Hi
I've just seen this nice video. I was quite interested to see, what topology have they used. So I carefuly analyzed what I've seen in the video.
Mains input is rectified with a bridge, decoupled by the first 4u7 MKP cap gunked onto the first transformer - whcih is a choke actualy - from the PFC controller. Behind the choke, we can clearly see a TO247 mosfet and a diode. Then there is the filterbank.
The DC/DC converter then takes the PFC's output of probably around 400-420 volts and produce 2x200Vdc in series on the two output caps. The main DC/DC is a standard halfbridge topology, with two secondaries, two bridge rectifiers and double output choke.
The rectangular cutouts in the board are for airflow cooling, not isolation gaps.
Now the more interesting part, the actual convertor: They've used H-bridge topology. Each half-bridge has its own output choke. Between the other ends of the two chokes, there's the second polypropylene capacitor. After that, commonmode choke was placed. The output is immediately after the commonmode choke, near ? a varistor. Seems there are no additional filtering caps. Pretty underestimated filtering. I expected somewhat better filtering there.
The most interesting part is, that the four mosfets in the H-bridge have all blocked the internal body diodes. The four TO220 two-legged diodes Dave showed in the video, are connected in series with drain electrodes of the mosfets. Then there are 8 small plastic diodes (like DO-41 ones) antiparallel with that. God why? I thought, that outblocking the mosfets internal diode is worth only for high switching frequencies, like 100+ kHz, which I think won't happen here, considering the quite bad board layout. Why have they did it? Your guess is good as mine. Maybe they have chased each miliwatt of heat and this helped a little to increase efficiency a little.
How do you think the current transducer works there? It is obviously connected on the plus side of the supply to the H bridge. Wtf? DC biasing the transformer / measuring DC current with it? No? I quite don't understand the location of the transformer. Very strange to me. Source shunts would do much easier.
As I mentioned, the bord layout is not as good as I think it should be. Note the big curent loop, between the H-bridge stage and the electrollytic caps. Crazy. The cap connected after the output chokes is also connected via too long leads and traces. The layout should minimize stray inductances there to gain better HF suppression on the output.
The four PIC micros on the front panel are just funny touch to whole, as is the chassis grounding connection. Even if it would be connected (where?), it wouldn't respect the starpoint earthing - which is here important for reliability. It is not good to earth something somewhere to the chassis, and then elsewhere connect the chassis to the PE lead. There are to many interconnections in between, which could possibly make trouble.
I am also concerned, that the inverter's filter design is dodgy. There should be cap in between inverter supply ground and the choke output. The cap between the chokes only does not suppress the HF switching components between inverter ground and outputs. Oh yes, there's a commonmode choke there, but it is more like "how ya doing" than a properly designed filter. If there is enough capactity between inverter's ground and chassis (PE), it is something I would really be quite concerned about when testing the thing on EM compatibility. For more clearity, I redrawn the schematic of the inverter part of the circuit.
Here are some reverse-engineered pictures of the thing and its topology. Interesting to note, that one of the output post is labeled as "N" (neutral) on the front panel. Douesn't make any sense, if the whole inverter section is possibly floating, so both outputs symmetrical.
Edit: the last shot explains the labeling "PH N GND" quite well. grrrrrrrh. They've just shorted one side of the floating output to PE with some crappy foil cap.
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