The circuit described bellow is dangerous. Using it improperly will kill you. On the other side I may also made mistakes during the design and built. I'll take absolutely no responsibility for it. If you want to build it, please don't ask for circuit board or help. I won't help you.
So, I continued to work on the issues from the previous post.
"Mill a hole for the mains socket and the circuit breaker to the backpanel"
"Mill the holes for the banana jacks to the front panel"
Actually it was much simpler than I meant originally. My step drills eventually arrived. Sooner than expected. Never used such tool previously. On the first try I was able to drill the holes in no time.
"Finish the wiring"
"Set the correct decimal dots"
It wasn't easy to remove those solder blobs, but done
"build a dummy load to be able to test the current measurement"
Actually a professional DC electronic load what is able to work above 300V isn't cheap. So I decided to pick a 100W 1K resistor and screwed onto an old s478 heathsink. The question is if the fan have to be used. Finally it worked without it.
"Paint the front panel"
Actually I had serious problem with assembling the panel meters into the front panel. Most of the fixing clamps are broken of (because of the material aging or bad construction, who knows)
I hate that hot snore glue, but I had no other option here, to keep the panel meters in its place:
"Build the phase switching electronics (not mandatory, maybe after finish)"
Actually I've quite a progress with it, but it will be the subject of an other post. Not finished yet, so it is not assembled into the unit yet.
"Create the console for the caps"
This was funny. I don't know why I completely forgot that the outside (and therefore of the mounting screw also) of those large cans are the negative pole of the capacitor. building two caps with different potential on the same conductive (aluminum) mount is not a best idea of the world:
Luckily I realized this before switching on, and exchanged the mounting plate to a plastic one (unused etched FR4):
As I'm at the end of the todo points. The project is almost finished (just the phase switching electronics missing):
I'll finish the phase switching electronics and install it.
The PSU itself has some room for improvement. Like cold start current limiting and proper capacitor draining. I'm not quite sure, that those improvements will be done in the near future. The usability of the equipment will tell.
As the other PCBs are arrived for the supply, I continued the build. Finished the separated isolated supplies for the panel meters (these are nothing else just a simple dual 7809 based linear supplies):
Also added the power distributor and some wiring for the backpanel:
Connected the panel meters and, milled parts of the front panel (manually as my CNC mill is still broken) How the whole thing looks like today:
And its working, partially:
As you see the decimal dot is on the bad place (it is more likely 330V than 33V) In addition I took a picture of the board on thermal camera. You can clearly see that the two capacitor draining resistors getting warm:
So I can tell, it is progressing, but quite few things still ahead of me:
Mill a hole for the mains socket and the circuit breaker to the backpanel
Mill the holes for the banana jacks to the front panel
Finish the wiring
Set the correct decimal dots
build a dummy load to be able to test the current measurement
Paint the front panel
Build the phase switching electronics (not mandatory, maybe after finish)
I've many ideas in my had, what to build, what to experiment with. A few of them involve using mains voltage directly. Some of this need to rectify and clean the input before using. My lab power supplies are able to produce 60V DC maximum, what is clearly not enough for those experiments. A cost of a proper high voltage variable DC supply is enormous, and I don't need most of the features of it right now:
Not need to be variable. My built circuits will have rectifications on its own. The input comes from mains anyways so this is the only voltage I need.
Not need to be stabilized. Same concept as above.
Not need to be isolated. I know, at this point the real professionals start to scream: IDIOT!!!! Let me explain why I'm not:
1. I've built a proper isolation transformer in the past. I can use it, when it is necessary.
2. My negligence: two way rectified mains after filtering in my country is around 650V DC. It is lethal anyways. If you make a mistake, it will kill you. It can't kill you twice because of the missing isolation.
So the plan: Build a simple two way rectified supply with large can electrolytic capacitors (I bought 3300uF/500V ones for a good price. These puppies are huge). Add necessary circuits for small panel meters to be able to measure, what is coming out from the circuit. Add necessary circuit to discharge the capacitors. If they left unattended, they can still kill you after long time. Add a special circuit I designed for it. It has two functions:
Test if the equipment grounded to the protective earth (it is not a proper grounding test, but if your lab is properly grounded, it will tell you if you have cabling problems)
Test the polarity of the incoming supply and change it if necessary. So the 0V output line of the equipment is always connected to the Null and never to the Line.
This circuit is still under development, so I don't know if it will work or not, but it isn't absolutely necessary for my power supply design. It adds some protection to the circuit, but nothing substitute the extreme care and the proper isolation.
I started to design this something like two weeks ago. Ordered the circuit board on the last Saturday. Actually it is already in my hands since Thursday, thanks to the extremely cheap, fast and high quality PCB manufacturer I found recently: ALLPCB (10 pcs 100x100 two sided boards for $5.49 delivered in 5-6 days - insane):
Yesterday I had some time to populate the board:
Those cans are huge, I told you.
Let see some measurement:
I've an isolation transformer, as I told before. Ouch! My Fluke 117 unable to measure the output voltage. According to the specification it is able to measure until 600V. In fact it was working until 650V, but the supply is above this. Lets change to a 1000V rated tool:
So, the PSU works now. My first impression, that the 100k/5W resistors I connected in parallel with the capacitors are improper for draining them. It take quite a long time (several minutes) to do their job, and generating some (not to much) heat during the operation (the 3W consumption on the display of the isolation transformer). It is sufficient now, but I'm thinking to replace them to some active solution. (an AC Relay with some lower value/higher power resistors maybe). This is it for now. Next is building into the enclosure, adding and calibrating the panel meters.