Corsair AX1500i Power Supply Review
by E. Fylladitakis on September 11, 2014 5:00 AM EST- Posted in
- Cases/Cooling/PSUs
- Corsair
- PSUs
- 1500W
External Appearance
Without a doubt, the AX1500i has an imposing presence. It is based on the same subtle visual theme as the rest of the AX series, but the 22.5 cm (8.86 in) long chassis is definitely eye-catching. It goes without saying that the AX1500i will not easily fit inside small cases and compact designs, but that's hardly a problem as this clearly is not a product meant to power anything less than the most advanced gaming computers and workstations. Decorative stickers can be seen on both sides of the chassis, while the sticker with the electrical specifications can be found at the top. The fan guard is a combination of circular and parallel wires, visually complimented by the embossed parallel lines design of the chassis.
The front of the chassis is littered with the many modular cable connectors, as well as the Corsair Link USB connector and a self-test button. The back is plain, with just the C19 cable plug and a small switch to be found. The switch does appear very small for a unit of this size but actually the AC input does not go through the switch, as with most designs; the switch electronically isolates the AC input by deactivating the inrush current relay. This is a neat trick and actually improves efficiency a little bit as well, as there are no losses on the contacts of the switch.
Internal Design
The 140 mm fan responsible for the cooling of this monster is a Corsair-branded NR140P fluid dynamic bearing fan. There is little information about this particular fan to be found in Corsair's website but, after testing the fan, our instrumentation shows that it has a maximum speed of about 2100 RPM and a maximum volume flow of about 75 CFM.
Unsurprisingly, Flextronics is the OEM behind the creation of the AX1500i and it is somewhat similar to the smaller AX1200i. However, there are great differences as well; in order to improve the efficiency to meet 80 Plus Titanium standards, Corsair essentially made the entire unit digital.
The build quality is exceptional, with an immaculate soldering job and a ridiculous amount of glue used to mechanically secure the components and minimize high frequency vibration noises. In fact there is so much glue that many components are literally buried inside lumps of grey stuff. Unfortunately, due to the excessive use of glue, we could not fully identify the number of AC filtering components. We were able to count six Y capacitors, four X capacitors, and three filtering inductors, which is already more than enough, but we suspect that even more of them are hidden under the lumps of glue.
Elsewhere, a metallic shield guards against EMI. It is also worth mentioning that thread locker glue has been used on almost every screw and metallic clips are used to ensure the tight contact of transistors onto the heatsinks, which is definitely not something we see every day – as a matter of fact, not even most top-tier units are so well made.
The major changes over the AX1200i, as well as over any other PSU that we have seen to date, are located at the primary rectifier and PFC circuit. Instead of using a rectifier bridge, Corsair is using two transistors for rectification and they have eliminated the PFC diode, replacing it with a digitally controlled circuit that allows for the generation of higher quality waveforms. As for the passive PFC components, there are four large coils and two Nippon Chemi-Con 680 μF capacitors. And when we get to the secondary capacitors, chaos ensues. There are electrolytic capacitors from at least three brands (Nippon Chemi-Con, Rubycon, and Nichicon) and solid capacitors from at least two manufacturers (CapXon and Teapo), and we may have missed some under the mountains of glue.
The second major change lies at the generation of the DC voltage lines. Unlike most other advanced units that generate only a single 12 V line and then convert all minor lines from it, the AX1500i has two virtual LLC converters. The major LLC converter generates the massive 12 V line and the secondary converter generates the 5 V line. The 3.3 V line is then derived from the 5 V line via a typical DC-to-DC converter. Due to the insane amperage, Corsair had to use large metallic bars to distribute the ground on the connector's PCB. A metallic bar also collects the freshly generated 12 V line, but it is then transferred onto the secondary PCB via seven thick wires.
Corsair Link
A couple of years ago, Corsair introduced the Link software that allowed for the monitoring and even partial control of compatible devices. It can be used to monitor and log system parameters, such as the CPU temperature and the speed of fans, as well as to perform certain actions when the appropriate hardware is used. For instance, you can program the lighting of the Hydro H100i to change according to the temperature reading.
With the AX1500i, Corsair Link can be used to monitor just about every primary parameter; voltage, amperage, and power on both the input and outputs, as well as the internal temperature and the speed of the cooling fan. The user can also create virtual OCPs, limiting the maximum current through certain connectors. As far as accuracy is concerned, the software readings usually are a bit off, but they are precise enough to be useful to the end user. You can see in the following pictures that we are using Link to depict the stability of the AX1500i when the input voltage is changed while the unit is operational; the AX1500i simply kept working without a glitch both when the voltage took a dive from 230 VAC to 127 VAC and when it went up to 248 VAC.
While the software worked well for us, we should mention that the version of Corsair Link with support for the AX1500i is still a Beta, so glitches and software issues could arise. We didn't encounter any during the limited time of our testing, however.
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CrazyElf - Thursday, September 11, 2014 - link
It will mostly be of use for people who are using quadruple GPU configurations or highly overclocked triple GPU configurations.But yes, as the article notes, it's a niche product and arguably an overpriced product for what it offers. We'll see what similar 1500-1600W PSUs offer by other manufacturers in the coming months.
Vatharian - Thursday, September 11, 2014 - link
Good, you mentioned, almost. I've build recently dual cpu (using Supermicro X9DRG-QF), 5 GPU (Titan black) workstation, water cooled (for sake of efficiency and longevity, not wow factor), and it refused to boot on Corsair AX1200i, switched to dual Seasonic X1250, and it peaks around 2.1kW from wall (on 230V).piroroadkill - Thursday, September 11, 2014 - link
Holy shit. Now that's baller.mapesdhs - Thursday, September 11, 2014 - link
And I thought my quad-580 3930K was nuts. :DCool dude!!
Ian.
Chrispy_ - Monday, September 15, 2014 - link
Assuming you're running an SSI EEB board, you should really be using server-grade EPS supplies rather than this consumer junk. Drawing 2.1kW from the wall is all the evidence you should need for this! ;)Barilla - Thursday, September 11, 2014 - link
80+ and 80+ titanium are two different things. And there are actually some people that need this kind of power, although not many.Sabresiberian - Thursday, September 11, 2014 - link
You know what is really useless? Comments about how a product is useless.They do more to show how limited the imaginations of the authors (of such comments) are than anything else.
petteyg359 - Sunday, February 15, 2015 - link
Just because you don't give a crap about efficiency doesn't mean others won't. Going from 84% to 92% efficiency on a 500W load is over 1.2 kWh saved every day. At $0.15 per KWh, the PSU will more than pay for itself within the warranty period.Pissedoffyouth - Thursday, September 11, 2014 - link
As a 220v user (New Zealand), due to higher efficiency should we also see lower temperatures?DanNeely - Thursday, September 11, 2014 - link
Slightly. 220v is generally 1-2% more efficient than 110; meaning at full load you'd have 15-30W lower losses being converted into heat.