Just over 18 months ago, Intel launched their significantly revised ATX v3.0 power supply standard, and with it, the 600 Watt-capable 12VHPWR cable to power video cards and other high-drain add-in cards. The release of the standard came with a lot of fanfare and excitement – the industry was preparing for a future where even flagship video cards could go back to being powered by a single cable – but shortly after, things became exciting again for all the wrong reasons.

The new 12VHPWR connector proved to be less forgiving of poor connections between cables and devices than envisioned. With hundreds of watts flowing through the relatively small pins – and critically, insufficient means to detect a poor connection – a bad connection could result in a thermal runaway scenario, i.e. a melted connector. And while the issue was an edge case overall, affecting a fraction of a fraction of systems, even a fraction is too much when you're starting from millions of PCs, never mind the unhappy customers with broken video cards.

So the PC industry is taking a mulligan on the matter, quickly revising the ATX specification and the 12VHPWR connector to fix their design flaws. In its place we have the new ATX v.3.1 power supply specification, as well as the associated 12V-2×6 connector, the combination of which are intended to serve the same goals, but with far less of a chance of errant electricity causing damage.

Ultimately, the combination of the two new standards has required backwards-compatible changes on both the device (video card) side, as well as the power supply side. And as a result, power supply manufacturers are now in the process of releasing ATX v3.1-compliant PSUs that implement these revisions. For PSU vendors, the changes are relatively trivial overall, but they are none the less important changes that for multiple reasons, they are making sure to promote.

Getting down to business, the first ATX v3.1 power supply to enter our testing labs comes from ADATA sub-brand XPG, a prolific player in the PSU market. XPG recently expanded its product lineup with the introduction of the Core Reactor II VE series, the company's first foray into ATX 3.1-compliant PSUs. As a direct successor of the Core Reactor II series, the Core Reactor II VE is a relatively simple 80Plus Gold unit that distinguishes itself with its straightforward design, aimed at providing steady performance without the high expense.

In today’s review, we are taking a look at the 850W version of the Core Reactor II VE series, which is, for the time being, the most powerful ATX 3.1 unit XPG offers.

XPG Core Reactor II VE 850W
Power specifications ( Rated @ 40 °C )
RAIL +3.3V +5V +12V +5Vsb -12V
MAX OUTPUT 22A 22A 70.8A 3A 0.3A
120W 850W 15W 3.6W
TOTAL 850W
80PLUS RATING Gold
AC INPUT 100 - 240 VAC, 50 - 60 Hz
MSRP $119

Packaging and Bundle

The XPG Core Reactor II VE 850W PSU features robust and visually appealing packaging. The box, made from durable cardboard, is adorned in a vivid red color and prominently showcases an image of the unit on the front. To ensure the PSU is well-protected during transport, it is securely encased in dense packaging foam.

The bundle is straightforward, containing just essential components such as mounting screws and the necessary AC power cable. Additionally, it includes several decorative stickers to add a touch of personalization.

This PSU features a fully modular design, which enables the removal of all DC power cables, including the 24-pin ATX connector. The cables are uniformly black, from their connectors to the wires, and are designed without sleeving, resulting in a consistent visual aesthetic.

XPG Core Reactor II VE 850W
Connector type Hardwired Modular
ATX 24 Pin - 1
EPS 4+4 Pin - 2
EPS 8 Pin - -
PCI-E 5.0
(12V-2×6)
- 1
PCI-E 8 Pin - 3
SATA - 6
Molex - 2
Floppy - -

The XPG Core Reactor II VE 850W ATX 3.1 PSU

External Appearance

The XPG Core Reactor II VE 850W PSU is encased in a chassis that measures 86 mm × 150 mm × 140 mm (H × W × D), aligning with the standard ATX dimensions. This relatively compact size enables the power supply unit to fit seamlessly into most tower PC cases. XPG’s engineers were forced to use a 120 mm fan for cooling, as a larger fan does not fit in such a small chassis.

Opting for a subtle aesthetic, the Core Reactor II VE 850W PSU features a sleek matte black finish. The design maintains a refined appearance, enhanced by embossed geometric patterns on the sides and an abstract geometric fan cutout that adds visual interest. The top of the unit displays a detailed sticker that provides its electrical specifications and certifications.

The front side of the XPG Core Reactor II VE 850W PSU hosts only the standard on/off switch and AC receptacle. The modular cable connectors are neatly organized on the rear of the unit, facilitating easy and mistake-free connections. Although the connectors are not color-coded, they are enclosed by a clearly printed, bright white legend on the chassis, which assists in precise cable installation.

 

Internal Design

The XPG Core Reactor II VE 850W PSU is equipped with a Hong Hua HA1225H12F-Z 120 mm fan, which includes an FDB (Fluid Dynamic Bearing) engine. This type of fan is favored by manufacturers of high-quality PSUs. The fan in this model can reach a maximum speed of 2200 RPM, an impressive figure for a 120 mm fan. The manufacturer’s website states that there should be a 2400 RPM fan installed but that probably was a typographic error.

The XPG Core Reactor II VE 850W ATX 3.1 PSU is manufactured by Channel-Well Technologies (CWT), a renowned OEM known for its capability in producing mid to high power output PC power supplies. CWT’s reputation as a respected OEM is firmly established, with their platforms being integral to some of the most popular power supply units on the market. We can also see that the same exact platform was used for the Core Reactor II 850W ATX 3.0 PSU, verifying that the difference between the ATX 3.0 and ATX 3.1 standards are very subtle, primarily reduced to the length of the PCI-Express 5.0 connector sense pins and their configuration. If anything, the quality went down a bit compared to the ATX 3.0 version of the series, as we can see that higher quality passive components were being used.

The Core Reactor II VE 850W PSU employs well-established topologies, ensuring reliable performance without unexpected deviations. The input stage of the power supply features a more robust transient filter than the ATX design guide baseline, equipped with four Y capacitors, two X capacitors, but just one filtering inductor, followed by two bridge rectifiers on their dedicated heatsink. A copper sheet shields the filtering stage from the rest of the unit. The Active Power Factor Correction (APFC) circuit active components lie on the primary heatsink along the edge of the PCB. The active APFC components are two 33N60M2 MOSFETs and a diode, along with a filtering inductor and a massive 400V/680μF capacitor from Elite.

In the primary inversion stage, the Core Reactor II VE 850W PSU utilizes a half-bridge LLC topology with main switchers (25N60EFL) mounted on a dedicated heatsink, a typical setup in contemporary power supplies for its cost-effectiveness and reliability. The secondary stage conversion features eight OnSemi NTMFS5C430N transistors on a vertical daughterboard, delivering a single 12V output. The 3.3V and 5V rails are managed by DC-to-DC conversion circuits on another daughterboard.

On the secondary side, the PSU incorporates a mix of both electrolytic and solid-state capacitors from Elite and CapXon, both of which are known but are not considered to be amongst the most premium capacitor manufacturers. The ATX 3.0 version of the series featured capacitors from Japanese manufacturers instead.

ATX 3.1: New 12V-2×6 Connector & PCIe Slot Power Excursions
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  • Dante Verizon - Thursday, May 2, 2024 - link

    These tests confirm what I always say: buy a PSU with 20% more power than recommended for your system.

    You'll have a safety margin, the PSU will work cooler, quieter and should even last longer
    Reply
  • haukionkannel - Thursday, May 2, 2024 - link

    So this is the first psu with somewhat fixed 12 pin power connectors. What gpus have now? These new connectors aka do we see improved safety from now on…. Reply
  • Ryan Smith - Thursday, May 2, 2024 - link

    GPUs have already started using the revised connector. PSUs take a bit longer to spin up, both because they don't sell through as quickly, and because there are material changes to power delivery in ATX 3.1 that had to be accounted for. Reply
  • Samus - Tuesday, May 7, 2024 - link

    Are these HP12V connectors backwards compatible with one another between cards, cables and PSU's? Reply
  • flgt - Thursday, May 2, 2024 - link

    I’m know it’s tough with all the legacy hardware, but they really need to go the 48 VDC at this point if they are writing new specs. Reply
  • Railgun - Thursday, May 2, 2024 - link

    What? Reply
  • zodiacfml - Friday, May 3, 2024 - link

    I like 48V but that would require change across the industry, like datacenters and more. Tesla is likely to go this route, they already announced a revolutionary datacenter years ago for efficiency. Reply
  • meacupla - Friday, May 3, 2024 - link

    The thing is though, 48V isn't all that efficient due to CPU/GPU/DRAM etc. all wanting 1.1~1.5V.
    The larger the step is, the less efficient the conversion becomes.

    Laptops have this all figured out already, and 19.5~20V has the best power efficiency.
    USB-C PD allows up to 240W (48V, 5A), but no one has bothered to implement this on either end.
    There are no laptops with 240W USB-C input, and no chargers that do 48V, 5A output. The only 240W PD parts out are cables.
    The reason being the above mentioned efficiency loss when stepping down the input voltage.
    Reply
  • Scabies - Friday, May 3, 2024 - link

    Framework 16 allows 240W charging. Admittedly, their best GaN adapter tops out at 180W. Reply
  • zodiacfml - Saturday, May 4, 2024 - link

    I think conversion losses is even or same for specific target chip voltages. Actually, many modern PSU designs steps up voltages from the power outlet to insane numbers so that losses and AC transformer size required is minizmied then step down the voltage through solid state components or DC converters. Reply

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