Primary Analysis
Contents
We were very curious to check what components were chosen for the power section of this power supply and also how they were set together, i.e., the design used. We were willing to see if the components could really deliver the power announced by OCZ.
From all the specs provided on the databook of each component, we are more interested on the maximum continuous current parameter, given in ampères or amps for short. To find the maximum theoretical power capacity of the component in watts we need just to use the formula P = V x I, where P is power in watts, V is the voltage in volts and I is the current in ampères.
We also need to know under which temperature the component manufacturer measured the component maximum current (this piece of information is also found on the component databook). The higher the temperature, the lower current semiconductors can deliver. Currents given at temperatures lower than 50° C are no good, as temperatures below that don’t reflect the power supply real working conditions.
Keep in mind that this doesn’t mean that the power supply will deliver the maximum current rated for each component as the maximum power the power supply can deliver depends on other components used – like the transformer, coils, the PCB layout, the wire gauge and even the width of the printed circuit board traces – not only on the specs of the main components we are going to analyze.
For a better understanding of what we are talking here, please read our Anatomy of Switching Power Supplies tutorial.
This power supply uses two GBU605 rectifying bridges in its primary stage, which can deliver up to 6 A each (rated at 100° C), so the total current the rectifying section of this power supply can handle is of 12 A. This section is clearly overspec’ed: at 115 V this unit would be able to pull up to 1,380 W from the power grid; assuming 80% efficiency, the bridges would allow this unit to deliver up to 1,104 W without burning this component. Of course, we are only talking about these components, and the real limit will depend on all the other components in this power supply.
The active PFC circuit from this power supply uses three power MOSFET transistors (20N60C3 – the same one used by several other power supplies we took a look, like Antec Neo 550 HE, Cooler Master iGreen Power 430 W, Corsair HX620W and Thermaltake Toughpower 750 W) and this is the first time we see such design. All other high-end power supplies we’ve seen to date use only two transistors (except Enermax Galaxy 1000 W, which uses four transistors). Each 20N60C3 can handle up 300 A @ 25° C each in pulse mode (which is the case).
The active PFC transistors and the PFC diode are installed on the same heatsink.
Figure 10: Active PFC transistors and PFC diode.
In the switching section, two FQPF18N50V2 power MOSFET transistors in two-transistor forward configuration are used, and each one has a maximum rated current of 72 A at 25° C in pulsating mode, which is the mode used, as the PWM circuit feeds these transistors with a square waveform, or 12.1 A at 100° C in continuous mode. Interesting to note that these are the same transistors used by Corsair HX620W power supply.
The two rectifying bridges are installed on the same heatsink used by the switching transistors.
Figure 11: Switching transistors and rectifying bridges.
The primary is controlled by a CM6800 integrated circuit, which is an active PFC and PWM controller combo. It is located on a small printed circuit board shown in Figure 12.
Figure 12: Active PFC and PWM controller integrated circuit.
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