Page 1:TPG-1250D-T Power Supply Review
Page 2:Packaging, Contents, Exterior And Cabling
Page 3:A Look Inside And Component Analysis
Page 4:Load Regulation, Hold-Up Time And Inrush Current
Page 5:Efficiency, Temperature And Noise
Page 6:Protection Features
Page 7:Cross-Load Tests And Infrared Images
Page 8:Transient Response Tests
Page 9:Ripple Measurements
Page 10:Performance, Performance Per Dollar, Noise, And Efficiency Ratings
Page 11:Pros, Cons And Final Verdict
A Look Inside 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. Our main tools for disassembling PSUs are a Thermaltronics soldering and rework station, and a Hakko FR-300 desoldering gun.
|Manufacturer (OEM)||Channel Well Technology|
|Transient Filter||6x Y caps, 2x X caps, 2x CM chokes, 1x MOV|
|Inrush Protection||NTC Thermistor & Bypass Relay|
|Bridge Rectifier(s)||2x Vishay LVB1560 (600V, 15A @ 125°C)|
|APFC MOSFETs||2x Toshiba TK25N60X (600V, 25A @ 150°C, 0.105Ω)|
|APFC Boost Diode||2x SCS110AG (600V, 10A & 117 °C)|
|Hold-up Cap(s)||1x Chemi-Con (420V, 560uF, 2000h @ 105°C, KMR)|
1x Chemi-Con (400V, 680uF, 2000h @ 105°C, KMW)
|Main Switchers||4x Alpha & Omega AOTF29S50 (600V, 18A @ 100°C, 0.15Ω)|
|FET Drivers||2x Silicon Labs Si8230BD|
|Primary MCU||Texas Instruments UCD3138 (31.25 MHz, 32-bit it ARM7TDMI-S Processor, 32KB Flash, 3x Feedback loop control, 14-bit DAC, up to 2 MHz switching frequency)|
|Secondary MCU||Microchip PIC32MX230F064D (40 MHz, 64KB Flash, 13x analog channels, 10-bit ADC, USB interface)|
|Topology||Primary side: Interleaved PFC, Full-Bridge & LLC Resonant Converter|
Secondary side: Synchronous Rectification & DC-DC converters
|+12V MOSFETs||12x Alpha & Omega AON6240 (40V, 67A @ 100°C, 1.6mΩ)|
|5V & 3.3V||DC-DC Converters:|
6x Sinopower SM3117NSUC (30V, 85A @ 100°C, 7.2mΩ @ Vgs=10V)
PWM Controller: 1x Anpec APW7159C
|Filtering Capacitors||Electrolytics: Nippon Chemi-Con (105°C, KY, KZE)|
Polymers: Apaq, Chemi-Con
|Supervisor IC||Infinno ST9S313-DAG (OVP, UVP)|
|Fan Model||Thermaltake TT-1425 (Hong Sheng OEM, A1425L12S, 140mm, 12V, 0.30A, 1560 RPM, hydro-dynamic bearing)|
|Rectifier||1x M03N65D FET|
|Standby PWM Controller||On Bright OB5269CP & SPN5003 (N-Channel Enhancement Mode FET)|
The TPG-1250D-T is based on CWT's fresh CST platform, which appears to feature a semi-digital design. It uses a couple of MCUs for APFC control and the digital interface. Some of the unit's protection capabilities are probably handled by one of the MCUs, too. We call this implementation semi-digital because the minor rails are addressed by an analog PWM controller. The same may also apply to the primary switchers, as we found an Infineon PWM controller on a board described as the "PWM Card". The +12V rail might be digitally controlled, though we can't be certain since we don't have the TPG-1250D-T's schematics. On top of that, the rail's less-than-tight load regulation raises some doubts. Without concrete information from CWT, we can only guess at what two MCUs actually do. But from the moment we failed to find an analog controller (that is to say there is no APFC controller), we could safely assume that one of the MCUs took over its role.
The main PCB is large, and the primary side's heat sinks are quite small. Meanwhile, there are no heat sinks on the secondary side. As CWT used to do in its high-end platforms, the +12V FETs are cooled by the PCB they're installed on and a pair of bush-bars. In order to save space, CWT uses a number of daughterboards. We do like that this platform employs spade terminals for connecting the AC receptacle to the PCB, meaning less desoldering work for us.
The transient filter starts at the AC receptacle with two Y caps. It continues on the main PCB with four more Y caps, two X ones, two CM chokes, and a small MOV. There is also an NTC thermistor for inrush current protection, which is supported by a bypass relay.
A dedicated heat sink hosts two Vishay LVB1560 bridge rectifiers, which combine to handle up to 30A of current.
The PSU uses an interleaved PFC converter, meaning that there are two APFC converters operating in parallel with a phase difference between them. This minimizes input/output current ripple and lowers conduction losses, increasing efficiency and doubling the effective switching frequency. Each APFC converter uses one Toshiba TK25N60X FET along with a SCS110AG boost diode. The bulk caps are provided by Chemi-Con and they have different capacities and voltage ratings. There is nothing wrong with a mixed capacity since the caps are installed in parallel. However, both capacitors should have the same voltage rating. The larger cap is only rated for up to 400V, which comes close to the APFC converter's 380VDC bus, while the other is rated at 420V.
This board hosts the primary and secondary MCUs (as they're described on the PCB). The primary MCU is a Texas Instruments UCD3138. It's probably the main PWM controller, and it appears to handle the APFC converters. The secondary MCU is a Microchip PIC32MX230F064D; it provides the USB interface, which connects the PSU to your motherboard. The Microchip MCU might also handle regulation of the +12V rail.
The primary switchers are four Alpha & Omega AOTF29S50 FETs arranged into a full-bridge topology. An LLC resonant converter is also used to lower their switching losses.
A daughterboard next to the main switchers houses a couple of Si8230BD drivers, each of which controls a pair of the primary FETs. On the same board, an Infineon PWM switching controller is also installed. Unfortunately, there is no way to identify it without completely removing the daughterboard.
Another daughterboard holds the 5VSB converter, which is connected to the modular PCB through a purple wire. The 5VSB regulator uses an On Bright OB5269CP IC, and we also spotted a M03N65D that's probably used for regulation on the same board.
The two parallel transformers are very close to the PCB that holds the FETs (12 Alpha & Omega AON6240s) responsible for regulating the +12V rail. Only four bus-bars are used for cooling these FETs and the PCB itself. This is probably why CWT used so many of them.
A large vertical PCB houses both DC-DC converters that generate the minor rails. Each converter uses three Sinopower SM3117NSUCs, and the common PWM controller is an ANPEC APW7159C. High-quality filtering caps, sourced by Chemi-Con, are installed in these converters.
Polymer caps from Apaq are used for filtering purposes on the secondary side. We also spotted several small Chemi-Con electrolytic caps. They're all rated at 105°C.
Many Apaq polymer caps are installed on the modular PCB for filtering. On the back of the same board, we noticed several thick wires that are routed/soldered on the front side of the PCB, transferring earth and power.
On the solder side of the main PCB we spot a supervisor IC, which provides some of the PSU's protection features. It is a Infinno ST9S313-DAG.
On the rear side of the PCB we also find an SPN5003 N-Channel logic enhancement mode power field effect transistor. According to its manufacturer, this component is suited for reducing vampire power. Close by is another IC, a Texas Instruments UCC27324 dual-MOSFET driver. The photo above clearly shows CWT's lousy soldering job.
The main PCB sports average soldering quality. We expected much better craftsmanship from CWT, especially in such a high-end PSU.
The fan is made by Hong Sheng and its model number is A1425L12S. This is a mid-speed fan supported by a relaxed profile, so it manages to offer quiet operation under tough conditions. According to Thermaltake, this fan uses a hydro-dynamic bearing. Moreover, there is a LED strip installed on the fan, which can be controlled through the DPSApp.
Thermaltake states that the fan's blades are designed for high static pressure to offer improved cooling. Moreover, anti-vibration rubber pads are used on the fan frame's four corners for lower noise output.
- TPG-1250D-T Power Supply Review
- Packaging, Contents, Exterior And Cabling
- A Look Inside And Component Analysis
- Load Regulation, Hold-Up Time And Inrush Current
- Efficiency, Temperature And Noise
- Protection Features
- Cross-Load Tests And Infrared Images
- Transient Response Tests
- Ripple Measurements
- Performance, Performance Per Dollar, Noise, And Efficiency Ratings
- Pros, Cons And Final Verdict