Dielectric Induction producing Ground Currents

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magnetic induction makes the world turn from Electric Motors to induction cougars but have you ever heard of dye electric induction dielectric induction is the electric counterpart of magnetic induction it is the working principle behind a capacitor while magnetic induction is based on changing current dielectric induction is based on a changing voltage so it is based on a changing dielectric field instead of a changing magnetic field and this has benefits for example with dielectric induction there is no lens law foreign [Music] and I'm open source researching Nikola Tesla's bifida pancake coil and his impulse electricity let me now explain and show you with two experiments how dielectric induction works this is a new chapter in my open source research I have now started researching current impulses that are made from capacitor discharges I will give a short overview of what is happening later in this video I will go deeper and deeper into detail I use the fast charge and discharge of a capacitor to produce both polarity current impulses whereby an inflow and an outflow of energy is created in the form of a displacement current to juice these two current impulses I need to quickly charge an ultra fast discharge a capacitor to get this discharge to be ultra fast I need a low resistance shortcut Nikola Tesla used a spar gap for this which is suited for a very high voltage discharges but I use parallel mosfets that can share the extremely high capacitor discharge currents my discharge voltage will thus be limited since parallel mosfets are limited in their maximum voltage so I need to get the voltage of the capacitor discharge higher to get a decent effect and I have designed a brand new circuit that uses resonance to increase this capacitor discharge voltage to be able to do all this I use bi-filer pancake coils that act as capacitor plates let me now explain some of the circuit Basics before going deeper into the experiments the mosfet switch will only discharge a relatively low voltage capacitor with low energy but this small discharge is part of a much higher resonant voltage of a special capacitor this special capacitor is only partly discharged and due to the much higher voltage the capacitor discharge energy is much higher this is because the energy increase in a capacitor is related to the square of the voltage when the voltage for example increases 10 times then the energy increases 10 times 10 is a hundred times this means a small change in voltage will have a much higher change in energy this is very interesting as this means the mosfets only deal with small amounts of energy while at the same time it sets much larger amounts of energy in motion let me now explain this further so here are two bifiler pancake coils if I hold them together they form the plates of a capacitor but at the same time they are still coils so I call this a coil capacitor which reminds me of Doc Brown's flux capacitor from the 1985 movie Back to the Future well Revelation a vision a picture in my head a picture of this flux capacitor this special capacitor can be DC charged by giving one of the plate coils a DC voltage while the other plate coil stays grounded if I then quickly discharge the voltage of that one plate by connecting it to ground this fast voltage change produces an intense or longitudinal displacement current as a result of the changing voltages the plate coils of the coil capacitor will become resonant there is more going on which I will explain later in this video now to increase the voltage difference between the plates I flip one of the plate coils over as a result the Dual resin coils will now be 180 degrees out of phase which increases the voltage difference of the coil capacitor plates here's the L2 L3 coil capacitor whereby L2 acts as one plate of a capacitor and L3 acts as the other plate of a capacitor and they together can charge up a dielectric field in between the blades now this is not only a capacitor but it's also a close coupled coil and if we take a closer look then you can see that L3 is clockwise from the inside to the outside while L2 is counter clockwise from the inside to the outside in other words I flipped the L3 coil over so it is counter rotating and this is done so that the resonant voltages of L2 and L3 will be opposing will be 180 degrees out of phase which means that when L2 reaches its positive maximum the L3 will reach its negative maximum this will be the zero line so we've got a positive and a negative maximum which will have a very large voltage difference between them and this voltage difference is creating a dielectric field which charges up the coil capacitor so here the inside rims are open ended and that is where the resonance takes place and the outside rims are grounded on Earth but L2 has a capacitor through which it is grounded to Earth and this capacitor is causing L2 to have a DC offset but it is not constant this capacitor is being charged up and discharged so we have a charge up and a discharge as this is the zero voltage and here is a negative voltage and this discharge is a very very fast causing a very strong displacement current between those coil plates now to use that displacement current I have created parallel capacitors over them so here is a small capacitor parallel over the bifida coil and here is a large parallel capacitor over the L3 coil and this causes the L3 parallel resonance to have a very large impedance and that large impedance causes the displacement to not be able to flow and it more or less creates a vacuum in that capacitor and that vacuum is balanced out by the Earth ground which provides the displacement current into the L3 plate coil and that makes it Amplified in its resonant energy so there is a lot more voltage and current in L3 than would be expected now let me show you step by step how this works with my new circuit first let's take a look at how I charge and discharge the small capacitor to start you need a DC power supply a mosfet switch a coil an ultra fast diode and a small capacitor this is the basic circuit we've got a positive and a negative power supply DC of which the positive DC is Earth grounded we have a switch in Orange we have a diode we have a coil L1 and we have a C1 capacitor of two nanofarads if the switch is closed then C1 is shorted out but the magnetic field of L1 will build up due to the supply of voltage thus it will produce a magnetic field like this red spiral that means there is energy in the fields around that coil as long as that switch is closed when the switch is turned off again the coil will shortly become resonant but only for a quarter wave and it will charge up the capacitor parallel to the mosfet switch with the negative voltage dielectric Fuel and that is the first current impulse which is relatively slow now the switch is opened the orange one is not conducting anymore now l1's magnetic field has no right to exist anymore so that field energy will transform due to Resonance so it will produce a negative voltage drop which charges up the C1 capacitor with a negative voltage so that L1 Powers up that C1 with a dielectric field and once C1 is charged we've got a stable situation again there will be no change to prevent this coil and capacitor from staying resonant a diode is placed between the coil and the capacitor this diode prevents the capacitor from discharging back into the coil so it needs to be very fast so the resonance already stops after a quarter wave whereby the voltage in the capacitor stays negative so that voltage would continue to be negative on C1 if the mosfet switch is now turn on again this capacitor will be shorted out and discharged through the mosfet switch so now this switch is closed again the Orange Line conducts again and will charge the coil up but more importantly C1 is shorted out through that switch so the voltage over C1 drops to zero because it was a negative voltage and now it will be zero volts again equal to Earth ground this is the second current impulse which is much faster due to the absence of inductance the capacitor discharge will produce very high currents through the switch but luckily only for a very short amount of time so if we open and close the switch we will produce what is called a square wave and it actually isn't quite a square wave because the charging of C1 this red part is dependent on the resonant frequency of L1 and C1 which will be a quarter wave resonance so there's a quarter wave of resonance which is a current impulse and that is a little bit slower than the discharge because the discharge happens through this circuit which is a short circuit which is very low resistance and very small inductance it is a straight discharge and it is very rapid so this discharge is much faster than the charge the charge time can be 700 nanoseconds depending on how big the inductance of L1 is and the capacity of C1 but the discharge will be much quicker it only takes around 60 nanoseconds that means the capacitor discharges in 60 billionth of a second and that's really fast the result is a very rapid change in voltage in a very small amount of time which we will use for dielectric induction as this fast change in voltage creates the strong longitudinal displacement currents since the charge speed of the capacitor is slower than the discharge speed it means during the discharge there is more energy flowing into than that air is Flowing out of the conductor during the charge of the capacitor let's take a look at this charge and discharge speed in the first experiment here are my parallel mosfets so these are two stacked mosfets they are matched in their gate Source threshold voltage to be able to switch on and off simultaneously this is important as they need to share the high current load on that PCB I have soldered the capacitors three times 330 picofarads per board so in total almost two nanofarads of capacity this is the coil L1 it is a speaker wire coil and it is wired unifiler so the two windings are joined together at the start and the end of the coil making a single winding here is the power supply it's three microfarads capacitor parallel to the power supply because it will deliver the currents that will charge up the coil with the magnetic field it is grounded on the positive voltage so that's the Earth ground and here is the diode in between the L1 coil and the mosfet switch and the capacitors I will probe the capacitor at the source of the mosfet so this will read the voltages of that capacitor I'll now turn the system on I'm at a frequency of 70 kilo cycles per second if you now look at the scope the green line is the voltage probe with a setting of 50 volts per Division and underneath in blue purple is the square wave that drives the mosfets simultaneously will now increase the power supply and we will see the square wave being produced as you can see the voltage is charged up to a negative value so we have a negative voltage in that capacitor that is being charged and discharged 250 volts well this is a beautiful signal right now the power supply delivers 0.47 amps at 14.6 volts I'll make a screenshot turn the system off first we're going to take a look at the charge so this is the charge you might be a little bit confused because it's going down but it is a negative voltage so I have now set this to 200 nanoseconds per division I'll turn on the cursor I'll set one marker here where it starts charging and I'll set one marker around here where it has reached its charge we can see now in the bottom right corner that delta T is 654 nanoseconds so that is the amount of time it takes to charge up this capacitor of nearly two nanofarads to a voltage of around 250 volts now I am going to look at the discharge and the discharge is through the mosfets the parallel mosfets and you might already be able to see it it is much faster I'm now at a time scale of 20 nanoseconds let's go even further why not so now the start point in the end point is a little bit more vague I would say here it is discharged and here it starts charging so that measures out to be around 60 nanoseconds in discharge time so that is 10 times as fast discharging than it is charging now a high frequency voltage Square wave of several hundred volts is produced whereby the charging of the capacitor to a negative voltage is slower than the discharging of the capacitor back to ground voltage this means that the biggest displacement current will occur during the discharge of the negative voltage back to ground so to be clear these rapid unipolar changes in voltage are current impulses and these current impulses create unipolar displacement currents which means there is an energy movement in a single Direction into or out of the conductor I have made a short video that explains this let's take a look at it this is a capacitor which has two plates when the capacitor plates have different voltages a dielectric field exists between the plates which holds the electric charge energy when a shortcut is created with a wire over the plates the non-conventional real magnetic current flows from the negative plate to the positive plate at the same time to close the circuit a dielectric displacement current flows from the positive plate to the negative plate through the dielectric material between the plates together these two different currents close the circuit what is important to realize is that when the negative plate suddenly becomes positive the energy flows into the plate from the ambient medium this is the coil capacitor it is made of two bifiler pancake coils there are closely stacked together and I've cast them in epoxy because that is a good dielectric and holds them in place as you can see it is red on this side and it is red on this side and that is because one of the coils is flipped over that makes it out of phase let me now measure the capacity of this coil capacitor and the inductance of the two coils I have now connected it to the outside rims of both by file coils and I'm measuring at a frequency of 100 kilo cycles per second and this gives us 560 picofarads of capacity between these two by final coils I have now connected it to one coil on the outside the inside rim and now measure the inductance I'm now measuring 302.4 microenries for the L3 coil now I'm gonna connect up the other coil L2 outside and inside rim and measure its inductance and this one is 310.2 micro henries the second experiment I will now place the coil capacitor in parallel with the C1 Square wave capacitor the two plate coils are completely identical and when coupled they form a capacitor of around 550 picofarads this coil capacitor is very special because it is a capacitor and a coil at the same time and space now I have extended the capacitor plates of C1 Pi L2 and L3 which together is the coil capacitor so this plate is extended by L2 and that plate is extended by L3 so these coils which are pancake coils are actually acting as capacitor plates which are parallel to this C1 capacitor this means that C1 now is a little bit bigger in capacity by adding those plates so L2 and L3 will also be charged and discharged and because there is field energy being charged and discharged here these coils will be able to become resonant the resonance is used to not only raise the voltage but also to increase the currents but to do this at a low speed we need to tune the resonance down by adding parallel capacity over L2 and L3 so here is a capacitor parallel to its primary L2 coil is a C2 tuning capacitor this capacitor will tune the resonant frequency of L2 giving plenty of resonant voltages on the inside rim of the plate coil thus the characteristic impedance will be tuned to the high resonant voltage side and a low resonant current and here is also a capacitor the second plate of the coil capacitor is called the L3 secondary coil it is Earth grounded on the outside rim and again parallel to the secondary L3 coil is the C3 tuning capacitor which is larger and it will drastically increase the impedance of the l3c3 parallel resonance which is important for this to work more on this later so now we have a coil capacitor that will become resonant for clarity I will give a DOT here and a DOT there an adult here to clarify the inside rims and the outside rims of the coils now L3 is grounded with its outside rim on Earth ground now C1 is two nanofarads just like before and C2 will be equal in size also two nanofarads but C3 will be a times larger 16 nanofarads and still these coils will have the same resonance frequency now how can it be first of all they are close coupled so they have mutual capacity but also Mutual inductance which means that their magnetic fields are entangled and this C2 L2 parallel resonance will want to go in a very high frequency due to the relatively small capacitor and the c3l3 parallel resonance will want to get to much lower resonant frequency because that 60 nanofarads takes a lot more time to charge up but we can use harmonics of these frequencies and tune it to a much lower frequency whereby the C3 is at a sub-harmonic of C2 let's take a look at the waveforms L3 and we take a look at the waveform of which is three times higher so now in this period of time instead of one wave now we have three waves one two three so this is its third harmonic it has a frequency three times as high as L3 one wave two wave three waves while L3 only has one wave so this is the third harmonic whereby the waveform perfectly fits inside of L3 now this means that the L3 C3 resonance capacitor and coil has a very large impedance due to its parallel resonance compared to L2 C2 and that is very important because when that switch is closed and C1 is being discharged by the shortcut the same will happen here with L2 and L3 these act as capacitor plates and they they want to discharge but they are also resonant and this will hinder due to its large impedance a sudden change in voltage which wants to happen through the shortcut so that large impedance hinders that voltage change and creates an imbalance which will need balancing out and it will be balanced out by Earth ground in theory this will change the characteristic impedance of L3 C3 towards favoring High resonant currents with lower resonant voltages but this will not hold up in practice not only the current but also the voltage will be high and that is truly extraordinary as the energy is coming from somewhere else than the power supply now Earth ground will produce a displacement current into that resonance system of L3 and C3 to balance out that energy vacuum and by doing so it will increase the resonant energy of L3 and C3 so we now have an influx of energy and that is a displacement current that is feeding that resonance system of L3 and C3 which increases the voltage and increases the resonant current so the coil capacitor is placed in parallel with a small C1 capacitor the C1 voltage Square wave which we have seen in the first experiment will now also charge and discharge the L2 L3 coil capacitor so the L1 will charge up the coil capacitor and the mosfet switch will discharge the coil capacitor and in this charge and discharge process the coil capacitor will become resonant the coil capacitor will not be fully discharged but the energy displacement in the field will be much larger since the voltage is so much higher from being resonant okay I have now connected the coil capacitor so the two coils which form the capacitor and I placed the L1 coil to the side because I do not want magnetic coupling here I want to show you dielectric induction parallel to the L2 coil is this capacitor which is equal in size to the capacitor which is in parallel with the mosfet switch so 6 times 330 picofarads makes 1980 picofarads near two nanofarads of capacity the L3 coil is grounded on the outside rim and I have not connected the capacitor to the inside rim of L3 so it's free to resonate it has low impedance I'm now going to show you the voltage sign of the L2 with the yellow Probe on the inside rim of L2 which is resonant and the green probe will be on the Square wave of the C1 capacitor I will now turn the system on and show you the oscilloscope the system is now turned on and the power supply delivers a current of 0.85 amps at 25.9 volts I made a still shot of the scope so it can turn the system off again and we see in yellow the voltage of L2 let me turn off the green which is the voltage of the C1 capacitor so this is the voltage of the inside rim of the resonant L2 with its parallel capacitor of nearly two nanofarads in its series capacitor of nearly 2 nanofarads as you can see it is now at a sub-harmonic of three octaves below because we have three sine waves in total per period so here is one period and the blue on and off of the mosfet switch we can count this is the low one two three periods per period of the mosfet switch so this would be driven best at three octaves higher which would be 3 times 55 kilo cycles per second but I do this specifically it needs to be a odd harmonic because we're charging and discharging the capacitor so here is the discharge and this is where the mosfet is being turned on and it shorts out the capacitor so it creates this sudden shift in voltage and this balances the Resonance of L2 to be grounded on Earth ground so it is now higher and then here is the charge when the mosfets are turned off L1 produces the impulse and it charges up that C1 capacitor and then it stays charged and the L2 resonance will have a DC offset so now it is ringing at a DC offset of that negative charge of that capacitor let me clarify that by introducing the voltage on the source of the mosfet so this is the voltage of the parallel capacitor on the mosfet C1 it is zero volts then it is charged up and then it rings along with the Resonance of L2 and then it is discharged again so the charge voltage looks higher it is one two three four almost five hundred volts negative while the discharge is only one two three hundred volts this is because that capacitor becomes resonant with the L2 coil so L2 is now both series and parallel resonant it is series resonant with C1 and it is parallel resonant with C2 and both capacitors are equal in size so I now connected the tuning capacitor to the L3 plate coil and this creates a large impedance because the capacity is much bigger than the L2 capacitor C2 is two nanofarads but C3 is 25.3 nanofarads which is much larger and gives a much higher impedance to L3 so it resists the change in energy so I would expect to have a large current in L3 but not a high voltage due to the high capacity let me again turn the system on and here is the signal okay the system is now still at the same power level the frequency I tuned it to 55.14 kilo cycles per second which is almost the same as before in yellow the L2 inside rim and L3 inside Rim is now in Orange both channels have a 200 volts per division now what you can see is that L2 does not show a perfect sine wave and it is a little bit wobbly in Orange we have a voltage of 793.65 volts Peak to Peak and that is exceptional high for a capacity that is so large we have 25.3 nanofarads parallel to 2l3 so how can that be so high the energy must be coming from somewhere anomaly what was to be expected is that due to the increased capacity of C3 the resonant voltage of the L3 secondary would be much lower but instead it is still relatively High there isn't significant increase in energy in the resonance L3 and C3 the source of this energy is the earth ground let me show you this with a current probe so this is my current probe it's a pintech b8655 which is 500 kilo cycles per second rated and I'll put it on the 200 millivolt per amp setting and the arrow will Point towards the coil and I'll hook it up to the L3 inside Rim like so now the probe is set to a AC measurement so let's take a look at the current in that L3 coil I'll turn the system on again so now we see the current of the inside rim of L3 and it shows a current of 6.6248 amps Peak to Peak what you can also see is that it is not a perfect sine wave it is a little wobbly to say the least so now in yellow we have the L2 voltage and you might see some similarities on the wobbly current of L3 and the wobbly voltage of L2 there seems to be a correlation between the fluctuations in both those measurements and this indicates to me that this is actually not a magnetic current that I'm measuring in L3 but actually a displacement current which is related to the changes in voltage of that coil capacitor now the question stays where does that energy come from and therefore I will now probe the Earth ground now to be clear this whole resonance system is only grounded on one point and that is this Earth wire and I've now put my current clamp on the earth wire so the Earth ground is being probed for the current I removed all other Earth grounds from the system and they're all connected to that single wire and now we're gonna take a look at the current through that Earth ground wire which should be zero but it isn't that's where the energy is Flowing let's take a look at the oscilloscope I use the same power settings as before so this is the current of the ground which is not supposed to be flowing but it is and if we take a look at L3 and compare it then we can see that it has a different frequency this peak is one and this peak is one but we have one two three times the frequency of the single L3 sine wave and that corresponds with the frequency of L2 by itself now let's take a look at L2 and compare it with the current again and now L2 in yellow comes in we can see here is the discharge when the mosfet is conducting and here is the charge when the mosfet opens up the switch so between the charge and the discharge there is one and a half wave and again one and a half wave so that corresponds with that frequency of the L1 coil which I tuned before to the third sub octave so switch is turned on switch is turned off and we have three oscillations in that period and that is the ground current which is very odd to me because the L2 isn't at that frequency anymore so where does that frequency come from now this is rather unique and it is caused by the Fast Change in voltage of the L2 plate the L3 plate is close coupled to L2 and wants to react to this voltage change but due to its high impedance it can't so there is a vacuum of energy created which is a form of implosion and nature response to this unbalance by providing energy and this energy vacuum is balanced out by Earth ground which supplies the needed displacement current energy into L3 and C3 which amplifies the resonant current and voltages of L3 thus an energy pump is created which draws in energy from the surrounding ambient medium the Earth conclusion so we have an unbalanced capacitor by giving both plates unequal amounts of surface area whereby the small plate changes voltage very rapidly while the other large plate resists this voltage change because it has a higher impedance and the unbalance which this creates is balanced out by Nature providing the needed extra energy to create balance in the form of an inflow of displacement current so by using die electric induction large displacement currents are created that create an inflow of energy into the resonance system which produces High resonant currents and voltages dielectric induction Works without using magnetic induction so there is no lens law which is a great benefit so this is an example of how plate coils can be used to create resonance by using dielectric induction and not only that it creates an inflow of energy from outside of the system and this is the next chapter in my research the high voltage Square wave are actually two current impulses that induce positive and negative displacement currents if you want to support my open source research you can do so by leaving a donation or my PayPal account which is listed below thank you for watching and see you next time

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Channel: Master Ivo

Views: 98,329

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Keywords: induction, ground, current, dielectric, field, magnetic, master ivo, tesla, nikola, steinmetz, lecture, education, electricity, free energy, explanation, tesla coil

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Length: 44min 26sec (2666 seconds)

Published: Fri Jun 30 2023