Better yet replace the latching switch, or disable the latching mechanism, so that the plunger has to be pushed in for the device to stay energized, then add a latch to the plunger. Alternatively if there's too much air leakage for that to work, you can add a physical mechanism that is joined to the switch an moves a painted flag inside the case. The most foolproof solution would likely be to have the indicator bulb in series with the switch tho, that way the indicator bulb MUST be on in order for the circuit to be energized.

That’s exactly why I value KZbin comments so much! They often provide valuable suggestions, important insights, and great ideas. During the construction, I did consider that the LED could pose a safety risk if it's defective. However, I decided against making the circuit more complex for two reasons: 1. When I turn on the power supply, I press the pneumatic switch to check if the LED is functioning correctly. If it doesn't light up when I press the switch, I know there's an issue. 2. The safety switch shouldn't be activated anyway if the power supply is not in a safe state. So, even if the pneumatic switch is on, it shouldn't be a problem to activate the safety switch. Nevertheless, you're absolutely right, and it would have been better to make the system fail-safe. I like the idea of a second LED (e.g., green) indicating when the device is in a safe state. I might add that later on.

@AdvancedTinkering the downside of the second bulb is that you then have to carefully consider the driver circuit for it, as it can't have a fail mode which leaves the bulb on. If it fails in the on state, and your caution bulb circuit fails in the off state, you're back to a dangerous condition. Your toggle idea makes sense, however the point of safety systems is to mitigate human error, i.e. if you're distracted or excited and forget to do it. Another thing about it is that light colors are rather subjective, for instance on the hv tools I work on red (amber really) indicates main power is off (and thus the hv is off) and green indicates power ready (and thus hv is on), however the breakers in the panel have a red flag to indicate energized and a green flag to indicate de-energized haha. You'd need labels.

I've bean 3d printing functional parts (prototypes and the like) for years, and I do not believe the FDM process is capable of making a part that's free of air bubbles. I spent some time prototyping pump heads, even printed solid they would weep (slowly leak) when pressurized. However, SLA printers definitely are, I think this project would have worked perfectly with some SLA prints.

@@TinkerLynx Printing clear PLA proves that very well. No part is clear but cloudy, unlike a section of spooled filament.

I absolutely agree. I think SLA printed parts would perform a lot better.

I suspect the resin printed insulation would not have the same problem. However we can still improve the performance of printed parts. You can likely try using different materials than PLA but also try using the annealing method that powdered salt. You print at 100% and then place the part in a container filled completely with the finely powdered salt and bake in the oven at the glassing temperature - please look up the exact temperatures for the exact materials before attempting. The part shrinks a tiny amount but becomes completely solid, gets way better mechanical properties and likely also improved performance in this regard.

@@johnmadden9613 I could see the salt causing some issues given that the salt is made of sodium and chlorine ions but I'm not entirely sure about that to be honest

Thank you!

⁠@@AdvancedTinkeringIn a DIY/OS Birkeland-Eyde Reactor maybe if you replicate it? (Granted plenty of projects as-is, but a really well built one would be AMAZING!)

That was actually one of the methods I had considered. I saw CNC Kitchen's video on it a while ago and thought it could make a significant difference. Still, I wouldn't trust FDM-printed components when it comes to high voltage.

Very good point! It would probably make sense to use a momentary microswitch and keep the air in the tube compressed through another mechanism (a three-way valve, for example) in case I need to run the power supply continuously.

Unless the high voltage supply is going to be fully integrated into whatever it's being used for then some form of "dead man's switch" is absolutely essential. This is especially true if it's going to be used as an interchangeable supply for multiple projects. Basically, if it's possible to energise with the high voltage exposed it should require some form of continuous human input to keep it going.

Thank you! If I make a video about different materials, printing parameters, and post-processing methods, I will also test PP. However, I can't promise when I'll get to it. Regardless of the results, I would never trust 3D printed parts as insulation for high voltage. A single defect in the layers is enough to reduce the insulation effectiveness to practically that of air. I would always recommend using epoxy resin with the appropriate dielectric strength as the actual insulation.

@@AdvancedTinkering I wonder if you could submerge the part in epoxy and place it in a vacuum chamber to fill the cracks.

@@RiehlScience Possibly, that could be a method that works, especially with a very thin resin. However, in many cases, it might be simpler to design the parts so that they can be filled with epoxy resin. That's how I made the high-voltage connector for the power supply (shown in my last video on the power supply). I would be very interested in how SLA-printed components behave compared to FDM-printed ones. Unfortunately, I don't have an SLA printer to test that.

​@@RiehlScience Hi, I did that, you can see that bubbles exit at all points where there is infill unterneath. Even at 100% infill there is still some air that comes out of it. I would sugest that you use PLA only for the structure, such as outside walls and standoffs, and leave the insulation to the epoxy. I used very thin PLA standoffs so the epoxy could get into all cracks under vacuum, and it worked out ok up to 30 kV.

@@AdvancedTinkering I wonder how much of the issue with the PLA prints is the filament color. Black plastic should have fairly high carbon content (from the pigment), I would be interesting in seeing performance of different colors.

I and a few other people were thinking about this fail safe issue, seems like you know the perfect solution! Thanks for sharing your expertise with that!

I suspect that different colors perform differently. But since the dielectric strength even of black PLA should be relatively high (assuming no defects), I suspect it is related to small channels between the layers. I experienced a breakthrough with white PLA at a voltage it should have withstood with consistently fused layers. I'll test over-extrusion, thanks for the tip!

@@AdvancedTinkering I saw a demonstration where for a 600V rated cable, the white/red insulation held up to over 1kv but the black broke down just a little above 600V. so there could be some significant difference at high voltage.

@@AdvancedTinkering Maybe getting transparent filament would work well with the over-extrusion: Thomas Sanladerer has made a video on printing transparent (and not just milky-translucent) parts, which also boils down to over-extruding to remove all air bubbles. It would also help to see if a particular part has bubbles or not, without needing to test it with HV :)

Black PLA is indeed conductive to some extent.

Thanks for the advice! I will try that.

Exactly what I was thinking also. Every time I print with a hilbert curve it over extrudes. But also there shouldn't be any one short path (air gap or just a un-adhered surface) that would have a low breakdown voltage. Hopefully just giving as much surface area for each layer.

I didn't think about that, thanks for pointing it out! But probably, I would rather buy a new momentary microswitch to be sure. Then I would just need to design a mechanism to keep the air in the tube compressed in case I want to run the power supply continuously.

In meinem letzten Video zum Bau den Netzteils zeige und benutze ich Corona Dope zum isolieren der Anschlüsse am Zeilentransformator ;) Es zum Beschichten von 3D gedruckten Teilen zu verwenden ist eine sehr interessante Idee. Das werde ich testen.

@@AdvancedTinkering Hmm, irgendwie habe ich den Teil im vorherigen Video übersehen. Muss deine watch- und session-time wohl durch nochmaliges anschauen etwas erhöhen. 🙂

War auch nur kurz und fast beiläufig erwähnt. Kann man schnell verpassen :) Aber ich beschwere mich natürlich nicht, wenn du es erneut schaust ;)

I didn't know that. Thank you very much for the part numbers!

@@AdvancedTinkering no problem 👍

Unfortunately no... I feel so bad that I neglected the Stern-Gerlach experiment. But unfortunately, I need a picoampere meter, which I can't afford at the moment. I hope you enjoy the other projects too! At least I can say that the project for which I need the high-voltage power supply fascinates me just as much as the Stern-Gerlach experiment.

I also experienced a breakdown with white PLA filament at a voltage that a flawless, solid piece of PLA should have withstood. However, I didn't compare two identical PLA parts made from white and black filament. That would indeed be very interesting. I agree with you that pigments in black plastics often lead to a lower dielectric strength.

As an Italian, if you paint it red it will turn on faster.

High voltage is indeed one of the most intimidating things I have worked with. It can behave in ways that are very challenging to predict.

Do you use the 3D printed parts as insulation for high voltage? And if so, at what voltage? I also experienced a breakthrough of white PLA during the project at a voltage that a solid piece of PLA should have been able to withstand. That's why I suspect it may be due to small defects in the 3D printed parts. I guess resin prints would perform a lot better. Good to know that the microcontrollers are relatively resistant to electromagnetic noise. Thanks for the information!

@@AdvancedTinkering I have use white PETG for high voltage standoffs, in which the print is just being used to hold a HV terminal up in the air. Since the print isnt conductive, it doesnt try to snake-down the bushing and arc to ground. But this is basically, If the arc can arc 60mm, I'm running that 60KV through HV wire ( Rated for >75KV ) up through the center of the 3D printed bushing, and at the top of the bushing, I have my contact. That bushing would be much longer than the arcing length, like say 120mm, to simply hold the HV up off the ground. So, in this case its not being a "insulator" in the sense of running a bare wire through it, but I tend to call ceramic high-voltage bushings ( like you see on top of transformers ) Insulators. If you're running bare wire through the center, and trying to make the plastic print keep that voltage in, then I could see it being hit/miss. Since like you said, impurities, if air-gaps exist they could encourage corona, and potentially break through. Sorta like how a 3D printed PLA vase although it looks solid, can still leak water. If water can leak through the layers, air/corona/electricity likely can too, if I had to guess by that logic. I guess ideally HV wire is nice for that stuff. But. Maybe another approach could be casting if needed? Like resin-cast somehow? Would work similar to the potting material. I think as you said, Resin-Prints probably would work, since its a solild material with no impurities. Could maybe look into 3D printing a form to cast silicone in. Silicone is often used for HV, such as super flexible high-voltage silicone wire

I absolutely agree. Since PLA actually has a relatively high dielectric strength, I'm convinced, that tiny air channels and bubbles inside the plastic (maybe in addition with absorbed water) cause the breakdown. I'm sure SLA printed parts would perform a lot better. I unfortunately can't test that, since I don't have a SLA printer.

The problem with that method is: how do you connect the "power enable" button to the HV supply without an electrical connection. Which means I would be back at an IR remote. Or I would need a momentary microswitch which is actuated by the pneumatic switch and then actuates the relay. Or am I missing something?

The HV connector is double-walled and filled from the inside with an epoxy resin with a high dielectric strength. The only possibility of a breakdown would be if the high voltage arcs orthogonally to the layers over a distance longer than the spark gap in air. I documented the construction of the connector in my last video on the power supply. Nevertheless, I cannot guarantee that the connector is safe. I'm pretty sure that SLA (Resin) printed parts provide better insulation.

​@@AdvancedTinkering Ah yeah, I remember now. Lets hope it holds up. In regards to a interlock on the lid, it doens't hurt to add it and should be fairly simple/cheap to do so. And as others have mentioned, consider fail safe states. I'm looking forward to see the progress and what the supply is made for. Stay safe!

I believe there are a few words with silent letters, but it's more of an exception. I can't think of any off the top of my head. Perhaps. At least, X-ray crystallography would be a very interesting project ;)

@@AdvancedTinkering ah then it must have been the French influence that gave English so many 😁 Ones like knife and knee have always baffled me. If you're not going to pronounce the K why not just spell them without it? 🤷‍♂️ Haha, I do agree, very interesting indeed. I've always wanted to learn more about it so hopefully someday I'll get to see someone give it a try 😉

Yes, SLA printed parts should perform a lot better. Unfortunately I do not have a SLA printer to actually test it.

@@AdvancedTinkering We have at work insulation tester up to 6kV AC/DC. Maybe I can print out a test piece 10mm long (PLA/PETG) and measure the resistance/impedance. I have SLA but I dont use it now. Just to know for the future.

Yes, I researched the dielectric strength of PLA before building the power supply, and it does indeed seem to be relatively high. However, my practical experiments have shown that 3D printed parts with multiple layers do not come close to reaching these values. I was already familiar with Kerry D. Wong's blog post. Interestingly, he also uses black PLA. Since the PLA layers for his tests were only 0.18 mm thick, I suspect that there was a very good fusion of the PLA. Once you have many layers, there might eventually be a compromised spot where an arc could form. That's why I suspected defects between the layers. But it's a very interesting question. I think I will test a few different colors and post-processing methods.

@@AdvancedTinkering The layer-height is very interesting. Usually thicker layers mean stronger parts. Maybe printing hotter will help because it increases fusion? Indeed very interesting

Unfortunately a bit too late :D

I don't know why I completely forgot about this, even though I have a label printer. I will do that right away!

I used an X9C104 as a potentiometer. However, I wasn't really satisfied with the module. There were constantly minor issues, and I never managed to get them to run reliably. This was also the reason why I abandoned the idea of an IR remote control. But it could just have been my lack of skill or a cheap/defective module.

The pigments will indeed reduce the dielectric strength. However, I also experienced a breakdown with white PLA at a voltage that the plastic should have easily withstood if it did not have any defects. So, I'm quite sure that other colors printed with FDM printers may not provide sufficient insulation either. But it seems like some testing would be necessary to confirm.

@@AdvancedTinkering white PLA is more often than not dyed with zinc oxide and its concentration is relatively very high. If insulation is what you're going for, use clear plastic and also print it very hot and very slow to avoid air gaps.

Those are great suggestions! Thanks!

@@AdvancedTinkering no problemo, used to work on HV laser power supplies in a past life

I also had a breakdown of white PLA. But I never tested the difference in detail. I will do that!