In addition to Thermaltake’s GF1 ARGB PSU line, which Channel Well Technology made, Thermaltake also decided to include another similar line in its portfolio, the Toughpower GF2 ARGB. All GF2 units are based on a High Power platform and have similar specifications to the GF1 models, making us wonder why Thermaltake created internal competition. The only differences are the RGB side panels on the GF2 units and the PWM control of the fan since this High Power platform uses an MCU to adjust fan speed.
The 850W member of the GF2 ARGB is a little less performant than the similar-capacity GF1 ARGB model so, if they both available at the same price, the GF1 seems like the better buy. Besides the GF1 ARGB 850W, which with a little more tuning could be added in our best power supplies article, other strong opponents of the GF2 ARGB 850W are the Corsair RM850x (2021), the XPG Core Reactor 850, and the Seasonic GX-850.
The GF2 ARGB line consists of three models with capacities ranging from 650W to 850W. All units are fully modular, and their RGB lighting is compatible with the software provided for the mainboards of Asus, Gigabyte, MSI, and ASRock. Besides the 18-LED fan, the PSUs’ panels also feature RGB lighting, so you have to make sure that you will use these PSUs along with a chassis that doesn’t hide them in a separate compartment.
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Product Photos
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The Toughpower GF2 ARGB 850W will be our test subject. This PSU is strong enough to support a potent gaming station equipped with an Nvidia RTX 3080/90 or an AMD RX 6800/6900 XT graphics card, along with a high-end CPU which will allow the GPU to deliver its full performance without any issues. It has to prove, though, that it is a better choice than the CWT-made Toughpower GF1 ARGB 850W unit since its price is at the same levels.
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Product Photos
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Specifications of Thermaltake Toughpower GF2 ARGB
|
Manufacturer (OEM) |
High Power |
|
Max. DC Output |
850W |
|
Efficiency |
80 PLUS Gold, Cybenetics Platinum (89-91%) |
|
Noise |
Cybenetics Standard++ (30-35 dB[A]) |
|
Modular |
✓ (fully) |
|
Intel C6/C7 Power State Support |
✓ |
|
Operating Temperature (Continuous Full Load) |
0 – 40°C |
|
Over Voltage Protection |
✓ |
|
Under Voltage Protection |
✓ |
|
Over Power Protection |
✓ |
|
Over Current (+12V) Protection |
✓ |
|
Over Temperature Protection |
✓ |
|
Short Circuit Protection |
✓ |
|
Surge Protection |
✓ |
|
Inrush Current Protection |
✓ |
|
Fan Failure Protection |
✗ |
|
No Load Operation |
✓ |
|
Cooling |
140mm Hydraulic Bearing Fan [TT-1425 (A1425S12S-2)] |
|
Semi-Passive Operation |
✓ (selectable) |
|
Dimensions (W x H x D) |
150 x 85 x 160mm |
|
Weight |
1.64 kg (3.62 lb) |
|
Form Factor |
ATX12V v2.53, EPS 2.92 |
|
Warranty |
10 Years |
Power Specifications of Thermaltake Toughpower GF2 ARGB
| Rail | 3.3V | 5V | 12V | 5VSB | -12V |
| Max. Power | Amps | 22 | 22 | 70.9 | 3 |
| Watts | 120 | 850 | 15 | 3.6 | |
| Total Max. Power (W) | 850 |
Cables & Connectors for Thermaltake Toughpower GF2 ARGB
| Modular Cables | ||||
| Description | Cable Count | Connector Count (Total) | Gauge | In Cable Capacitors |
|---|---|---|---|---|
| ATX connector 20+4 pin (610mm) | 1 | 1 | 18AWG | No |
| 4+4 pin EPS12V (660mm) | 1 | 1 | 16AWG | No |
| 8 pin EPS12V (660mm) | 1 | 1 | 16AWG | No |
| 6+2 pin PCIe (500mm+160mm) | 3 | 6 | 16-18AWG | No |
| SATA (510mm+160mm+160mm+160mm) | 3 | 12 | 18AWG | No |
| 4-pin Molex (500mm+150mm+150mm+150mm) | 1 | 4 | 18AWG | No |
| FDD Adapter (+160mm) | 1 | 1 | 22AWG | No |
| ARGB Sync Cable (610mm+160mm) | 1 | 2 | 26AWG | No |
| AC Power Cord (1400mm) – C13 coupler | 1 | 1 | 18AWG | – |
There are plenty of cables and connectors, including two EPS, six PCIe, twelve SATA, and four 4-pin Molex connectors. On top of that, all cables are long, and the distance between the peripheral connectors is adequate.
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Cable Photos
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Component Analysis of Thermaltake Toughpower GF2 ARGB
We strongly encourage you to have a look at our PSUs 101 article, which provides valuable information about PSUs and their operation, allowing you to better understand the components we’re about to discuss.
| General Data | – |
| Manufacturer (OEM) | High Power |
| PCB Type | Double Sided |
| Primary Side | – |
| Transient Filter | 4x Y caps, 2x X caps, 2x CM chokes, 1x MOV, 1x Champion CMD02X (Discharge IC) |
| Inrush Protection | – |
| Bridge Rectifier(s) |
2x HY GBU1506L (600V, 15A @ 100°C) |
| APFC MOSFETs |
2x Infineon IPA50R140CP (500V, 15A @ 100°C, Rds(on): 0.14Ohm) |
| APFC Boost Diode |
1x CREE C3D08060A (600V, 8A @ 152°C) |
| Bulk Cap(s) |
1x Rubycon (400V, 470uF, 3,000h @ 105°C, MXK) & 1x Rubycon (400V, 390uF, 2,000h @ 105°C, MXH) |
| Main Switchers |
2x Infineon IPA60R180P7S (600V, 11A @ 100°C, Rds(on): 0.18Ohm) |
| APFC Controller |
Infineon ICE3PCS01G |
| Resonant Controller | Champion CM6901X |
| Topology |
Primary side: APFC, Half-Bridge & LLC converter |
| Secondary Side | – |
| +12V MOSFETs | 6x Infineon BSC027N04LS (40V, 88A @ 100°C, Rds(on): 2.7mOhm) |
| 5V & 3.3V | DC-DC Converters: 6x Infineon BSC0906NS (30V, 40A @ 100°C, Rds(on): 4.5mOhm) PWM Controller(s): ANPEC APW7159C |
| Filtering Capacitors |
Electrolytic: 3x Nippon Chemi-Con (1-5,000h @ 105°C, KZE), 3x Nippon Chemi-Con (4-10,000h @ 105°C, KY), 3x Rubycon (3-6,000h @ 105°C, YXG), 1x Rubycon (6-10,000h @ 105°C, ZLH) |
| Supervisor IC | WT7527RA (OCP, OVP, UVP, SCP, PG) |
| Fan Model | Thermaltake TT-1425 A1425S12S-2 (140mm, 12V, 0.70A, Hydraulic Bearing Fan) |
| Fan Controller | STC STC15W401AS |
| 5VSB Circuit | – |
| Rectifier |
1x PFC P10V45SP SBR (45V, 10A), UTC 2N70L FET (700V, 2A, 6.3Ohm) |
| Standby PWM Controller | SI8016HSP8 |
| -12V | – |
| Rectifier |
1x KEC KIA7912PI (-12V, 1A) |
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Overall Photos
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This is a High Power platform, and the design looks good. The heat sinks are small, but this is an efficient PSU, so there won’t be any issues there, although larger heat sinks could allow for a more relaxed fan speed profile, hence for lower noise output.
On the primary side, we meet a half-bridge topology and an LLC resonant converter. On the secondary side, a synchronous rectification scheme is used for 12V, and a pair of DC-DC converters regulate the minor rails.
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Transient filter
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The transient/EMI filter has all necessary components, including a Champion CMD02X discharge IC, which provides a small efficiency boost.
We didn’t find an NTC thermistor. Nonetheless, the PSU has low inrush currents, so there is inrush current suppression through another circuit, which the APFC controller controls.
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Bridge rectifiers
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The pair of bridge rectifiers is installed on a dedicated heat sink, which is pretty small. Still, these rectifiers can easily handle the PSU’s full power even with low voltage input.
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APFC converter
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The APFC converter uses two Infineon FETs and a single CREE C3D08060A boost diode. The bulk caps are provided by Rubycon and have enough capacity to provide a longer than 17ms hold-up time. The APFC controller is an ICE3PCS01G IC.
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Main FETs and primary transformer
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Two Infineon IPA60R180P7S installed into a half-bridge topology are the primary switching FETs. The LLC resonant controller is a Champion CM6901X IC.
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12V FETs and VRMs
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Six Infineon BSC027N04LS FETs regulate the 12V rail, while the minor rails are generated through a pair of DC-DC converters.
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Filtering caps
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The electrolytic filtering caps are provided by Chemi-Con and Rubycon and are of good quality. A large number of polymer caps is also used for ripple filtering purposes.
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Supervisor ICs
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The supervisor IC is a WT7527RA, and right beside it, we find an STC STC15W401AS MCU, used to control the cooling fan’s speed.
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RGB Board
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This is the RGB controller’s board.
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5VSB circuit
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The 5VSB circuit uses a UTC 2N70L FET on its primary side and a PFC P10V45SP SBR on its secondary side.
The -12V rail is regulated through a KEC KIA7912PI regulator IC.
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Modular board front
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Several polymer caps are installed on the modular board, forming a secondary ripple filtering layer.
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Soldering quality
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Soldering quality is satisfactory.
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Cooling fan
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The cooling fan is quite strong, and it uses a hydraulic dynamic bearing so that it will last for long.
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