Cold Test Results

For the testing of PSUs, we are using high precision electronic loads with a maximum power draw of 2700 Watts, a Rigol DS5042M  40 MHz oscilloscope, an Extech 380803 power analyzer, two high precision UNI-T UT-325 digital thermometers, an Extech HD600 SPL meter, a self-designed hotbox and various other bits and parts. For a thorough explanation of our testing methodology and more details on our equipment, please refer to our How We Test PSUs - 2014 Pipeline post.

The SilverStone Strider Gold S 1500W met its 80Plus Gold conversion efficiency requirements, even if only barely. We recorded a maximum conversion efficiency of 90% at 50% load and an average of 90.0% within the nominal load range (20% to 100% of the unit's capacity). Low load performance is mediocre, with the ST1500-GS maintaining an efficiency of 80% at 10% load, which drops to 74.4% at just 5% load. These are actually good figures considering the size of the power supply, yet they are nothing special by today's standards.

Always considering its massive power output, the ST1500-GS maintains very low internal temperatures. The primary heatsink of the PSU barely reached 67°C under maximum load, when the four transistors were pumping more than 1.5kW to the main transformer. This can be partially attributed to the "stepping" behavior of the cooling fan. While the load is low, the fan is barely audible when unobstructed, meaning that it would be virtually imperceptible with the PSU installed inside a case. At 55%-60% load, the speed of the fan steps up and the fan becomes audible, yet the noise output remains within comfortable limits. If the load exceeds 70% of the unit's capacity, then the fan speed steps up again, making the fan clearly audible and clearly prioritizing thermal performance over acoustics.

The SilverStone Strider Gold S 1500W PSU Hot Test Results
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  • malkolm - Tuesday, April 7, 2015 - link

    Maybe i missed it, but what about security features like OCP and so on?
    From the "power specifications" on page 1 i would asume the PSU to be a multi-rail device, of course. But is it truly a two-rail design or is it split even more?
  • DanNeely - Tuesday, April 7, 2015 - link

    I'm curious why your full load test pulled so much current on the 3.3/5V rails. You've got them both over 90% individually; but only have the 12v rail at 78% load. Any realistic load near the full output would be skewed much more heavily toward maxing out 12V. On the mobo, USB ports are the only significant user of +5V; and I don't think there're any major users of 3.3V at all. (PCIe cards are allowed to draw upto 10W of it; but AFAIK the only ones that did were transitional models that combined an existing legacy-PCI design with a bridge chip.)

    More troubling is that you're drawing a total of 193W of 3.3/5V power but the PSU is only rated to give 150W combined on those rails. While it obviously didn't cause anything to fail or go out of spec; but going nearly 30% out of spec is troubling. The only justification for doing so deliberately that I can think of is if your tester couldn't go above 110A on the 12V rail; although in that case I think it should've been called out explicitly in the article.
  • E.Fyll - Thursday, April 16, 2015 - link

    Actually, I have a much better justification for that.

    The only official testing procedures that exist, which are given in the methodology article, result to these minimum loads. If you had checked this article, you would see that my tester can go up to 240A on the 12V alone anyway.

    I cannot lower the load to the 3.3V/5V buses without inventing my own testing methodology, in which case I would be rendering all comparisons between reviews useless and misleading. This is a general problem with very high output PSUs, the specifications go down the drain and fail to meet even basic certification standards, all in the name of massive power output. Perhaps I will consider "circumventing" this issue in my future reviews by forcing a divider once the load exceeds 1000W.
  • Pissedoffyouth - Tuesday, April 7, 2015 - link

    Is there any hardware which could even use this amount of power?

    Let's say some OC'd 8 core Intel i7 or dual CPU 18 core xeons, 4x crossfired 7990s under full mining load with a 8 drive raid 5 15k RPM SAS setup, let's add some hardcore water cooling and every device in the house charging off USB.

    Would this even push a kilowatt?
  • MobiusPizza - Tuesday, April 7, 2015 - link

    The only case you are even anywhere close to using >1kW is with quad SLI/Crossfire and top end GPUs.
  • DanNeely - Tuesday, April 7, 2015 - link

    Even without overclocking even a 3 GPU system could exceed 1kw. There've been cards with rated TDPs of at least 300W; IIRC seeing 375 for something but that might've been a 3rd party dual GPU card not an official design since IIRC the PCIe spec tops at 300W.

    4x300W cards is 1200W, add an overclocked CPU fast ram and all the other odds and ends in a case and you could hit >1400W easily enough. (According to CPUz, my 4790k hit 145-150W at 4.7ghz with 32gb of DDR3-2400 ram under some prime95 FMA stress testing loads.)
  • 3DVagabond - Saturday, April 11, 2015 - link

    Try and get a quad sli/crossfire setup to load all 4 gpu's 100%. Not going to happen.
  • hammer256 - Tuesday, April 7, 2015 - link

    4x GTX690, a -E platform, and lots of fans would do the trick ;) Not for gaming though.
  • hammer256 - Tuesday, April 7, 2015 - link

    The PSU used for that system is a LEPA G1600, a bit cheaper than this one.
  • rtho782 - Wednesday, April 8, 2015 - link

    You can't crossfire 4 7990s, as they are dual chip already, so 2 7990s is quad crossfire, and would use less power than 4 7970s.

    I used to have an overclocked i7 920 (130W TDP, pushed to 4GHz so probably ~180W), 12GB ram, a few hard drives, 7970+7990 trifire, and absolute max I'd use (corsair link on an AX1500i) was ~880W.

    Now, with 4970k and 980SLi, I struggle to hit ~475W.

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