at maximum power. Here, each one already has a slightly different noise level, which we also report. If there are missing measurements between the results for any of the fans, this means that it was not possible to set the target noise level. Either because its minimum speed exceeds the quietest mode of 31.5 dBA or vice versa because the fan is quieter than 45 dBA at maximum power.
It is important to add that our noise level measurements are incomparable to the values quoted by the fan manufacturers in their specifications. One of the reasons is because we use a parabola-shaped collar around the sensor of the noise meter, which increases sensitivity. This is important in order to distinguish and set to the same noise level even modes at very low speeds, especially 31.5 dBA.
The noise meter next to the fan is quite close for sufficient resolution. The distance between the frame and the sensor is 15 centimeters. The sensor is positioned in such a way that there is no distortion or that the noise level measurements are not affected by airflow. Therefore, the noise meter is centered perpendicularly to the frame that defines the depth of the fan. Everything is always at the same angle and at the same distance. We use an inclinometer and markers to set the distances precisely and always the same.

The noise meter sensor is positioned relative to the position of the fan from the profile. It is centered to the depth of the frame both vertically and horizontally.

We use a Reed R8080 noise meter to measure noise levels. This allows real-time averaging of samples, which is important for fine-tuning individual modes. We tune the fans until the specified noise level is reached to two decimal places, for example 31.50 dBA. The noise meter is the only instrument we calibrate inside our testlab. The other instruments have been calibrated by the relevant technical institutes. However, in the case of the noise meter, calibration is required before each test and we therefore have our own calibrator. This is already calibrated externally according to the standard.

33 dBA or 33 dBA

The noise level, given as a single dBA value, is good for quick reference, but it doesn’t give you an idea of exactly what the sound sounds like. That’s because it averages a mix of noise levels of all frequencies of sound. One fan may disturb you more than the other, even though they both reach exactly the same dBA, yet each is characterized by different dominant (louder) frequencies. To analyze thoroughly with an idea of the “color” of the sound, it is essential to record and assess noise levels across the entire spectrum of frequencies that we perceive.

Spectrograph with noise levels at individual sound frequencies

We already do this in graphics card tests, and we’ll do it for fans too, where it makes even more sense. Using the UMIK-1 miniDSP microphone and TrueRTA’s mode-specific, fixed dBA application, we also measure which frequencies contribute more and which contribute less to the sound. The monitored frequency range is 20-20,000 Hz, which we’ll work with at a fine resolution of 1/24 octave. In it, noise levels from 20 Hz to 20 000 Hz are captured at up to 240 frequencies.

The information captured in the spectrograph is a bit more than we will need for clear fan comparisons. While you’ll always find a complete spectrograph in the tests, we’ll only work with the dominant frequencies (and their noise intensities) in the low, mid, and high bands in the comparison tables and charts. The low frequency band is represented by 20–200 Hz, the medium by 201–2000 Hz and the high by 2001–20 000 Hz. From each of these three bands, we select the dominant frequency, i.e. the loudest one, which contributes most to the composition of the sound.

To the dominant frequency we also give the intensity of its noise. However, in this case it is in a different decibel scale than those you are used to from noise meter measurements. Instead of dBA, we have dBu. This is a finer scale, which is additionally expressed negatively. Be careful of this when studying the results – a noise intensity of -70 dBu is higher than -75 dBu. We discussed this in more detail in the article Get familiar with measuring the frequency response of sound.

Strict acoustic safeguards are required to ensure that these measurements can be carried out with satisfactory repeatability at all. We use acoustic panels to measure the same values at all frequencies across repeated measurements. These ensure that the sound is always reflected equally to the microphone regardless of the distribution of other objects we have in the testlab. The baseline noise level before each measurement is also naturally the same. The room in which we measure is soundproofed.

To accurately measure the frequency characteristics of sound, it is important to maintain acoustic conditions at all times. We use a set of acoustic panels to create these.

Like the noise meter, the microphone has a parabolic collar to increase resolution. The latter is specially in this case not only to amplify but also to filter out the noises that occur whether we want them or not behind the microphone. We are talking about the physical activity of the user (tester). Without this addition, human breathing, for example, would also be picked up by the spectrograph. However, this is successfully reflected off the microphone sensor by the back (convex) side of the collar. As a result, the spectrogram only contains information about the sound emitted by the fan itself.

Static pressure measurement…

Finally, it is time to move further down the tunnel a bit. Just behind the fan is a static pressure sensing probe. Its position has been chosen with maximum measurement efficiency in mind. In other words, the sensors are placed at the points of highest pressure (although this is virtually the same everywhere in the unconstrained part of the tunnel).

The Fieldpiece ASP2, which is connected to the Fieldpiece SDMN5 manometer, is used to measure the static pressure in the tunnel. The latter also allows measurements in millimetres of water column, but we measure in millibars. This is a more finely resolved base unit for this meter. And only from there we convert the measured values into mm H₂O to allow easy comparison with what the manufacturers state.

Internal part of the probe to measure the static pressure inside the tunnel…

The difference in cross-section at the intake and exhaust (where the exhaust in this case is considered to be the anemometer) is related to the fact that the pressure increases in the narrowed part and with it the airflow. In order to avoid distortion at this level and to prevent the airflow from being stated as higher than it actually is, the Bernoulli equation must be applied to the measured values to compensate for the difference between the intake and exhaust cross-section (it also takes into account the motor housings). After this, it is again possible to confront our results with the paper parameters.

… and the external part leading to the manometer

The greater the difference between the manufacturer’s claimed values and ours, the less the specifications correspond to reality. If the claimed values are significantly higher, it is certainly an intention to artificially give an advantage to the fans on the market. However, if the manufacturer quotes a lower pressure value than we do, it points to something else. Namely, a weaker tightness of the measuring environment. The less tight the tunnel is, the lower the pressure you naturally measure. This is one of the things we tuned for an extremely long time, but in the end we ironed out all the weak spots. Whether it’s the passage for the probe itself, the flanges around the anemometer, even the anemometer frame itself, which is made up of two parts, needed to be sealed in the middle. Finally, the flap at the tunnel outlet must also be perfectly tight. That’s because static pressure has to be measured in zero airflow.

The furthest part from the fan – cap for static pressure measurements

But there is one thing that often lowers the pressure of the fans a bit. And that’s protruding anti-vibration pads in the corners or otherwise protruding corners. In other words, when the fan doesn’t fit perfectly to the mounting frame at the inlet, and there are small gaps around the perimeter, that also affects what you measure. But we have not gone into this because it is already a quality feature of the fan. In the same way, it will “stand out” and perform a bit weaker than it has the potential to do with better workmanship, even after application by the end user.

… and airflow

With airflow measurements, we can well explain why the test tunnel is shaped the way it is. It doesn’t consist of two parts just so that the “exhaust” can be conveniently clogged for pressure measurements. The anemometer (i.e. the wind speed measuring instrument) is held together by two parts, two formations, through the flanges.
The front part, at the beginning of which the fan is mounted, becomes steadily narrower and from about two thirds of the way through the cross-section is smaller than that of a 120 mm fan. The reason for this is that the cross-section of the anemometer is always smaller than that of the fans tested. The taper towards the anemometer fan is as smooth as could be chosen and the tunnel walls are smooth. This has minimized the occurrence of unnatural turbulence.
The difference between the cross section at the intake (fan under test) and at the constriction point (anemometer) also means a difference in dynamic pressure, the principles of the Venturi effect apply here. In order to avoid distortion at this level and to ensure that the fan airflow is not different from what it actually is, the Bernoulli equation must be applied to the measured values (for maximum accuracy, the calculation also takes into account the internal cross-sectional area of the anemometer, i.e. its inactive part ). After all this, it is again possible to confront our results with the paper parameters.

We use an Extech AN300 anemometer with a large 100 mm fan for the measurements. Its big advantage over other anemometers is that it is made for bidirectional sensing. This allows tests at different fan orientations. However, the “pull” position is more suitable or accurate for measurements, even though it may not seem so at first glance, but we’ll explain.

Here, we get to the second part of the tunnel, the part behind the anemometer. It is part of the whole device, mainly to allow a laminar flow of air to arrive at the rotor of the anemometer. Otherwise, uncontrolled side whirls would be reflected in the results, which are inconsistent with accurate measurements. Therefore, we will test the flow in the pull position. If anyone would like us to elaborate more on this topic, we can elaborate further at any time in the discussion below the article. Ask away. 🙂

The rear of the tunnel ensures, among other things, that the air supply to the anemometer fan is laminar

In connection with the anemometer, we will return a little more to the noise measurements and to the setting of modes according to fixed noise levels. It may have occurred to you as you were reading that the anemometer fan is also a source of sound that needs to be filtered out when testing fans. For this reason, we insert a belay pad between the frame and the anemometer fan before each measurement and mode setting according to the fixed noise level.

Everything changes with obstacles

So far, we have described how static pressure and airflow measurements are made under conditions where the fan has no obstacles in its path. In practice, however, fans do not usually blow into an empty space, but have a filter, grille or radiator in front of or behind them, the fins of which need to be pushed through as efficiently as possible.

A set of practical obstacles with which we measure the effect on airflow, static pressure, but also noise

We will also measure both airflow and pressure through practical obstacles for the reasons stated above. These include two types of filters that are usually used in PC cases. One fine – nylon and the other plastic with a thinner mesh. One other obstacle is the hexagonal grille perforated at 50%, on which the vast majority of fans – intake and exhaust – are installed. In some cases, we measure the effect of the obstacles on the results at positions (behind or in front of the rotor) that are used in practice. All obstacles are both pushed through to detect pressure drops, but also pulled through, which in turn speaks to the impact on airflow.

We use two radiators that differ in thickness and fin density. The EK CoolStream SE120/140 is 28 mm thick and the FPI is 22, the Alphacool NexXxoS XT45 v2 is thicker (45 mm) but with less FPI. CoolStream’s fin disposition is also similar in parameters to AIOs. The results on the NexXxoS will again be attractive for those who build their own water cooling loops, where the fans should work well even at low speeds – hence the lower fin density.
These obstacles and especially the radiators, but also the grilles, increase the mechanical resistance in front of the fan, resulting in higher noise levels. However, we will still tune the fan speeds to the specified noise levels of 31.5 to 45 dBA. Naturally, the speeds will always be lower than when testing without obstructions, but we will maintain the noise levels for clarity. The different noise levels with and without obstacles will only be at maximum power. In this mode it will also be nice to see how the fan design works with the obstacle and in which case the noise level increases more and in which less.

How we measure power draw…

Is it worth addressing the power draw of fans? If you have seven of them in your computer (three on the radiator of the cooler and four for system cooling in the case) and they are also backlit, the power draw starts at tens of watts. This makes it worth dealing with.
All fans are powered by Gophert CPS-3205 II laboratory power supply. It is passive and virtually noiseless, so it does not distort our noise level measurements. However, for the PWM fans, a Noctua NA-FC1 controller is connected through which the fans are regulated. We also have a shunt between the power supply and the Noctua controller. On it, we read the voltage drop, from which we then calculate the current. However, the voltage on the power supply is set so that 12 V goes to the Noctua NA-FC1. We then also set the exact 12 V to measure the maximum power of the 3-pin linear power supply fans.

In the power draw tests, we will be interested in the power draw in fixed noise level modes in addition to the maximum power consumption at 12 V or 100% PWM. That is, at those settings at which we also measure other parameters. Finally, in the graphs you will also find the power consumption corresponding to the start-up and minimum speeds. The difference between these two settings is that at start-up speed you need to overcome the frictional forces, so the power draw is always higher than at minimum speed. At these, the fan is already running and just reduces power to just before a level where it stops.

These start-up and minimum power draw data are a substitute for the start-up and minimum voltage information. You often encounter this when reading about fans, but with PWM fans there is no point in dealing with it. And although it is possible to power a PWM fan linearly, it will always perform better with PWM control – lower starting and minimum speeds. Therefore, it would be unfair to compare these parameters for all fans using linear control. That way, fans with PWM would be disadvantaged and the results distorted.

…and motor power

In addition to power draw, it is important to consider one more parameter that is related to the power supply – the power of the motor. This is usually listed on the back on a label and is often mistaken for power draw. However, the voltage and current indication here is usually not about power draw, but about the power of the motor. The latter must always be well above the operating power draw. The more, the longer the life expectancy of the fan.
Over time and with wear, fan friction increases (through loss, hardening of the lubricant, dust contamination or abrasion of the bearings, etc.). However, a more powerful motor will overcome the deteriorating condition of the fan to some extent, albeit at a higher power draw, but somehow it will cope. However, if the difference between the motor power and the operating power draw of the new fan is small, it may no longer be able to exert sufficient force to turn the rotor under increased friction due to adverse circumstances.

The label detail often does not talk about power draw, but about the maximum power of the motor

To test the power of the motor, we set the fan to full power (12 V/100 % PWM) and increase the mechanical resistance by braking the rotor in the middle. This is a higher load for the motor, with which the power draw naturally increases. But this is only up to a point, until the rotor stops. The power of the motor in our tests corresponds to the highest achieved power draw that we observed when the fan was being braked.
We use the Keysight U1231A high sample rate precision multimeters to analyse motor performance (as well as normal operating power draw). In addition, the individual samples are recorded in a spreadsheet, from which we then graph the maximum. The final value is the average of three measurements (three maximums).

To write that we have something mapped out to the last detail is perhaps too bold, but after proper preparation, few pieces of hardware are as easy to evaluate as fans. Of course, this had to be preceded by long preparations, developing a methodology, but you already know the story. What you don’t know yet is the first fruit, or rather the results of Akasa, SilentiumPC, SilverStone, Xigmatek or more exotic Reeven fans.

Measuring the intensity (and power draw) of lighting

Modern fans often include lighting. This is no longer a “cooling” parameter, but for some users the presence of (A)RGB LEDs is important. Therefore, we also measure how intense this lighting is in our tests. These tests are the only ones that take place externally, outside the wind tunnel.
We record the luminosity of the fans in a chamber with reflective walls. This internal arrangement is important to increase the resolution for us to measure anything at all with lower luminosity fans. But also so that the readings do not blend together and it is obvious which fan is emitting more light and which one less.

Fan in the light chamber to measure the intensity of (A)RGB LEDs

The illumination intensity is measured in the horizontal position of the fan, above which is the lux meter sensor (UNI-T UT383S). This is centered on the illumination intensity sensing chamber.
The illumination is controlled via an IR controller and the hue is set to RGB level 255, 255, 255 (white). We record the brightness at maximum and minimum intensity. According to this, you can easily see if the brightness is high enough, but conversely also if the lower level is low enough for you.

In addition to the brightness intensity, we also measure the power draw that it requires. This is again through the shunt, which is between the Gophert CPS-3205 power supply and the (A)RGB LED driver. After this we get a reading of the lighting power draw. In the graphs we show it separately, but also in sum with the motor power draw as the total maximum fan power.

Results: Speed

Why is there a missing value sometimes? There may be more reasons. Usually it is because the fan could not be adjusted to the target noise level. Some have a higher minimum speed (or the speed is low, but the motor is too noisy) or it is a slower fan that will not reach the higher decibels. But the results in the graphs are also missing if the rotor is brushing against the nylon filter mesh. In that case, we evaluate this combination as incompatible. And zero in the graphs is naturally also in situations where we measure 0.00. This is a common occurrence at extremely low speeds with obstructions or within vibration measurements.

Results: Airflow w/o obstacles

Results: Airflow through a nylon filter

Results: Airflow through a plastic filter

Results: Airflow through a hexagonal grille

Results: Airflow through a thinner radiator

Results: Airflow through a thicker radiator

Results: Static pressure w/o obstacles

Explanatory note: We measure the static pressure without obstacles in two different situations – with laminarized and with turbulent intake. The results in this section reflect the first case. That is, the air intake to the rotor is laminarized by the guidance tunnel. In this setup, the fan has a larger volume of air available and the achieved static pressure values are higher. This is the optimum environment in which to measure fan parameters correctly.

Results: Static pressure through a nylon filter

Výsledky: Static pressure through a plastic filter

Results: Static pressure through a hexagonal grille

Static pressure through a thinner radiator

Results: Static pressure through a thicker radiator

Results: Static pressure, efficiency by orientation

Explanatory note: Depending on the impeller orientation, different static pressures may be achieved. Within these graphs we observe the ratio between the “pull” and “push” positions, this gives us a sort of coefficient. If its value is above 1.00, it means that the fan exerts a higher static pressure when pulling. If the value is below 1.00, the opposite is true. Sometimes, however, this ratio is overall balanced.

Reality vs. specifications

Explanatory note: For a quick overview of how manufacturers “spice up” specifications, we have a sort of “truthfulness” coefficient. We calculate this by putting our measured values in proportion to those given in the specifications by the fan manufacturers. A result of “1.00” means that the claimed parameters match the values we have recorded. After such a finding, we can conclude that the manufacturer has done his job honestly and the way he presents the fan agrees. The more the coefficient number is different from 1.00, the less accurate the claimed specifications are. Of course, the better case for the user is if the coefficient is higher than 1.00 (and it is, for example, 1.20), then the real parameters exceed the paper ones. Conversely, if the coefficient starts with zero, then the fan does not reach the parameters on paper. For example, a value of 0.80 means that the real airflow or static pressure is 20 % lower than the manufacturer claims.

Results: Frequency response of sound w/o obstacles

Measurements are performed in the TrueRTA application, which records sound in a range of 240 frequencies in the recorded range of 20–20,000 Hz. For the possibility of comparison across articles, we export the dominant frequency from the low (20–200 Hz), medium (201–2,000 Hz) and high (2,001–20,000 Hz) range to standard bar graphs.

However, for an even more detailed analysis of the sound expression, it is important to perceive the overall shape of the graph and the intensity of all frequencies/tones. If you don’t understand something in the graphs or tables below, you’ll find the answers to all your questions in this article. It explains how to read the measured data below correctly.


Fan	Dominant sound freq. and noise level, no obstacle@33 dBA	NF-F12 PWM		NF-A15 PWM
	Low range		Mid range		High range
	Frequency [Hz]	Noise level [dBu]	Frequency [Hz]	Noise level [dBu]	Frequency [Hz]	Noise level [dBu]
MSI MEG Silent Gale 12	50,4	-81,7	369,7	-81,0	19897,0	-90,8
Asus ROG Strix XF120	50,4	-80,2	329,4	-76,2	19330,5	-90,8
Akasa Vegas X7	123,4	-77,0	369,7	-83,3	19330,5	-90,7
Reeven Coldwing 12	38,9	-79,7	1317,5	-84,0	19330,5	-90,7
Reeven Kiran	138,5	-80,6	369,7	-83,3	19330,5	-90,8
SilentiumPC Sigma Pro 120 PWM	N/A	N/A	N/A	N/A	N/A	N/A
SilentiumPC Sigma Pro Corona RGB 120	92,4	-83,0	369,7	-78,0	18780,2	-90,8
SilverStone SST-AP121	47,6	-77,5	261,4	-86,4	19330,5	-91,0
SilverStone SST-FQ121	31,3	-87,5	1208,2	-79,9	19330,5	-90,9
Xigmatek XLF-F1256	41,8	-69,7	213,6	-77,3	19330,5	-91,0

/* Here you can add custom CSS for the current table */ /* Lean more about CSS: https://en.wikipedia.org/wiki/Cascading_Style_Sheets */ /* To prevent the use of styles to other tables use "#supsystic-table-1176" as a base selector for example: #supsystic-table-1176 { ... } #supsystic-table-1176 tbody { ... } #supsystic-table-1176 tbody tr { ... } */


Fan	Dominant sound freq. and noise level, no obstacle@39 dBA	NF-F12 PWM		NF-A15 PWM
	Low range		Mid range		High range
	Frequency [Hz]	Noise level [dBu]	Frequency [Hz]	Noise level [dBu]	Frequency [Hz]	Noise level [dBu]
MSI MEG Silent Gale P12	23,1	-73,5	380,5	-73,3	18780,2	-90,9
Asus ROG Strix XF120	130,7	-70,9	369,7	-75,2	19330,5	-91,0
Akasa Vegas X7	127,0	-77,8	369,7	-76,1	19330,5	-90,9
Reeven Coldwing 12	160,0	-74,0	369,7	-76,8	19330,5	-90,9
Reeven Kiran	184,9	-75,2	369,7	-75,2	17726,2	-89,8
SilentiumPC Sigma Pro 120 PWM	97,9	-81,7	369,7	-78,1	2635,0	-86,2
SilentiumPC Sigma Pro Corona RGB 120	20,3	-67,8	380,5	-77,3	2487,1	-85,6
SilverStone SST-AP121	103,7	-76,2	339,0	-73,4	2031,9	-86,5
SilverStone SST-FQ121	138,5	-75,2	1208,2	-71,1	18780,2	-90,9
Xigmatek XLF-F1256	190,3	-77,1	761,1	-75,5	19897,0	-91,1

/* Here you can add custom CSS for the current table */ /* Lean more about CSS: https://en.wikipedia.org/wiki/Cascading_Style_Sheets */ /* To prevent the use of styles to other tables use "#supsystic-table-1153" as a base selector for example: #supsystic-table-1153 { ... } #supsystic-table-1153 tbody { ... } #supsystic-table-1153 tbody tr { ... } */


Fan	Dominant sound freq. and noise level, no obstacle@45 dBA	NF-F12 PWM		NF-A15 PWM
	Low range		Mid range		High range
	Frequency [Hz]	Noise level [dBu]	Frequency [Hz]	Noise level [dBu]	Frequency [Hz]	Noise level [dBu]
MSI MEG Silent Gale P12	28,3	-73,5	380,5	-71,0	2487,1	-85,9
Asus ROG Strix XF120	23,1	-62,9	369,7	-71,7	2347,5	-89,1
Akasa Vegas X7	N/A	N/A	N/A	N/A	N/A	N/A
Reeven Coldwing 12	195,8	-68,3	380,5	-71,3	2031,9	-90,0
Reeven Kiran	130,7	-73,1	219,8	-70,2	17726,2	-89,4
SilentiumPC Sigma Pro 120 PWM	138,5	-70,0	1522,2	-71,9	2560,0	-82,9
SilentiumPC Sigma Pro Corona RGB 120	190,3	-70,5	369,7	-66,5	2416,3	-82,4
SilverStone SST-AP121	130,7	-66,8	439,7	-66,1	2347,5	-90,9
SilverStone SST-FQ121	127,0	-71,2	369,7	-66,5	2031,8	-81,4
Xigmatek XLF-F1256	130,7	-71,5	239,7	-60,9	18780,2	-91,1

/* Here you can add custom CSS for the current table */ /* Lean more about CSS: https://en.wikipedia.org/wiki/Cascading_Style_Sheets */ /* To prevent the use of styles to other tables use "#supsystic-table-1154" as a base selector for example: #supsystic-table-1154 { ... } #supsystic-table-1154 tbody { ... } #supsystic-table-1154 tbody tr { ... } */

Results: Frequency response of sound with a dust filter

Note: For these measurements, a plastic filter is used, which, compared to a situation without an obstacle, bends the sound considerably more than a non-obstructive nylon filter.


Fan	Dominant sound freq. and noise level, dust filter@33 dBA	NF-F12 PWM		NF-A15 PWM
	Low range		Mid range		High range
	Frequency [Hz]	Noise level [dBu]	Frequency [Hz]	Noise level [dBu]	Frequency [Hz]	Noise level [dBu]
MSI MEG Silent Gale P12	134,5	-78,9	369,7	-82,8	19330,5	-90,8
Asus ROG Strix XF120	95,1	-74,3	380,5	-85,8	19330,5	-91,0
Akasa Vegas X7	116,5	-77,5	369,7	-85,6	19330,5	-90,7
Reeven Coldwing 12	123,4	-76,8	1566,8	-92,1	19330,5	-90,7
Reeven Kiran	130,7	-72,9	239,7	-86,9	19330,5	-90,8
SilentiumPC Sigma Pro 120 PWM	N/A	N/A	N/A	N/A	N/A	N/A
SilentiumPC Sigma Pro Corona RGB 120	103,7	-79,2	369,7	-83,6	19330,5	-90,9
SilverStone SST-AP121	50,4	-81,8	155,4	-78,6	18780,2	-91,0
SilverStone SST-FQ121	41,8	-75,8	329,4	-82,7	19330,5	-91,0
Xigmatek XLF-F1256	47,6	-74,2	232,9	-78,7	19897,0	-91,2

/* Here you can add custom CSS for the current table */ /* Lean more about CSS: https://en.wikipedia.org/wiki/Cascading_Style_Sheets */ /* To prevent the use of styles to other tables use "#supsystic-table-1175" as a base selector for example: #supsystic-table-1175 { ... } #supsystic-table-1175 tbody { ... } #supsystic-table-1175 tbody tr { ... } */


Fan		Dominant sound freq. and noise level, dust filter@39 dBA	NF-F12 PWM		NF-A15 PWM
		Low range		Mid range		High range
		Frequency [Hz]	Noise level [dBu]	Frequency [Hz]	Noise level [dBu]	Frequency [Hz]	Noise level [dBu]
MSI MEG Silent Gale P12		179,6	-74,1	369,7	-76,6	2957,7	-89,1
Asus ROG Strix XF120	Asus ROG Strix XF120	130,7	-63,8	329,4	-76,4	4832,6	-90,4
Akasa Vegas X7		151,0	-69,1	369,7	-77,7	19330,5	-90,8
Reeven Coldwing 12		155,4	-66,4	369,7	-77,8	18780,2	-90,9
Reeven Kiran		169,5	-67,8	369,7	-78,0	17726,2	-90,2
SilentiumPC Sigma Pro 120 PWM		123,4	-68,6	369,7	-75,2	2873,5	-86,7
SilentiumPC Sigma Pro Corona RGB 120		138,5	-68,1	391,7	-78,0	2487,1	-88,9
SilverStone SST-AP121		151,0	-78,6	339,0	-74,3	19897,0	-90,9
SilverStone SST-FQ121		142,5	-69,8	1173,8	-74,9	2031,9	-90,2
Xigmatek XLF-F1256		113,1	-71,2	369,7	-74,8	18780,2	-91,0

/* Here you can add custom CSS for the current table */ /* Lean more about CSS: https://en.wikipedia.org/wiki/Cascading_Style_Sheets */ /* To prevent the use of styles to other tables use "#supsystic-table-1156" as a base selector for example: #supsystic-table-1156 { ... } #supsystic-table-1156 tbody { ... } #supsystic-table-1156 tbody tr { ... } */


Fan		Dominant sound freq. and noise level, dust filter@45 dBA	NF-F12 PWM		NF-A15 PWM
		Low range		Mid range		High range
		Frequency [Hz]	Noise level [dBu]	Frequency [Hz]	Noise level [-dBu]	Frequency [Hz]	Noise level [dBu]
MSI MEG Silent Gale P12		127,0	-73,0	219,8	-68,8	5747,0	-83,3
Asus ROG Strix XF120	Asus ROG Strix XF120	23,1	-62,9	369,7	-71,7	5583,4	-81,4
Akasa Vegas X7		N/A	N/A	N/A	N/A	N/A	N/A
Reeven Coldwing 12		190,3	-62,7	369,7	-71,9	2347,5	-86,1
Reeven Kiran		169,5	-67,8	369,7	-78,0	17726,2	-90,2
SilentiumPC Sigma Pro 120 PWM		20,3	-64,4	246,8	-70,1	2635,0	-81,8
SilentiumPC Sigma Pro Corona RGB 120		23,1	-61,2	174,5	-63,9	2487,1	-84,4
SilverStone SST-AP121		20,3	-67,9	439,7	-67,9	4561,4	-83,3
SilverStone SST-FQ121		179,6	-64,9	369,7	-71,2	5915,4	-90,3
Xigmatek XLF-F1256		142,5	-62,7	246,8	-57,8	4974,2	-83,7

/* Here you can add custom CSS for the current table */ /* Lean more about CSS: https://en.wikipedia.org/wiki/Cascading_Style_Sheets */ /* To prevent the use of styles to other tables use "#supsystic-table-1157" as a base selector for example: #supsystic-table-1157 { ... } #supsystic-table-1157 tbody { ... } #supsystic-table-1157 tbody tr { ... } */

Results: Frequency response of sound with a hexagonal grille


Fan	Dominant sound freq. and noise level, hexagonal grille@33 dBA	NF-F12 PWM		NF-A15 PWM
	Low range		Mid range		High range
	Frequency [Hz]	Noise level [dBu]	Frequency [Hz]	Noise level [dBu]	Frequency [Hz]	Noise level [dBu]
MSI MEG Silent Gale P12	100,8	-81,2	369,7	-80,3	19330,5	-91,0
Asus ROG Strix XF120	38,9	-79,7	349,0	-72,4	19897,0	-90,9
Akasa Vegas X7	100,8	-85,3	359,2	-80,3	19330,5	-90,9
Reeven Coldwing 12	92,4	-79,8	369,7	-79,7	19897,0	-90,9
Reeven Kiran	97,9	-84,4	391,7	-77,8	19897,0	-90,8
SilentiumPC Sigma Pro 120 PWM	N/A	N/A	N/A	N/A	N/A	N/A
SilentiumPC Sigma Pro Corona RGB 120	92,4	-83,0	369,7	-77,9	18780,2	-90,8
SilverStone SST-AP121	113,1	-80,9	246,8	-84,0	19330,5	-90,9
SilverStone SST-FQ121	38,9	-76,9	1522,2	-81,7	18780,2	-90,9
Xigmatek XLF-F1256	63,5	-83,3	380,5	-78,8	19897,0	-90,9

/* Here you can add custom CSS for the current table */ /* Lean more about CSS: https://en.wikipedia.org/wiki/Cascading_Style_Sheets */ /* To prevent the use of styles to other tables use "#supsystic-table-1158" as a base selector for example: #supsystic-table-1158 { ... } #supsystic-table-1158 tbody { ... } #supsystic-table-1158 tbody tr { ... } */


Fan		Dominant sound freq. and noise level, hexagonal grille@39 dBA	NF-F12 PWM		NF-A15 PWM
		Low range		Mid range		High range
		Frequency [Hz]	Noise level [dBu]	Frequency [Hz]	Noise level [dBu]	Frequency [Hz]	Noise level [dBu]
MSI MEG Silent Gale P12		164,7	-80,6	339,0	-71,1	19330,5	-91,0
Asus ROG Strix XF120	Asus ROG Strix XF120	92,4	-77,5	369,7	-70,1	19330,5	-91,2
Akasa Vegas X7		31,3	-84,3	369,7	-74,3	18780,2	-90,8
Reeven Coldwing 12		123,4	-71,2	380,5	-71,3	18780,2	-90,9
Reeven Kiran		127,0	-77,7	380,5	-73,4	19330,5	-90,8
SilentiumPC Sigma Pro 120 PWM		63,5	-83,4	380,5	-74,0	2347,5	-83,8
SilentiumPC Sigma Pro Corona RGB 120		134,5	-72,0	369,7	-75,1	19897,0	-90,8
SilverStone SST-AP121		53,4	-81,9	380,5	-70,8	19330,5	-91,0
SilverStone SST-FQ121		41,8	-78,9	369,7	-75,0	19330,5	-91,1
Xigmatek XLF-F1256		50,4	-70,3	246,8	-72,7	19897,0	-90,9

/* Here you can add custom CSS for the current table */ /* Lean more about CSS: https://en.wikipedia.org/wiki/Cascading_Style_Sheets */ /* To prevent the use of styles to other tables use "#supsystic-table-1159" as a base selector for example: #supsystic-table-1159 { ... } #supsystic-table-1159 tbody { ... } #supsystic-table-1159 tbody tr { ... } */


Fan		Dominant sound freq. and noise level, hexagonal grille@45 dBA	NF-F12 PWM		NF-A15 PWM
		Low range		Mid range		High range
		Frequency [Hz]	Noise level [dBu]	Frequency [Hz]	Noise level [dBu]	Frequency [Hz]	Noise level [dBu]
MSI MEG Silent Gale P12		130,7	-72,7	415,0	-67,2	2487,1	-89,3
Asus ROG Strix XF120	Asus ROG Strix XF120	119,9	-73,4	604,1	-69,6	19330,5	-90,9
Akasa Vegas X7		33,6	-81,5	427,1	-70,2	18780,2	-90,9
Reeven Coldwing 12		160,0	-64,7	369,7	-67,7	19897,0	-91,0
Reeven Kiran		155,4	-73,7	369,7	-69,7	19330,5	-90,8
SilentiumPC Sigma Pro 120 PWM		130,7	-77,8	369,7	-68,1	4431,5	-90,1
SilentiumPC Sigma Pro Corona RGB 120		20,3	-64,8	369,7	-73,0	3044,4	-89,2
SilverStone SST-AP121		130,7	-78,0	570,2	-64,9	18780,2	-91,2
SilverStone SST-FQ121		169,5	-64,4	246,8	-77,4	19330,5	-91,0
Xigmatek XLF-F1256		58,2	-74,2	678,0	-63,8	19330,5	-90,9

/* Here you can add custom CSS for the current table */ /* Lean more about CSS: https://en.wikipedia.org/wiki/Cascading_Style_Sheets */ /* To prevent the use of styles to other tables use "#supsystic-table-1160" as a base selector for example: #supsystic-table-1160 { ... } #supsystic-table-1160 tbody { ... } #supsystic-table-1160 tbody tr { ... } */

Results: Frequency response of sound with a radiator

Note: For these measurements a thinner radiator of 28 mm is used. Such thickness (and restrictiveness with FPI 22) is common in practice (also within AIO coolers).


Fan		Dominant sound freq. and noise level, thinner rad@33 dBA	NF-F12 PWM		NF-A15 PWM
		Low range		Mid range		High range
		Frequency [Hz]	Noise level [dBu]	Frequency [Hz]	Noise level [dBu]	Frequency [Hz]	Noise level [dBu]
MSI MEG Silent Gale P12		155,4	-80,8	310,9	-79,9	19330,5	-91,0
Asus ROG Strix XF120	Asus ROG Strix XF120	95,1	-77,9	329,4	-78,9	2347,5	-90,0
Akasa Vegas X7		119,7	-79,9	339,0	-83,0	19330,5	-90,8
Reeven Coldwing 12		127,0	-78,2	339,0	-84,8	19897,0	-90,9
Reeven Kiran		127,0	-81,4	339,0	-84,4	19897,0	-90,8
SilentiumPC Sigma Pro 120 PWM		N/A	N/A	N/A	N/A	N/A	N/A
SilentiumPC Sigma Pro Corona RGB 120		130,7	-77,0	339,0	-84,9	18780,2	-90,9
SilverStone SST-AP121		50,4	-79,9	329,4	-81,4	19330,5	-90,9
SilverStone SST-FQ121		80,0	-81,8	329,4	-83,1	18780,2	-91,0
Xigmatek XLF-F1256		36,2	-66,0	783,4	-80,6	19897,9	-90,9

/* Here you can add custom CSS for the current table */ /* Lean more about CSS: https://en.wikipedia.org/wiki/Cascading_Style_Sheets */ /* To prevent the use of styles to other tables use "#supsystic-table-1161" as a base selector for example: #supsystic-table-1161 { ... } #supsystic-table-1161 tbody { ... } #supsystic-table-1161 tbody tr { ... } */


Fan		Dominant sound freq. and noise level, thinner rad@39 dBA	NF-F12 PWM		NF-A15 PWM
		Low range		Mid range		High range
		Frequency [Hz]	Noise level [dBu]	Frequency [Hz]	Noise level [dBu]	Frequency [Hz]	Noise level [dBu]
MSI MEG Silent Gale P12		195,8	-77,5	403,2	-71,9	19330,5	-90,8
Asus ROG Strix XF120	Asus ROG Strix XF120	130,7	-62,5	329,4	-87,8	18780,2	-91,1
Akasa Vegas X7		155,4	-75,8	339,0	-76,5	19330,5	-90,7
Reeven Coldwing 12		160,0	-71,4	339,0	-77,9	19897,0	-90,9
Reeven Kiran		58,2	-81,9	329,4	-73,1	19330,5	-90,8
SilentiumPC Sigma Pro 120 PWM		127,0	-72,9	339,0	-78,0	2487,1	-76,5
SilentiumPC Sigma Pro Corona RGB 120		134,5	-68,8	538,2	-80,3	2635,0	-87,1
SilverStone SST-AP121		123,4	-69,2	854,3	-77,3	18780,2	-91,1
SilverStone SST-FQ121		146,7	-71,3	1522,2	-79,6	19330,5	-90,9
Xigmatek XLF-F1256		58,2	-76,1	739,4	-71,9	19330,5	-91,1

/* Here you can add custom CSS for the current table */ /* Lean more about CSS: https://en.wikipedia.org/wiki/Cascading_Style_Sheets */ /* To prevent the use of styles to other tables use "#supsystic-table-1162" as a base selector for example: #supsystic-table-1162 { ... } #supsystic-table-1162 tbody { ... } #supsystic-table-1162 tbody tr { ... } */


Fan	Dominant sound freq. and noise level, thinner rad@45 dBA	NF-F12 PWM		NF-A15 PWM
	Low range		Mid range		High range
	Frequency [Hz]	Noise level [dBu]	Frequency [Hz]	Noise level [dBu]	Frequency [Hz]	Noise level [dBu]
MSI MEG Silent Gale P12	25,6	-74,3	339,0	-71,7	2416,3	-85,1
Asus ROG Strix XF120	164,7	-66,8	320,0	-68,2	2416,3	-83,8
Akasa Vegas X7	N/A	N/A	N/A	N/A	N/A	N/A
Reeven Coldwing 12	195,8	-69,4	391,7	-71,9	2152,7	-85,6
Reeven Kiran	123,4	-71,7	391,7	-71,2	3225,4	-84,4
SilentiumPC Sigma Pro 120 PWM	142,5	-72,4	339,0	-72,5	2152,7	-76,1
SilentiumPC Sigma Pro Corona RGB 120	23,1	-59,7	329,4	-69,7	2635,0	-81,1
SilverStone SST-AP121	127,0	-65,5	310,9	-70,2	18780,2	-90,9
SilverStone SST-FQ121	20,3	-66,0	201,6	-65,8	18780,2	-90,9
Xigmatek XLF-F1256	130,7	-64,2	739,4	-64,3	3133,6	-90,8

/* Here you can add custom CSS for the current table */ /* Lean more about CSS: https://en.wikipedia.org/wiki/Cascading_Style_Sheets */ /* To prevent the use of styles to other tables use "#supsystic-table-1163" as a base selector for example: #supsystic-table-1163 { ... } #supsystic-table-1163 tbody { ... } #supsystic-table-1163 tbody tr { ... } */

Results: Vibration, in total (3D vector length)

Explanatory note: We have already described how to measure the vibration intensity in the corresponding chapter within the testing methodology. However, it is worth emphasizing here what we mean by “cumulative vibration”. In order to be able to interpret the motion in the three axes (X, Y, Z) as simply as possible, with a single number, we consider the individual axes as vectors and calculate the so-called 3D vector from them. A more detailed account at the level of the individual axes is given in the next three chapters of this article.

Results: Vibration, X-axis

Results: Vibration, Y-axis

Results: Vibration, Z-axis

Results: Power draw including LED

Results: Power draw w/o LED

Results: Motor power

Results: Cooling performance per watt, airflow

Explanatory note: From airflow measurements, you know how efficient the fans are when set at the same noise level. We also measure the operating power draw in fixed noise level mode tests, so we can easily quantify which fan is not only more cooling efficient, but also more energy efficient. That is, which fan achieves higher airflow per unit of power draw.

Results: Cooling performance per watt, static pressure

Explanatory note: From static pressure measurements, you know how efficient the fans are when set at the same noise level. We also measure the operating power draw in fixed noise level mode tests, so we can easily quantify which fan is not only more cooling efficient, but also more energy efficient. That is, which fan achieves higher static pressure per unit of power draw.

Airflow per euro

Explanatory note: The following charts will give a quick overview of the airflow rate per price unit. We can thus talk about the coefficient for the price/performance ratio. This is the ratio of the measured airflow rate in m3h of pressure to the fan price (in euros) multiplied by 1000. This is specifically so that the results do not start with unflattering zeros.

Static pressure per euro

Explanatory note: The following charts will give a quick overview of the amount of static pressure per price unit. We can thus talk about the coefficient for the price/performance ratio.This is the ratio of the measured static pressure in mm H₂O to the price of the fan (in euros) multiplied by 1000. This is specifically so that the results do not start with unflattering zeros.

Results: Lighting – LED luminance and power draw

Results: LED to motor power draw ratio

Explanatory note:Lighting has a significant contribution to fan power draw. The ratios in these graphs express the relationship between LED power draw and motor power draw in standard modes from 31 dBA progressively to maximum speed. The LEDs are always set to maximum brightness. The lower the value in the graphs, the more dominant the lighting is in the total power draw. This is not necessarily “wrong”, hand in hand with this usually goes a higher luminance, which can be controlled to some extent. To what extent you already know from the previous chapter.

Evaluation

The application possibilities of the MSI MEG Silent Gale P12 are exceptionally broad. What does this mean? Firstly, that in addition to the wide speed range (187~1905 rpm) at low PWM intensity, this fan can also run in a passive mode. But that’s just the basics, the important thing is, of course, efficiency and sound. And when the headline talked about versatility, it was because of the fact that the Silent Gale P12 delivers balanced performance on both radiators and grilles within a computer case.

Compared to the Strix XF120, the Strix XF120 is more efficient and at a low noise level (31 dBA) very significantly so. This is the level at which system fans in well-optimised computers operate. Coexisting with a nylon dust filter, it’s additionally completely different music than the fans from the big comparison test. But since it is not a cheap fan, the Silent Gale P12 definitely needs all this.The MSI fan also has a significantly high airflow and also pressure through radiators, so it is without a doubt suitable for this use. The only thing it slightly lags behind the Strix XF120 in is static pressure on radiators at higher noise levels. However, at lower (more acceptable for quiet PCs) levels, it’s all in control of the Silent Gale P12.

It is also worth praising the fact that MSI does not mislead in the specifications. The reported airflow overlaps with our measurements. The specified static pressure values differ more significantly from our measurements, but these are still not dramatic differences. We measured 1.89 mm H₂O and the parameters state 2.21 mm H₂O. It’s also due to the fact that neither of our samples can do 2000 rpm. The reality is 1900 rpm and it’s questionable whether some pieces will even make it to the paper maximum at 12 PWM controller power. Most of the time, fans are a hair faster, here the opposite is true. But you’ll probably just wave your hand over this one, because either way you’ll be tuning the speed to lower noise levels. And those are good to break down to the individual frequency level.

The sound is clean, aerodynamic (no mechanical components from the bearings and motor), we’ve already mentioned that. However, it is important to add that high (more unpleasant) frequencies are successfully avoided by the Silent Gale P12 and even at high (~1590) speeds it stays in the spectrum of deeper tones. That is, as long as he has no obstacle in front of it. It’s worse with a plastic dust filter, with it, the fan already hisses clearly at 5-7.5 kHz. However, this is not a shortcoming of the Silent Gale, and it applies to other fans as well (including those from Noctua), and in the future it will be interesting to see if any of the models show lower frequencies in this situation.

The more pronounced frequencies with the hexagonal grille are also below 2 kHz (i.e. quite pleasant). So once again we come back to the fact that the MSI fan is really suitable for use in a case as well. Vibrations are, moreover, negligible, so it won’t rattle even on the thinner sheet metal that has become a symbol of contemporary manufacturing. Low vibration intensity or low friction is also associated with low power draw (0.22-1.23 W). However, the motor power is high (4.31 W), which is only good.

On the other hand the scores forairflow per euro and static pressure pre euro are both lacking. The Silent Gale P12 is expensive and certainly more expensive than it would benefit from compared to the Noctua NF-A12x25 PWM chomax.black, compared to which it only has the benefit of the motor shutting down at low speeds. It’s admittedly a harsh statement for an otherwise good fan, but it would probably also be naive to expect Noctua to pull the short end of the stick in key features, it certainly doesn’t. The Silent Gale P12 will therefore have a tough life despite the fact that there is almost nothing to fault it for. But if you come across it at a sale, don’t hesitate for a second.

English translation and edit by Jozef Dudáš


MSI MEG Silent Gale P12
+ Suitable for every use
+ High airflow and static pressure through restrictive obstacle
+ Wide speed range plus passive operation
+ Very low speeds possible (stable from approx. 187 rpm)
+ Virtually noiseless operation of bearings and motor (no non-aerodynamic noises)
+ The sound consists of lower (more pleasing to the ear) frequencies
+ Extremely robust design
+ Very low power draw (below 1.2 W) considering the high performance
+ Extra-low, negligible vibration
+ Really powerful engine
+ Long service life expectancy
- Weaker price/performance ratio
- It does not reach the specified 2000 rpm and caps at about 1900 rpm
- Price at the level of the better Noctua NF-A12x25 PWM chromax. black
Approximate retail price: 31 EUR

/* Here you can add custom CSS for the current table */ /* Lean more about CSS: https://en.wikipedia.org/wiki/Cascading_Style_Sheets */ /* To prevent the use of styles to other tables use "#supsystic-table-1170" as a base selector for example: #supsystic-table-1170 { ... } #supsystic-table-1170 tbody { ... } #supsystic-table-1170 tbody tr { ... } */

Continue: Results: Frequency response of sound with a hexagonal grille