AC Ripple and Power FactorAC Ripple and Noise on the DC Outputs
The amount of AC ripple and noise present on the DC outputs was checked using an oscilloscope. This AC component may be present in the KHz range where most switching power supplies operate or it may be more prevalent at the 60 Hz line frequency. I adjusted the O-scope time base to look for AC ripple at both low and high frequencies.
The new ATX12V V2.2 specification for DC output noise/ripple is defined in the ATX12V Power Supply Design Guide.
Ideally we would like to see no AC ripple (repetitive) or noise (random) on the DC outputs – the cleaner the better! But in reality there will always be some present. I measured the amplitude of the AC signal (in millivolts, peak-to-peak) to see how well the power supply complied with the ATX standard. The following table lists the ripple/noise results during all of the load tests for the main output voltages of interest.
The Corsair TX850 power supply exhibited satisfactory AC ripple suppression across the entire load range, even when delivering 850W. All measurements stayed within the recommended ATX guidelines but they were not as good as many competing models. This is an area where the CWT platforms have struggled in the past and it appears to be one area that Corsair was not able to significantly correct. In reality however, the TX850 should perform very well in real-world operation. (I typically wouldn’t push an 850W PSU beyond about 600W, which is approximately 70% of the max rated capacity).
Power Factor (PF)
Power factor is defined as the ratio of true power (measured in watts) to apparent power (measured in Volt Amps). It measures how effectively AC power is being used by a device. The difference between true power and apparent power is expressed as the power factor and results from the way true power and apparent power are measured. Ideally we would like to have true power and apparent power equal to one another, which would result in a PF of 1.00 or 100% effective power utilization.
AC Volts x AC Amps = VA (Volt Amp)
Purely Resistive AC Load: VA = Watts (same as DC circuits)
Inductive/Reactive AC Load: VA x PF = Watts
AC Volts x AC Amps x PF = Watts
I measured the AC Power Factor with an Extech power analyzer at both 115 VAC and 240 VAC input voltages. The TX850 power supply uses Active PFC circuits so as expected; the majority of readings were close to 1.0 at full load.
Note: A power supply with active PFC is more environmentally friendly (doesn’t pollute the AC transmission grid with harmonics) and will draw less current, but it will not save you money on your monthly electric bill unless you are a commercial user whose bill is based on PF and usage.
I’ve had it for 13 years and it’s still good, never issues. I’m not planning to change it yet, but maybe I will have to because of a new case.
I’ve had it for 12 years and it’s still good also. And I’ll stick with for a while longer since my next card will be a RTX 2060, so no worries so far. Amazing PSU.