As we’ve already mentioned Cooler Master are using the Enhance OEM for this power supply, this design is exclusive to Cooler Master so it won’t be found in any other brand’s products. The design makes use of a 560 uF, 450V and 105 degrees rated Panasonic hold up capacitor as well as an array of 105 degrees rated Nippon Chemi-Con capacitors used for regulation. The Enhance 3D Circuit design makes use of an LLC resonant converter and DC-DC converters for the minor rails. The supplied fan is Yate-Loon made and can operate up to 2300 RPM if needed, given the efficiency of this unit I do not expect it would need to operate that fast.
Test Procedure
At eTeknix we take the power supply testing procedure very seriously and have invested a lot of resources into acquiring the appropriate testing equipment. For all power supply reviews we test the power supplies with dedicated power supply testing equipment. This means we are able to get the most accurate results from our testing as opposed to using software benchmarks (such as OCCT) or multi-meter readouts which are broadly inaccurate.
Our test machinery is as follows:
Sunmoon SM-5500ATE Active Load Tester (1200W rated)
Sunmoon SM-268 Active Load Tester (450W rated)
GW Instek GPM-8212 Digital Power Meter
Stingray DS1M12 USB Oscilloscope
Voltcraft DT-10L laser tachometer
The eTeknix test procedure involves:
Testing each power supply at 20/40/60/80/100% load (with balanced load across all rails) and measuring PFC (power factor correction), efficiency (actual power divided by power “pulled at the wall”) and voltage regulation (deviance from expected voltages of 3.3/5/12 on the main rails).
Measuring ripple with an oscilloscope at 20/40/60/80/100% load.
Measuring fan speed after a stabilisation period of five minutes at each load scenario using the Voltcraft DT-10L laser tachometer and a reflective strip on the fan.
Testing each power supply’s OPP (Over Power Protection) mechanism and seeing how many watts each power supply can deliver before shutting down
Other things to consider are that
We recognise that a single yellow 12 volt cable can provide only 6 Amps before overheating (which corrupts voltage regulation and efficiency) and so we used an adequate number of cables for each power supply to ensure there is not efficiency loss from poor cables selection
Our Sunmoon SM-5500ATE power supply tester is not capable of testing more than 300W on each of the 12 volt rails so where a power supply provides more than 300W on a 12 volt rail that power is distributed over multiple 12 volt rails on the load tester. For example a power supply with one 12 volt rail supplying 750 watts would be spread equally over three 12 volt rails on the load tester, a power supply with two 450W 12v rails would be spread over four 12v rails on the load tester, two 225W 12v rails for each of the 12v rails on the unit.
We use the same time scale and horizontal millivolt scale on our oscilloscope for all ripple tests, that is a 20ms T/DIV (horizontal) and a 0.02 V/DIV (vertical) meaning the scale is from -80mV to +80mV, ATX spec dictates that the 12v rail must fall within 150mv of ripple and the 3.3/5 within 50mv so that scale allows us to include both 150 and 50mV peaks. (Some older PSU reviews use different scales which were later ditched as the visual representation they give is inadequate, in these reviews written measurements are provided only).
Deviance is the terminology used to represent the way voltages diverge from the expected values