You should give superconducting magnets a try. You won't have to worry about heat or any power loss, just need a good source of liquid nitrogen. Would love to see your detailed analysis of one!
I think even that "ordinary" electro magnet (without the need to build one out of exotic superconducting materials) would probably be able to get as strong as the neodymium magnets without generating too much heat, if cooled down by liquid nitrogen. Copper never really get super conducting, but it lower it's resistance really much (about 8,8 times compared to 25°C) at liquid nitrogen temperatures.
Even just submerging these commercial electromagnets in liquid nitrogen would allow you to significantly over-power them without them heating up and loosing efficiency
Thank you very much! I was under an unusual time pressure for this video since I basically got carried away with the number of experiments testing an electromagnet for the first time. Truly exciting and enlightening for me. But I always aim for quality over quantity ;) Much more to come!
@@brainiac75 I can resonate with quality over quantity: something I've tried taking to heart on my own channel. Can't wait to see more, keep it up good sir!
Overclocking an electromagnet and colling it with an AIO. Are we now at LTT? 😆 Biggest gains on that magnet would come from cooling it down with LN2. Would be a great vid, temperature vs magnetic strength vs power draw. With that tesla meter of yours, it would be very interesting to see that curve!
Laboratory LN2 has largely been replaced by Peltier pump. With a Peltier we do not need to go down to -196° but merely remove the heat the power in the magnet is dissipating. The electrical resistance will always produce heat and the magnetic field will add to the impedance because it counters the potential voltage (delta V). The electro-magnet needs to dissipate heat at the same rate it creates it to remain at equilibrium. Unit of heat is Joule, rate of heat is J/s = Watts. We need a Peltier pump that cools equal to the heating. Another power supply and a suitable Peltier.
A lot of times when stuff is advertised as "12V" they actually mean something more like 14V because that is the kind of voltage it would actually see in an automotive application and most 12V applications are automotive. Could explain some of the wattage discrepency.
Most are not automotive at all not even close and 14.4v-14.6v is more accurate in automotive when using a alternator with no load and that can drop fast depending on load and alternator etc
@@primus711 13.8v is considered "standard" alternator voltage, the way 120/240v is standard in the house. Yes it can vary up and down a bit but that is a good average to use for ratings. There is however much usage of 12v outside of automotive applications. In those applications they really do mean TWELVE volts! Things like massive servers have a PS that outputs about 12.2v @ 100+ amps, voltage always adjusting to meet demand and stay at 12v. 12v is also heavily used for all kinds of control circuits - I think one of the uses of these magnets is to lock doors remotely, such a system would likely use a 12v power supply. If it was made in china, I don't care what it is or how much it cost, the specs are not reality.
The magnetic strength doubling with a 4 fold increase of wattage is logical. The field strength is linear with the current, and the current is linear with the voltage. Since P=I*U and I and U both increase linearly with the field strength, the power (wattage) increases quadraticly (or the magnetic field with the root of the power). To combat the heating issue, set your power supply to "unlimited" voltage, and limit the current, then the field strength will stay constant (even though it still heats up a lot)
Electromagnets are interesting in their own right, though happy to hear that passive neodymium magnets beat them out in some cases! Great video as always.
I'm an engineer that designs linear motors with permanent magnets. Your testing of the open air magnetic field does not represent the lifting power of the electromagnet. If you put the electromagnet against a flat piece of steel with a gauss meter in between, you would measure a much higher field. Note that the steel plate should be thick to get the highest measurements (10 mm thick is probably enough). With the electromagnet in the open air (no steel plate), the magnetomotive force must be distributed across the air gap between the center circular pole and the outside ring pole. If you put those poles against against a flat steel plate (steel has high permeability), the air gap is much smaller, and you will end up with a much larger field (probably around or over 10000 Gauss, approaching the saturation point of the steel pole in the center). When you use the neodymium magnet against a steel plate, it's large magnetomotive force is mostly spent creating a magnetic field across its own (low permeability) interior -- its own material acts much like an air gap. It's magnetomotive force is so high, however, that it can create high forces. I would suggest that you perform a lifting test with the two magnets, and see how much weight you can lift with each one. Hang your magnet from a strong support with the poles facing down on the electromagnet (it looks like the electromagnet may have threaded holes for this purpose). Stick a thick (1 cm or more), flat piece of steel to the bottom of the magnet. Add weight to the steel until it falls off. That will give you a much better idea of the lifting capability. Repeat with the Neodymium magnet (You will likely have to use a clamp to hang the Neodymium magnet, or you can just stick it to the bottom of a thick steel beam or plate). The electromagnet will have high attractive forces with a small gaps, but the force will fall off quickly with increasing gaps. The Neodymium magnet's forces will fall off more slowly with increasing gap. When performing the same test with a thin sheet of steel, the sheet of steel will saturate (it has high permeability for only about the first 20000 gauss, and then saturates), and you will get much lower attractive forces. Good luck!
One of the measures of a good quality holding magnet is how smooth and flat it's surface is. The better quality ones are ground better. The same applies to the steel plate, so a machined/ground one is WAY better than a rusty cold rolled steel bar.
How crucial would the remaining air gap be? Because you could even go a step further and use something like heat sink grease to eliminate the air. The only drawback is if you even look at the stuff it gets everywhere.
I am curious about the inner and outer diameter thickness of the electromagnet, like how will it affect the performance if the center is thin and the outer is thick in diameter and which thickness will be the best option for high performance, can you help me with that?
The electromagnet has the advantage of metal cup to close (concentrate) the magnetic circuit. If you gave the neo magnet a similar cup it would increase its holding force, further increasing its advantage. A lot of fridge magnets do this so they can use cheaper ceramic magnets that wouldn't hold without the cup. flexible sheet magnets do something similar by alternating polarity in stripes. You should also look at switchable permanent magnets as they have feature parity with electromagnets.
Yep, didn't have time for it for this video, but I will try to source a 50x30 mm neo magnet (preferable grade N52) and a potted 50x30 mm neo magnet. Would make for a much better one to one comparison. No doubt that the neo magnets will still win though. Thanks for watching!
I have some pretty thin 30mm neo magnets that are in steel cups, and it does make a huge difference. The manufacturer didn't have to bother with gluing them, it's almost impossible to get them out.
Your electromagnets brought some memories. When I first got to deal with the math of electromagnets, I decided to try some optimization of my own. To my frustration, the math "converged" always to the lowest number of wire turns, using heavier and heavier gauge wires. In fact, my end result was that a single turn of wire that filled the whole available volume always produced the highest magnetic flux with least resistive heat. Of course, the flux density is determined by the air gap, as long as the core does not saturate. Your probing showed well below my usual assumption of 1.2 T (tesla = 10 000 gauss) to 1.5 T field density saturation for ordinary magnetic core materials. So you would be able to push beyond the neodymium field density with a single turn winding and maybe 0.1 V / 200 A supply without excessive heating, if you can provide such a supply. (0.1 V x 100 A = just 10 W).
@@NEW-WATER-ATTRIBUTES-2023 I am not at all sure what exact help you would expect. I just have one idea that may be easier to implement than, say some superconducting suggestion. It is to make your coil of copper tube, such as the one used in air conditioner heat exchangers. You could find that kind in most any big hardware store. Then you would need to insulate the tube, with for example heat shrink tubing before winding it to a coil. An alternative would be some insulating spacers mounted between coil turns after winding, I assume you would already have insulation around the iron core. With appropriate fitting(s) and a pump, or just tap water, you could reduce the temperature rise to negligible level, meaning you could use much more current. This kind of arrangement is used in flameless - Eddy current - annealing heaters. In them, they don't need insulation, because they have the coil stiff, just air core magnet, maybe 2 or 3 inches inside diameter, 3 to 6 inches long. I assume you would want DC use, and a more compact structure, with a U- or maybe E- shaped iron core. However, keep in mind that any iron core eventually saturates, and after that any increase in magnetizing current causes only field increase at the same rate that results in open air. All that means, initially the iron core effect is good and strong, but after saturation level, FURTHER INCREASE tapers off. I hope this at least gives you some idea what to consider, or try next. As to the source of current, somebody already suggested using car batteries. Just pick some with a high cranking current rating (like 600 amperes or more). The cranking current rating is for relatively short times, so you still might need two or more in parallel, if you want more than about 10 or 20 seconds duration. And of course, the cables from the batteries to your coil must be thick and short. I would suggest 0 or 00 size welding cables. 0000 size could handle over 600 A long term, but I don't think any practical batteries would. Finally, you would need a really big switch to turn your current on and off!
Magnets happen to be one of my favorite subjects. I believe if the core were taken out and shaved to half its diameter, and then rewound with more windings, you could potentially double the gauss output with the same volume. Can't wait to see you build some of your own! Imagine the ones they use in wrecking yards to lift entire cars, the possibilities are endless. Speaking of turning on and off, I have seen some permanent magnet gadgets that turn on and off the magnetic field by flipping a lever. What's that all about? Great video!
Just started binge watching this channel a few videos ago. Looking forward to seeing the progression up the liquid-> water -> sub-ambient -> L2N goes, as the colder it run, the better it runs.
You can get "switchable" permanent magnets as well, where you turn something on top to change the positioning of two magnets to cancel eachother out in the off position. (I'm sure you know this, but since you mentioned the ability to turn off as the main advantage I thought I'd add this comment)
Thanks for the reminder! I do need to make a video about the magnetic lifters - and even build my own using permanent magnets to demonstrate how they work. So many videos to make - so little time for it :D
I do upload a video every month (twice a month if you include the one on Patreon), but you may only be notified of my magnet videos if you only watch those? But yes, quality over quantity for my channel :D Thanks for watching!
@@brainiac75 wow that's a great mindset but i feared that you lose subs overtime when you're in the process of making new vids because of how long it takes to make one and yes i do watch some of your videos sometimes but only youtube videos I don't use patreon neither i don't know what patron is.. haha
I love making those little homemade bolt electromagnets in fact, If you give the electromagnet more current it will get hotter. More Voltage = More Strength | More Current = More Heat. I even tried to make an electromagnet oven by giving it around 5v DC 2 amps. this gave the magnets a fair amount of strength. but they got very hot. I was almost able to make toast with my oven! They even have induction cookers that are just a giant electromagnets with lots of current. It's fun to experiment with this kind of stuff! keep it up Brainiac75!!
I thought for a while how i could compare different magnets strengths with something carried everyday. Soooo i use a standard bic lighter standing up with the magnet flat on the same table. From how far away will the magnet pull over the lighter.
There is a trick with electromagnets , which allows you to reach higher pulling force than any permanent magnet is able on , without overheating of the coil . You need to grind (as fine as possible ) electromagnet’s poles and the metal surface on which you want to lock them . Than use capacitors battery ( you may need ultracapacitors ( also known as supercapacitors or ionistors ) ). Charge the capacitors battery to few times higher voltage than the electromagnet is rated for . Than discharge the capacitors battery via the electromagnet’s coil . The enormous current pulse will create enormous magnetic field . The interesting part is that this field doesn’t disappear or weaken in the magnetic guide after the the coil current is disrupted so there is no any reason for heating and the magnetic guide loop can stay closed infinitely. You can open it by applying the same amount of current but with opposite polarity of the voltage on coil terminals . You can see such experiments in the following video ua-cam.com/video/s-5FMFzSPYU/v-deo.html unfortunately on Russian language . By the way the strongest magnetic fields are archived by electromagnets !
Please don't say "overclock" when you are only changing voltages and currents to values out of spec. The correct term is "overvolt" Having said that, I've enjoyed the video! Let's see what the future brings for that little magnet-on-demand! Cheers
Great video, When I was younger I used to work for a company that had an electro magnetic lock on the door. During office opening hours the door was propped open and the magnet was at the top of the door frame. For fun we would turn the lock on and put some paperclips on the magnet. Then when someone walked through the door we would turn the magnet off as the paper clips dropped on their head. It was harmless fun as we watched from a distance as the bemused person wondered where the paperclips came from. This would amuse us for hours.
What about heating in the electro when holding a load (poles connected with Fe object)? What about advantages of electros vs Neos in generator or motor applications (control vs economy)?
Great video. This gave me inspiration to prepare some electromagnets for use around the shop. My son wanted to make a solenoid engine for a class of his. Running the math to look for more power we found a honey comb array of smaller core and coils had a lot of advantages. We never built it though. His teacher was happy just with the math Thanks again for the video
I made my own electromagnet recently out of an old microwave transformer. Using a couple old car batteries it got hot fast but it was so strong with that much current, the shovel would instantly stick and not come off until the power was disconnected haha It was fun trying out different ways of powering and messing with different sizes of transformers
Making a a hybrid of the two would have novel properties, like being able to turn a permanent magnet's field temporarily off, or able to steer its direction. Hybrids are used in load speakers and bidirectional solenoids.
Would be interesting to see how using various power supply wave forms affects the strength of the magnet. Is the relationship linear if say pulsed square or sawtooth wave DC is supplied or is there a relative gain or loss in the resultant magnetic field?
@@martinshoosterman Perhaps but other effects might be observed as well, such as linearity of attenuation, affect on input current to magnetic strength at different amplitudes and frequency, or any unexpected effects. It might answer the question you ask.
I love how we are both thinking about water cooling the electromagnet. But do watch out for the magnetic impeller inside many all-in-one cooling solutions. It might be better to get a custom water cooling loop.
I'm happy you are finally getting into electromagnets. I really like neodymium magnets. I allways seem to find stray magnets and I have an ever growing collection. I found a stack of 4 2"x3x1/4 on a shopping cart. Those are super strong and were an amazing find.
You might like to read ‘Magnetic Venture” by Audrey Wood. All about Oxford Instruments and the development of big magnets for NMR and later super cooled magnets for MRI scanners.
I’d love to see you take a look At electro permanent magnets. They’ve always fascinated me. Basically a “pulse” of current switches them on and off - during either operation, no electricity is required!
Funny my first thought with the electromagnet when I saw its performance was - what if it was cooled and you over-volted it? And of course the next thought was - what if you cooled it with LN2? Also I think it would be neat if you could get your hands on a bitter electromagnet or maybe collab with a bitter magnet manufacturer. I think the current record for man made magnetic fields is a bitter magnet rated at 45.5 Tesla (455,000 gauss). Would be super cool to see you experiment with one.
Very nice video! Have you heard about the combination permanent- and electro- magnets used for safety critical / lifting applications? This unit includes a permanent magnet with an electromagnetic component. The permanent magnet will produce an external magnetic field under normal non-energized conditions. When the electric coil is turned on, it provides an internal magnetic path, preventing the unit from producing an external magnetic field. No power is required to HOLD the load on the magnet, but power is required to RELEASE the load. These are used for lifting and hoisting, where a power failure with a "pure" electromagnet would result in a dropped load. I think they call it an "electropermanent magnet" assembly.
Oooh! This is fun! I'm particularly interested in how active cooling could affect it. I've been wanting to try building a little Gauss/coil gun for a while, and have been curious if cooling the coils could improve performance, but haven't been sure how much, if any difference it could make. (been thinking of using a Peltier cooler to get them quite cold)
I'd definitely like to see the results of cooling the elecromagnet. Regular computer heatsink, heatsink with fan, submerged in ice water, heatsink with ice water submersion, liquid CPU cooler, or even liquid nitrogen as someone mentioned. Maybe you could use an intermediate medium to work your way down to liquid nitrogen temps instead of doing it all in one step. Hopefully you'll do several of those, but even one cooling method will be neat. Thanks for a great video as always.
Very detailed overview. I challenge you to solve the faraday paradox!!! A faraday homopolar generator with fixed magnets on the rotor, poles will be axially and radially. It produces dc voltage with no back emf
You should go all out with experimenting with pushing a electromagnet's ability and using a cooling system. Its just really interesting to be able to play with the settings, adjustments, etc. Im wondering if there could be some insane ways a super powerful one, or a setup system of them could be used if say: hypothetically you ran some off of a modern advanced nuclear energy reactor. Could be small form, thorium reactor, LFTRs... But could definitely power some really fun science experiments that's for sure. And the energy source would be efficient, no emissions, stable, strong. It would be exciting to power a efficient system that runs off of the electrical output from a power source like that.
I used to use an electro magnet at the machine shop I worked at and there was a slight delay from when the power was cut to when it lost its pull force , I was wondering if that just the nature or a electro magnet or if the system was using Capacitors that had to discharge first
I look forward to more of these! Cooling tests will be fun. You could do some pulse tests as well. If you can manage the power supply requirements you can pulse 10 times or more it's rated current, albiet for only a split second. I'm not sure what you would use it for but it would probably make an interesting video.
Yes, I want to see how much pushing or pulling force it takes to open a purely magnetically "locked" building door with just an average-sized "lock-"plate and magnet (not something with a huge magnet to a mostly metal door). And then demonstrate those doors' failsafe locking mechanisms that auto-trip in a power outage.
YES! more electromagnets!! That is pretty cool. I think you should give a microwave transformer a try, easy to get and you can cut out the secondary and put 2 primaries into it for more coils!
Some permanent magnets can also turn on/off by bend their flux in the same direction or opposite direction.(you need at least 2 of them with electromagnet material to make the magnetic force go in loop when turn opposite direction for turning off.)
💡Stack an electromagnet and neodymium. (Epoxy a coil around the neodymium magnet.) You can use a pulse to temporarily cancel out the permanent magnet. Iron can also be used to focus the power just like the electromagnet in this video, just make the center part the neodymium magnet. 👍
Since they are designed to stick to metal, how much would a metal plate dissipate heat from the magnet? I am always wondering this looking at the door magnets at my school.
It would be interesting to see how high the field strength can go if you can supply a pulsed DC power to the electromagnet. - the 8W magnet is average power, and just as with lasers and LED's - pulsing with a low duty cycle should give a high(er) peak-output power... Playing with Power - Pulsed Power Push/Pull'er (or perhaps not, the iron core has a B-H curve, so it's possibly not reacting fast enough) 2*12V car batteries and a beefy relay (w. rev diode protection) controlled by a variable oscillator might be safer for your power-supply ;ø) Looking forward to future videos on these pucks - btw, where did you buy them (and the Radiocode meter, etc. - links/info would be appreciated)
Interesting. May give it a thought, though back EMF and basically running a DC magnet as an AC magnet may get me in trouble :) But I will try running it on AC in a future video. Just to see what happens with heating, field strength etc. I am a total noob when it comes to electromagnets... The electromagnet was bought from Conrad Electronic.
@@brainiac75 AC is alternating current ;ø) - so the magnet will also be alternating its poles. Magnetic Hysteresis then becomes an issue (problem), as energy is spent turning the magnetic domains inside the iron/magnet. Less emitted field pr unit energy spent. Pulsing the magnet with DC - ought to strengthen it, as the h-field moves up-down without having to rotate. Wikipedia has good illustrations of this. This should (I think - not 100% sure) strengthen the field when powered on, and still remain magnetic when power is off. I could build you an electronic switching device for pulsed DC + tell you a bit more (I'm an electrical engineer + radio 'everything'). I live quite close to your favorite sweets-store, if you're interested :ø) - and I have some time on my hands, electrical components + equipment, and I'm curious what your Lake Shore Teslameter reports. (er også bidt af en magnet og deres mysterier)
It seems peculiar that you focus so much on wattage of an electromagnet. The magnetic flux you get is proportional to current times number of turns in the coil (at least until you reach magnetic saturation of the core). If you rebuild the graph at 4:35 with current as the x value, you'd get a pretty much linear plot. So, if you want power efficiency, you need to minimise the coil resistance. Use thicker wire gauge, and/or employ some radical cooling (dry ice or even liquid nitrogen).
do you know of an small inexpensive 12vdc electromagnet like the one in the video that can be left turned on for longer than an hour? all the ones i see say 10 minutes or left or they over heat.
Just bolting a regular finned heatsink to the back of the electromagnet would help keep the temps down when overvolting the electromagnet. There is however a risk of burning out the windings if too much current is applied. If you want to push the overvolting experiment further there's no reason you couldn't put the electromagnet in a simple waterbath, at least up to the top lip, since the windings are insulated and potted in resin. That would dissipate the heat quite well.
Congratulations ! This is one of the bether videos that a have seen ! The question is : If I need 8w of power or 8 joules by second of energy to get 400 N of pull , what kind of energy the permanent magnets need and where it receves this energy from? It is almost sure the neodymium magnets receves a kind of energy from universe , then it is not so absurd to imagine a magnect mouter runing by itselfs . Do a video comparing the capacity of moving wheght corps by eletromagnets and permanent magnets along the space. Please!
You should try to make halbach array out of neodymium, electro magnets, and super conducting magnets. You can arrange them to concentrate the fields and make them even stronger or make them cancel out to "turn off" neodymium magnets.
I really enjoyed your video . I have a question , what is better in a marine environment Neodymium or Samarium cobalt ? How long do the coatings last on Neodymium magnets in a marine environment ? What about a comparison of the impact resistance ? what about the affect of direct tropical sun , heat + UV ?
Good job on the video! It's interesting and educational but I respectfully take issue with your use of the word "overclocking". Electromagnets do not have clocks. Therefore, you cannot overclock them. You can over-power them, but not overclock them. Here is the definition of overclocking: "Overclocking is the action of increasing a component’s clock rate, running it at a higher speed than it was designed to run." It applies only to clocked devices such as microprocessors and some other types of computer chips. Keep up your awesome videos!
PS so if you traced the field around your electro magnetic field with iron filings would there be a node at each end of the flat cerface of the magnet like your test showed
Has the term "overclocking" become an accepted idiom for everything now regardless of whether there are any quartz crystals sending any clock pulses or not?
You should test electromagnet door locks. The ones commercial buildings use to lock their doors. Not a lot of pull force, but holding force is incredible.
Can you make a video about magnets slowly falling down when put near a copper or aluminium sheet? I have a small HDD magnet and experiment with this, but now I want to see what will happen with your more powerful and substantial magnet. will it fall slower?
These magnets don't mind so much being heating up. They are used in metal industry to lift e.g. large metal plates and iron beams. They are usually not activated for more than from a few seconds, to a few minutes at a time. With 4 to 8 of these, just in sizes that are larger, you can lift lift metal plates for e.g. ship construction, that weights several tonnes. I don't remember the pulling power of magnets of this kind, that has a diameter 4 to 5 times the size, but we are talking maybe a tonne per magnet. But you always want to have twice as many magnets as needed. One, several of the magnets can be short circuited/defect, second, their max pulling power decreases radically, just by having dust in the environment.
How does this compare with the electromagnets currently being installed in the ITER experimental fusion reactor? There's a lot of info for ITER - I'd be interested if you would check it out and do a comparison with it like you did with the Earth's field.
This is exactly what I need to do my experiments with a variety of stuff. But especially plant growth and cellular health. I need an affordable electromagnetic device that allows it to be variable and see the actual strength of the magnetic field or it’s frequency.
For this and your N40 magnet, I think the best video would be temperature vs magnetic flux density vs max load, with an overclocked electromagnet with a UPS, and cooled by either liquid nitrogen, liquid oxygen or water that is just above freezing point.
The magnetic bridging was interesting, first time I've seen it. I'm curious about using this for an electromechanical sculpture. If you wanted to lift a block (containing a permanent magnet) above it, what would be the most efficient way to do so. For example, shape and size ratio of permanent magnet, bridging vs not, orientation of permanent magnet, Halbach array usage?
The most powerful magnetic fields are generated by compound coils, admittedly using super conductors. If electric vehicle development is not to be limited by the availability of rare earth elements, then motors must use electromagnet field generation, rather than permanent neodymium magnetics.
I do have some old videos where I put big neodymium magnets near a CRT TV. Think I did it lately in the video 'Monster magnet meets plasma ball'. You can see the field lines but I haven't noticed a vortex?
@@brainiac75 it's Ken L. Wheeler discovery (if i recall), on UA-cam as Theoria Apophasis, he has cool video magnetism and device to see magntic field, like magnetic film or ferrocell
If you want to try cooling the electromagnet with a PC AIO cooler, look for something with a pump that's not in the waterblock, I can't imagine it will pump very well if at all with an electromagnet stuck to it.
Got to it a little late, but awesome work as always!! I'd love to see if the magnet can handle more power without concern for heat, is there some sort of limit for how much you can safely pump in them?
What about those on/off permanent magnets like in the bases for some car equipment. Are they the best of both worlds? Can you make such a "magnet" from neodymium magnet?
You should give superconducting magnets a try. You won't have to worry about heat or any power loss, just need a good source of liquid nitrogen. Would love to see your detailed analysis of one!
How much money would it cost me to generate 2-4 tesla on my desk?
Yo, codeparade! Love your game, and happy to see you here
I think even that "ordinary" electro magnet (without the need to build one out of exotic superconducting materials) would probably be able to get as strong as the neodymium magnets without generating too much heat, if cooled down by liquid nitrogen. Copper never really get super conducting, but it lower it's resistance really much (about 8,8 times compared to 25°C) at liquid nitrogen temperatures.
Even just submerging these commercial electromagnets in liquid nitrogen would allow you to significantly over-power them without them heating up and loosing efficiency
Hi CodeParade! Loving your new game :)
Could we all just take a moment to appreciate the quality put into these videos? Truly amazing, keep it up man!
Thank you very much! I was under an unusual time pressure for this video since I basically got carried away with the number of experiments testing an electromagnet for the first time. Truly exciting and enlightening for me. But I always aim for quality over quantity ;) Much more to come!
@@brainiac75 I can resonate with quality over quantity: something I've tried taking to heart on my own channel. Can't wait to see more, keep it up good sir!
@@brainiac75 I can't wait to see what it can do with a cooling system!
@@brainiac75 hi
@@brainiac75 Can you build electromagnet using different core materials?
The truly strongest form of magnetism is produced by your enthusiasm for magnets. It's what keeps attracting people back to your channel.
100/10 nice
Overclocking an electromagnet and colling it with an AIO. Are we now at LTT? 😆 Biggest gains on that magnet would come from cooling it down with LN2.
Would be a great vid, temperature vs magnetic strength vs power draw. With that tesla meter of yours, it would be very interesting to see that curve!
Wonder what the differences are in cinebench before and after overclocking.
The black stuff on top may crack in liquid nitrogen.
Laboratory LN2 has largely been replaced by Peltier pump. With a Peltier we do not need to go down to -196° but merely remove the heat the power in the magnet is dissipating. The electrical resistance will always produce heat and the magnetic field will add to the impedance because it counters the potential voltage (delta V). The electro-magnet needs to dissipate heat at the same rate it creates it to remain at equilibrium. Unit of heat is Joule, rate of heat is J/s = Watts. We need a Peltier pump that cools equal to the heating. Another power supply and a suitable Peltier.
Cody's lab has done a video of cooling an electromagnet with LN2. It works great: ua-cam.com/video/YledrMyoqgs/v-deo.html
A lot of times when stuff is advertised as "12V" they actually mean something more like 14V because that is the kind of voltage it would actually see in an automotive application and most 12V applications are automotive. Could explain some of the wattage discrepency.
Most are not automotive at all not even close and 14.4v-14.6v is more accurate in automotive when using a alternator with no load and that can drop fast depending on load and alternator etc
@@primus711 13.8v is considered "standard" alternator voltage, the way 120/240v is standard in the house. Yes it can vary up and down a bit but that is a good average to use for ratings.
There is however much usage of 12v outside of automotive applications. In those applications they really do mean TWELVE volts! Things like massive servers have a PS that outputs about 12.2v @ 100+ amps, voltage always adjusting to meet demand and stay at 12v. 12v is also heavily used for all kinds of control circuits - I think one of the uses of these magnets is to lock doors remotely, such a system would likely use a 12v power supply.
If it was made in china, I don't care what it is or how much it cost, the specs are not reality.
watts = {(volts)^2 }/ohm
That was such a good safety tip. I would have never thought about needing a UPS for your lab bench power supply.
The magnetic strength doubling with a 4 fold increase of wattage is logical. The field strength is linear with the current, and the current is linear with the voltage. Since P=I*U and I and U both increase linearly with the field strength, the power (wattage) increases quadraticly (or the magnetic field with the root of the power). To combat the heating issue, set your power supply to "unlimited" voltage, and limit the current, then the field strength will stay constant (even though it still heats up a lot)
Electromagnets are interesting in their own right, though happy to hear that passive neodymium magnets beat them out in some cases! Great video as always.
I'm an engineer that designs linear motors with permanent magnets. Your testing of the open air magnetic field does not represent the lifting power of the electromagnet. If you put the electromagnet against a flat piece of steel with a gauss meter in between, you would measure a much higher field. Note that the steel plate should be thick to get the highest measurements (10 mm thick is probably enough). With the electromagnet in the open air (no steel plate), the magnetomotive force must be distributed across the air gap between the center circular pole and the outside ring pole. If you put those poles against against a flat steel plate (steel has high permeability), the air gap is much smaller, and you will end up with a much larger field (probably around or over 10000 Gauss, approaching the saturation point of the steel pole in the center). When you use the neodymium magnet against a steel plate, it's large magnetomotive force is mostly spent creating a magnetic field across its own (low permeability) interior -- its own material acts much like an air gap. It's magnetomotive force is so high, however, that it can create high forces.
I would suggest that you perform a lifting test with the two magnets, and see how much weight you can lift with each one. Hang your magnet from a strong support with the poles facing down on the electromagnet (it looks like the electromagnet may have threaded holes for this purpose). Stick a thick (1 cm or more), flat piece of steel to the bottom of the magnet. Add weight to the steel until it falls off. That will give you a much better idea of the lifting capability. Repeat with the Neodymium magnet (You will likely have to use a clamp to hang the Neodymium magnet, or you can just stick it to the bottom of a thick steel beam or plate).
The electromagnet will have high attractive forces with a small gaps, but the force will fall off quickly with increasing gaps. The Neodymium magnet's forces will fall off more slowly with increasing gap.
When performing the same test with a thin sheet of steel, the sheet of steel will saturate (it has high permeability for only about the first 20000 gauss, and then saturates), and you will get much lower attractive forces.
Good luck!
One of the measures of a good quality holding magnet is how smooth and flat it's surface is. The better quality ones are ground better. The same applies to the steel plate, so a machined/ground one is WAY better than a rusty cold rolled steel bar.
How crucial would the remaining air gap be? Because you could even go a step further and use something like heat sink grease to eliminate the air. The only drawback is if you even look at the stuff it gets everywhere.
@@kennybruce2597 Not the presence of air specifically makes it weaker but the distance between the steel plates, the lack of ferromagnetic material.
I am curious about the inner and outer diameter thickness of the electromagnet, like how will it affect the performance if the center is thin and the outer is thick in diameter and which thickness will be the best option for high performance, can you help me with that?
Thanks!
The electromagnet has the advantage of metal cup to close (concentrate) the magnetic circuit. If you gave the neo magnet a similar cup it would increase its holding force, further increasing its advantage. A lot of fridge magnets do this so they can use cheaper ceramic magnets that wouldn't hold without the cup. flexible sheet magnets do something similar by alternating polarity in stripes.
You should also look at switchable permanent magnets as they have feature parity with electromagnets.
Yep, didn't have time for it for this video, but I will try to source a 50x30 mm neo magnet (preferable grade N52) and a potted 50x30 mm neo magnet. Would make for a much better one to one comparison. No doubt that the neo magnets will still win though. Thanks for watching!
@@brainiac75 Could you run some experiments on hybrid magnets? (Electro-Permanent Magnet)
I have some pretty thin 30mm neo magnets that are in steel cups, and it does make a huge difference. The manufacturer didn't have to bother with gluing them, it's almost impossible to get them out.
@@brainiac75Also, electromagnets can be much more compact. An electromagnet can be much stronger for it's size than a neodymium.
Your electromagnets brought some memories. When I first got to deal with the math of electromagnets, I decided to try some optimization of my own. To my frustration, the math "converged" always to the lowest number of wire turns, using heavier and heavier gauge wires. In fact, my end result was that a single turn of wire that filled the whole available volume always produced the highest magnetic flux with least resistive heat. Of course, the flux density is determined by the air gap, as long as the core does not saturate. Your probing showed well below my usual assumption of 1.2 T (tesla = 10 000 gauss) to 1.5 T field density saturation for ordinary magnetic core materials. So you would be able to push beyond the neodymium field density with a single turn winding and maybe 0.1 V / 200 A supply without excessive heating, if you can provide such a supply. (0.1 V x 100 A = just 10 W).
My post pH.D E.E. says..... Your right!
Hey there , I need to pick your brain as to me you have my answer somehow I am searching for...what do you say? Can u help me
Can u help me
@@NEW-WATER-ATTRIBUTES-2023 I am not at all sure what exact help you would expect. I just have one idea that may be easier to implement than, say some superconducting suggestion. It is to make your coil of copper tube, such as the one used in air conditioner heat exchangers. You could find that kind in most any big hardware store. Then you would need to insulate the tube, with for example heat shrink tubing before winding it to a coil. An alternative would be some insulating spacers mounted between coil turns after winding, I assume you would already have insulation around the iron core. With appropriate fitting(s) and a pump, or just tap water, you could reduce the temperature rise to negligible level, meaning you could use much more current. This kind of arrangement is used in flameless - Eddy current - annealing heaters. In them, they don't need insulation, because they have the coil stiff, just air core magnet, maybe 2 or 3 inches inside diameter, 3 to 6 inches long. I assume you would want DC use, and a more compact structure, with a U- or maybe E- shaped iron core. However, keep in mind that any iron core eventually saturates, and after that any increase in magnetizing current causes only field increase at the same rate that results in open air. All that means, initially the iron core effect is good and strong, but after saturation level, FURTHER INCREASE tapers off.
I hope this at least gives you some idea what to consider, or try next. As to the source of current, somebody already suggested using car batteries. Just pick some with a high cranking current rating (like 600 amperes or more). The cranking current rating is for relatively short times, so you still might need two or more in parallel, if you want more than about 10 or 20 seconds duration. And of course, the cables from the batteries to your coil must be thick and short. I would suggest 0 or 00 size welding cables. 0000 size could handle over 600 A long term, but I don't think any practical batteries would. Finally, you would need a really big switch to turn your current on and off!
@@InssiAjaton pass me an email I send you something ,pls be quick
Magnets happen to be one of my favorite subjects. I believe if the core were taken out and shaved to half its diameter, and then rewound with more windings, you could potentially double the gauss output with the same volume. Can't wait to see you build some of your own! Imagine the ones they use in wrecking yards to lift entire cars, the possibilities are endless.
Speaking of turning on and off, I have seen some permanent magnet gadgets that turn on and off the magnetic field by flipping a lever. What's that all about? Great video!
In these gadgets there are 2 permanent magnets. If you flip a lever polarity of one of them flips cancelling each other out.
@@geometrydash-krokoo-6503 cool!
Just started binge watching this channel a few videos ago. Looking forward to seeing the progression up the liquid-> water -> sub-ambient -> L2N goes, as the colder it run, the better it runs.
You can get "switchable" permanent magnets as well, where you turn something on top to change the positioning of two magnets to cancel eachother out in the off position. (I'm sure you know this, but since you mentioned the ability to turn off as the main advantage I thought I'd add this comment)
Thanks for the reminder! I do need to make a video about the magnetic lifters - and even build my own using permanent magnets to demonstrate how they work. So many videos to make - so little time for it :D
@@brainiac75 Well considering your upload cadence, you are doing very well when it comes to views/subs- so no rush.
Like the way a magchuck for a mill works
@@lenselinkberinge yeah, the ones for welders and millers are usually top notch, since they have to be for safety reasons.
@@brainiac75 Make the first, and biggest neodinium switch. I'm sure turning the lever would be hard 😂
This guy take months to make a video but it was worth it
I do upload a video every month (twice a month if you include the one on Patreon), but you may only be notified of my magnet videos if you only watch those? But yes, quality over quantity for my channel :D Thanks for watching!
@@brainiac75 wow that's a great mindset but i feared that you lose subs overtime when you're in the process of making new vids because of how long it takes to make one and yes i do watch some of your videos sometimes but only youtube videos I don't use patreon neither i don't know what patron is.. haha
The King of Magnetism is Back!
I love making those little homemade bolt electromagnets in fact, If you give the electromagnet more current it will get hotter. More Voltage = More Strength | More Current = More Heat. I even tried to make an electromagnet oven by giving it around 5v DC 2 amps. this gave the magnets a fair amount of strength. but they got very hot. I was almost able to make toast with my oven! They even have induction cookers that are just a giant electromagnets with lots of current. It's fun to experiment with this kind of stuff! keep it up Brainiac75!!
I thought for a while how i could compare different magnets strengths with something carried everyday. Soooo i use a standard bic lighter standing up with the magnet flat on the same table. From how far away will the magnet pull over the lighter.
I wish I had cared about my firsts as much as this guy. Starting his first electromagnet for the first time with his first power supply. Very cool.
There is a trick with electromagnets , which allows you to reach higher pulling force than any permanent magnet is able on , without overheating of the coil .
You need to grind (as fine as possible ) electromagnet’s poles and the metal surface on which you want to lock them . Than use capacitors battery ( you may need ultracapacitors ( also known as supercapacitors or ionistors ) ). Charge the capacitors battery to few times higher voltage than the electromagnet is rated for . Than discharge the capacitors battery via the electromagnet’s coil . The enormous current pulse will create enormous magnetic field . The interesting part is that this field doesn’t disappear or weaken in the magnetic guide after the the coil current is disrupted so there is no any reason for heating and the magnetic guide loop can stay closed infinitely. You can open it by applying the same amount of current but with opposite polarity of the voltage on coil terminals . You can see such experiments in the following video ua-cam.com/video/s-5FMFzSPYU/v-deo.html unfortunately on Russian language .
By the way the strongest magnetic fields are archived by electromagnets !
Please don't say "overclock" when you are only changing voltages and currents to values out of spec. The correct term is "overvolt"
Having said that, I've enjoyed the video! Let's see what the future brings for that little magnet-on-demand! Cheers
I love brainiac's content every time
I love this channel so so much. Thank you, Brainiac75!
Great video, When I was younger I used to work for a company that had an electro magnetic lock on the door. During office opening hours the door was propped open and the magnet was at the top of the door frame. For fun we would turn the lock on and put some paperclips on the magnet. Then when someone walked through the door we would turn the magnet off as the paper clips dropped on their head. It was harmless fun as we watched from a distance as the bemused person wondered where the paperclips came from. This would amuse us for hours.
What about heating in the electro when holding a load (poles connected with Fe object)? What about advantages of electros vs Neos in generator or motor applications (control vs economy)?
Will come back for the follow-up video. Well done!
Great video. This gave me inspiration to prepare some electromagnets for use around the shop.
My son wanted to make a solenoid engine for a class of his. Running the math to look for more power we found a honey comb array of smaller core and coils had a lot of advantages. We never built it though. His teacher was happy just with the math
Thanks again for the video
I made my own electromagnet recently out of an old microwave transformer. Using a couple old car batteries it got hot fast but it was so strong with that much current, the shovel would instantly stick and not come off until the power was disconnected haha
It was fun trying out different ways of powering and messing with different sizes of transformers
Would be nice to see it cooled down with LN2!
Making a a hybrid of the two would have novel properties, like being able to turn a permanent magnet's field temporarily off, or able to steer its direction.
Hybrids are used in load speakers and bidirectional solenoids.
Would be interesting to see how using various power supply wave forms affects the strength of the magnet. Is the relationship linear if say pulsed square or sawtooth wave DC is supplied or is there a relative gain or loss in the resultant magnetic field?
wouldn't you just end up making a speaker at that point.
@@martinshoosterman Perhaps but other effects might be observed as well, such as linearity of attenuation, affect on input current to magnetic strength at different amplitudes and frequency, or any unexpected effects. It might answer the question you ask.
0:52 How much difference does it make how nicely the wire is wrapped?
Not much. Wire length that is not going around it just doesn't add any strength, but adds a little bit of resistance and heating.
I love how we are both thinking about water cooling the electromagnet.
But do watch out for the magnetic impeller inside many all-in-one cooling solutions. It might be better to get a custom water cooling loop.
A quality experiment to entertain before bed. Goodnight, Brainiac75.
I'm happy you are finally getting into electromagnets. I really like neodymium magnets. I allways seem to find stray magnets and I have an ever growing collection. I found a stack of 4 2"x3x1/4 on a shopping cart. Those are super strong and were an amazing find.
You might like to read ‘Magnetic Venture” by Audrey Wood. All about Oxford Instruments and the development of big magnets for NMR and later super cooled magnets for MRI scanners.
Of course the real fun is combining the two types of magnets. That's how you get things like motors, actuators, voice coils, etc.
I’d love to see you take a look At electro permanent magnets. They’ve always fascinated me. Basically a “pulse” of current switches them on and off - during either operation, no electricity is required!
0:37 "Becareful near strong magnets, dont let them near you fingers" next shot is him holding the electro-magnet
Funny my first thought with the electromagnet when I saw its performance was - what if it was cooled and you over-volted it? And of course the next thought was - what if you cooled it with LN2?
Also I think it would be neat if you could get your hands on a bitter electromagnet or maybe collab with a bitter magnet manufacturer. I think the current record for man made magnetic fields is a bitter magnet rated at 45.5 Tesla (455,000 gauss). Would be super cool to see you experiment with one.
Very nice video!
Have you heard about the combination permanent- and electro- magnets used for safety critical / lifting applications? This unit includes a permanent magnet with an electromagnetic component. The permanent magnet will produce an external magnetic field under normal non-energized conditions. When the electric coil is turned on, it provides an internal magnetic path, preventing the unit from producing an external magnetic field. No power is required to HOLD the load on the magnet, but power is required to RELEASE the load. These are used for lifting and hoisting, where a power failure with a "pure" electromagnet would result in a dropped load. I think they call it an "electropermanent magnet" assembly.
Oooh! This is fun! I'm particularly interested in how active cooling could affect it.
I've been wanting to try building a little Gauss/coil gun for a while, and have been curious if cooling the coils could improve performance, but haven't been sure how much, if any difference it could make. (been thinking of using a Peltier cooler to get them quite cold)
I'd definitely like to see the results of cooling the elecromagnet. Regular computer heatsink, heatsink with fan, submerged in ice water, heatsink with ice water submersion, liquid CPU cooler, or even liquid nitrogen as someone mentioned. Maybe you could use an intermediate medium to work your way down to liquid nitrogen temps instead of doing it all in one step.
Hopefully you'll do several of those, but even one cooling method will be neat. Thanks for a great video as always.
Seeing you overclock the magnet with an AIO would be awesome, hope you do it!
Superconducting Magnets are fascinating as well as dangerous too
Thanks for the Video
Very detailed overview. I challenge you to solve the faraday paradox!!! A faraday homopolar generator with fixed magnets on the rotor, poles will be axially and radially. It produces dc voltage with no back emf
Will you create a VOD upon gram comparison? To understand traveling usage
You should go all out with experimenting with pushing a electromagnet's ability and using a cooling system. Its just really interesting to be able to play with the settings, adjustments, etc. Im wondering if there could be some insane ways a super powerful one, or a setup system of them could be used if say: hypothetically you ran some off of a modern advanced nuclear energy reactor. Could be small form, thorium reactor, LFTRs... But could definitely power some really fun science experiments that's for sure. And the energy source would be efficient, no emissions, stable, strong. It would be exciting to power a efficient system that runs off of the electrical output from a power source like that.
Does the power of push will be the same of pull ? thank you !
Good video for a nice evening.
I used to use an electro magnet at the machine shop I worked at and there was a slight delay from when the power was cut to when it lost its pull force , I was wondering if that just the nature or a electro magnet or if the system was using Capacitors that had to discharge first
I've had the fortune to be around industrial strength electric magnets from a young age. It's amazing what can be done with them
You know very well, how the permanent magnets are beeing magnetized 🙂 That is fun!
I look forward to more of these! Cooling tests will be fun. You could do some pulse tests as well. If you can manage the power supply requirements you can pulse 10 times or more it's rated current, albiet for only a split second. I'm not sure what you would use it for but it would probably make an interesting video.
Yes, I want to see how much pushing or pulling force it takes to open a purely magnetically "locked" building door with just an average-sized "lock-"plate and magnet (not something with a huge magnet to a mostly metal door). And then demonstrate those doors' failsafe locking mechanisms that auto-trip in a power outage.
Your channel is such a great find
Guys in the future our electromagnets will be water-cooled, braniac is making a breakthrough 😂
Ok this is definitely something I never imagined hearing: Watercooling and overclocking your magnet. LOL
Thanks for your efforts!
What is the steel used for the electromagnet!
What is the core material!
Are there lamimated sheets any where?
I sense a monster neodymium versus monster electromagnet battle coming up, maybe like King Kong versus Godzilla??
YES! more electromagnets!! That is pretty cool. I think you should give a microwave transformer a try, easy to get and you can cut out the secondary and put 2 primaries into it for more coils!
I second the AIO cooling for a future video.
I'd really like to see you make your own electromagnet, that is as strong as you can possibly (and safely) make it.
Some permanent magnets can also turn on/off by bend their flux in the same direction or opposite direction.(you need at least 2 of them with electromagnet material to make the magnetic force go in loop when turn opposite direction for turning off.)
Great video !
💡Stack an electromagnet and neodymium. (Epoxy a coil around the neodymium magnet.) You can use a pulse to temporarily cancel out the permanent magnet. Iron can also be used to focus the power just like the electromagnet in this video, just make the center part the neodymium magnet. 👍
Since they are designed to stick to metal, how much would a metal plate dissipate heat from the magnet? I am always wondering this looking at the door magnets at my school.
It would be interesting to see how high the field strength can go if you can supply a pulsed DC power to the electromagnet.
- the 8W magnet is average power, and just as with lasers and LED's - pulsing with a low duty cycle should give a high(er) peak-output power...
Playing with Power - Pulsed Power Push/Pull'er (or perhaps not, the iron core has a B-H curve, so it's possibly not reacting fast enough)
2*12V car batteries and a beefy relay (w. rev diode protection) controlled by a variable oscillator might be safer for your power-supply ;ø)
Looking forward to future videos on these pucks - btw, where did you buy them (and the Radiocode meter, etc. - links/info would be appreciated)
Interesting. May give it a thought, though back EMF and basically running a DC magnet as an AC magnet may get me in trouble :) But I will try running it on AC in a future video. Just to see what happens with heating, field strength etc. I am a total noob when it comes to electromagnets... The electromagnet was bought from Conrad Electronic.
@@brainiac75 AC is alternating current ;ø) - so the magnet will also be alternating its poles. Magnetic Hysteresis then becomes an issue (problem), as energy is spent turning the magnetic domains inside the iron/magnet. Less emitted field pr unit energy spent.
Pulsing the magnet with DC - ought to strengthen it, as the h-field moves up-down without having to rotate. Wikipedia has good illustrations of this. This should (I think - not 100% sure) strengthen the field when powered on, and still remain magnetic when power is off.
I could build you an electronic switching device for pulsed DC + tell you a bit more (I'm an electrical engineer + radio 'everything'). I live quite close to your favorite sweets-store, if you're interested :ø) - and I have some time on my hands, electrical components + equipment, and I'm curious what your Lake Shore Teslameter reports. (er også bidt af en magnet og deres mysterier)
When you change the polarity does the kilogauss value remains same?
It seems peculiar that you focus so much on wattage of an electromagnet. The magnetic flux you get is proportional to current times number of turns in the coil (at least until you reach magnetic saturation of the core). If you rebuild the graph at 4:35 with current as the x value, you'd get a pretty much linear plot. So, if you want power efficiency, you need to minimise the coil resistance. Use thicker wire gauge, and/or employ some radical cooling (dry ice or even liquid nitrogen).
because amperage is directly related to magnetix flux. how else can your clamp meter measure current accurately? 😉
good comment, cheers!
It is interesting what is the process of DIY making of permanent magnet with electricity.
Or fixing of existing one, which lost its properties.
What's the maximum length of wire that can be used to give the DC power? We want to use it like a switch for a setup to drop a ball from this magnet.
You ever do anything with saturable inductors and magnetic switching?
do you know of an small inexpensive 12vdc electromagnet like the one in the video that can be left turned on for longer than an hour? all the ones i see say 10 minutes or left or they over heat.
Just bolting a regular finned heatsink to the back of the electromagnet would help keep the temps down when overvolting the electromagnet. There is however a risk of burning out the windings if too much current is applied.
If you want to push the overvolting experiment further there's no reason you couldn't put the electromagnet in a simple waterbath, at least up to the top lip, since the windings are insulated and potted in resin. That would dissipate the heat quite well.
Congratulations ! This is one of the bether videos that a have seen !
The question is : If I need 8w of power or 8 joules by second of energy to get 400 N of pull , what kind of energy the permanent magnets need and where it receves this energy from?
It is almost sure the neodymium magnets receves a kind of energy from universe , then it is not so absurd to imagine a magnect mouter runing by itselfs .
Do a video comparing the capacity of moving wheght corps by eletromagnets and permanent magnets along the space. Please!
You should try to make halbach array out of neodymium, electro magnets, and super conducting magnets.
You can arrange them to concentrate the fields and make them even stronger or make them cancel out to "turn off" neodymium magnets.
I really enjoyed your video . I have a question , what is better in a marine environment Neodymium or Samarium cobalt ? How long do the coatings last on Neodymium magnets in a marine environment ? What about a comparison of the impact resistance ? what about the affect of direct tropical sun , heat + UV ?
If you could get your hands on different grades of samarium magnets, I'd be a subscriber forever
Good job on the video! It's interesting and educational but I respectfully take issue with your use of the word "overclocking". Electromagnets do not have clocks. Therefore, you cannot overclock them. You can over-power them, but not overclock them. Here is the definition of overclocking: "Overclocking is the action of increasing a component’s clock rate, running it at a higher speed than it was designed to run." It applies only to clocked devices such as microprocessors and some other types of computer chips. Keep up your awesome videos!
PS so if you traced the field around your electro magnetic field with iron filings would there be a node at each end of the flat cerface of the magnet like your test showed
Great content, infORMaTion!
Has the term "overclocking" become an accepted idiom for everything now regardless of whether there are any quartz crystals sending any clock pulses or not?
You should test electromagnet door locks. The ones commercial buildings use to lock their doors. Not a lot of pull force, but holding force is incredible.
Can you make a video about magnets slowly falling down when put near a copper or aluminium sheet? I have a small HDD magnet and experiment with this, but now I want to see what will happen with your more powerful and substantial magnet. will it fall slower?
These magnets don't mind so much being heating up. They are used in metal industry to lift e.g. large metal plates and iron beams. They are usually not activated for more than from a few seconds, to a few minutes at a time.
With 4 to 8 of these, just in sizes that are larger, you can lift lift metal plates for e.g. ship construction, that weights several tonnes.
I don't remember the pulling power of magnets of this kind, that has a diameter 4 to 5 times the size, but we are talking maybe a tonne per magnet.
But you always want to have twice as many magnets as needed. One, several of the magnets can be short circuited/defect, second, their max pulling power decreases radically, just by having dust in the environment.
Can you do levation with the electromagnet? like make different object levitate and how big of an object can you levitate?
How does this compare with the electromagnets currently being installed in the ITER experimental fusion reactor?
There's a lot of info for ITER - I'd be interested if you would check it out and do a comparison with it like you did with the Earth's field.
This is exactly what I need to do my experiments with a variety of stuff. But especially plant growth and cellular health. I need an affordable electromagnetic device that allows it to be variable and see the actual strength of the magnetic field or it’s frequency.
For this and your N40 magnet, I think the best video would be temperature vs magnetic flux density vs max load, with an overclocked electromagnet with a UPS, and cooled by either liquid nitrogen, liquid oxygen or water that is just above freezing point.
The magnetic bridging was interesting, first time I've seen it.
I'm curious about using this for an electromechanical sculpture. If you wanted to lift a block (containing a permanent magnet) above it, what would be the most efficient way to do so. For example, shape and size ratio of permanent magnet, bridging vs not, orientation of permanent magnet, Halbach array usage?
The most powerful magnetic fields are generated by compound coils, admittedly using super conductors.
If electric vehicle development is not to be limited by the availability of rare earth elements, then motors must use electromagnet field generation, rather than permanent neodymium magnetics.
Would enjoy electromagnetic stuff!
I bet Brainiac's dream vehicle is one of those magnetic cranes that we see at scrap yards. I can't wait till he'll eventually get one. 😁
nice, btw have you heard about vortex on the poles of a magnet, that you can see using CRT tv set
I do have some old videos where I put big neodymium magnets near a CRT TV. Think I did it lately in the video 'Monster magnet meets plasma ball'. You can see the field lines but I haven't noticed a vortex?
@@brainiac75 it's Ken L. Wheeler discovery (if i recall), on UA-cam as Theoria Apophasis, he has cool video magnetism and device to see magntic field, like magnetic film or ferrocell
If you want to try cooling the electromagnet with a PC AIO cooler, look for something with a pump that's not in the waterblock, I can't imagine it will pump very well if at all with an electromagnet stuck to it.
Got to it a little late, but awesome work as always!! I'd love to see if the magnet can handle more power without concern for heat, is there some sort of limit for how much you can safely pump in them?
What would be the effect of winding a coil around a permanent magnet core? To what extent would it add to or subtract from the permanent magnet force?
What about those on/off permanent magnets like in the bases for some car equipment. Are they the best of both worlds? Can you make such a "magnet" from neodymium magnet?