I think you are right. The diode does have some small junction capacitance. However, the large peak current will probably not occur in real life, or at least not to that extent, if you consider the diode terminal resistance and inductance...

@@FesZElectronics And even if it does, the duration is so small it's practically negligible.

I did not think about that. What sort of active methods are you thinking about - is there something specific you tried in the past?

@@FesZElectronics I am not thinking about something in particular. Varistors have the reputation to not age well so I wonder if like rectifiers there is some active method to limit inrush current. Many dc regulators allow or embed soft start features so maybe there is a way to make some general circuit a bit more elaborate to mitigate the inconveniences of the NTC or the relay solutions presented at the end of the video.

Its true that in certain high power application multiple protection elements are used, the exact combination being based on reaction speed and power handling capability. Its not uncommon to see a capacitor in parallel with a TVS or some other diode, and GDT (arrestor). Depends on the application and the specific pulse that needs to be handled.

Smart idea! But inductive elements are usually expensive and big. I think the P-MOS solution someone mentioned in another comment will win. And in practice for loads like a few 100's W a NTC resistor I encountered most often.

@@LukaszTNT I saw the comment with the P-MOS solution and I didn't get how it can limit the inrush current. In the moment you apply voltage, there is the time to charge the gate of the mosfet and the resistance drops so quickly that I think it's possible to have a still very high inrush current to charge up the capacitors. And if the effect is due to the on resistance of the mosfet, just replace it for a miliohm range resistor.

Got lazy with mine… have a seperate 5V psu, always on driving a raspberry PI running Octoprint, so I just connect the raspberry PI to one of those SSR to control the 24V PSU for the printer. Normally those SSR’s do have integrated snubbers, so you dont have to worry about all those kind of things.

I never thought of using that type of contactor; the switches and relay where some components I already had around, that is why I wanted to use them. Anyway, regarding the printer supplies built in inrush protection, I did not check it in detail, but the box has a 10A rated switch - so I guess the inrush limiter will protect that, however the extra switch I used was only 1A rated... The relay that will keep the printer on is 10A rated, but I wanted to use a low current switch for turn on.

Indeed, its not perfect for AC circuits, but, if the AC frequency is far smaller than the transient, then its ok. For example in 50/60Hz circuits, with a small enough capacitor, the impact will be minimal on the "off" state.

I guess what I did not fully highlight is that both switches (for turn on and turn off) have just one stable position - Open for the mains, Closed for the relay driving; while you are pushing on them they change state, but once you let go they revert - like a push button. So the Mains switch turns on the supply, but the relay keeps it on as long as the relay is supplied

@@FesZElectronics OK: The mains switch is a momentary type that only passes current while depressed. Makes sense now. BTW: For relay bounce/oscillation... Years ago, I ordered 100, 1N4001 diodes and the vendor shipped 1000 instead. I offered to return them but they said "keep it". I'll be using those for relay over-shoot for the foreseeable future.

For AC, you don't normally know when the power will cut out - on the positive or negative halfwave. So the inductive kickback can have any polarity. The Diode-Zener combination will only work on AC if you can ensure the turn off always occurs when the AC is positive. Dual zenner does not have this issue - it will protect regardless of the polarity.