Great video but there's one very important thing missing at the beginning of the video. The capacitor from the microwave holds a massive amount of voltage and sometimes the resistor that is responsible for bleeding out the capacitor fails, creating a deadly trap for whoever touches it. ALWAYS SAFELY DISCHARGE ANY CAPACITORS YOU ARE WORKING WITH AND MAKE SURE THAT YOU ARE COMFORTABLE WORKING WITH HIGH VOLTAGE BEFORE YOU ATTEMPT TO BUILD THIS POWER SUPPLY. Every year people die because they put they hand where they are not supposed to.

You sir, are a master educator. I've worked in both K-12 and adult education/training for computer technicians. Your explanations,pacing, and use of visuals are awesome.

Hands down, one of the best damn explanations of the electronic parts of a microwave and their function i have seen

I will add AWESOME since it was not used yet. I spent a career in electronics and related tasks, but I have never seen a finer video. Even for myself it presents great explanations and illustrations for a good basic ohms law review. I look forward to the rest of your presentations. I agree with the other constructive comments especially those related to safety. I might add a caution to remove all jewelry when working with these voltages. Safety here can not be over stated. Thank you

Excellent video, brilliant explanation. The power transformer still has a shunt in between the coils as well. I have de-shunted the MOT and used them successfully for zapping wasps.

Everyone seems to be impressed by the depth of the video… I was flabbergasted when he used the stick to point components. I wish everyone did that!!!

My mind is blown, I have watched 10's of videos on microwaves, MOTs, and magnetron's, and this is the best and most comprehensive, you deserve more subscribers, and I'm sure you'll have them if your other content is as great as this.

First off, I really enjoyed the content on this video. I'll consider this as a reference for my own projects using a uWave oven transformer based supply. Considering the potential danger here, I did want to make some comments on safety. Having worked at Los Alamos National Labs in the Pulse Power world for many years, I was made to go to extensive high voltage safety courses yearly. It was not my intent to be a nit-picker but some things I saw in the video *triggered* me so I felt I should say something. A. The leather/cotton gloves are a *no no*. If they become damp, or the working environment is humid, those particular gloves can be more dangerous to rely on than not using gloves at all. B. Your power switch (IMO) is too close to the work. One should create a safety operating procedure for working with high voltage that does not involve exposing the operator to undue proximity to the high voltage work to energize or de-energize the system. C. We were taught to *always assume the system is energized* and in the case of high voltage systems with storage capacitors, we were to create an operating procedure for safing the system. One component of safing the system was a discharging procedure, and then a safing (shorting) procedure. Typically the discharging was done with a *shorting hook* or some kind of insulated probe, a grounding clip, and usually an integral discharge resistor. Finally the system would be *strapped* or shorted across the output leads for maintenance, configuration, or storage. E. I recommend an insulated guard around HV connections to mitigate accidental contact of the operator against the terminals or creating an unintentional HV circuit with extraneous conductors that might come in contact with the terminals during operation. I thought the safety glasses recommendation was a very good one. Having had high power components explode and hit me in the face, I can attest to their value in this kind of work And finally, for your own safety, I recommend you lead your presentation with a disclaimer. :D

I use 2 of them and a full wave bridge circuit. Just feed the primary in opposite phase. Now you can ground the transformers case to safety ground and use the 2 hot leads with a single diode each for full wave rectification. I have bought identical cheap 1.2kw microwave ovens for exact this purpose. The combined cost is still cheaper than a new dedicated HV transformer. I remove the two heater winding and rewind them. One feeds the tube heater, the other produces 12V for the electronic and relays. I run a 1300w RF amp with that circuit and it works well. It can do 1500w when the amp is switched to class C for digital. Many microwave oven transformers are current limited by the use of magnetic shunts. One can remove those to draw full current from the transformer

This is exactly the Microwave Transformer video that I have been looking for. Clear explanation of the process and most importantly clear explanation of how these transformers behave.

So much here to appreciate. A very well organized sequence with supporting calculations, consistent tempo and a great lecture voice. Just outstanding. In this design, I can’t help wonder about output lead insulation proximity to the enclosure face holes, and potential for plasma arcing through the chassis. I see great care with the panel face wing nut lugs, but the two cables seem very close. I’d love to understand how he arrived at the cable insulation.

This feels like a proof of one of those crazy questions from a physics textbook. Thank you for a imaginative learning experience.

Thank you for this magnificently produced presentation. I never leave comments but this one deserved it.

Anyone who needs this much of an explanation of Ohm's law and voltage dividers has no business working with such high voltages.

What a confident, clear explanation of how the microwave oven works and how it is to be used as a 6 kV power supply. Magnificent listening to you.

aaaand, the good youtuber I found who's explaining stuff using the right ways that work with my brain, he actually stopped making videos years ago, this is happening too often, very sad.

What a beautiful , simple ,no nonsense explaination,……..! Speech so calm . Precise ! He seems to be a teacher with a degree in science , electronics ? If so , his students are very lucky….! Hardware design,…..impeccable , Like a Swiss Watch,……

I really enjoy your way of presenting all the components. I wish more people would be as educational as yourself. thank you and kudos for a great learning experience 👏

Would love to see more videos from you. Just stumbled across your content.

I am totally in awe with the cadence and speed of your lecture. Most of the electrical stuff is beyond me but I am now studying how you speak in the video. I hope to emulate you (in a different subject). Thank you.

HI Jim, I have never seen a video like this in my entire life and 20 years of experience in Electrical Engineering. You method of explaning with crystal clear details and calculations is beyond explanation. This is a must for electrical engineering student. I liked your video and shared it with my students. Thank you so much for tons of educational material in this very simple power supply design but it has a lot in it. Regards.

Great video. I've used the same full wave doubler you use. Works well with zvs drivers powering AC flybacks too. You can double and even triple the voltage of your ferrite core transformers.

If you want to get a little more current out of it, remove the magnetic shunts from the transformer. There should be two little metal wedges stuck between the primary and secondary windings.

Oops! I just noticed that your schematic indicates that your metal enclosure is not grounded! That's an industry standard *No - No!* Metal cases MUST be grounded when connecting to mains. As it stands now lethal voltages are present between the Zero and 6000 volt terminals and the Zero Terminal and the Transformer Core and any metal making contact with the Core. If I'm wrong, please correct me.

One of the best electronics youtube videos I have seen. In fact I will just rate it the best! You would make an excellent teacher for electronics, as the best teachers are the ones who can simplify a complex subject like you have with this one. An important video to teach right also, as safety is a massive concern here. Looking at the below comments, I'm not the only one who appreciates the clarity of this video. A big thank you for your efforts, so much appreciated! :)

Fantastic video, I would recommend to call the transformator metal for zero, and the two outputs for +3000 and -3000, just as your sehematic say at 23:22 Another problem is ripple at full load is very dominant, and at no load the 2100V rated capacitors are charged to 3kV, also an important note : some capacitors contain the diode, and also some times a 2100V "zener" in older owens the zener is a an extra diode acros the diode, and the normal diode is the one to chassis.

this is so reminiscent of those old school educational films. pure delight!

You have taken a lot of time patiently explaining things. A variac and a voltmeter at the primary wood be added advantage. Thank you

An excellent video, with very precise articulation of the engineering analysis. Am curious about what you will use this for - possibly as the plate transformer for an HF linear amplifier?

Kudos my friend, that is probably the best explanation of a proper calculation test of any power supply I've ever seen and heard. I can't wait to see some of your other videos and I will be building one of these power supplies with of course a active cooling fan. Thanks again

Really good quality, and almost perfectly edited

*WARNING!* Those attempting reproduction of Jim's design take note! The Output Terminal labeled *"ZERO"* is *DEADLY!* Properly labeled, it should read *Output Common* or at the very least ... *"Common"!* Simultaneously touching the *"Zero Terminal"* and Earth Ground, water pipes or any electrical chassis at ground potential could *KILL YOU!* Personally, I'd be labeling the "Zero Terminal "* with industry recognized danger symbols and graphics! Hell, at these voltages I'd be *EXTRA VERBOSE* with my labeling! Aside from that unfortunate oversight, Jim's video is excellent! Voltage Doubler circuit theory was clear, concise and accurate. The *Salvage and Re-purpose* segments were also excellent and easy listening! I subscribed within the first few minutes of it!!! Wakodahatchee Chris

Superb! KZbin needs more content creators like yourself! Interesting, practical, and educational. Just wonderful, thank you.

I think you need to explain that anyone building this or messing with a microwave does so at their own risk !! You did say these voltages can be fatal, Im adding also cause terrible burns. I'm somewhat puzzled why anyone needs such a high voltage power supply. The only purpose I can think of is an RF linear amplifier. I shudder to think of an inexperienced person attempting to build this power supply or even attempting to probe these voltages. These voltages can jump gaps, and if you dont understand, please stay clear of this project. It will kill you !! I hope nobody is injured or killed after trying to duplicate this project. It is very dangerous !!

Very much appreciate the detailed explanation and accompanying illustrations. This will help since my Tesla inspired “coil for electromagnets” to convert concentrated solar power driving a Tesla turbine. Thanks for the help and tips for not getting pulverized.

Excellent quality! Very well explained as well. Keep up the good work.

Great video. I like the narration and the high detail. Also for explaining not just how to make the supply but where each component came from and what it's original purpose was.

12:37 for those who are curious about the number 0.707 which is the result of calculating Vpeak -> Vrms Vpeak*sqrt(1/2)=Vrms => Vpeak*1/sqrt(2)=Vrms both, sqrt(1/2) and 1/sqrt(2) ≈ 0.707 (well, 0.70710678… to be precise-ish) (sqrt(2)≈1.414 -> 1/1.414≈0.707) In the end, Vpeak/sqrt(2)=Vrms

What an exceptionally clear and well-presented video and nicely-done project! I’m sad you’re not making videos any more, but I can on,y imagine the amount of effort that went into this. I’ve permanently filed this, as I’ve wanted a high voltage power supply for some time now :-)

Best KZbin video I have seen. I love that you know your material and you don't waist time. If I could give you an award for best video I would. I have kept the parts of an old microwave around for many years thinking I may have a use for them. Watching your video I was wandering what I would use a 6k dc power supply for?

Thanks for the brilliant technical description. As below wonder what I would do with this power supply? Thanks for the video, looking forward to more of the same.

Yikes! I'd be nervous working with a HV PS that has a metal chassis and metal wing nuts, even if I built it. I would want an internal metal chassis but an external plastic or wood case. Large banana jacks for the the connections and a plastic switch for on/off. Still you have to be mighty careful working with the output!

really cool from you to take the time to explain the details, as a beginner I really appreciate

Brilliant presentation. So clear and concise! I have built a couple of these with "full wave" full wave to get about 2kV. Be aware that some transformers have one of the HT leads internally connected to ground which makes the useless for this purpose.

Oh my my. I have never seen a better explained video on the subject.

Hi there and thanks for the upload, very informative but (as others have already said) as a professional EE, I must raise major safety concerns for any inexperienced or careless person who might try to copy your work. With the suggested wing-nut connectors and gardening gloves, and no power warning light, this is probably the most dangerous project I have seen recently. Please don't build anything like this if you have ANY doubts, and do watch my video about safety aspects of using microwave oven transformers. At least one person has been killed by a MOT. On the technical side, the transformer waveform is badly distorted because the core is heavily into saturation due to the cost-cutting with short windings and a narrow magnetic path. This saturation causes the transformer to pull more current and heat up even on no load. If you are stripping two microwaves, you can solve this by running two transformers, with the primaries in series and the secondaries in series, with the transformer cores joined to form a centre-tap which could be grounded through a high-voltage resistor for a slight safety improvement.

Just found your channel, and yes master educator. I love electronics since i was 5years old. but i felt that math was for people that needed it. found out the hard way later in life going back to school. Thank you for your time explaining the importance of mathematics in electronics

As stated, he did a great job of going through all of the math, and explaining everything, how ever you seriously scrued up on the output, as you mentioned it is a doubler, and if you were using a supply transformer with a floating secondary, you could call the output "0 & 6,000 volts, but that is not what you have. Because the transformer secondary is one end grounded, the output is actually two 3100 volt half wave supplies in series, which is a plus and minus 3100 volts to chassis, so by labeling the one side 0 volts and the other 6,000 you have given a false representation of what is actually present, and if someone builds this Supply and connects the 0 volt side of the power supply to the chassis of there project, it will cause the power supply chassis to be + 3100 volts above the chassis of there project. And I can tell from your explanation of the build that you are smart enough to know how dangerous this could be. I'm sure it was just an oversight, but a dangerous one at this voltage level, as you mentioned, it's well inside the lethal range, so please correct this on your video before there is a tragic accident!!!

Excuse me Jim but, the Yesa ET-1043 meter being used starting at 28:40 is a VOM type and as such, it does not contain an amplifier that effectively increases the meter's input impedance. Using this type of meter rather than one containing a DC amplifier stage will introduce a significant error in readings obtained from the Voltage Divider HV Probe that you've described. The meter itself will be an additional resistance in parallel with the four 100K resistors. The input impedance of this type of meter can be as low as 20K ohms thus introducing a huge error in the voltage divider readings. Of course, all of the current calculations you've done to describe the operation of the HV Divider are not including a 20K ohm resistance that is in parallel with the four 100K ohm resistors. I have searched for the input impedance of the Yesa ET1043 meter and found that it has not been published. You can however easily determine the impedance by 1st measuring any DC voltage with the VOM then, put a 2M ohm potentiometer in series with the meter. Increase the series resistance of the pot until the meter reads exactly 1/2 the 1st reading. Finally, measure the resistance of the pot that was in series with the VOM to reduce the reading to 1/2 the initial reading. This will be the input impedance of the Yesa ET-1043 so you can add it to the actual HV Divider circuit. I just now did this using a Dawson DDM421 Digital Multimeter (an amplified type) and found that its' input impedance is 1.007 M Ohms.

Thank you for talking through all the steps in your video so clearly and completely. For safety reasons I would never attempt to build this project as I am totally blind: however I found your video informative and educational and really enjoyed the content and it refreshed a lot of my knowledge on power theory.

Brilliant. I happened to have all the components around to follow along and build. I did have some beefy resistors and a 40k probe, so I was able to test my own numbers. 6,303Vdc with no load. I learnt so much from this. Thank you.

Outstanding analysis! And excellent explanations! Thank you!

28:10 "of course, there's a risk of shock" - a wee bit of an understatement. 10 mA going through a flexor muscle will prevent its relaxation - grab that wire and somehow complete the circuit and you won't be able to drop it. An indicator light to know it's powered and some bleeding resistors across those capacitors would be good to have.

To build a 750W 25kOhm power resistor, you'd need about 38 light bulbs rated 20W@110V, or 18 bulbs rated 40W@230V, all connected in series of course.

Brilliant video and graphics for any budding young electrical engineer. Wish my early days electrical engineering lecturer had had the same skills as you have...some 60 years ago.

I have disassembled two transformers from microwave oven to use them for welding projects and found, that the transformers get very hot with just primary winding without any loads. Then I have calculated the number of turns for primary winding and counted the real numbers of turns on the primary. The real number of turns was less at least to 25% vs calculations. So, the transformers from microwave ovens will not work long time, max 20-30 min. For welding project it's ok, but NOT for longer time!

I was confused for a while since I've always used a straight line and an arc line to represent a capacitor and 2 straight lines in parallel to present a contact points after you explained it I caught on, great job at instructing

Very thorough explanation of the build.

Wow so many great comments here and yes this is brilliantly presented, thank you and looking forward to more great content.

I like your presentation. Precise and concise. I enjoyed it.

I love the amount of information and extensive education in basic electricity. Great video, thank you for the upload. Although, this video is extraordinary in it's information and instructions I fear it is lost on 95% of those watching it as they don't want the how and why's of the project, they want the black and white, "put this there and that's there" mindless instructions. Society today has been groomed for zombification and care nothing for the education over instant gratification. Sadly.

One of the best explanations I have ever had the pleasure of following....

ya, this is really really well done! Thankyou, im a beginner trying to learn and this was marvelous!! im in need of more powerful adjectives....

All very good, but what are you doing to be doing with this high voltage ⚡️

Do we get a free coffin⚰️ when we've built this ???

Excellent description of the circuits. Great job. I work with high power high voltage daily in my job. I like this project very much and don't want to see anyone injured and that pain placed on you. As well as possible legal liability. So, please let me share a few critical observations. 1. This IS NOT a project for beginners. Period. 2. The meter you are using at the 30:00 minute mark is either 20K/volt or, worse yet, 1K/volt. That will present a 20K ohm load in parallel with your sense resistor giving an inaccurate reading. Take this resistance into consideration as well. I calculate this to be 952.3 ohms for the total sense resistance. 3. The output terminals on this supply are outright criminal. The relief openings behind the bolts are FAR TOO SMALL for safety. Please find some proper recessed high voltage terminals and matching plugs. It is far too easy to contact these terminals and DIE INSTANTLY. 4. Go to the automotive parts store and purchase spark plug wire, 20KV break down at a minimum, for your leads. I use 40KV rated wire on my 6KV supply here in my home lab. 5. You should bring out the ground and then relabel the out put terminals "+3000V" and "-3000V", labeling the ground "0V". This gives the option of a grounded 3KV supply ("safer") or a floating 6KV supply by ignoring the ground (0V) terminal. 7. If you place a variac transformer on the primary side of the HV transformer, you now have a zero to full voltage high voltage power supply. My commercial HV supply (Leybold) does exactly this. LAST COMMENT. You can see how I use my commercial high voltage power supply in my video entitled, "PhiloCam Part 16 - Power supply problem proven beyond a doubt".

Very detailed and crystal-clear explanation. Well Done. Love it.

Excellent description ! BUT if one is NOT aware : BE CAREFFUL 6,000 volt produced by ths circuit is electric chair death voltage !

Thank you. I think you explained this quite well and still accurate while leaving out a few more technical physics matters. It is interesting how often these units are often thrown away while there are components that still have many years of life left. Thank you for your video. I am going to build this and maybe add a voltage doubler to have a nice gas laser power supply.

Great instructional video you have here. I like it. Your description of the oscilloscope is very good. Could you do an O-Scope video on operating a Scope from a newbies point of view, please? I would like to see what yo come up with!

You have a great narrative voice.

THANKS FOR THE GREAT VIDEO!!! As an upgrade, you could put another capacitor in parallel with EACH of the existing two for more smoothing (two more caps). A volt meter using a voltage divider for calibration would be nice (maybe one for current also...this one would be easy to use as-is). A VARIAC at the AC input would make a great 'variable' DC supply. WARNING: Be aware that the variac can step the input above 120VAC! The only thing that bothers me is the voltage rating of the caps...close...espically if variac driven at the higher voltage region.

What an excellent presentation. Very professional, and very informative.

Excellent video and great graphics. I'm impressed. Thanks for making it.

This video is insanely well made, good job!

Use the filament wire for an on-off light.

I hope, that in an open forum such as this, any builders realize that this can put ones lights out permanently and treat this with the respect that it deserves. I remember almost getting the belt from my father when I made a Jacob's Ladder from a Neon sign transformer when I was 12. I probably did need a spanking.

i just watched this whole video and i dont really know anything about electrical engineering but this is cool

What an analysis. A whole course to someone like me, done in style.

I’m curious - did you have a particular purpose for this power supply, or just general use? Excellent presentation, btw!

Very good presentation, images and communication made the video outstanding.

Oh yeah, FEMALE output connectors would eliminate a SERIOUS shock / short accident...which will happen sooner or later in this front panel design! THANKS AGAIN FOR THE GREAT VIDEO!!

i wish you were instructor in my navy electronics school. well explained!

Great video, however I am not sure I understood the necessity to build such power supply. What would be a purpose for it?

You will find but the fan runs on it's own supply instead of the transformer on the front panel and the synchronous motor that runs the turntable also have its own supply

Very informative. You should be a teacher. You are great at conveying your knowledge...

Good Sir - I used your tutorial - it is one of the best on KZbin. Thanks! It worked perfectly. Now I have two questions, but first some background. - I wanted to throttle down the output voltage so I put a variac on the AC input. This worked very well when all I had on it was a volt meter. My project also calls for pulsing the high voltage. I am currently doing that with two solid state relays. One to connect the positive output to the load and the other to connect the negative output to the load. They pulse at exactly the same rate and are driven by the same driver - both on and both off at the same time. they are being pulsed on for about 50 millisec out of 110ms cycle time. I have to isolate the ground for my project. When I turned on the variac with only a minimal load with the outputs of the power supply hooked to the load through the pulsing relays, the variac started buzzing and then a wisp of smoke! I shut it down immediately. The variac has a 20 amp fuse but it did not blow. After my hands stopped shaking I removed the pulse, hooked it up to a voltmeter, and it worked just like before. Now for my questions - 1 Why would this happen? 2. Would it likely work if I pulsed the input to the variac instead of the DC output from the power supply? Thanks! Mark Cooper

Great tutorial. I've got an old microwave that I've been hesitant to tackle but now I'm confident as to how to approach it. One thing, shouldn't the case of the toggle switch be earthed? EDIT: I see it was once it was in the enclosure.

Absolutely lethal...how you can say this falls within safety limits and to have open terminals on wing nuts right next to the power switch

Ditto on the last comment. Definitely a top tier presentation. Thank you very much. ⭐️⭐️⭐️⭐️

How is it I have I not found you, until now? You have left no questions unanswered! Nice work! New subscriber!👍🇺🇸

i’m not qualified to say this is a perfect video. but it’s refreshing to not hear distracting “music” or other ambient sounds, useless stuttering n suffixes n prefixes like um, ah, nnn boring us. clear pictures is really pleasing. u sound like my brother, an EEE. or r u an audiobook reader with that pleasant voice n good delivery? being a jack-of-all-trades, this wuzn’t totally satisfying 4 me. i’d preferd the last 15 minutes b used 2 show me the potential of this creation. :o)))

Good, educational video, but people, pleaae learn the AC/DC rectification fundamentals on low voltage. I advise against building this particular arrangement. The primary winding on the transformer is NOT designed to work on floating 3kV level. It works only because a well built transformer uses huge safety margins (and required to be HiPot tested). Look at how much insulation is on the secondary side and almost none on the primary! Several aspects of the mechanical build is also a major safety issue. You do NOT use wing nuts and bare metal connectors on 230V even, let alone at 6kV. The output terminals should be insulated and a connector rated for at least 6kV continuous use should be used. There should be a visual indication that the output voltage is present on the terminals. Ideally it should continuosly indicate as long as the voltage is still above 50V (!), even when the primary is switched off already. There should be some sort of interlock which is, when not enabled, does not allow switching on the output. HV capacitors and test circuit outputs are usually required to be SHORTED to each other and to earth when not enabled, otherwise it is UNSAFE to touch. On typical proper lab testing systems one level of interlock on the safety enclosure is responsible for shorting the outputs and a second level to enable the HV power. This seems ridiculosly complicated and inconvenient but the energy and voltage at these levels can kill you instantly. Like PhotonicInduction said: You will be dead before you hit the floor.

Nice, VERY thoroughly explained! I would only suggest adding small case fan like used in a computer. To really test this PSU at full load, one might put 42 *incandescent filament bulbs* in series, each rated 20 watts. This derives from 120 V @ 0.167 A equalling 20.04 W, and 5100 V divided by 120 V equalling 42.5 bulbs. With 42 bulbs, each bulbs will receive 121.4 V, well within their allowable voltage range. For people in countries with other voltages, similar math will show that, for example, 40 watt bulbs of 230 V rating will do nicely with 22 bulbs in series.

Great sir highly apprciated and greatceffort and well scoped video and very very well elaborated for every single person hope to see your farther videos

Every so often while watching this "but trust me on the sunscreen" went through my head.

That would make a cool charging station for uncle fester .(Adam's family)

I fear these instructions will enable incompetent people to build something that is very damn dangerous! This thing can and will KILL YOU! I don't know the extent of liability for which you would be held accountable, but this is not something an untrained individual should be fooling with.,.. I sure hope no one gets killed.

I wanted to make a custom multi voltage bench dc power supply, not quite that high voltage but a decent range, so I went with a 48v power supply to feed a programmable buck regulator then another boost type circuit to increase the 48v and run that through a higher voltage buck for another range of output. The microwave transformer is probably too much voltage for what I had in mind but seems like something that could be pretty useful to easily get voltages well above the easily accessible 120v/240v for experiments... How hard would it be to create some kind of way to vary the output voltage? Perhaps it could be done on the input side of the transformer since that’s much more commonly available - a “dimmer switch” type of thing? I always wanted to see how nice strings of LED Christmas lights would look powered by DC... I made a DC string for my sister who’s affected by the flicker one time, but it was just 12vdc so required a somewhat cumbersome series-parallel wiring... I always thought it would be cool to build an adapter that would supply just the right voltage of dc to make any simple string light up solid, probably not even that hard to design, but a variable hv dc supply would be a decent way to figure out the design parameters since if it was as easy as full wave rectification and a capacitor there would likely already be products on the market, or not...

Great content. I can't help but wonder if it would be safer to put the terminals on a different side than where your hand will be turning the switch off and on?