EEVblog 1482 - Mains Capacitor Zener Regulator Circuit

Hi Dave, these brief 'explanation' videos are a very useful resource for 'faded memory' refreshers (I'm a long retired engineer). Thank you ☺️

I wish we had your TH-cam videos back during my university engineering days in the 90s - thanks!

The Zener regulator makes perfect sense with the series resistance impedance on the AC side and low current loads.
Good that you give the safety warnings, they're absolutely essential with this type of circuits.
BTW it looks like I'm starting to teach people electronics.
Ttoday at our local hackerspace I had to explain the FULL BRIDGE RECTIFIER's principle of operation to one guy who has a university degree in IT but was not taught the basics of EE.
He had a pair of IN-12B Nixie tubes that he wanted to use in a project, only didn't know how to wire them... poor thing. I breadboarded a simple 200VDC PSU with two power transformers connected back to back for galvanic separation from mains, and taught him how to control these nixies using transistors.

Very cool. I had an LED bulb go out so I smashed the power supply out of it to see how it worked. This pretty much looks exactly like what I saw... Simple rectifier spitting 50 to 60 volts DC out to run a panel of 50 little LEDs. Great explainer!

Wow! That I found this in it's entirety intriguing speaks volumes of you terrific delivery, thanks Dave

Love these whiteboard videos Dave. By far the best series for me

Thanks Dave. I've been perusing the comments and realise how much learning can be got from quite simple circuits such as this.

"Come a Gutsa". Gotta love Dave's dielect! Lol.

Hi Dave. Actually I think that the cuircuit with the two zener-diodes in series is a quite smart solution.
Just imagine the case of a 3.3V linear regulator hanging on the 24V rail; that would mean, in addition to the relay current comes the control logic current: a cheap uC + temp sensor + some LEDs, might sum up to additional 15mA; meaning you need twice the input capacitance and have twice the power drop on the 24V zener.
Compared to that, the shown configuration provides the current for the 3.3V rail almost for free.
I guess, the relay coil version is selected to match the control logic current consumption, in order to get the total component cost down.
BTW: greetings from Germany. I like your channel a lot.

While capacitive droppers make poor power factors it really helps the power company. Most load anywhere is generally inductive - think electric motors used for practically everything in industry and residential. Fans used in ventilation, or motors driving compressors in HVAC and refrigeration or motors pumping liquids and such. Thus power companies know the power factor is generally inductive and they have to add capacitive reactance to balance it. There are capacitor banks on distribution lines and at substations to compensate for the inductive loads. You using something with a capacitive dropper helps bring the inductive load down a bit. Though modern LED lights are back to being resistive loads as they are using linear regulation driver ICs. But since the LED array drops about 90% of the line voltage the linear regulator doesn't waste much power. So I wouldn't worry too much about capacitive droppers at all.

ALWAYS wanted to know about these type of circuts. THANKS

Great explanation, Dave about the loss of capacitance, not creating enough voltage, which caused the problems further down the circuit. Hope that made sense.

Interesting circuit break down, thanks!

Great timing with this content. I was just looking into my failed mains ac power meter. It seems to use this to power dc circuit and voltage is way to low.
So it seems you just pointed me to the culprit (ac capacitor). All other possible sections were testing as good.

This capacitance degradation in 'Polly put the kettle on' capacitors is a well known phenomena but doesn't seem to be acknowledged by the manufacturers. I've had several small electrical devices like coffee machines and mains timers fail due to this effect. It would be interesting to set up a test to count the number of breakdown events occurring and the rate of capacitance reduction. I suspect it's mainly a problem in 230V countries where many areas, like mine (and BigClive's), still operate at 240V - 250V or maybe it's a function of how clean the mains supply is. It doesn't appear to be a problem on DC supplies, spacecraft use these capacitors to filter the main DC bus and they work happily for a couple of decades. Having said that they are voltage derated by at least 50%. I would do the test myself but I don't have an oscilloscope which would be necessary to establish the size of the current pulses.

Hi Dave.
A trick with this circuit is to select the upper electrolytic value so that when fully charged it will reliably close the relay, but set the quiescent current (set by the 0.22 UF cap) to a value which will still hold the relay in. With the spec sheet you showed, the relay should hold in easily at half the voltage and the cap could be reduced to 0.1 UF, so long as the upper electrolytic cap was sufficiently charged up by the time the "start" signal arrived.

4:05 thank you. just prior after watching the other video I spent 5 minutes googleing Australian slang. Thought I was missing something.

this kind of video suits you 100%

Thank you very much, another fun learning video.

Finally some nerdy electrovideo! By the way, the zener needs to be able to handle the power of 24v 16mA when the relay is not activated. Hope you are doing fine Dave! Thanks! /Tomas

Excrement!...erm Excellent! :P
youre starting to step into BigClives world with this one Dave!...always good to have the technical background tho!
speaking of Zappy!.. ive got a cheap coffee grinder.. ive copped multiple zaps off it!.. it obviously doesnt have any bleeder resistors across the capacitor...ive started to short the plug prongs on a metal frame every time i pull it from the wall

Fun video dave, this and the repair video. And quite informative ....

big Clive done a similar failure mode video. There was a capacitor in a cap drop circuit that lost capacitance over time. I think it was the power supply for the clock inside a oven. there was also a relay circuit, the relay wouldn't operate due to a cap dropper losing its capacitance over time.

Worth calling out that the strange-looking stacking of 24V and 3V3 kinda allows the microcontroller to be powered "for free"-ish in some vague sense. I.e., a 240V AC mains + dropper cap = a high compliance, practically-fixed-current AC current source; if you were to run the MCU off a LDO off the 24V, then the current for the MCU and the current for the relay coil would be added up. But with those elements in series, it's only the compliance voltage of the current source that needs to be increased, and since it's already at 240V, it's all good to go.

Nice stuff Thanks Dave 😊 👍

This HP41C calcularor 😍, typical of a good engineer

In some of these types of circuit the zener only limits the maximum supply voltage if the load drops, rather than to regulate the supply voltage. For example, the zener in our fan controller limits the supply rail to +12V whereas the normal running voltage is about 5½V.

Hey Dave, I have seen these crude line capacitor dropper power supplies used since the early 1990's. I worked for a company that used these circuits in LED bulbs but, without the surge resistor. I modified the circuit by inserting a 100 ohm pulse rated resistor (US, 120 Vac), which improved reliability and power factor. These circuits are very vulnerable to voltage spikes and outputs from triac dimmers and squarewave/modified power inverters. The circuit you showed has a worst case surge current of 6.6 amps, assuming a clean sinewave. That particular circuit was likely designed by an engineer, then redesigned by management to further lower costs, then redesigned again by manufacturing who would only allow 10 reels of parts to be used on their pick & place machine. If the surge resistor was pulse rated, the redesigns probably changed it to a 1206 thick film chip resistor to reduce cost.
Of course, who cares about ripple on the regulated supply lines or voltage drift over temperature. These zener voltages are horribly unstable over temp. Also, placing a filter capacitor in parallel with a zener feed from a rectifier, can never be free of ripple (I wonder how the microcontroller reacts to that?).
I am assuming this circuit was powering a digital thermostat for a low cost space heater? With this circuit, it no longer replicates the mechanical thermostat it is replacing because, it will no longer run off DC (assuming these was no fan being used).
This circuit has horrible power factor as you mentioned, although would be insignificant when the heating element is energized. The power factor of the circuit is usually overlooked due to the low power draw but, becomes a problem due to the amount of power line harmonics it generates and resulting power loss at the power plant, which is roughly 7 times the power as measured at the device itself.
The power factor problem was recognized in the 1990's and since then, home appliances drawing greater than 50 watts employ some type of power factor correction. The worst offenders now are induction motors but, they have been redesigned as well such that the worst power factor I have witnessed lately is 0.85. Additionally, most all electronics use an off-line-switcher instead of a step-down 50/60 Hz power transformer. So, the mains are far less inductive these days.
If your house is powered from a simple 2 or 4 pole generator, the power factor can quickly consume available generating capacity. Let's assume you are charging a solar battery bank from your generator. The difference in power factor between battery chargers that have 0.5 versus 0.9 is huge, with the 0.5 needing almost twice the generator capacity.

Yes we find it interesting. Thanks Dave :)

Love the calculators making cameos on your whiteboard videos. I'm always surprised at how many of them I have myself, including the HP-41 here. :-)

I find the whiteboard videos really helpful. I don't have any ee background I just like to tinker with and fix things as a hobby so I lack a lot of the fundamentals.

Good info. Thank you.

Damn this guy is good, excellent explanation.

In capacitor power supplies with relays, a relay with the highest possible voltage and lowest current is often used.
It is often common for the zener diode to get hot when the relay is off because the current is then heating up the diode. If the relay is on, the diode is often very cold because the power is then in the relay.
The series connection is clever because the 16mA is available anyway, an additional 3.3 or 5 volts are irrelevant for the current.
The disadvantage of the capacitor power supply is that 16mA always flow. Yes, always!

I found this very informative...cheers.

Nice topic...

I came across a resistor based version of this in the standby circuit of the Revox power amp restoration I recently completed. It gets way too toasty for my taste, so I disconnected it; besides, the optocoupler that turns on the mains is probably shot too. I replaced the original with a higher value to cut down the current, but it still was too hot even after short periods of powering it. Note: I'm convinced the zener would have properly conducted, since the original value was also supposed to work across 110V and I have 240V here, so double R should not be an issue for the current...

Nice video, thanks :)

The grid delivering the power is largely inductive, so power factor correction usually means adding capacitance. Except for very long EHV lines where there is a huge amount of distributed capacitance and series inductors need to be added.

good explanation thanks

Very interesting video. And a wise choice of a RPN calculator, 'cause there are no problems here with implied multiplication whatsoever. I like the good old HP 41C.

Nice calculator you have there! Just like mine....

Interesting stuff.

An HP-41C? Your taste in calculators just stepped up several notches.

I mean, it's an electrical heater. A resistor just keeps a low level heater running. Say it's a feature!

Plugging in a capacitive load into the electrical grid is not a problem. Yes, there is (reactive?) power that the grid needs to supply and then accept back each cycle; this produces non-imaginary current flowing through wires that heats them up and has to be made up for by the generators.
But this is capacitive reactance, and is 180° in phase from inductive reactance. The (US) national grid operates on a power factor of 0.8, which is inductive. Most of the loads on the grid are inductive; transformers and motors mostly. That means the generators have to supply power to build up the magnetic field in all this inductance, which heats wires &etc.
I once worked for a company with many large assembly lines. They had many large motors each and we used heaters with some inductance themselves. In order to prevent extra fees because we were inductive-loading the power factor out of tolerance, we had a Capacitor Farm. All those magnetic fields growing and shrinking in our motors were feeding power into our own capacitors locally, so the generators saw a normal load and the long-distance wires to the power company could stay cool.
So if you plug a capacitive load into your house receptacle, rejoice in knowing that you're just balancing out a bit of your refrigerator's inductive load, and making those generators a bit less loaded.

Today me and a colleague also had a failure in a capacitive dropper circuit - but it was not the capacitor. After the diode bridge there was a simple linear regulator with a 30 V zener-diode, a 10 kΩ resistor to limit the zener current and an NPN-transistor. This intention of the supply was to keep the coil of a 24 Vdc relay energized - pumping 29 V into the coil, why?
However, after about 25 years in duty both the transistor and the zener diode had failed which I diagnosed in the end from the about 0V over the zener diode and 0.4 V base-emitter voltage of the transistor.

"Without the load you get nothing", apart from 240V RMS, on the outlet of the rectifier presumably? I came across a "reactive voltage dropper" circuit a few years ago when I tried repairing a paper shredder. Being a naive mostly home taught electrical engineer, I was expecting to find a transformer and voltage regulator circuit to drive the LED indicators and optical paper sensor, but all I found was a capacitor and resistor. After a quick Google I found out what they were doing and why. And promptly decided that poking around a circuit board that wasn't isolated from 240V wasn't going to do my life expectancy much good. Did consider buying a plug-in earth leakage trip so I didn't trip my entire flat when the inevitable touching of the live line happened.

Thanks for the excellent explanation... I guess that is also the way YAMAHA build their standby power supply in their home cinema amplifiers... btw. also a 220nF capacitor ^^

Perhaps a followup to this would be to model the circuit with one of the many SPICE type simulators? It would then be possible to see the phase of the input current wrt the voltage, to look at the effect of having the relay on or off (on current drawn and its phase). It would also be possible to demonstrate the effect(s) of using a resistor rather than a capacitor.

What happens when the NPN transistor is turned on on time 16:28 ? Which one of the two transistor will blow up first ? Did you miss a limiting current resistor between the PNP and the NPN ?

The current capacity is not that dodgy: Having the rails in series means the current gets to be used twice: That same ~15mA is always available for the micro regardless of whether the relay is on or off: It's in series, not parallel.

Dave, correct me if I'm wrong but the 3.5 "W" (VA) is not supplied by the grid, it is supplied by the power factor correction panel at the facility main distribution center. For example, installed alongside transformer LV output panels.
If reactive power consumption of your generator's load increases, you do not push more water, steam etc. to your generator. You change the field excitation current.

I never concern myself with capacitors loading the grid, figuring that all of the inductive loads on the grid more than compensate. So the capacitors are benefiting the grid. Do I have this right?

All in all they did excellent design "design to fail"

Actually in this case where it’s driving a heater, using a 5 watt resistor to drop the voltage would actually just contribute to the heating!

I'll have to look for your power factor content, even though I get what it is, I'm yet to feel like I fully understand it, I definitely don't feel like I understand how the PF correction circuits work.

The thing about that design is the microcontroller was still functioning normally even when the power supply was only working at 50% capacity.

Nice video Dave
13:20 This Power Factor business means you're getting your circuit to work but the energy supplier has to carry the cost of the use of your circuit.
Conventional meters in the house can't measure the Apparent power and so you actually save some money.
The suppliers want everyone to go to Smart meters which can....
I wonder why !!

Hi Dave; you said PNP but you've drawn it as a PNPN.

Here we go. We are at school again !

Thanks a lot Dave for this vidéo. I am not sure I understand how a 16 mA power supply can source enough current for both the relay (15 mA) and the logic part (?? mA).

Assuming this circuit is out of a coiled-wire resistive heater, with or without a fan, wouldn't the heater's primary operation effectively offset the capacitive line reactance at the plug?

I think the explanation about the Zener-Diodes and the degrading dropper capacitor is a bit awkward: those diodes are mainly needed to limit the voltage for the transistors, in particular if the the relay coil is turned off. For a longer lasting circuit, the dropper capacitor probably should be 300nF, and then the Zener is also "eating" the surplus energy. It's true, that the Zener are getting redundant, when the dropper capacitor degrades too much over time.

If you take the capacitor apart and unroll the layers, I wonder if you could see the damage? What would that look like under the microscope?

You come a gutsa!

OMG! U mean I just repaired my ''home'' appliance? wow! time 4 a Impy-dance!

Quick question. If the diode rectifier provides 240V+ and we shave off 24V and 3.3V, where does the rest go? Does it get blocked by the diodes? Does it get dissipated by them? Thanks

Would you do a video on esaki or Gunn diodes

Hi Dave, I have a question. Could it make a difference if I swap a polar capacitor (220nf) n that circuit against a bipolar one? Could the bipolar cap have lower ESR and mess up the circuit?

Nice calculator, does it still work? I was the engineer for the CPU on the first 41C model.

Is the rail voltage at the rectifier 27 volts or if the second Zener Diode 5 volts is it 29 volts? If so then it' may be using the Zener diodes in series with the virtual ground. That would make sense such as using 2 12 volt Zeners to make a 24 volt power source.

9:50 Isn't it a bit strange to do "order of magnitude" calculation using 3 digits of precision for the resistor (1.45 *10^4) ? Mains voltage only has 2 digits (2.4 *10^2). It would have been nice to round that to 15k for example.

is it not safe to put fingers on a 5v usb lead from say an arlec plug adapter that has usb outlet ?

Has anyone heard of mains supplies in Australia ever going over ~253v for a long time eg. more than half a second to say a few minutes?
Do the street/suburb/local transformers have cut-outs to deal with this?
I guess all the MOVs in devices would go up in smoke after a second or two, and a lot of devices would end up with damaged parts?

That chassis is hot as

Having a power resistor waste 5 W as heat isn't necessarily a bad thing in a heater, since heat is what you are trying to create! :) (But in almost every other case it would be bad of course). In this case it would still be a problem because the zener regulator would use the same amount of current regardless if the relay is energised or not. Could they have used a power resistor to only power the relay, and some other way to power the control circuit that only needs a tiny current (one of the linear regulators mentioned in the other video maybe?). That would be more efficient and a resistor is less likely to cause problems than the capacitor.

Enjoy these whiteboard videos.
Though you weren't able to explain the whole circuit without spoilers 🤣

Is there a particular reason they use 24v relays instead of 12v? If they are pinching pennies, wouldnt it save them twice over. (Able to use a lower value cap), etc..

yeah it was an interesting and useful video dave. actually im sorry to have zoned out a bit in the middle with the specifics. but that is more due to my lack of interest due to having an inherent utter conpept for all these god awful circuits that i just find so apalling. rather than it being any fault in your educational style or presentation these. you made some great points, and also i am sure that inevitably will be coming across a great many real world examples of these. to need to actually at least identify them at least. to have a good grasp of what they are. so will need to watch this again. but more to the point: what other types of banger / substandard ac power circuits are there apart from this style? you know.... the others for which i can also harbor a similar level of contempt / that goes boom and/or kicks out a crap ton of interference. all for saving those precious bom cost dollar. it would be great to see them all. and maybe even some rankings table with columns pros and cons. one column could be interference. another column power factor. another column effeciency (and therefore also that means heat --> reliability). another column bom cost, etc. etc. a true rankings of the worst of the worst. haha

Couldn't one use a capacitor on each leg to get an isolated output?

6:18 - AC 'Sthircuit' Theory?? Ahahaha!

I guess a MOV might've saved the X2 cap losing so much capacity?

the eternal quest for cheapness--

wouldn't you have 240 x 1.4 so really 330 volts after the bridge???

Don't forget, reactance is just the imaginary component of the impedance. The impedance is a complex number.

Dave, it’s ok to say ‘Impedance’. I lost count the times you use finger quotes to say ac resistance.

Considering this device is actually called a HEATER, some 3.7 watt power dissipation from a resistive dropper wouldn't worry me too much.. if it was in a light or something else then I'd be more concerned

If you want to use a non-isolated MOSFET to switch rectified mains, you need a more nuanced capacitive dropper circuit.

I think worrying about 3.7W dissipation from a resistor in a 2kW heater is rather amusing.

I beg you sir to do a few videos for mains capacitor solar exposure 1850’s solar storm stuff. Super dangerous i know for the regular but ya gotta break some eggs ;-)

Small correction. The generator has to provide 3.7VA not 3.7W.. Or perhaps just "the generator has provide the 'current', ie the 16mA, but this is 90 degrees out of phase, so it amounts to 'no power'" And actually quite often the "generator" doesn't have to provide that extra current at all, because there will be an inductive load somewhere more locally which just supplies (and hence offsets) the capacitive "leading" current.

dave didnt YOU come a gutsa here? the zeners in series would mean that the zener voltages should add up and 24v + 3v3 or 5v would be roughly 30v and if you guesstimate the coil current from the datasheet at 30v (given are only 24v and 36v) you would get anywhere between 15mA and 10mA thus the zener current would still be edgy but not that edgy. if it really was in the order of 1mA i would expect the circuit to not even work with the good cap. assuming a coil current of 12mA at 30v (right between 15 and 10mA) there would be 4mA for the zeners which i learned to be roughly sufficent for small signal level type zeners...

WOW - 47 Ohms as inrush protecting resistor? Even when we are effectively dealing with a series circuit of an capacitor with 220nF and the electrolytics? No way that the 47 Ohms would make that much of a difference to the inrush current. It is much more likely that this 47 Ohms resistor is nothing more than just fusible resistor to break the circuit if for example the diodes in the rectifier. The 220nF cap alone would limit current down to not more than just a few Milliamps... ;-)

I opened up the Sonoff th10 hardwired smart switch to modify it's firmware, and discovered it used this style circuit. Possibly with a switchmode regulator, but certainly with the whole circuit at some mains potential. That's ok, right? It's hardwired in and you're not touching the microcontroller. Except that there's a 3.5mm audio socket on the side to plug in a temperature probe. I then wanted to plug the waterproof temperature probe into my fishtank.
I made another modification - plugged it directly into a 5v USB port and just buggered off the 240 part. Don't trust cheap Chinese devices without opening them up and reverse engineering them!

In a nutshell: Arlec is pretty cheap stuff! Not my primary choice.

Polyputaketalon, 👌🤣👍 ❗

G'day m8. You could have just rang the SEC and got them to change the mains frequency to 100Hz then you wouldn't 'ave to buy a new cap. Yeah, I know. Catch ya l8r m8.

I guess if you increase the capacitance to 300nF you will get a more output current and a longer lasting capacitor .

You made the same mistake as in a video a while ago about power generation. The generator doesn't have to generate the power (just think about how that would work in relation to the conservation of energy. The genreator generates 3.7 watts, and it just.. disappears?). Parts of the cycle, the generator would have to push a little harder, and the next part of the cycle, energy will be delivered back to the generator, effectively pushing it forward. In a lossless system, this means there's no net power generated.