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Author: Subject: DIY power supply for electrolisis
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[*] posted on 14-11-2016 at 10:38
DIY power supply for electrolisis


I recently stumbed upon these kits for a regulated 0-30V 2mA-3A power supply. With that, plus a fan for cooling the circuit, and a 24V AC transformer, you got a cheaper power supply (a proper 30V 3A one can cost ~60-80€). 8€ for the kit, 7€ for the transformer, and if you want you can add a display, plus a case, for a total cost of arround 40€.

Is there any downside to this? I cant really find any, other than having to asemble it, wich isnt that bad, practising my solder habilities can be good.

Is 3A not enough for electrolisis? I have been doing electrolisis with less, however its pretty slow.
~0.1mol/hour/z in ideal conditions acording to my calculations using faraday electrolisis law for 3A.
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[*] posted on 14-11-2016 at 11:26


I recommend you buy an old ATX PSU, 50 AMPS and 5, 3,3 and 12V rails.
Might be even cheaper too.
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[*] posted on 14-11-2016 at 12:02


ATX power supply beats the pants off any competition simply due to availability and price, and a 5V @ 20A output.

For finer control (which is probably uneccessary) a Buck circuit will get you exactly the current you want at any particular voltage.

www.t-es-t.hu/download/microchip/an626a.pdf




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[*] posted on 14-11-2016 at 12:56


Yes its a nice kit, the current control stops you killing it and could be usfull for other things. Even with a fan the heat sink look a bit optamistic for +90w dissipation.

Why do you think it comes with the transformer?

There are lots of ready made voltage and voltage/current regulator boards on ebay for a round that price and much less. But that one only needs a suitable transformer and probably a bigger heat sink. It comes with the C and rectifer.

For electrolisis a switching one is more efficent.

As others have said its hard to better a ATX PS for cost and current and you can get them for from scrapped PCs for free. If you want the voltage control you can add a switching 8A regulator for about £/$ 4. You can also mod them for variable voltage.
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[*] posted on 14-11-2016 at 13:37


have to agree with aga (did I just say that ?)
a PSU is cheap and not that nasty, and if you blow it up, there are another 1000 of them in peoples garages ready for the job. its all I use.




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[*] posted on 14-11-2016 at 14:56


I have a old computer to scrap, with some luck it will have a ATX with that PSU.
@diddi blow it up? Ehh I hope I don't, any precautions I should take other than not shocking me in some dumb way?
Do the ATX PSUs need any kind of vent or just vent holes?
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[*] posted on 14-11-2016 at 16:11


I managed to fry a computer power supply. I forget the details. It was probably easily salvageable. But although my theoretical knowledge of such things is ok, my practical knowledge is on a level below worm poop. I follow wires around and look at little circuit boards, chips and capacitors without a clear idea of what is happening.
In the end I bit the bullet and bought one of these:
2011092068341785.jpg - 32kB

(well, ok: one very like it.)

I haven't looked back. It is great to be able to set a particular current and walk away.
So I would say your ideal solution is dependent on budget and skillset.




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[*] posted on 14-11-2016 at 17:14


make sure the fans are working. mine melted when I left it running in my garage for a couple of days during very hot weather. the don't like being shorted out either.



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[*] posted on 14-11-2016 at 19:29


A 50w mosfet, an opamp and a shunt resistor will give additional regulation.
the mosfet and shunt resistor need cooling. So a fan and heat sink also.
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[*] posted on 14-11-2016 at 23:42


Heat dissipation can be a major problem, which is one aspect where a Buck design helps out.

Much less component heating as the power output is switched rather than just dissipating the excess as heat. Component size is also generally much smaller.

The downside is that if the control circuit screws up, the inductor & mosfet get toasted as it basically shorts out the power supply.

Buck & Boost regulator circuits are well worth a look if you're interested in power electronics.




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[*] posted on 15-11-2016 at 01:57


On and off for >40 years my main hobby has been electronics
and in my case, if it is not in a box it gets damaged, misplaced or canibalised, and an assembly of miscellaneous modules ends up as a self-shorting mess.

Because I do audio and rf electronics, the electronic noise of most switchmode power supplies is unacceptable,
so I like linear power supplies.

The problem with linear power supplies is heat dissipation,
e.g. a 0-30V @ 0 - 5A dc linear power supply,
the internal raw dc supply needs to be greater than 30V, say c36V.
when the psu output is maximum current at minimum voltage, the heat dissipated in the regulator is 36V x 5A = 180 Watts
... that is quite a large heatsink, possibly requiring forced air (a fan).

IF funds allow, I would go for something like the psu pointed to by j_sum1.

For just rough bulk electrolysis I'd consider;
. automotive 12V battery charger
. ac -> transformer -> bridge rectifier -> electrolysis cell(s)
. add a large electrolytic capacitor to the above for 'constant' voltage as opposed to 'pulsing'
. for up to 1A, a wall-wart/plug-in power adapter is probably lying in a drawer somewhere in your house.

......................................................

For the electrolysis of water https://en.wikipedia.org/wiki/Electrolysis_of_water
1.23 V + 'overpotential' is required, 1.5V to 2V total per cell,
if you use higher voltage per cell (e.g. 12V) then all that is achieved is excessive heating of the cell.
Rather than cranking up the voltage, use pH<=0 or >=14 electrolyte,
so for a 12 V supply of fixed maximum current, six cells in series will produce six times the gas output of one boiling cell.

One bit of trivia that I have been considering is the option for producing pressurised gasses (if not careful, a.k.a. 'a bomb')
electrolysis producing gas at 100 - 200 bar only requires 3% more energy input (slightly increased 'overpotential')




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[*] posted on 15-11-2016 at 04:19


Im currently using 4V 2A old cell phone charger.
The first thing I did was look for proper lab bench PSU in amazon, then in a secondhand spanish website, however the prices were still off what I want to spend on this.
For my budget, the ATX PSU looks really good, since I basically have to spend nothing at all on it, as I can adapt it with what I have laying arround in my house, and I think I have one in an old computer I have to salvage, so i'll probably stick to that.
In the future, i'll probably want to get a proper PSU.
AC -> transformer -> bridge rectifier -> electrolysis cell, looks good if I want to electrolyse a lot of certain chemical, however I want to have something to be able to electrolyse whatever, using a proper voltage, and current.
I also have this thing that I am really scared of AC. Even if I just work with 24VAC that aint gonna cause any harm, I get uneasy with it, getting shocked by touching just one wire isn't something I like. Thats just because of inexperience tho.
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[*] posted on 15-11-2016 at 12:28


+1 on the notion of getting an off-the-shelf PSU.

In the end, you have to ask yourself "what do I want to achieve here?".

A better way to equivalently rephrase that question would be, "do I want to 'work' for less than minimum wage, and devote my time to this instead of my other projects?".

If all you care about is getting some results out of your project(s) - in this case, electrolysis - quickly and with minimal effort and trouble, then an off-the-shelf unit is the way to go.
Place an order, and you're ready for action in maybe 2-3 days, with little more effort needed than involved in unpacking the box.

As an aside, these PSUs have built-in short circuit and overload protection, and the better ones also have a thermal cutout, so you'd have to screw up really badly to fry one of these.

But if you want to learn some new things about PSUs and electronics in general, while not in a hurry to get an actual usable PSU out of the whole ordeal, and don't mind getting totally sidetracked like that, then by all means, go the DIY route.

Sure, you'll almost invariably end up "working for way less than minimum wage" if you factor in the time spent on such a project, vs the cost of an off-the-shelf solution, and also the difference in quality of the finished DIY product vs the commercial one.

But that's an excellent learning opportunity. Let's say that something doesn't work right, or outright blows up?
Successfully trace the problem to its root cause - don't do shotgun debugging - and the conclusions drawn might well be much more valuable than the amount of time wasted, and save you far more grief in the future.

In fact, even if it does actually work the first time around, you can still draw useful conclusions from it, even if not right away - in pretty much every DIY job, there's always something that can be improved.
Even if you can't seem to think of any way to improve it any further at the moment, all it means is that you need to work on improving your skills some more.
And then when you come back to it, you'll be like "hey, THIS and THAT seems suboptimal when you think about it, but I can fix that".

Of course, all that effort would be totally wasted if you do counterproductive things like "shotgun debugging", and fail to draw any useful conclusions.

I personally know a few people like that - they try doing something "new" and totally unfamiliar, and fail to do even the most basic research beforehand.
They then throw a hissy fit when it invariably fails to work the first time, make a bunch of totally random changes, then it still fails to work again and again - and then they toss that project into the bin, and move on to the next, generally repeating the same cycle over and over, never learning anything useful out of it. Sad.

[Edited on 15-11-2016 by The Mad Plater]

[Edited on 15-11-2016 by The Mad Plater]
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[*] posted on 15-11-2016 at 13:23


How much H2 do you need per hour? I think we've just covered this in another thread. https://www.sciencemadness.org/whisper/viewthread.php?tid=64...

My design based on an ATX is quite robust (So far!) But if very specific voltage control is what you need, then a voltage reg module will need to be added; these are fairly inexpensive. My experience with electrochemistry was that it was frustratingly precise, exact voltage, temperature, electrode surface area, concentrations, purity, pH, current density, membrane permeability...and others, all had to be measured and controlled for something not only practical but reproducible. Aside from water, electrolysis of anything else is going to require other equipment and control of more than just voltage.

But your needs may not be so demanding, I don't know the exact details of where your project is going to say that you can't get by with just a bit of voltage tweaking.
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[*] posted on 16-11-2016 at 14:00


This webpage, which I have written a few years ago, may help you:

http://woelen.homescience.net/science/chem/misc/psu.html




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Want to wonder? Look at https://woelen.homescience.net
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[*] posted on 16-11-2016 at 16:24


@Chemetix I dont have any particular project in mind, the psu is the project itself
@Woelen thanks for the link, it is explained quite better than in others I have seen. What I cant really understand, in an electrolysis, I have learned that you need a minimum voltage (the decomposition potential) and the current dictates how many moles of product are generated. In what cases would it be good to limit the current, and where would it be better as much current as possible?
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[*] posted on 16-11-2016 at 16:46


Quote:
What I cant really understand, in an electrolysis, I have learned that you need a minimum voltage (the decomposition potential) and the current dictates how many moles of product are generated. In what cases would it be good to limit the current, and where would it be better as much current as possible?


Limiting current limits current density. (The other parameter is the electrode geometry.) The current density has an effect on the side reactions that can occur at the electrode, the rate of gas production (if applicable), the form of crystals produced, the amount of electrode cavitation and erosion.
A bit of overpotential is always needed to get any current at all. But in general it is easy to overdo it. My experience is that best results are obtained by keeping the overpotential low and hence current density low and simply allowing a lot of time to get the reaction done. This will of course depend a lot on what particular electrolysis you are doing.

Anyway, this is the beauty of a PSU of the kind that I linked. I get to set the maximum current and also the maximum voltage. And the unit either regulates the voltage so that I achieve the max current or applies the maximum voltage that I have set. Like I said, if you can afford it, this is the way to go.

[Edited on 17-11-2016 by j_sum1]




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[*] posted on 16-11-2016 at 17:44


All the ATX PSUs I've experimented with will terminally shut down if a short circuit or overcurrent condition is presented. I have to unplug, wait for ~15 seconds and plug back in in order to restart it. The need for a shunt can be kind of a PITA as well but in general, they're very robust. A simple PWM with a Hall effect or shunt control loop and generous filtering can upgrade the ATX with crude voltage and current control.

I have a huge TCR power supply that weighs almost as much as I do. 0-20V @ 0-130A all day, all night. This is overkill for simple or small scale electrolysis. For small stuff, I've never had a problem with the ATX + control circuit that I mentioned above.

If you use the ATX in the raw, you're obviously limited to 1.7, 3.3, 5, 7, 8.7 and 12 volts -- though you may need to trick it into allowing you to reference one of the power rails as 'ground'. Worst case scenario is 3.3, 5, and 12 volts. If the electrodes touch, the PSU will simply shut down and you'll need to power cycle.




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[*] posted on 16-11-2016 at 18:46


I just put together a small epectolysis unit, wall-wart > buck converter (3 adjustment knobs) > A/V digi display > terminal block... It sure functions, though controll is something else all together.

Though it is supposed to trim down the voltage, I cannot get this to happen. So either I wired something wrong or the current draw is too little to to kick it into gear. Basically V rising like no load to above stated on wallwart. 9v 200ma in > 11v 0.05a through cell. After some ions got into sol. (Thank you Cu) it has dropped considerably below the imput voltage. Now 3.36v 550ma. But again not seeing it adjustable.

I am at the mercy of electrode spacing, sol. conductivity and submerged surface area it would seem. No time to rip it apart and check though, if an aftermarket potentiometer got a cold solder or something.

IMAG8252.jpg - 1.1MB IMAG8250.jpg - 1.7MB

1479349586074.jpg - 1.1MB

Been making the Mrk II a cookie cutter kind of project. All available and cheap parts. Limited tools needed, easy soldering and all. Supposed to be an all around voltage changer/bat charger/electrochem toy. Like hook to an auto battery, drop to 5v limit current 1A and charge a USB device. I used the Mrk I to do electrochem poorly, power hobby projects and charge my son's power wheel car that was free w/o a charger. This is just more options and better made.

Bannana jack/screw down terminal's, power jack for commom wall-wart size that can be set to the terminal screws for center neg or pos kinds, volt meter on power out defines values nicely, 3 new pots for ease of controll.

Been using it to get soluble Cu for the doping of charred bread experiments. Havent been home for several weeks, work, so no accesable chems to play with. Little time to dick around recently also, as many here know the same story on their end

Maybe a significant load would ease the controlls( or I fudged). Wouldnt bee too bad to hook up a small motor for mixing plating sols. We shall see what comes of it.
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[*] posted on 16-11-2016 at 22:11


I bought a couple of cheap PWM controllers via eBay
http://www.ebay.co.uk/itm/12V-40V-10A-Pwm-Dc-Motor-Speed-Con...
Regulator - 555 - MOSFET - Diodes ... easy to diy but cheaper to buy
They are perfect for inductive motor or resistive heating loads,
as the output is switched between open circuit and full supply voltage.
(diodes and transistor effects ignored)
Due to the design, BOTH sides of the output have to be electrically isolated from the input power
... no common 0V or +V
For a (nearly) constant load voltage, series inductance is required
(the pwm works with dc motors due to their intrinsic inductance and inertia)
capacitance in parallel with the load helps - but series inductance is essential.

[Edited on 17-11-2016 by Sulaiman]




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[*] posted on 16-11-2016 at 23:43


have you found them usefull for electrolysis? seem to recall buying a cpuple my self and finding little use for them. adjustable VAC wall outlet was made and used for a hot plate, a soldering iron and a failed attempt to run a fan (shaded pole type from bathroom exhaust vent). few other things called for it.

think I am somewhere in the middle of trying to install a USB jack to my other power supply project. LM317 based, super simple circuit. there was some indecision as to which voltages to include from the multi tap transformer, how to power the 12v fan and I havent revisited it yet. left some copper on the pcb for duplexing a small pcb later,12v regulator. tend to run out of realestate inside them boxes real fast. learning as you go doesnt help with a solid vision, so I try to save improvements for later models unless its stupid not to include said tech.

I do have one of the nice(ish) bench top PSU's from ebay. but kinda hard to drag that thing everywhere in good condition. the little projects are fun, enriching and usefull.




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[*] posted on 17-11-2016 at 01:33


No, I have not tried PWM for electrolysis as I like linear PSUs

This thread is looking in the wrong direction,
1 determine maximum required rate of gas production e.g litres/minute, moles/hour etc.
2 decide on 'N', the number of gas production cells electrically in series e.g. 12V max. N = 6, 5, 4 ... you choose based on your cell design
3 calculate current required for desired gas rate production (x 1/N) .. now buy/make a suitable psu
4 assume 1 mA/mm2 (1 kA.m-2) current density and calculate minimum electrode areas

OR conversely, with a rough idea of electrical power requirements from the above;

1 find a suitable power supply, note its maximum voltage (Vm) in volts and current (Im) in amps
2 determine number of cells required in series electrically, N = (Vm) / (Vcel)l, use Vcell = c2v5
3 determine area of electrodes = (Im)/1000 m2
4 use Faraday constant 96485 A.s.mol-1 to determine maximum gas rate production per cell, then multiply by N for maximum total gas rate production.
Remembering that this is per mole of electrons, so for H2 and O2 divide by 2 and 4 respectively.

[Edited on 17-11-2016 by Sulaiman]




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[*] posted on 19-11-2016 at 09:59


@Sulaiman, I don't have in mind an HHO cell, chlorate cell or whatever other experiment involving electrolysis and wanting to archieve a big yield. I want just wanted a better power supply than what I currently use (an old mobile phone charger)

Finally the weekend is here, and I am home, where I could take the atx psu out of my computer, tested it a bit and it seems to work pretty nicelly :)
I now want to make some experiment with it but I dont know what... I may try making some bleach.
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