Concepts of "OU" devices

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Vidura posted this 27 November 2022

As promised I will import this thread from the backup forum. In first place I want to give credit and express my gratitude to Sergei Deyna, a great Researcher from Russia. He has made a huge number of experiments in diverse areas of physics, and published many papers from which I have used some parts for posting in the forums with his kind permission.

In this thread we will have a look on some basic concepts and principles of AU devices. It is well known from Newtons theory about thermodynamics, that energy cannot be created or destroyed. But it can be transformed in different forms, and it can be collected for our purposes. So if we want to understand, or replicate, or design such a machine, in first place we have to ask two key questions:

1.) Where does the surplus energy come from?

2.)How does this happen, what are the involved physical principles?

 

Let's take as an example a well-known and accepted AU machine, the heat pump. I think most of you know about this device, which is widely implemented in refrigerators, heating systems, or reversible air-conditioning devices which can operate in both directions. It is well known by engineers, that a modern heat pump can have a COP up to 6( for heating systems with liquid medium temperature exchanger's) . That means for one unit electric power , six units of thermal energy can be obtained. Refrigerators use the very same system, but the obtained heat energy is just wasted without using it.

For the first question it is quite obvious that the extra energy comes from the thermal background energy of the environment (air, water, earth ).

The second question is also not very difficult if someone has some basic information about thermodynamics.

Anyway a detailed analysis will help us for better understanding and give some inspiration for other less known and accepted machines.

We have two main parameters, temperature and pressure.

Under normal circumstances they will have proportional relationship, any increase in pressure will rise the temperature and vice versa.

This relates to a closed system, which does not interchange Energy with the environment, and is also called an adiabatic process. To get a non-adiabatic process, which is of our interest, some specific conditions have to be present. Of course the temperature exchangers on the hot and cold side are required in hardware, as well as a closed circuit filled with a medium. It can be any gas in our case, but for better performance special refrigerant is used, which will experience a change of its state of aggregate from gas to liquid and back, which increases the heat transfer by orders of magnitude. Then we need to create a difference of pressure inside the circuit,  usually a compressor will provide the propulsion of the medium, and a release valve will help to divide the circuit into two zones of different pressure. A heat exchanger will be placed in in each zone of pressure.

This setup produces a shift of phase between pressure and temperature, and this is what is making the process non adiabatic, and allows to transfer heat energy from a lower temperature level to a higher one, making possible all the before mentioned practical implementations of this devices.

 

Now let's make an analysis of another thermodynamic device:

There is another way to create a heat pump without a compressor and refrigerant, in which the working fluid itself (for example, gas) becomes a source of temperature differences and, under certain conditions, is capable of performing mechanical work itself.

Since all thermal phenomena are reversible, then by supplying thermal energy to the machine, mechanical work can be obtained at the output. Such devices are usually called thermoacoustic motors.

The simplest thermoacoustic machine consists of a resonator in the form of a tube and a regenerator made of a porous material, on the sides of which a temperature difference is created. In the simplest case, the regenerator can be a burner inserted inside the resonator (in the form of a vertically mounted glass tube) or a heated metal porous mesh, as shown in the figure below. 

The optimal position of the flame is in the centre of the resonator, and the grid is approximately L / 4 distance from the lower end.

The heat engine or thermoacoustic machine is of special interest for us, as it will help us to understand and draw analogy to various types of electrical self-feeding devices, which uses the principles of resonance.

The theory of the effect under consideration was created by Rayleigh in 1878, in which he discovered the principle that currently underlies all thermoacoustic.

And so, we will compare the principles of operation of the heat pump (generator) and the heat engine:

 

1) if heat is transferred to the gas at the moment of maximum rarefaction and/or heat is taken away at the moment of maximum compression , then this stimulates the transfer of heat energy.

 

The thermodynamic phenomenon underlying thermoacoustic is reversible.

 

The principle of operation of a heat engine :

2) if heat is transferred to the gas at the moment of maximum compression and / or heat is taken away at the moment of maximum rarefaction, then this stimulates gas oscillations.

 

The thermoacoustic device can be based on two modes of  resonant oscillations, on standing waves or on traveling waves.

Here  standing wave device with the graphs for displacement, pressure and temperature:

 

Below we can see a travelling wave device.

And in this video you can see a traveling wave resonator, which is used to produce electric energy from the vibrations of an attached magnet:

An interesting point is that a standing wave will be established in a half-wave resonator, when pressure and displacement will perform harmonic oscillations. But in addition to pressure and displacement, the working fluid in the resonator also changes the temperature according to a sinusoidal law, especially in the pressure antinodes. Depending on whether the ends of the resonator are open or closed, the pressure antinodes will be located either in the centre of the resonator or at its ends, respectively. The illustration below shows diagrams in which pressure antinodes are visible at the edges and in the centre.

The hydraulic RAM pump is an example for a self-oscillating device, that uses a non-compressible medium to collect energy from a low level source and shift it to a higher one, more suitable for our purposes. There are many different ways to get free energy. Some relative simple to do, others much more complex. Why there are such few replications of the BTG devices from Ruslan, Akula, Kapanazde to name only a few? Are we all that silly  that we are not able to replicate? I don't think so, first there are needed skills of various types to build them, and second, and this is the most important cause, we do not completely understand the theories and underlying principles. And this is the main purpose of this thread, to fill the gaps of knowledge.

The reason for analysing the thermodynamic devices is that they will help to draw analogy to the electrical machines, and understand intuitively what's going on.(left brain hemisphere). Thinking about the inconvenience with certain areas of textbook physics, I decided to decline to open disputes against them, as this would only lead to unfruitful discussion with those who are not ready to abandon the obsolete ideas. Instead I will simply trying to show alternative ways of explanations, and try to fit all together in a broader view.

In continuation we will begin to look for the analogies to the electric generators which are based on the principles of resonance for energy collection.

 

 

 

 

Vidura

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Vidura posted this 27 November 2022

As promised I will import this thread from the backup forum. In first place I want to give credit and express my gratitude to Sergei Deyna, a great Researcher from Russia. He has made a huge number of experiments in diverse areas of physics, and published many papers from which I have used some parts for posting in the forums with his kind permission.

In this thread we will have a look on some basic concepts and principles of AU devices. It is well known from Newtons theory about thermodynamics, that energy cannot be created or destroyed. But it can be transformed in different forms, and it can be collected for our purposes. So if we want to understand, or replicate, or design such a machine, in first place we have to ask two key questions:

1.) Where does the surplus energy come from?

2.)How does this happen, what are the involved physical principles?

 

Let's take as an example a well-known and accepted AU machine, the heat pump. I think most of you know about this device, which is widely implemented in refrigerators, heating systems, or reversible air-conditioning devices which can operate in both directions. It is well known by engineers, that a modern heat pump can have a COP up to 6( for heating systems with liquid medium temperature exchanger's) . That means for one unit electric power , six units of thermal energy can be obtained. Refrigerators use the very same system, but the obtained heat energy is just wasted without using it.

For the first question it is quite obvious that the extra energy comes from the thermal background energy of the environment (air, water, earth ).

The second question is also not very difficult if someone has some basic information about thermodynamics.

Anyway a detailed analysis will help us for better understanding and give some inspiration for other less known and accepted machines.

We have two main parameters, temperature and pressure.

Under normal circumstances they will have proportional relationship, any increase in pressure will rise the temperature and vice versa.

This relates to a closed system, which does not interchange Energy with the environment, and is also called an adiabatic process. To get a non-adiabatic process, which is of our interest, some specific conditions have to be present. Of course the temperature exchangers on the hot and cold side are required in hardware, as well as a closed circuit filled with a medium. It can be any gas in our case, but for better performance special refrigerant is used, which will experience a change of its state of aggregate from gas to liquid and back, which increases the heat transfer by orders of magnitude. Then we need to create a difference of pressure inside the circuit,  usually a compressor will provide the propulsion of the medium, and a release valve will help to divide the circuit into two zones of different pressure. A heat exchanger will be placed in in each zone of pressure.

This setup produces a shift of phase between pressure and temperature, and this is what is making the process non adiabatic, and allows to transfer heat energy from a lower temperature level to a higher one, making possible all the before mentioned practical implementations of this devices.

 

Now let's make an analysis of another thermodynamic device:

There is another way to create a heat pump without a compressor and refrigerant, in which the working fluid itself (for example, gas) becomes a source of temperature differences and, under certain conditions, is capable of performing mechanical work itself.

Since all thermal phenomena are reversible, then by supplying thermal energy to the machine, mechanical work can be obtained at the output. Such devices are usually called thermoacoustic motors.

The simplest thermoacoustic machine consists of a resonator in the form of a tube and a regenerator made of a porous material, on the sides of which a temperature difference is created. In the simplest case, the regenerator can be a burner inserted inside the resonator (in the form of a vertically mounted glass tube) or a heated metal porous mesh, as shown in the figure below. 

The optimal position of the flame is in the centre of the resonator, and the grid is approximately L / 4 distance from the lower end.

The heat engine or thermoacoustic machine is of special interest for us, as it will help us to understand and draw analogy to various types of electrical self-feeding devices, which uses the principles of resonance.

The theory of the effect under consideration was created by Rayleigh in 1878, in which he discovered the principle that currently underlies all thermoacoustic.

And so, we will compare the principles of operation of the heat pump (generator) and the heat engine:

 

1) if heat is transferred to the gas at the moment of maximum rarefaction and/or heat is taken away at the moment of maximum compression , then this stimulates the transfer of heat energy.

 

The thermodynamic phenomenon underlying thermoacoustic is reversible.

 

The principle of operation of a heat engine :

2) if heat is transferred to the gas at the moment of maximum compression and / or heat is taken away at the moment of maximum rarefaction, then this stimulates gas oscillations.

 

The thermoacoustic device can be based on two modes of  resonant oscillations, on standing waves or on traveling waves.

Here  standing wave device with the graphs for displacement, pressure and temperature:

 

Below we can see a travelling wave device.

And in this video you can see a traveling wave resonator, which is used to produce electric energy from the vibrations of an attached magnet:

An interesting point is that a standing wave will be established in a half-wave resonator, when pressure and displacement will perform harmonic oscillations. But in addition to pressure and displacement, the working fluid in the resonator also changes the temperature according to a sinusoidal law, especially in the pressure antinodes. Depending on whether the ends of the resonator are open or closed, the pressure antinodes will be located either in the centre of the resonator or at its ends, respectively. The illustration below shows diagrams in which pressure antinodes are visible at the edges and in the centre.

The hydraulic RAM pump is an example for a self-oscillating device, that uses a non-compressible medium to collect energy from a low level source and shift it to a higher one, more suitable for our purposes. There are many different ways to get free energy. Some relative simple to do, others much more complex. Why there are such few replications of the BTG devices from Ruslan, Akula, Kapanazde to name only a few? Are we all that silly  that we are not able to replicate? I don't think so, first there are needed skills of various types to build them, and second, and this is the most important cause, we do not completely understand the theories and underlying principles. And this is the main purpose of this thread, to fill the gaps of knowledge.

The reason for analysing the thermodynamic devices is that they will help to draw analogy to the electrical machines, and understand intuitively what's going on.(left brain hemisphere). Thinking about the inconvenience with certain areas of textbook physics, I decided to decline to open disputes against them, as this would only lead to unfruitful discussion with those who are not ready to abandon the obsolete ideas. Instead I will simply trying to show alternative ways of explanations, and try to fit all together in a broader view.

In continuation we will begin to look for the analogies to the electric generators which are based on the principles of resonance for energy collection.

 

 

 

 

Vidura

Vidura posted this 07 January 2023

In this post I will summarize the Idea and proposed implementation in the BTG. 

1. A resonant circuit at a relative low frequency is used as principal resonator, and would be the equivalent of the thermoacoustic resonant conduit.

2. A high voltage source provides the potential needed for the atomic excitation. This has a low energetic cost, provided that the source dipole, or secondary resonator(TC, Kacher)is not depleted.

3. The antenna coil would be the equivalent of the hot heat-exchanger. The Drossel inductor might have the purpose to block the dielectric displacement wave and let pass only potential(?).

4. The bifilar section of the principal resonator is intended to produce a phase shift between the anti-node of potential and the associated atomic excitation. It is the analogue of the stack, or regenerator in thermoacoustic.

5. The long earth-ground wire has the purpose to dissipate the radiation of the excited atoms, when they are returning to their low energy state. It is most important to tune the oscillations of the ground current with the principal resonator, it has to be part of the oscillatory circuit. It would be the equivalent of the cold heat-exchanger, and cold spot in thermoacoustic.

If this 5 components are properly set up with the correct parameters, there should appear an undampened oscillation in the principal resonator by a positive feedback in each cycle. Then some amount of the gain can be extracted by

6.the removal coil or similar means for a regulated extraction of  usable energy and provide the feedback for the needed input power. 

Vidura

Munny posted this 14 December 2022

Opposing magnetic fields open a whole new path of discovery.

Vidura posted this 07 January 2023

The important question where does the "firewood" come from:

The statement that a high voltage cannot excite atoms to energy levels higher than the energy it supplies itself is certainly true for a closed system, an adiabatic process without interchange with the environment. Under normal conditions the high voltage and the level of excitement will be simultaneous, in phase. As the atom acquires a higher energy level it absorbs photons of certain range from the environment(or background radiation) to compensate  for the stability of the atom. when the emf decreases, it emits them again. The process becomes non-adiabatic when a phase shift between the applied EMF and the level of excitement is achieved, then the system becomes opened for an exchange of energy with the background radiation. The absorption of this radiation would become possible beyond the  energy level of applied EMF, as the maximum of atomic excitement would be time differing from the former. Similar to the phase shift of temperature and pressure in thermoacoustic.

 I will remind you that for the moment it is a hypothesis, but if it is possible to proof the effects experimentally, it might be considered as a valid theory.

Vidura

Vidura posted this 07 January 2023

A little bit profound view of the proposed principle: It shall be remarked that I try to follow classic physics  and conventions as far as possible.  Let's consider a conductor in solid state of aggregation: Composed by atoms whose positive charged nuclei are bound in the molecular lattice and  the negative charged electrons hold in their orbits by the nuclear forces. A conductive material differs from the dielectric in the availability of valence electrons, which can be dislocated by a minimal emf applied to the conductor, and move then freely across the molecular structures. The free electrons are repelling each other cause of the coulomb force but they can't leave the conductor under normal conditions. For this reason they behave similar to a gas and can be compressed or rarefied by the forces of an applied EMF. At higher energy levels beside the already free valence electrons  also the other electrons in orbits closer to the nuclei are excited and rise to higher orbits, and get eventually dislocated when the atoms reach the ionisation level. In this case they will add to the displacement of those already present. We could conclude, that the energetic level of excitement increases in proportion to the distance between the nuclei and the electrons and vice versa. As the EMF, or other source of external energy(radiation, heat for example) diminishes, the electrons will return to their lower energy state occupying an orbit closer to the nuclei, while emitting a photon of the matching wavelength. When such a photon impacts on a nearby object of the same material it would likely be absorbed rising it's excitement level, which under the right conditions(resonance) would lead to the appearance of an EMF in this separate conductor. In this case a phase shift between the two EMF should be observed, not at 180º like in the case of capacitive coupling, but 90º  because when the potential of the emitting conductor falls, the one of the receiver would rise simultaneously. If it is possible by such means to delay the level of excitement relative to the potential, we could assume that there are possibilities to build "charge resonators" powered by the background radiation of the environment, as the electrodynamic analogues of the thermoacoustic resonators.   

One more comparison with thermodynamics: At a surficial view we could think that the heat in a heat pump comes from the energy applied to the compressor. But also in this case the phase shift between pressure and temperature makes it clear that this is not the case. The energy of the compressor rises the gas pressure , concentrating the already present thermal energy of the medium. It would be including be possible to recover an important amount of the prime mover energy at the release valve(replacing it by a turbine for ex.) without affecting the level shifting of temperature. Also the COP of this devices makes it clear, that the  heat energy does not come from the compressor, unless the small fraction of its losses.

An argument for a similar process in atomic excitation by means of an EMF: The excitation would be caused by coulomb forces acting upon the elementary charges which composes the atoms. For this process no current flow is required and should be inhibited by the layout of the system(open circuit).

If phase shift is possible, the absorption of background energy would happen at a different time when the potential is not at its maximum value.

Vidura

Vidura posted this 27 November 2022

Almost half a century later in 1959 the laser was discovered, based on the very same principals of quantum mechanics.

 

In the following extract  we can find some most interesting details:

 

An electron in an atom can absorb energy from light (photons) or heat (phonons) only if there is a transition between energy levels that matches the energy carried by the photon or phonon. For light, this means that any given transition will only absorb one particular wavelength of light. Photons with the correct wavelength can cause an electron to jump from the lower to the higher energy level. The photon is consumed in this process.

 

When an electron is excited from one state to that at a higher energy level with energy difference ΔE, it will not stay that way forever. Eventually, a photon will be spontaneously created from the vacuum(?? To be discussed further) having energy ΔE . Conserving energy, the electron transitions to a lower energy level which is not occupied, with transitions to different levels having different time constants. This process is called "spontaneous emission". Spontaneous emission is a quantum-mechanical effect and a direct physical manifestation of the Heisenberg uncertainty principle. The emitted photon has random direction, but its wavelength matches the absorption wavelength of the transition. This is the mechanism of fluorescence and thermal emission.

 

A photon with the correct wavelength to be absorbed by a transition can also cause an electron to drop from the higher to the lower level, emitting a new photon. The emitted photon exactly matches the original photon in wavelength, phase, and direction. This process is called stimulated emission.

 

The gain medium:

 

The gain medium is put into an excited state by an external source of energy. In most lasers this medium consists of a population of atoms which have been excited into such a state by means of an outside light source, or an electrical field which supplies energy for atoms to absorb and be transformed into their excited states.

 

The gain medium of a laser is normally a material of controlled purity, size, concentration, and shape, which amplifies the beam by the process of stimulated emission described above. This material can be of any state: gas, liquid, solid, or plasma. The gain medium absorbs pump energy, which raises some electrons into higher-energy ("excited") quantum states. Particles can interact with light by either absorbing or emitting photons. Emission can be spontaneous or stimulated. In the latter case, the photon is emitted in the same direction as the light that is passing by. When the number of particles in one excited state exceeds the number of particles in some lower-energy state, population inversion is achieved. In this state, the rate of stimulated emission is larger than the rate of absorption of light in the medium, and therefore the light is amplified. A system with this property is called an optical amplifier. When an optical amplifier is placed inside a resonant optical cavity, one obtains a laser.

 

At this point some might get some inspiration what we are looking for?

Ask yourself what have these processes in common, and how could this be associated with the thermodynamic processes, and moreover with the electrodynamic resonators mentioned earlier.

Vidura

Vidura posted this 27 November 2022


 
Post by Atti on Apr 1, 2022 at 12:19pm
I send my greetings to all the forums.
I apologize and apologize to all the forums for not being able to participate in the daily discussions. (I try to make up for writing and reading)
Unfortunately, there have been a lot of problems lately. I won't burden anyone with these. Everyone has a problem.
I may not have had to, but for the sake of constant harassment, I deleted the content from the youtube channel. I'm angry at harassing certain people. And there was no reason for anyone.

For now, I will make my brief remark in this thread.
Maybe this is the best place to write. But of course the moderator can correct it.
In the current situation and during my investigations, I have gained an experience that I will now share with you.
For now, this is a theory (in part) that I show, but I will try to demonstrate further evidence. There are some topics that are no longer just theory! I need more evidence.
The essence of this is briefly as follows. In several points and from several inventions and embodiments. And the point! Not one Led lamp will light up, but in a proper concept you can even participate in the electricity supply of our apartment!
They all come together. But let's take it in order. (I tried to explain to Chris at the time too, but for some reason he only saw the enemy in me, in vain I argued for the implementations)
I am sure there are geniuses in every country on Earth who are trying to think differently. And their goal is not to get the money!
Therefore, their work may coincide.
The work, proof and presentation of an individual and his / her invention registration can be seen here:
feprinciples.files.wordpress.com/2016/06/hu9601424a2.pdf
users.atw.hu/tuvok1/sent_by_you/Patyi/Egyik_kivetel_az_energia-megmaradas_tetele_alol.pdf
www.google.com/search?q=J%C3%A1nos+Vajda+overunity.com&hl=hu&biw=1920&bih=969&ei=XAZHYrJyhfawB5KcnbAN&ved=0ahUKEwiykKaGhPP2AhUFO-wKHRJOB9Y4ChDh1QMIDg&uact=5&oq=J%C3%A1nos+Vajda+overunity.com&gs_lcp=Cgdnd3Mtd2l6EAM6BwgAEEcQsAM6BQghEKABSgQIQRgASgQIRhgAUNIOWMceYNYhaAFwAXgAgAFkiAH3ApIBAzMuMZgBAKABAcgBCMABAQ&sclient=gws-wiz

The first one in an hour. Sometimes with English commentary.

Reflections from the end of the cable:

fizipedia.bme.hu/index.php/Nagyfrekvenci%C3%A1s_jelek_terjed%C3%A9s%C3%A9nek_fizikai_alapjai

 

Respectively related experiments and writings.

That is. The point is this. When two fields (magnetic) meet, the energy increases. Square.

During my research, I realized that there is a state where the direction of energy reverses and fills back the source field. You can see this on my yt channel during the reflection.
For now, the compilation looks like this:
-base source driven by H-bridge (battery or power supply)
-other base source also driven by H bridge
(assume that the H bridge has a protection diode that forms a graetz bridge)
-load
When two basic sources meet (it is difficult to say exactly what is happening here), their secondary energy increases while one of the basic sources is recharged. The video is only about the same frequency. But when it comes to different harmonics, it's still the case! In fact!
So there is a situation where our primary coil becomes secondary! However, if its voltage is higher, it is no longer a source but an energy absorber. That is, the direction of the current is reversed! Charges our power supply and battery. (I'm currently experimenting with a battery)
And there is currently only one transformer in this vision!
It does all this with more energy filled. Energy is measured with a linear consumer. So be careful not to lie to yourself!
I will definitely sign up if I can provide more information.
If you feel like it, feel free to repeat it. this gives you a reference as to whether the direction is good or needs to be corrected.

Part of my own experiment:  

don't want to bore anyone with that. I don't want to distract anyone from this. I just wanted to show that there probably isn’t a solution.
If anyone has an opinion I would love to read it. Especially if someone points out the mistakes.

I apologize for the google translation.
Perseverance for everyone!

Nagy Attila.

Vidura

Shelfordella posted this 08 January 2023

I agree about the physics approach you mentioned, I like to add this, Faraday on the electrotonic state. https://archive.org/details/in.ernet.dli.2015.500031/page/n27/mode/2up

"A little theory and calculation would have saved Edison 90 per cent of the labor." Nikola Tesla

Vidura posted this 12 January 2023

    do these devices have a common theory of operation? (referring to BTG)

There is a common pattern in this devices. Note that the builders where in most cases radio technicians, therefore their explanations and also implemented technic approaches are related to this theme. Regarding the principles, there are differing versions, but nothing thoroughly verified. Some speech of "pushing the magnetic field with high voltage" others refer to nuclear magnetic resonance. Lately I have read a translation of a video, where Ruslan explains how the different parts of his device interact. He was careful not giving any explanations about the physical principals, stating that it was good enough to know how to set up the parameters, and light the lamp.  

Not for me, but anyway as it is the only detailed description I found of what supposedly happens in the device, I will post in brief:

First the tesla coil, or Kacher. Its function is of course to produce the HV HF, and is a 1/4 wave resonator. He describes the spiral transmitter as a capacitor, and the choke in-between is used for fine-tuning. The grenade coil is the reception coil, the spiral is placed over the partially cancelling sector. On the other end(normal wound)  a second inductor is coupled, which is driven in antiphase(180º. This sets up the standing wave tuned to 1/2 wave. The modulation has to be synchronised to apply the pulses in the potential antinode when it has passed its maximum. He emphasized the importance of the ground wire, which has to be tuned in syntony with the tesla resonator, which can be done eventually winding it up a few turns near a current antinode. In the circuit of the grenade the principal capacitor, and a bridge rectifier with another capacitor across.

To tune this all together requires certainly some skills in radio engineering   

 

The general description is sound, of course as you know from the earlier posts, my hypothesis is not according the before mentioned, below description how this would be explained in context with it.

 

The TC produces the scalar potential waves(could be described as dielectric pressure waves), when it is resonating with the ground wire it produces the actual "pumping force" of the medium(electrons).  The grenade and the secondary inductor are two LCR resonators, which have to be tuned to the same frequency, but in antiphase. Two current waves(displacement of charges) in opposite direction give rise to an standing wave. The antinode of voltage has to be established in the sector of the cancelling windings under the spiral. In the moment when the antinode has passed its maximum(maximal pressure of electrons) the impact of scalar waves on the charges will rise pressure further, increasing their kinetic energy accelerating them faster and  absorb photons from the environment to keep stable. Then in the phase of relaxation the charges propagate (more precisely their kinetic energy) across grenade winding to the ground wire while decelerating relative to the positive charges of the conductor emitting photons in this process.

A gradient of the atomic excitement  is needed in the grenade coil, where the potential gradually decreases from the spiral to the part which connects to the ground wire. As the  turns of  adjacent layers are close to each other's, the emitted photons of decelerating charges will excite the neighbouring turns, but with diminishing energy level towards the ground wire which has the function of a dissipator (making the cold spot of excitement in the system)in addition to be part of the resonant system.

Vidura

Jagau posted this 12 January 2023

Hello Vidura
Interesting what you say here. I hear you talking about scalar wave and dielectric pressure. There is an interesting book to read written by Charles P. Steinmetz at the beginning of the century whose title is:

ELECTRIC DISCHARGES, WAVES AND IMPULSES


The first two chapters talk extensively about the subject that will surely interest you and I myself found several similarities with my current projects, I hope this can help you in your project and to have answers to your questions.

Chales P. Steinmetz

There obviously is no more sense in thinking of the capacity current as current which charges the conductor with a quantity of electricity, than there is of speaking of the inductance voltage as charging the conductor with a quantity of magnetism. But while the latter conception, together with the notion of a quantity of magnetism, etc., has vanished since Faraday's representation of the magnetic field by the lines of magnetic force, the terminology of electrostatics of many textbooks still speaks of electric charges on the conductor, and the energy stored by them, without considering that the dielectric, energy is not on the surface of the conductor, but in the space outside of the conductor, just as the magnetic energy.

 

You will have understood that Steinmetz when he speaks of dielectric field he also means electrostatic field which is the same thing said differently.

Jagau  

Attached Files

Vidura posted this 14 January 2023

Quoting:Jagau

Hello Vidura
Interesting what you say here. I hear you talking about scalar wave and dielectric pressure. There is an interesting book to read written by Charles P. Steinmetz at the beginning of the century whose title is:

ELECTRIC DISCHARGES, WAVES AND IMPULSES


The first two chapters talk extensively about the subject that will surely interest you and I myself found several similarities with my current projects, I hope this can help you in your project and to have answers to your questions.

Chales P. Steinmetz

There obviously is no more sense in thinking of the capacity current as current which charges the conductor with a quantity of electricity, than there is of speaking of the inductance voltage as charging the conductor with a quantity of magnetism. But while the latter conception, together with the notion of a quantity of magnetism, etc., has vanished since Faraday's representation of the magnetic field by the lines of magnetic force, the terminology of electrostatics of many textbooks still speaks of electric charges on the conductor, and the energy stored by them, without considering that the dielectric, energy is not on the surface of the conductor, but in the space outside of the conductor, just as the magnetic energy.

 

You will have understood that Steinmetz when he speaks of dielectric field he also means electrostatic field which is the same thing said differently.

Jagau  

You're right about that, I have read the book from Steinmetz. Actually it has been demonstrated long time ago with Leyden jar's that energy is stored in the dielectric, and the displacement of charges a secondary effect of dielectric waves.

Vidura

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