FREE ELECTRICITY - Kind of

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  • Опубликовано: 8 янв 2025

Комментарии • 25

  • @timh.2137
    @timh.2137 8 дней назад +1

    Your dad was definitely telling you a tall tail because what the man in the RV did was not illegal he "stole" nothing!

    • @aiyogarage
      @aiyogarage  8 дней назад

      @@timh.2137 would you mind explaining your argument further?

  • @n3qxc
    @n3qxc 10 дней назад +1

    if there is no usable power here, how can I light fluorescent lamps in my hand while standing under these powerlines? Your application testing was on the microscale considering the amount of current going thru the overhead lines to create huge magnetic fields. Ask yourself this question... why are those wires so freaking high in the air? And another anomaly is that you can dig the earth around the powerlines and never find an earthworm. As A teen, I experimented with hanging wires near the powerline towers in my back yard.... a 20 ft wire lifted to about 10 ft off the ground was able to produce 3 inch sparks, so yes thats allot of voltage, so take that voltage and feed it to a flyback transformer and see how much power you can achieve from the primary windings.... It's called impedance matching.... High resistance winding tied to a high impedance antenna coupled to a low impedance winding to transfer the high voltage to low voltage with more current. one day I'll make a video to prove this is usable power.

    • @aiyogarage
      @aiyogarage  10 дней назад

      Hey n3qxc, thank you for the comment.
      Yes, my testing was done on a micro scale to help demonstrate the concepts at play. I understand that the high voltage transmission lines are high in the air.. if you get any amount of conductor close enough to those lines you're going to get usable voltage and then some. The limitation I purposefully put on the example is that someone used extension cords strung across the ground.. so that the EMF induction would be limited and weak. Another aspect of the demonstration was to help the audience understand impedance and voltage drop.
      I don't see how a flyback transformer being implemented or impedance matching would be useful in this particular scenario.
      Thank you for sharing your passion with myself and the audience.

    • @n3qxc
      @n3qxc 10 дней назад +1

      @@aiyogarage impedance matching is KEY.... maximum power transfers with proper matching..... try 32 ohm speakers on your home stereo vs the 8 ohm that they were designed for.... same thing goes for antennas and transmitters..... dump 1kw into a 3000 ohm antenna and nothing gets transmitted.... I suspect the best idea would be to have a tuned tank circuit as your pickup coil.... tuned for 60 hz.... Extension cords on the ground may sound like a far fetched plan, but maybe there is some luck in the idea that each conductor is insulated from each other along with having a particular impedance due to capacitance created by parallel wires separated by insulation. Also .. back to the other guy with the video... charging the cap to near 800 vdc.... yeah it took some time, but the level of energy stored in that single charge could be useful once it's stepped down to a usable level. The reason the guy chose 4 ft height was to remain legal by considering it a fence wire as he inquired about putting up a fence and was told there would be no issues. So a fence with the top wire insulated from the poles would be a great collector. But even still... I dont see how it could be considered theft of service. This wouldn't have any loading effect on the overhead lines. There is more power lost in the corona discharge than anything. I love the purple glow of those insulators on a rainy night!

    • @aiyogarage
      @aiyogarage  10 дней назад

      @@n3qxc I understand that impedance matching has its place in RF and stereo installation, but in low frequency inductance, impedance matching would have negligible effects to the circuit. The critical variables would be distance to the lines, the amount of conductor strung under the lines, and the current flowing through the high voltage transfer lines.
      That is a good point about keeping the coaxial off the ground. I had forgotten that was apart of his approach for testing, was to identify it as a fence.

  • @kevinroberts781
    @kevinroberts781 10 дней назад +1

    But but but but but
    You right

    • @aiyogarage
      @aiyogarage  10 дней назад +1

      @@kevinroberts781 thank you

  • @nzkvack
    @nzkvack 11 дней назад +1

    You say what you're aiming to do is essentially make a transformer, but it looks like you have an antenna.
    A transformer would have two ends of each winding. You're measuring one end of the secondary "coil" but referencing your meter to the return side of the primary "coil."
    What happens when you put your meter across the secondary coil? (I.e. connect positive lead to one side of yiur wire and negative to the other.)

    • @aiyogarage
      @aiyogarage  11 дней назад

      @@nzkvack nothing happens. It will read 0 volts since there’s no difference in potential. It is a really weird problem to look at and experiment with. It’s what inspired me to make the video in the first place.

  • @kcgunesq
    @kcgunesq 11 дней назад +2

    I'm sure you have a lot more knowledge about this than do I, but wouldn't induction be transmitting the current and not the voltage, with the voltage simply being the result of the induced current interacting with the system impedance? Also, wouldn't you need to insure that you are inductively coupling at right angles to the magnetic field?

    • @aiyogarage
      @aiyogarage  11 дней назад +2

      @@kcgunesq great questions. The amount of current produced by the high voltage line will determine the strength of the EMF that gets induced as voltage on the “extension cords”. I experimented with a few different ways to couple the magnetic field. The biggest problem is that the high voltage transmission line is in a straight line and can’t be coiled that would optimize induction. It’s not an ideal scenario. That’s why the point of the video is to see if it’s possible/practical to try and get power this way. Thanks for the comment!

    • @bmanmcfly
      @bmanmcfly 10 дней назад

      This is a good question and difficult to frame in text form. Volts represent an EMF potential difference between 2 points. The voltage between the line and ground is going to be different from the voltage in the induced current on the second line that's going to relate to the voltage, distance, and other variables relating to that second circuit.
      I'm a bit too drunk to try and run the numbers at the moment, but it's not wrong to suggest that a useful amount of power could be extracted over time with that kind of setup. It is technically "stealing" power, but that's also representing power "lost" in transmission, but I suspect (again in my currently drunken state) that the levels of power that could be extracted might be enough to help charge a battery (know that you can charge a battery with very little voltage or current over a long enough time), but probably not enough to actively power a light bulb.

    • @aiyogarage
      @aiyogarage  10 дней назад

      @ sober up and re watch the video

  • @mortysmith8049
    @mortysmith8049 11 дней назад +1

    You clearly have a fascination for this, i'm not entirely sure what your goal is though other than to siphon energy from a source?
    Reason I ask, there are lots of other sources teaching how to induct such as the infamous Tesla coils. It was Tesla's (not that he was the first) life mission to be able to send wireless current to power homes, of course he failed at this as it's not possible, at least in a useful manner.
    With regards to your project, I understand I think you are attempting to replicate - however the system used isn't efficient. Windings is used in transformers, inductors etc. Have you thought about introducing this into your concept?
    If you desire accurate measurements you will need a clamp amp-meter. These are designed to measure amp from the EMF. Normally you put the clamp around a cable, but as you are measuring a high voltage source, the amp-meter will be influenced. This will be able to give you measurements at various distances away from the lines. From there you can work out exactly how close to the lines you would need your 'receiver' to collect electricity.
    Apologies if I'm teaching you to suck eggs (British expression!), equally if there is anything your unsure of fire away. I'm no expert though I am an electrician in the domestic sector :)
    (tbf though most sparks ive met know bugger all! haha)

    • @aiyogarage
      @aiyogarage  11 дней назад

      Hey Morty, thank you for the comment!
      My goal, as stated in the video, is to see if usable voltage is obtainable by running extension cords under high voltage transmission lines.
      I think you might have stopped the video a bit early, I do utilize windings and mention transformers towards the ending of the video.
      An amp clamp meter would be for measuring amperage.. I am not utilizing an amp meter as I am showing the voltage induction.
      Thank you for your input. Cheers.

    • @mortysmith8049
      @mortysmith8049 11 дней назад +1

      Ah yeh I missed that bit I'm afraid regarding the windings. In that case, have you tried stripping the cable you use to run parralel to the high voltage lines?
      The goal of the amp-meter is to determine the 'strength' of signal. Since amps and volts are connected via Ohms law you can work out what voltage you recieve. This can tell you how high or close to the HV you need your cables to induct your desired voltage.

    • @aiyogarage
      @aiyogarage  11 дней назад

      @@mortysmith8049 No worries Morty, I appreciate the interest in the topic.
      So I did mention the amperage draw for the "high voltage" lines during the video. The initial draw on the 28 AWG enamel wire is only 1 amp and the amperage draw on the insulated 18 AWG is 4 amps. I understand the fundamentals of OHMs law, but they would not be applicable to this low efficiency induction circuit. This would fall under faradays law which would be the following:
      ε = -N (dΦ/dt)
      Where:
      ε represents the induced electromotive force (EMF), measured in volts (V). This is the "voltage" generated by the changing magnetic field.
      N is the number of turns in the coil or loop of wire. If you have a coil with multiple loops, the induced EMF is multiplied by the number of loops.
      dΦ/dt represents the rate of change of magnetic flux, measured in Webers per second (Wb/s). This is how quickly the magnetic field passing through the loop is changing.

  • @cheako91155
    @cheako91155 12 дней назад

    You've done a poor job removing your meter's leds(sense wires) from the test, ruclips.net/video/0TTEFF0D8SA/видео.html

    • @aiyogarage
      @aiyogarage  12 дней назад

      @@cheako91155 I did my best to have my test LEADs cross perpendicular to the live voltage. They’re simple demonstrations to show a concept.

    • @mortysmith8049
      @mortysmith8049 11 дней назад +1

      I LOVE electroBOOM, he is hilarious!!

    • @mortysmith8049
      @mortysmith8049 11 дней назад

      @@aiyogarage check out electroBOOMS 'wand' that he made. It is the same concept in terms of receiving electricity via an EMF.

    • @aiyogarage
      @aiyogarage  11 дней назад

      @@mortysmith8049 I agree! He's a total hero of mine!