Contents
- 1Introduction
- 2Tsunami K P4-500W
- 2.1First Look
- 2.2Test Results
- 2.3Disassembly
- 2.4Specifications and Conclusions
- 3Honli ATX 680
- 3.1First Look
- 3.2Test Results
- 3.3Disassembly
- 3.4Specifications and Conclusions
- 4Powercase PHKPOW550120MM
- 4.1First Look
- 4.2Test Results
- 4.3Disassembly
- 4.4Specifications and Conclusions
- 5Aywun A1-3000
- 5.1First Look
- 5.2Test Results
- 5.3Disassembly
- 5.4Specifications and Conclusions
- 6A-Power P4-A680
- 6.1Test Results
- 6.2Disassembly
- 6.3Specifications and Conclusions
- 7Auriga Power MPT-301
- 7.1Test Results
- 7.2Disassembly
- 7.3Specifications and Conclusions
- 8Numan AT-580H
- 8.1Test Results
- 8.2Disassembly
- 8.3Specifications and Conclusions
- 9Ultraview 750W
- 9.1First Look
- 9.2Test Results
- 9.3Disassembly
- 9.4Specifications and Conclusions
- 10Thermal Master TM-420-PMSR
- 10.1First Look
- 10.2Test Results
- 10.3Disassembly
- 10.4Specifications and Conclusions
- 11Comparisons, Conclusions and Fireworks
- 11.1Graphs
- 11.2Conclusion
- 11.3The Fireworks
Auriga Power MPT-301
Auriga is a brand I’ve only occasionally come across in the past, and the few I have seen have all been from this same model. The MPT in the model number gives away the OEM as being Casing Macron. I haven’t thus far been able to review a power supply from this company as every single last one I’ve seen has failed due to bad capacitors. This unit, however, seems to be an exception.
It looks like we are dealing with another 5V-heavy unit here. The good news is, though, I really wouldn’t be surprised if, for once, we have an honestly rated unit here. 300W is not a lot to ask from a power supply, and we have already had plenty of cheaper units which are capable of that.
Test Results
Test 1 (73.87W Load)
| Rail | Load | Voltage | Ripple |
| 12V | 2.37A | 12.0V | 15.8mV |
| 5V | 5.06A | 5.06V | 10.6mV |
| 3.3V | 4.88A | 3.32V | 6.0mV |
| −12V | 0.09A | −11.37V | 4.2mV |
| 5Vsb | 0.5A | 5.04V | 9.0mV |
| AC Power | 96.0W | ||
| Efficiency | 76.95% | ||
| Power Factor | 0.62 | ||
| Intake Temp | 25°C | ||
| Exhaust Temp | 29°C | ||
.
Test 2 (101.2W Load)
| Rail | Load | Voltage | Ripple |
| 12V | 4.68A | 11.89V | 19.8mV |
| 5V | 5.08A | 5.08V | 11.6mV |
| 3.3V | 4.87A | 3.31V | 6.0mV |
| −12V | 0.1A | −11.44V | 5.0mV |
| 5Vsb | 0.51A | 5.05V | 10mV |
| AC Power | 127.6W | ||
| Efficiency | 79.31% | ||
| Power Factor | 0.66 | ||
| Intake Temp | 25°C | ||
| Exhaust Temp | 31°C | ||
.
Test 3 (152.66W Load)
| Rail | Load | Voltage | Ripple |
| 12V | 9.12A | 11.72V | 28.2mV |
| 5V | 5.1A | 5.1V | 13.4mV |
| 3.3V | 4.87A | 3.31V | 7.4mV |
| −12V | 0.1A | −11.54V | 7.2mV |
| 5Vsb | 0.5A | 5.04V | 12.0mV |
| AC Power | 189.7W | ||
| Efficiency | 80.47% | ||
| Power Factor | 0.66 | ||
| Intake Temp | 25°C | ||
| Exhaust Temp | 33°C | ||
.
Test 4 (198.95W Load)
| Rail | Load | Voltage | Ripple |
| 12V | 9.21A | 11.83V | 31.4mV |
| 5V | 10.08A | 5.04V | 14.2mV |
| 3.3V | 10.0A | 3.30V | 9.4mV |
| −12V | 0.1A | −11.76V | 9.4mV |
| 5Vsb | 1.0A | 5.02V | 14.2mV |
| AC Power | 243.3W | ||
| Efficiency | 81.77% | ||
| Power Factor | 0.66 | ||
| Intake Temp | 25°C | ||
| Exhaust Temp | 37°C | ||
.
Test 5 (253.06W Load)
| Rail | Load | Voltage | Ripple |
| 12V | 13.46A | 11.63V | 41.2mV |
| 5V | 10.12A | 5.06V | 16mV |
| 3.3V | 10A | 3.30V | 11.2mV |
| −12V | 0.2A | −11.77V | 12.8mV |
| 5Vsb | 2.0A | 5.0V | 17.4mV |
| AC Power | 313.0W | ||
| Efficiency | 80.85% | ||
| Power Factor | 0.66 | ||
| Intake Temp | 26°C | ||
| Exhaust Temp | 41°C | ||
.
Test 6 (309.13W Load)
| Rail | Load | Voltage | Ripple |
| 12V | 15.61A | 11.61V | 50.4mV |
| 5V | 15.06A | 5.02V | 19.2mV |
| 3.3V | 9.97A | 3.29V | 13.2mV |
| −12V | 0.4A | −11.85V | 17.2mV |
| 5Vsb | 2.98A | 4.97V | 20.8mV |
| AC Power | 389.1W | ||
| Efficiency | 79.45% | ||
| Power Factor | 0.65 | ||
| Intake Temp | 26°C | ||
| Exhaust Temp | 43°C | ||
.
Overload Test (351.32W Load)
| Rail | Load | Voltage | Ripple |
| 12V | 19.5A | 11.43V | 52.4mV |
| 5V | 15.12A | 5.04V | 20.2mV |
| 3.3V | 9.94A | 3.28V | 17.6mV |
| −12V | 0.4A | −12.01V | 24.2mV |
| 5Vsb | 2.98A | 4.97V | 27.4mV |
| AC Power | 464.1W | ||
| Efficiency | 75.70% | ||
| Power Factor | 0.63 | ||
| Intake Temp | 30°C | ||
| Exhaust Temp | 54°C | ||
.
Yes, this unit is indeed honestly rated. Not only can it deliver the rated 300W, but it can do so with everything in spec. Unfortunately, however, it doesn’t appear to like being loaded too heavily on the 12V rail. In my more 12V heavy load test pattern, the 12V rail started at 12V on the dot in Test 1 and dropped to 11.61V in Test 6, which gives us 0.39V, or 3.25% regulation. The 5V rail had maximum and minimum values of 5.1V and 5.02V respectively, giving us 0.1V, or 2% worst-case regulation and 0.08V, or 1.6% variation. The 3.3V rail started at 3.32V and dropped to 3.29V in Test 6, which gives us 0.02V, or 0.6% worst-case regulation, and 0.03V, or 0.9% variation. It’s an excellent result on the 5V and 3.3V rails, but a very average result on the 12V rail.
The efficiency wasn’t too bad either – it did actually stay above 80% when loaded between 150 and 250W. The exhaust temperature was 4°C warmer than the intake to start with and was 17°C Warmer in test 6. This is kind of warm, but at least this unit has an excuse for getting warm – unlike the A-Power, it has a fan controller, and was fairly quiet throughout the testing. I was able to overload the power supply to 350W; it survived, but the 12V rail voltage was very close to the minimum allowable, the efficiency had dropped to just under 76%, and the exhaust temperature was a whole 24°C warmer than the intake (which itself was a few degrees higher than the other tests, as I performed it a later date than the other tests, and the weather was considerably warmer).
| Rail | Test 6 (309.13W) | Test 6 (309.13W) |
| 12V |  |
 |
| 5V |  |
 |
| 3.3V |  |
 |
| −12V |  |
 |
| 5Vsb |  |
 |
.
The ripple was kept well in check – staying below half the maximum allowable levels at all times.
Disassembly
The input filtering consists of two X caps, two common-mode chokes, four Y caps (plus a fifth after the rectifier) and one MOV, which is plenty of components. The bridge rectifier is a 6A part and the primary capacitors are 680µF parts from G-Luxon. The Switching Transistors are Fuji Electric 2SC2625 parts rated at 10A. These parts are all good enough for a 300W unit.
The 12V rail uses a MOSPEC U16C20C ultra-fast recovery rectifier, which is rated at 16A – just good enough for the claimed 15A of 12V capacity. The other two rails use SBL3040PT Schottky rectifiers, which are rated at 30A. Two are used on the 5V rail, and one on the 3.3V. These rectifiers are good for double the rated current on these rails. The capacitors on the secondary side are mostly from G-Luxon, with the exception of a few GoldLink and some small Fuhjyyu parts. These days G-Luxon caps are made by Teapo, but this unit uses the older G-Luxons, which are of extremely poor quality – almost down there with Fuhjyyu. As I have stated earlier, it’s a rare event that I see a Macron-built power supply that doesn’t have failed caps. This unit is the exception, not the rule.
The fan is made by Superred and uses a sleeve bearing. It is temperature controlled, and was only really noticeable during the overload test. The heatsinks are small and not particularly thick – especially the primary heatsink. This might just explain why the unit ran a little warm. I would much prefer to see some larger heatsinks used.
Specifications and Conclusions
| Real Wattage | 350W |
| OEM | Casing Macron |
| PFC | None |
| Price | Unknown |
| ATX Connector type | 20 pin |
| Worst-case voltage regulation (12v, 5v, 3.3v) | 3.25%, 2.0%, 0.6% |
| Worst-case ripple (12v, 5v, 3.3v) | 50.4mV, 19.2mV, 13.2mV |
| Worst-case efficiency | 76.95% |
| Input filtering | Adequate |
| CPU Connector | ATX12V (4 pin) |
| PCIe Connectors | None |
| Molex (Peripheral) Connectors | 6 |
| FDD Power connectors | 2 |
| SATA Power connectors | None |
.
Pros: Can deliver more than 300W, Good ripple suppression, Quiet, Reasonably efficient for a half-bridge design
Cons: Low quality capacitors (−2), Mediocre 12V regulation (−1), 5V-heavy (−1), Dated connector configuration (−1), Fan could be better (−1)
Score: 4/10
Loading ...