Page 1:Features and Specifications
Page 2:Unboxing Video
Page 3:Teardown and Component Analysis
Page 4:Load Regulation, Hold-Up Time and Inrush Current
Page 5:Efficiency, Temperature and Noise
Page 6:Protection Features and DC Power Sequencing
Page 7:Cross-Load Tests and Infrared Images
Page 8:Transient Response Tests
Page 9:Ripple Measurements
Page 10:EMC Pre-Compliance Testing
Page 11:Performance, Value, Noise and Efficiency
Page 12:Final Analysis
Teardown and Component Analysis
Before proceeding with this page we strongly encourage you to 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.
|Manufacturer (OEM)||Great Wall|
|Transient Filter||4x Y caps, 2x X caps, 3x CM chokes, 1x MOV|
|Inrush Protection||NTC thermistor & relay|
|Bridge Rectifier(s)||1x GBU25KH (800V, 25A @ 125°C)|
|APFC MOSFET||1x Infineon IPZ60R099C7 (650V, 14A @ 100°C, 0.099Ω)|
|APFC Boost Diode||1x Infineon IDH06G65C6 (600V, 6A @ 145°C)|
|Hold-up Cap(s)||1x Nippon Chemi-Con (420V, 420uF, 2000h @ 105°C, KMW)|
|Main Switchers||2x STMicroelectronics STP24N60DM2 (650V, 14A @ 100°C, 0.2Ω)|
|Driver IC||Silicon Labs Si8230BD|
|APFC Controller||Champion CM6502UHHX & CM03AX Green PFC controller|
|Resonant Controller||Champion CM6901X|
|Topology||Primary side: Half-bridge & LLC resonant controller|
Secondary side: Synchronous rectification & DC-DC converters
|+12V MOSFETs||2x Infineon BSC014N04LS (40V, 100A @ 100°C, 1.4mΩ)|
|5V & 3.3V||DC-DC Converters: 4x Nexperia PSMN2R0-30YL (30V, 100A @ 25°C, 2mΩ)|
PWM Controller: Anpec APW7159C
|Filtering Capacitors||Electrolytics: 2x Nippon Chemi-Con (4-10,000h @ 105°C, KY), 1x Rubycon (3-6000h@ 105°C, YXJ)|
Polymers: Nippon Chemi-Con
|Supervisor IC||IN1S429I -SCG|
|Fan Control MCU||PIC16F1824|
|Fan Model||Corsair NR092L (92mm, 12V, 0.22A, 3950 RPM, rifle bearing)|
|Rectifier||1x CSD18534 FET (60V, 69A @ 25°C, 7.8mΩ)|
|Standby PWM Controller||Infineon ICE5QR1680AG|
This platform was recently upgraded to facilitate higher efficiency and better performance. On the primary side, we find a half-bridge topology and an LLC resonant converter. The secondary side sports two FETs regulating the +12V rail and a pair of DC-DC converters handling the minor rails. There are very few electrolytic capacitors, since the majority of ripple filtering is taken care of by polymer caps.
Plenty of clearance on the secondary side allows for lots of airflow and lower fan speeds. Many parts are installed on the PCB's solder side, including the +12V FETs, so the top side isn't overpopulated. We're glad to see that Great Wall avoided using power transfer wires, which severely affect airflow.
The small PCB holding the AC receptacle also hosts a single choke, two Y caps, and one X cap. The EMI filter continues on the main PCB with the same number of caps, plus two chokes and an MOV.
A bypass relay supporting the NTC thermistor, providing inrush current protection, is installed below the APFC's X input cap.
The single bridge rectifier is a GBU25KH.
The APFC converter uses a single Infineon IPZ60R099C7 FET, along with a IDH06G65C6 boost diode provided by the same manufacturer. Nippon Chemi-Con provides the bulk cap; its capacity (420uF) is high enough that the SF450 Platinum achieves a greater-than 17ms hold-up time.
Two STMicroelectronics STP24N60DM2s arranged into a half-bridge topology serve as the main switching FETs. They are supported by an LLC resonant converter that boosts efficiency by limiting switching losses. The main FETs' driver is a Silicon Labs Si8230BD IC.
Champion's famous CM6901X is this PSU's resonant controller. The APFC controller is a Champion CM6502UHHX, and it's supported by a CM03AX Green PFC controller. All those ICs are installed on the main PCB's solder side.
This is a picture of the PSU's main transformer.
Two Infineon BSC014N04LSs function as the +12V FETs. Empty pads for four more FETs are populated on Corsair's SF750.
There are only three electrolytic caps on the secondary side, one of which belongs to the 5VSB circuit. Ripple filtering is mainly handled by polymer caps provided by Nippon Chemi-Con.
The standby PWM controller is an Infineon ICE5QR1680AG, and the secondary rectifier for the 5VSB rail is a CSD18534 FET. Most platforms use a Schottky barrier diode (SBR), but a FET is much more efficient.
On the front of the modular PCB, a number of polymer caps suppress ripple on the rails.
We cannot find any information on the supervisor IC, an IN1S429I-SCG.
Great Wall's soldering quality is very good, just as we'd expect from a high-end power supply.
Corsair uses the same rifle bearing fan as the one found on its 80 PLUS Gold-rated SF450. There is no need to change it, since it performs well, is quiet, and seems to be reliable.
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MORE: All Power Supply Content
- Features and Specifications
- Unboxing Video
- Teardown and Component Analysis
- Load Regulation, Hold-Up Time and Inrush Current
- Efficiency, Temperature and Noise
- Protection Features and DC Power Sequencing
- Cross-Load Tests and Infrared Images
- Transient Response Tests
- Ripple Measurements
- EMC Pre-Compliance Testing
- Performance, Value, Noise and Efficiency
- Final Analysis