Electrician Reacts to Photonicinduction INSANITY 🤯

I've been following photonicinduction for over 10 years. I love to see his madness get some recognition lol great vid m8

He surrounded the cables to increase the insulation further. The PVC tape to prevent water entering from the greens. He knows, what he is doing. He is insane, but genius.

Absolute OG, the GOAT, lord of the madlads, whatever language you happen to use, Photon is the KING of RUclips. Always will be. The giant rock in the unkillable washing machine is internet history. Andy deserves much better than life dealt him.

I love how the parallel cables try to spread appart just from the huge magnetic fields

“You can’t caught COVID via RUclips. Unless you have 5G of course” 😂😂😂 You have a great sense of humor my friend!

What a legend? OH yeah man he's a total legend. He did so much of this stuff like a decade ago, and he just suddenly came back recently. He's the kind of person that you can only wonder what he does for his day job to play with this stuff at home.

The man, the myth, the legend... Photonic Induction!

The ripples on insulators is to ensure that tracking currents on a dirty insulator are going a longer distance and maybe burn off locally instead of producing a full arc.

Even through the 185mm cable is only rated for around 400amps, he is counting on the duration of the surge of current being so short that it won’t have enough time to melt and vaporize the conductors. The energy transfer here is also extremely crazy if we use the capacitor energy storage formula: E= 1/2 * C * V^2 where c is the capacitance in farads, v is the the voltage, and e is the energy the capacitor stores in Jules. And by using this formula we can determine that the capacitor bank is releasing 45,000 Jules of energy in under a second which is totally insane! Anyway excellent way of explaining what’s going on for the folks who are not sparkies or electrical engineers

> Don't try this at home.
I want to know the kind of person who has a 200kA power source at home, but is also not qualified to blow up a capacitor with it.

Photonicinduction is an absolute legend. He is the man that inspired me to start my career in electrical engineering

Ya know I wish he’d come back to his channel. I don’t believe there is anyone else showing the amount of power he does. The man is a mad scientist and a national treasure of the U.K. His name is Andy Moir I believe

PI Is awesome. I used to love his videos a decade or so ago and he dropped off for some years due to some personal issues.
... Then, he returned, crazier than ever. This looks like one of his later videos.
He really is something special. I always cheer when he says, "until it pops".
You mention low production values - I don't think he likes to spend a lot of money on cameras because he keeps on destroying them.
I love the raw feel to his videos.

Dude is a national treasure for real, ive been watching his videos for decades 😂

Been watching this guy for a decade; you're absolutely correct, he is a legend.

Photonicinduction (Andy) is one cool dude and I can't recommend his channel enough, Andy over time has uploaded hundreds of insane "will it pop" videos. 👍🏻‍

I love his channel. His flourescent lighting video and mercury arc rectifier videos are brilliant and quite educational too!

The trick with the power cables is that those ratings are assuming continuous power draw over an extended period. For this application, the current is only going to exist for a brief fraction of a second, and so the total heating of the cable will be much lower, and thus you can pump a whole lot more current through it, as long as it's only for a very short time.
They still might not last forever, though, if you reuse them enough times...

5:20 "I like this guy already what a legend!"
Been watching him for years, you're not wrong... he's an absolute legend!

I'd have to say photon is amazing. He's done a lot of awesome stuff. Many demonstrations and experiments. He's a very intelligent man who does all the things you should never try at home so you can see it without having to try it yourself. Don't get me when, I'm familiar with installing light switches, outlets, switched outlets ceiling fans and the like. I know what I'm doing when it comes to stuff like that. I would never mess with anything over 240 volts and definitely not capacitors charged with thousands of volts. Microwave transformers can put out 5000 volts and the charged capacitor inside is something I wouldn't play with. I know my limits and won't do something dangerous. He's an electrical engineer and knows a lot more about not making mistakes than a do it yourselfer working with basic conduit. I like in the USA so we run on split phase. We do have 240 volts between phase 1 and 2 hots, but most of the plug receptacles and light fixtures run on a single phase to neutral. Only the big appliances like the dryer, electric stove, water heater, and the central heat pump for the whole house HVAC run on the full 240 volts. Everything else run on 120. Anyway we should all appreciate photon for doing the things we should never try unless suicide is the goal.

The reason I heard for the ripples in the high-voltage insulators is also due to rain conducting across. The gaps allow the rain to break when dripping down and reduces arc over.

Would love to see an electrician reacts to Bigclive’s cooking videos...... cooking with electricity of course. Also love photon 😍

I love that RUclips has recommended this for me! long time Photonicinduction subscriber. Andy is mental!
Would love to see more of his insanity broken down

The look on your face when he mentioned a pneumatic switch was absolutely PRICELESS. I immediately intuited the reason for this, as you did also, our reactions were the same, I couldn't resist the mischievous grin either!

The ribs on the insulators are for making it harder for tracking to happen. A spark will just jump across and take the shortest path - tracking will have to follow the surface.

Andy's an absolute beast. I've been watching his stuff for at least the alst decade - Never a dull moment (especially when he's shoving 20,000 watts through a giant metal halide lamp, or even just a measly 3kW through a 400w one! :) )

David: I don't think electroboom has done something this dangerous.
Photonicinduction: 5000a fuse let's start at 200000a

Wow, that was exciting! I'd love to see you react more to this channel. It's really cool to hear your knowledge on this stuff as you react! I hope you feel better soon, covid sucks! Praying for a quick recovery

The sheds on high voltage insulators are to increase the surface area between the conductor and what ever it is being insulated from. This is because when the insulators get wet you get high voltages creeping along the surface of the insulator and so you want a longer distance on the surface of the insulator as the insulating properties are reduced by atmospheric conditions.

Love photonic!
Glad to see I’m not the only one that flinches when he flips the switch! 😅

We tested lots of circuit breakers over 3 years I worked with Brar Electrical Systems and once we tested a 5000A circuit breaker. Our test sets have digital timers with huge Frankenstein nobs, transformer and contactor. 2000mcm cables, C clamps to buss bars would jump when testing. We used to suspend a screw driver in the air in the magnetic field. The "long time" test is at three times the rating, "short time" test is at 5 times the breaker rating and the instantaneous test is at 10 times the breaker rating. Extremely fun stuff.

Have watched photonicinduction for many years, Glad he made a recent return. CHEERS

his transformer video is mental when he drawn so much amperage from the mains supply the whole street lights flickered ( when he tried to overdraw a electric meter )

Oh yea, photonic is nuts! He does high current and high voltage experiments. Great fun to watch

One of the most amazing things about this feat is that even at 3000V he needed to keep the circuit resistance below 15 milliohms to deliver the 200,000 amps 🤯

7:15 The ribs on the insolators are there so water wouldn't form a continous film around the insulator, shorting it out. Thats als why most of the time the outline of the ribs go down-out and back in-up (umbrella shapes) so water would drip off at the lowest point and not wet the bottom surface so the bottom side of each rib would stay dry even trough rain.

Electroboom only PRETENDS to be crazy. He's got a wife and kids. Photonicinduction is actually crazy.

Regarding the HV line insulators, the shape of them isn't to prevent jumping, the gap does that, it's for another thing called "creepage".
There's two concepts at play there, there's what's called creepage and clearance.
There's two ways that current can "jump" a gap, a jump strictly speaking is via an arc through the air, which is where the clearance is the primary insulating factor, but it can also creep along a non conductive surface, this isn't so much a "jump", as it is along a surface, by having those "ribs" you increase the distance along that surface to the point where it is too far for it to creep across it.
You can achieve sufficient clearance, but still have problems with creepage if you don't design it properly, and creepage can be massively effected by for example water, so by shaping those insulators like that, they act like their own little stack of umbrellas, the underside being kept dry, and keeping enough dry surface to prevent creepage even if it has been raining.
So it's a clever design that both increases the surface distance between the conductor and the pylon, and provides protection from water wetting the undersides of each section.
The distances invoved in creepage and clearance are very dependent on the voltage and the physical conditions, eg moisture content of the air, surface dryness, surface finish, surface contamination, which water on it would be.
Also if there is a conformal coating that has an effect too, as the current could instead go through that rather than run along the now covered surface, adding a conformal coating could actually in some cases make things worse than leaving it exposed.
The design of things with creepage and clearance in mind can get very very involved, and that's just what I've picked up from looking into it for work and working with people who deal with this day in day out.
I wish I could post a pic on here, but if you search for "creepage and clearance" there's a great picture of such an insulator where someone has drawn on it the creepage and clearance paths (even though they've spelt creepage wrong) and it shows that the design of these drastically increases the creepage distance.
I will post the link as a reply to this, but I think that thinkLIST will have to approve it for it to be visible.

Still sad he's disappeared again, but happy to watch you enjoy his old videos. Glad I stumbled upon his channel when he just started, because he deleted quite a few.

You did exactly what I did for the steel wool bit and instinctively leaned back away from the screen! 🤣

This video is so dangerous he has to wear a hardhat just to watch it

You should see his video on a breaker from a WWII submarine... it's a thing of beauty and even after contacting the maker, they didn't have any specs for it...
And yes people, do not do this unless your completely aware of what your doing. Photon looks like a mad scientist type but he's supremely aware of what he's doing and how to do it safely... apart from burns in carpets and that's his back yard....

7:16 Just spent about half an hour researching this and it looks like your description is spot on. Fine details are as follows:
Insulators such as those pictured can break down typically in one of two ways: a puncture arc and a flashover arc. Puncture arcs quite literally burn through the material, leaving the insulator damaged. Flashover arcs, on the other hand, are when the electricity takes a path AROUND the insulator (as demonstrated), leaving the insulator more or less unharmed. Insulators as such are designed so that flashover arcs occur at lower voltages than puncture arcs.
Additionally, being out in the elements pretty much at all times, they have to be able to handle contaminants on the surface, such as dust, soot, or even water. As such, they're designed so that it maximizes the distance the electricity has to flow across the surface *through* those contaminants. Additionally, a lot of them have an upside down saucer shape to prevent said contaminants from building up on the underside, further making a complete circuit around the insulator less likely.
Obviously I'm not a professional, but it's still a pretty neat topic. Never thought such a simple thing would have so much effort put into it, eh?

On photonicinduction's pneumatic switch, I like the phrase "crazy but not stupid." The same could fit ElectroBOOM (considering he often electrocutes himself for comedic value and to prove a point) and Styropyro as well.

"Pulling power directly from the NATIONAL GIRD" if you know you know.

another interesting channel to watch. should definitely add that to your react list.

Photon makes electroboom seem like timid child's play. The video is no longer up but he once caused his entire street to brown out temporarily......
His name is Andy BTW if you're not aware yet.

His electric company is probably like there he goes again.

I remember finding similarly rated monster fuses, 3000A at 600WV. They came out of a huge induction casting machine. Got them and some 2000A 2800V hocky puck SCRs and a few large capacitors rated for high current RF duty all for free for help salvaging the copper from it. 🤓❤😁

PhotonicInduction is a pure legend when it comes to destroying electronics. I love watching his videos. If I recall correctly, though I may be wrong, in one of his videos he was showing off a hydrogen reactor he has to power his equipment and capacitor bank.

Part of the reason for insulator design is yes to provide more surface area the current needs to defeat to complete the circuit, but it's also to push that potential arc outwards so that it is forced outside of any magnetic field created between the two attached cables which would make it easier for arcing current to flow through (sort of like it's own invisible cable made up of a magnetic field "tube") as WELL as designed that way with the flare at the bottom (along with various geometry added around the lowest lip) to try and prevent water from rainfall from dripping down in a single stream from one cable end to the other that could cause a short to flow through it. The rain is essentially pushed outwards and made to drip rather than flow, so that there's no way it flows down close to the bottom connection point. I watched a video here on YT that went through the history of insulator disc designs and how they changed over time - their overall shape, the length of the entire set of insulators, how many are used etc. It was rather a fascinating look into something almost none of us ever think about that does such an important job!

Also this is such a good explanation of current / time graphs, love the Aussie touch too of course!

It takes a certain crazy mentality to fully enjoy his videos, great to see your reaction.

I love this video from him. The absolut madness of information at 4:24 is mind-boggling. I set this as a ringtone on my phone in the past 🤣🤣

Fair to say ElectroBOOM is "lets play with high voltage!"
Photonicinduction is "lets crank up the amps!"

Re insulator shapes: 1, as you said, to increase the creep distance. Once you have a flashover that is no longer relevant.
2. they are umbrella shaped for a reason. that way part of the insulators surface remains dry in the rain, it also accumulates less dirt that would allow for moisture to collect and allow for creep currents.

I believe Rodalco2007 in New Zealand also plays with high Voltage devices. He obviously works for a power company and has access to very high voltage equipment as well but not to the extreme as Andy's channel.

I saw the thumbnail and got really excited i thought he had uploaded again

Just a comment on the insulators, the reason they are shaped that way is for 2 reasons, the first is to drastically increase the creepage distance to reduce the how likely there will be surface tracking, the other reason is when they are out in the open, it would be incredibly hard to get all of the surface wet because of their shape, so you will get tracking on the wet surfaces but not as much on the dry. If you have been near a tower that is 220kV or higher after rain, you can hear them buzzing, that is tracking across the insulator surface which happens when pollutants contaminate the surface and get wet.

I worked for a company that that had work place feed with a 4Mwatt transformer. 72kvolts primary fused at 60 amps, 600 volts secondary. With 6000 amp fusing 200 feet away from transform. Feed from the transformer was stacked bus bars unfused.
1) first event we had 6000 amp main breaker blow because of MCC cells fusing uncorwardaided fusing. IE one cell was 1600 amps. We had x6cells =9600 amps. Normal current draw was about 4000 amps, but when we got a short circuit on one of cell feeder cables, it tripped main 6000 amp breaker. Contacts were all arced out.
2) then a while later we had the bus bar short out. They assumed a hot junction, as these bus bars were clamped to join, not a bolted connection. A joint every 8 feet. Not a good design. A person was walking about 50 feet away, almost shit his pants. The primary fuse blew. And the clamping bolts were torque to yield, so no way to come back later to retorque the clamp bolts. Maybe joint expanded from #1 trip. But we lost 3 weeks of power from that transformer waiting for bus bars. I would go with multiple single conductors. At least you only have 2 end bolts to torque. Instead of 60 plus clamp bolts.
3) even 12 Volts DC, with enough amperage can kill you. I was trying to jump start a wheel grapple loader. There were 2 D31 batteries on machine, but not enough voltage to spin engine, then i hooked another d31, and finally a 200 amp battery charger. Well over 1000 amps, enough to weld the start contacts together. I knew batteries were getting hot so i reached down to remove one of the jumper cables, when the batteries blew up due to hydrogen build up. I had an arc in a box, with nice battery acid coming at me. Good thing i wore my PPE. I am here today.

This is the first video of yours ive watched and its about one of my old all time favourite youtuber.

The look-up table you have for cable current is already quite heavily derated - and extremely conservative. If you look at other tables such as "SAE AS50881 - Wiring Aerospace Vehicle
specification" you will find that a 4/0 AWG (120mm2) cable is rated for approximately 1000 Amps continuous load (un-bundled with a PTFE/ETFE sheath & aramid jacket @ 1ATM). For a microsecond pulse like this, the cables can easily handle orders of magnitude more current that that.

Late to the party. My career was with the big American telephone system. Among other things, I maintained the power room for the electro-mechanical switches in New York City and as an international gateway.
It ran on batteries that were always floated to keep them charged. half a square block of five foot tall 2 volt lead-acid cells in strings to give 48 volts at gizallian (?) amps. They were all connected by thick copper plates that ran to more copper plate buss bars. An associate was doing something with a 1/2 inch ratchet, and you know what happened. He was stunned but the wrench disappeared. Only small pieces at the ends were still intact. The entire handle vanished. Thanks for the recollection.

For more fun, he should to use at least double the capacitance, or charging voltage. Yet, still impressive. Subbed!

Been watching Andy for many years one of my favorite channels

My only experience on HV is in the ACT, I work for a communications company that use some HV poles to run spans of Fibre in areas that underground is undesired, we use 70kn polymeric to isolate from potential in the poles and move out of the capacitive ranges.

Allen Bradley has a high current test facility in Milwaukee, Wisconsin, USA. A 50 HP motor drives a big flywheel low voltage generator (about 10 meters in diameter), Basically you spin up the generator, declutch the motor as you close air switches to the load causing the freewheeling generator to dynamically brake with the bolted fault. There is an air core transformer to select various voltages and currents. All cables and bus bars are supported by wood to avoid inducing unwanted currents . UL, IEC & NEMA testing certified.

If PI goes outside instead of just burning up the carpet, you know it’s serious!

Might I ask what screwdrivers are used for extremely high voltage? I have 1000V VDE screwdrivers that are approved for 1000volts but tested for 10,000 volts, do they just get bigger for more insulation or is there a technique involved?

Hi - the ribs on insulators serve two purposes - they disrupt the shape of the electrical field and they also are "umbrella shaped" so they don't collect rain

The ribs are against ice forming. In cases where you have ice rain, the underpass prevents a continious icesheet from forming, thus, preventing arching or short to earth. The Increase of surface is a nice bonus.

The ripples on the insulator/feedthrough/standoff are for electric field manipulation. A sinusoidal or parabolic pattern (revolved around the cable/current axis) takes advantage of electric field lines' tendency to follow the shape of the medium; the density of equipotential lines (voltage essentially) maximizes at the sharpest points for the same reason. A smooth, uneven pattern "squeezes" the radial potential gradient coming off the conductor as the dielectric thickness increases. The smooth slope and evenly space local maxima of a sinusoidal pattern increases the axial distance between points as the potential gradient increases as well (c.f. a step fuction shape which would have two sharp corners at each local maximum which are not optimally spaced from the next local maximum). The points with more potential energy are further apart and have the most protection due to design and simple geometries! This reduces material costs and can aid in design of directed dielectric breakdown.

In the UK we have the IET Wiring Regulations that are a British standard. Bs767. It has very similar charts to the ones you showed. For the short run and duration of use I'd not worry about the trunking/ conduit. I'd say the conduit was to protect the cable insulation as it tensed.

lol I like how it takes him a moment of awe before he realizes how crazy this is.

I remember that guy. He lit up a giant vintage tube that really freaked me out since I've never worked with tubes of any kind. Giant modern fuses, yes, but no tubes.

One of the only if not the only RUclipsr that has a plug in that has a plug that goes into the national grid lmfao

I have a question if a circuit has a spark gap would that circuit be considered open or closed?

To be a bit more precise, the ribs on insulators are there mostly for water. If it's enclosed, then it can be just a ceramic tube but if it's outside, a bit of water on the surface will be enough for high voltage to jump over it. Those ribs don't let the water to create low resistance path on the surface. That's also why there is different design depending on the orientation of the insulator.

I love the way you just totally got into it E joying watching him destroy stuff, then near the end said "this is insanely dangerous by the way, don't do this" like you weren't just nodding and smiling along haha.

the ridges in the insulators are also there to help keep from arcing when raining.

HV insulators are ribbed for both more surface area and to reduce water droplets from creating a shorter path. The more you have and the bigger they are the larger the voltage and amps can go through. Where they are used, eg. in salt air environments or in the plains, and the material they're made from, eg. glass, ceramic, composite, can also affect the flashover current.

This what is known as being as dangerously safe. ElectroBOOM is safely dangerous.

Hi I have been watching Phototonic for years, he is such a great Guy, His name is Andy and he lives in the Dartford area, he has not done very much the last few years, i have a good idea why but its none of my business. Anyway i hope things are sorting things out. even BigClive says he is ok but working hard and getting on with life!

The undulating design of the insulators is to increase the creepage distance across the surface of the insulator for the given distance between the conductors.
E.g. if you have a distance X between the conductors by castlating the insulator you can make the surface distance across the insulator 5X.
The reason why this matters is because the electrical energy will track across the insulator surface much easier than if it was free space between the conductor.
A longer path across the insulator surface gives a larger insulation voltage between the two conductors.

He is cool - completely authentic production. He has to be some kind of industrial high power electrical engineer who just loves what he does.

One important thing about electricians is: If they do a bad job, they get fired. Not necessarily by their boss, but more likely by their electrical installations blowing up in their faces.

I love Photonic and have watched him since the early days and he didn’t make vids for a long time and it was nice to see him back.

Photon's always been a fave of mine whenever he's managed to upload. Seeing ElectroBOOM etc. on here too, very excited to go through these. Although I think I might have spoiled the rest with this one 🤣
I'd love to see more Photon vids among the rest, if you've not already got them!

Mr. Photonicinduction is amazing. He went on a few year hiatus then he did this video and a few others. Then disappeared again for personal reasons.

Miss Photonicinduction. His videos were absolutely epic.

All Hail Photonicinduction! There is none greater.
I bet his power meter spins like a ufo.
And his name is Andy.

I've always heard it as the ribs on insulators are there so rain/water doesn't have a chance to create a path for the power back to the pole. i can see that being a concern in power transmission, as for here it may have something to do with making sure the path that the electricity would have to take if it is following the surface of the insulator far longer than if it was just a solid piece.

Do you know where to buy that large capacitors as a private person?

When considering insulation you must consider creepage and clearance. Creepage is the shortest distance over a surface between two conductors and clearance is the shortest distance trough air between two conductors. The ribs just increase the creepage distance.

I've always wondered what an actual electrician would think of that fellow's highly entertaining shenanigans :D

He is brilliant but he disappears for a while and then comes back. Make sure you watch his Health & Safety video, it is a bit sweary but his classic line I don't need to be seen from the f***in moon in this cracks me up every time I feel a bit down I watch that and its good for the soul. Also I like his Ironing video where he destroys a steam iron.

i love the way our man here leans back from the screen before every event. lol

Pretty sure he used the sleeving as extra protection and insulation. Protection as he is dealing with insane current-pulses here. The induced magnetic field is more than enough to move the cables and there it is a good idea to have more than the normal insulation to keep them apart (and keeping anything else away from them).

Bells or sheds on insulators.... That's for the "creep" distance and yes, the current would have to flow further to cause a flash over. The straight line measurement is called "strike". Each bell on an old porcelain type is usually rated for 10kV. So you can get a rough idea of the line potential by counting bells. Poly or single piece insulators are a little different and there's no way of counting sheds to determine the insulation class. You just go by looking at it's length to determine what kV rating it is.
And the short circuit fault current a wire or cable can handle is much more than the rated ampacity listed. We use 4/0 protective grounds for grounding (earthing) and I think they are rated for 20,000A fault current but only for 15 cycles or so. Which is much longer than any protective device should operate in, usually 5 cycles or so. I forget the actual ampacity / cycles, but it's much higher for momentary faults, for any wire or cable. As he was doing in that video.

I wonder if the ribbed ceramic high voltage isolation is also made this way to lower the chance of rain water bridging the gap?