Reactive power generator 2 kW. Electronic courses will help you in studying nuclear power plants. Heating from Andreev on a resonant choke with an Ш-shaped core from a transformer and DRL lamps

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Option #1. "Electronic. Reverse (reactive) power generator 1-5 kW.”

A device for rewinding or braking a counter. The device plugs into any outlet; no interference with electrical wiring or grounding is required. Consumers eat as usual, the generator does not interfere with them. But the induction counter (with a disk) counts in the opposite direction, and the electronic and electronic-mechanical counters stop, which is also not bad. The device causes power to circulate in two directions through the meter. In the forward direction, due to high-frequency modulation of the current, partial metering is carried out, and in the reverse direction, complete metering is carried out. Therefore, the meter perceives the operation of the device as a source of energy that supplies the entire electrical network from your apartment. The counter counts in the opposite direction at a speed equal to the difference between full and partial metering. The electronic meter will be completely stopped and will allow unmetered energy consumption. If the power of the consumers turns out to be greater than the reverse power of the device, then the meter will subtract the latter from the power of the consumers. The device makes the counter count in the opposite direction at a speed of up to 5 kW per hour (depending on the rewinding power you choose, the instructions provide all the data for collecting the device with a rewinding power of 1, 2, 3, 4 and 5 kW, the specification of the elements, the fundamental diagram, and a complete list of elements for all power options). The device is built on only two transistors, two logical chips of the K155 series, and also contains a dozen other common parts. A radio amateur can assemble and configure it even without much experience. If the meter is equipped with external current transformers and it is possible to connect to their secondary windings, then the winding power is multiplied by the transformation ratio. For example, if the current transformer CT is 0.38 1000/5, one generator will provide a winding speed of 1000 kW*h. Three generators can be used, one for each phase. There will be a triple effect. Applicable for three-phase meter. When plugged into the socket, it will subtract the specified power (1-5 kW) from the total metering power in the phase to which it is connected.

Peculiarities.

Positive: No interference with the electrical wiring is required. All electrical wiring remains intact. No grounding required. You can use the device for both single-phase meters with a voltage of 220V, and for three-phase 380V, simply by plugging it into any socket after the meter. The consumers are not connected to the generator. The residual current device (RCD) does not interfere with the operation of the device.

Negative: It is necessary to assemble the device... The method is quite expensive.

The cost of documentation with detailed illustrated instructions, which includes an electrical circuit diagram, assembly and configuration instructions, a complete list of all elements and materials used: 500 rubles.

Warning!

Dear site visitors! In your attempts to rewind or deceive counters, you will most likely succeed if you have already set yourself such a task! But do not forget, having achieved success, to be careful and wisely use natural resources. After all, after us, our children and grandchildren should also use this!!!

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The device is designed to rewind the readings of induction electricity meters without changing their connection circuits. In relation to electronic and electronic-mechanical meters, the design of which is incapable of counting down readings, the device allows you to completely stop metering to the level of the reactive power of the generator. With the elements indicated in the diagram, the device is designed for a rated network voltage of 220 V and a rewinding power of 1 kW. The use of other elements allows you to increase the power accordingly. A device assembled according to the proposed scheme is simply inserted into a socket and the counter begins to count in the opposite direction. All electrical wiring remains intact. No grounding required.

Theoretical basis

The operation of the device is based on the fact that current sensors of electric meters, including electronic ones, contain an input induction converter that has low sensitivity to high-frequency currents. This fact makes it possible to introduce a significant negative error into accounting if consumption is carried out in high-frequency pulses. Another feature is that the meter is a power direction relay, that is, if you power the electrical network itself using some source (for example, a diesel generator), the meter rotates in the opposite direction. The listed factors allow you to create a generator simulator. The main element of such a device is a capacitor of appropriate capacity. The capacitor is infected with high-frequency pulses from the network during a quarter of the period of the mains voltage. At a certain frequency value (depending on the characteristics of the meter's input converter), the meter takes into account only a quarter of the actual energy consumed. In the second quarter of the period, the capacitor is discharged back into the network directly, without high-frequency switching. The meter takes into account all the energy supplying the network. In fact, the energy of charging and discharging the capacitor is the same, but only the second is fully taken into account, creating an imitation of a generator powering the network. The counter counts in the opposite direction at a speed proportional to the difference per unit time of the discharge energy and the taken into account charge energy. The electronic meter will be completely stopped and will allow unaccounted energy consumption, no more than the value of the discharge energy. If the consumer’s power turns out to be greater, the meter will subtract the device’s power from it. In fact, the device leads to the circulation of reactive power in two directions through the meter, in one of which full metering is carried out, and in the other - partial.

Schematic diagram of the device

The schematic diagram is shown in Fig. 1. The main elements of the device are an integrator, which is a resistive bridge R1-R4 and capacitor C1, a pulse shaper (zener diodes D1, D2 and resistors R5, R6), a logic node (elements DD1.1, DD2.1, DD2.2), a clock generator (DD2.3, DD2.4), amplifier (T1, T2), output stage (C2, T3, Br1) and power supply on transformer Tr1. The integrator is designed to isolate signals from the mains voltage that synchronize the operation of a logical node. These are TTL level rectangular pulses at inputs 1 and 2 of the DD1.1 element. The edge of the signal at input 1 of DD1.1 coincides with the beginning of the positive half-wave of the mains voltage, and the decline coincides with the beginning of the negative half-wave. The edge of the signal at input 2 of DD1.1 coincides with the beginning of the positive half-wave of the mains voltage integral, and the decline coincides with the beginning of the negative half-wave. Thus, these signals are rectangular pulses, synchronized by the network and shifted in phase relative to each other by an angle p/2. The signal corresponding to the network voltage is removed from the resistive divider R1, R3, limited to a level of 5 V using resistor R5 and zener diode D2, then through galvanic isolation on the optocoupler OS1 is supplied to the logical node. Similarly, a signal corresponding to the integral of the network voltage is generated. The integration process is ensured by the processes of charging and discharging capacitor C1. The logical node is used to generate control signals for the powerful key transistor T3 of the output stage. The control algorithm is synchronized by the output signals of the integrator. Based on the analysis of these signals, a control signal for the output stage is generated at output 4 of element DD2.2. At the necessary moments of time, the logical node modulates the output signal with the signal of the master oscillator, providing high-frequency power consumption. To ensure the pulsed process of charging storage capacitor C2, a master oscillator is used on logic elements DD2.3 and DD2.4. It generates pulses with a frequency of 2 kHz and an amplitude of 5 V. The signal frequency at the generator output and the duty cycle of the pulses are determined by the parameters of the timing circuits C3-R20 and C4-R21. These parameters can be selected during setup to ensure the greatest error in metering the electricity consumed by the device. The control signal for the output stage, through galvanic isolation on optocoupler OS3, is supplied to the input of a two-stage amplifier on transistors T1 and T2. The main purpose of this amplifier is to completely open the output stage transistor T3 into saturation mode and reliably lock it at times determined by the logical node. Only entering saturation and completely closing will allow transistor T3 to function under difficult operating conditions of the output stage. If you do not ensure reliable complete opening and closing of T3, and in a minimum time, then it fails from overheating within a few seconds. The power supply is built according to a classical design. The need to use two power channels is dictated by the peculiarity of the output stage mode. It is possible to ensure reliable opening of T3 only with a supply voltage of at least 12V, and to power the microcircuits a stabilized voltage of 5V is required. In this case, the common wire can only conditionally be considered the negative pole of the 5-volt output. It must not be grounded or connected to network wires. The main requirement for the power supply is the ability to provide a current of up to 2 A at the 36 V output. This is necessary to put the powerful switching transistor of the output stage into saturation mode in the open state. Otherwise, it will dissipate a lot of power and it will fail.

Details and design

Any microcircuits can be used: 155, 133, 156 and other series. The use of microcircuits based on MOS structures is not recommended, since they are more susceptible to interference from the operation of a powerful switching stage. The key transistor T3 must be installed on a radiator with an area of at least 200 cm2. For transistor T2, a radiator with an area of at least 50 cm2 is used. For safety reasons, the metal body of the device should not be used as heat sinks. Storage capacitor C2 can only be non-polar. The use of an electrolytic capacitor is not permitted. The capacitor must be designed for a voltage of at least 400V. Resistors: R1 – R4, R15 type MLT-2; R18, R19 - wire with a power of at least 10 W; The rest are resistors of type MLT-0.25. Transformer Tr1 - any power of about 100 W with two separate secondary windings. The voltage of winding 2 should be 24 - 26 V, the voltage of winding 3 should be 4 - 5 V. The main requirement is that winding 2 must be designed for a current of 2 - 3 A. Winding 3 is low-power, the current consumption from it will be no more than 50 mA .

Be careful when setting up the circuit! Remember that not all the low-voltage part of the circuit is galvanically isolated from the electrical network! It is not recommended to use the metal body of the device as a heatsink for the output transistor. The use of fuses is mandatory! The storage capacitor operates in extreme mode, so before turning on the device it must be placed in a durable metal case. The use of an electrolytic (oxide) capacitor is not allowed! The low-voltage power supply is checked separately from other modules. It must provide at least 2 A of current at the 36 V output, as well as 5 V to power the control system. The integrator is checked with a dual-beam oscilloscope. To do this, the common wire of the oscilloscope is connected to the neutral wire of the electrical network (N), the wire of the first channel is connected to the connection point of resistors R1 and R3, and the wire of the second channel is connected to the connection point of R2 and R4. The screen should show two sinusoids with a frequency of 50 Hz and an amplitude of about 150 V each, offset from each other along the time axis by an angle p/2. Next, check the presence of signals at the outputs of the limiters by connecting an oscilloscope in parallel with zener diodes D1 and D2. To do this, the common wire of the oscilloscope is connected to point N of the network. The signals must have a regular rectangular shape, a frequency of 50 Hz, an amplitude of about 5 V, and must also be offset from each other by an angle p/2 along the time axis. The rise and fall of pulses is allowed for no more than 1 ms. If the phase shift of the signals differs from p/2, then it is corrected by selecting capacitor C1. The steepness of the rise and fall of the pulses can be changed by selecting the resistance of resistors R5 and R6. These resistances must be at least 8 kOhm, otherwise the signal level limiters will affect the quality of the integration process, which will ultimately lead to overloading the output stage transistor. Then they set up the generator by disconnecting the power part of the circuit from the mains. The generator should generate pulses with an amplitude of 5 V and a frequency of about 2 kHz. The pulse duty cycle is approximately 1/1. If necessary, capacitors C3, C4 or resistors R20, R21 are selected for this. The logical node does not require adjustment if installed correctly. It is only advisable to verify with an oscilloscope that at inputs 1 and 2 of the DD1.1 element there are periodic rectangular signals, shifted relative to each other along the time axis by an angle p/2. At output 4 of DD2.2, bursts of pulses with a frequency of 2 kHz should be generated periodically every 10 ms, the duration of each burst is 5 ms. Setting the output stage consists of setting the base current of transistor T3 to a level of at least 1.5 -2 A. This is necessary to saturate this transistor in the open state. To set up, it is recommended to disconnect the output stage with the amplifier from the logic node (disconnect resistor R22 from the output of element DD2.2), and control the stage by applying +5 V to the disconnected contact of resistor R22 directly from the power supply. Instead of capacitor C1, a load in the form of an incandescent lamp with a power of 100 W is temporarily turned on. The base current T3 is set by selecting the resistance of resistor R18. This may also require selection of R13 and R15 of the amplifier. After ignition of optocoupler OS3, the base current of transistor T3 should decrease almost to zero (several μA). This setting provides the most favorable thermal operating conditions for the powerful switching transistor of the output stage. After setting up all the elements, restore all connections in the circuit and check the operation of the complete circuit. It is recommended to perform the first switching on with the capacitance value of capacitor C2 reduced to approximately 1 µF. After turning on the device, let it operate for several minutes, paying special attention to the temperature of the key transistor. If everything is in order, you can increase the capacitance of capacitor C2. It is recommended to increase the capacity to the nominal value in several stages, checking the temperature conditions each time. The rewinding power primarily depends on the capacitance of capacitor C2. To increase power, a larger capacitor is needed. The limiting value of the capacitance is determined by the magnitude of the pulsed charge current. Its value can be judged by connecting an oscilloscope in parallel with resistor R19. For KT848A transistors, it should not exceed 20 A. If you need to increase the rewinding power, you will have to use more powerful transistors, as well as Br1 diodes. But it is better to use another circuit with an output stage of four transistors for this. It is not recommended to use too much unwinding power. As a rule, 1 kW is quite enough. If the device operates together with other consumers, the meter will subtract the power of the device from their power, but the electrical wiring will be loaded with reactive power. This must be taken into account so as not to damage the electrical wiring. Chapter.

This page will provide a description and propose a schematic diagram of a simple device for energy saving, so-called reactive power inverter. The device is useful when using, for example, such frequently used household electrical appliances as a boiler, electric oven, electric kettle and others, including non-heating electronic devices, TV, computer, etc. The device can be used with any counters, including electronic ones, even having a shunt or air transformer as a sensor. The device is simply inserted into a 220 V 50 Hz outlet and the load is powered from it, while all electrical wiring remains intact. No grounding required. The counter will take into account approximately a quarter of electricity consumed.

You can obtain a working diagram of this device indicating the values of the elements and detailed instructions for assembly and configuration.

A little theory. When powering an active load, the voltage and current phases coincide. The power function, which is the product of instantaneous voltage and current values, has the form of a sinusoid located only in the region of positive values. The electric energy meter calculates the integral of the power function and registers it on its indicator. If you connect a capacitance to the electrical network instead of a load, the current in phase will lead the voltage by 90 degrees. This will cause the power function to be positioned symmetrically with respect to positive and negative values. Therefore, the integral from it will have a zero value, and the counter will not count anything. In other words, try turning on any non-polar capacitor after the meter. You will see that the counter does not react to it in any way. Moreover, regardless of capacity. The operating principle of the inverter is as simple as a door and consists of using 2 capacitors, the first of which is charged from the network during the first half-cycle of the mains voltage, and during the second it is discharged through the consumer load. While the load is powered by the first capacitor, the second one is also charged from the network without connecting the load. After this, the cycle repeats.

Thus, the load receives power in the form of sawtooth pulses, and the current consumed from the network is almost sinusoidal, only its approximating function is ahead of the voltage in phase. Therefore, the meter does not take into account all the electricity consumed. It is not possible to achieve a phase shift of 90 degrees, since the charge of each capacitor is completed in a quarter of the period of the mains voltage, but the approximating function of the current through the electric brush, with correctly selected parameters of the capacitor capacitance and load, can lead the voltage by up to 70 degrees, which allows the meter to take into account only a quarter of the actual consumed electricity. To supply a load that is sensitive to the voltage waveform, a filter can be installed at the output of the device to bring the supply voltage waveform closer to the correct sine wave.

Simply put, an inverter is a simple electronic device that converts reactive power into active (useful) power. The device is plugged into any outlet, and a powerful consumer (or group of consumers) is powered from it. It is made in such a way that the current it consumes in phase is ahead of the voltage by 45..70 degrees. Therefore, the meter treats the device as a capacitive load and does not take into account most of the actual energy consumed. The device, in turn, inverts the received unaccounted energy and supplies consumers with alternating current. The inverter is designed for a rated voltage of 220 V and a consumer power of up to 5 kW. If desired, the power can be increased. The main advantage of the device is that it works equally well with any meters, including electronic, electronic-mechanical and even the newest ones, which have a shunt or air transformer as a current sensor. All electrical wiring remains intact. No grounding required. The circuit is a bridge based on four thyristors with a simple control circuit. You can assemble and configure the device yourself, even with a little amateur radio experience.

In the modern global world, saving energy resources takes first place in its relevance. Energy saving, in some countries, is actively supported by the state not only for large consumers, but also for ordinary people. Which in turn makes the reactive power compensator relevant for home use.

Reactive power compensation:

Many consumers, having read on the Internet about reactive power compensation by large plants and factories, are also thinking about reactive power compensation at home. Moreover, now there is a large selection of compensating devices that can be used in everyday life. You can read about whether it is really possible to save some money on this at home in this article. And we will consider the possibility of making such a compensator with our own hands.

I’ll answer right away – yes, it’s possible. Moreover, this is not only a cheap, but also a fairly simple device, however, to understand the principle of its operation you need to know what reactive power is.

From the school physics course and the basics of electrical engineering, many of you already know general information about reactive power, so you should go straight to the practical part, but it is impossible to do this without skipping mathematics, which everyone dislikes.

So, to start selecting compensator elements, it is necessary to calculate the reactive power of the load:

Since we can measure components such as voltage and current, we can only measure the phase shift using an oscilloscope, and not everyone has one, so we’ll have to go a different route:

Since we are using the most primitive device of the capacitors themselves, we need to calculate their capacitance:

Where f is the network frequency, and X C is the reactance of the capacitor, it is equal to:

Capacitors are selected according to current, voltage, capacity, power, respectively, based on your needs. It is desirable that the number of capacitors be greater than one, so that it is possible to experimentally select the most suitable capacitance for the desired consumer.

For safety reasons, the compensating device must be connected via a fuse or circuit breaker (in case of too high charging current or short circuit).

Therefore, we calculate the current of the fuse (fuse link):

Where i in is the current of the fuse (fuse), A; n – number of capacitors in the device, pieces; Q k – rated power of a single-phase capacitor, kvar; U l – linear voltage, kV (in our case, phase without).

If we use an automatic machine:

After disconnecting the compensator from the network, there will be voltage at its terminals, so to quickly discharge the capacitors, you can use a resistor (preferably an incandescent light bulb or neon) by connecting it in parallel with the device. The block diagram and circuit diagram are given below:

Block diagram of switching on the reactive power compensator

I'll demonstrate it more clearly

The consumer is connected to hole number one, and the compensator is connected to hole number two.

Schematic diagram of the reactive power compensator

Switching on via automatic fuse

The compensating device is always switched on parallel to the load. This trick reduces the resulting circuit current, which reduces cable heating; accordingly, a large number of consumers can be connected to one outlet or their power can be increased.

Free energy is the process of releasing large amounts of this element. Moreover, in this case, humanity does not participate in such development. The force of the wind contributes to the rotation of electric generators. The greater the pressure drop, the higher the atmospheric condition. As for humanity, this factor is considered to be bestowed from above. Therefore, there is no free energy generator circuit as such; modern experimenters put forward similar theories.

However, due to scientific research, scientists point to the opposite information. The great electrical engineers Tesla, Faraday and Volt forced humanity to take a different look at physics and electrification; today the consumption of energy resources has increased. Most specialists try to obtain sources from the external environment. Such actions are easily feasible, taking into account the fact that Nikola Tesla had already done similar experiments using generators.

Practical circuits of free energy generators

Obtaining minimum capacity occurs in several ways:

through magnets;
using the heat of water;
from ferrimagnetic alloys;
from atmospheric condensate.

However, in order to obtain electricity in large quantities, you need to learn how to manage this energy. Thanks to the practical design of free energy generators, light should reach every person, regardless of local location. This is confirmed by historical facts. Such an experiment requires enormous radiation power, which could not have been available in those days.

And even today existing stations are not capable of providing such a charge. To create a free energy generator circuit, certain tools and elements are required. So, to get the required amount of charged power, you would need a coil, which is what Tesla was using at the time. Electricity is received in the quantity that is needed.

Free energy generator: diagram and description

The essence is that humanity is surrounded by air, water, vibrations. So, there are two windings in the coil: primary and secondary, which are subject to vibrations, which in the process are crossed by etheric vortices in the direction of the cross section. The result induces voltage, essentially air ionization occurs. It appears at the tip of the winding, producing discharges.

An oscillogram of current fluctuations compares the curves. The inductive coupling is strong due to the transformer iron, which causes dense interweaving and oscillations between the windings. When extracted, the situation will change. The pulse will die out, but the power will expand, passing the zero point, and will break off when it reaches the maximum voltage, although the connection is weak and there is no current in the primary winding. Tesla argued that such vibrations continue thanks to the ether. The existing environment is designed to produce electricity. In practice, the working circuit of a free energy generator consists of a coil and windings. Moreover, the simplest way to obtain current looks like this (photo below):

Features of generator development

Tesla's practical experiments show that electricity can be generated using a generator, two coils and one additional coil without a primary coil, two windings. If you move a working and empty coil side by side at a distance of half a meter, and then simply move it away, the corona will die out. In this case, the current that is energized will not change its value depending on the position in space of the one that is not charging from the network. The explanation for the emergence and maintenance of such energy in an empty secondary winding is easily explained.

When electrical engineering developed, stations were built using alternating current. These buildings were low-power, covering one network of enterprises that were equipped with different equipment. Despite this, situations arose in which generators ran idle due to voltage surges. The steam forced the turbines to rotate, the engines worked faster, the load on the current decreased, and as a result, the automation cut off the pressure supply. As a result, the load disappeared, enterprises stopped functioning due to the surge in current, and they had to be turned off. During the development process, the situation was stabilized by connecting a parallel network.

Further development of electricity

After a certain time, power systems began to be improved, and such voltage failures partially decreased. However, a clear and principled theory has emerged. As a result, current drops and similar additional energy are called reactive power. Similar jumps arose from radio engineering of self-induction emf. Essentially, the coils and capacitors worked with and against the station. In addition, it was assumed that the current is in the direction of swinging, and the wires heat up on their own.

It was also determined that such failures occur due to resonance. But how an induction coil and condensate can increase the power of the energy system of hundreds of enterprises is something many academicians have thought about. Some found answers in the practical basis of Tesla's free energy generator circuit, but most pushed the question to the back burner. As a result, not only were engineers unable to cope with their responsibilities and trying to combat reactive power, but in the process they were joined by scientists who created a variety of equipment to eliminate

Characteristics of the Tesla generator

A decade after receiving the alternating current patent, Tesla created a self-powered free energy generator circuit. The fuel-free model consumes the power of the installation itself. To start it, a single impulse from the battery is required. However, this invention is still not used on the farm. The operation of the device directly depends on the design that includes the components:

Two special iron plates, one rises up and the other is installed in the ground.
Two wires are connected to the capacitor, coming from ground and from above.

A constant electric charge is transferred to the metal plate due to the fact that the sources emit radiant particles of microscopic size. The earth is a reservoir of negative particles, so the device terminal is connected to it. The charge is high, so the capacitor is constantly supplied with current, and thanks to this it is powered.

Development of a fuel-free device

The self-powered free energy generator circuit, due to its design, corresponds to the status of a fuel-free mechanism, because it uses cosmic radiation as an energy source. This device is able to activate independently, while extracting electricity from the earth's atmosphere. According to Tesla, a bunch of wires directed upward, beyond the atmosphere, will give a current that will come from the ground, because there is more heat in it than outside it.

In the process of passing voltage, it is possible to power an electric motor, which operates until the temperature drops in the ground. As a result, Nikola Tesla was able to develop a circuit for a fuel-free free energy generator. Moreover, this installation produces electricity without additional power sources - only the atmosphere is used. In the process, the energy of the ether was used to extract the charge of particles. After some time, the scientist argued that an ordinary machine is not capable of transformation.

Further developments of the mechanism

As a result, the scientist began to develop a turbine. This unit was based on a water pump, which was accelerated by flat iron discs. A similar basis can be part of others no less. As a result of the working process, the circuit of the fuel-free free energy generator was improved, electricity was transmitted in the required quantity. To assemble the device, you need to complete three steps:

assemble a secondary winding that is filled with a high volt content;
install primary coils with low voltage;
build a control mechanism.

To create a working circuit for a free energy generator, it is necessary to make a base where the secondary winding will be assembled. To do this, you will need a cylinder-shaped object, a copper wire that will be wound around it. The base material should not allow electricity to pass through, so it is better to use a PVC pipe. The winding is 800 turns. The primary wire must be thicker than the secondary wire. As a result, the fuel-free device looks like this.

General descriptions of mechanisms

The fuel-free free energy generator circuit works on the principle of recycling electricity back into the coil. Conventional devices operate using a carburetor, pistons, diodes, etc. That is, this device does not require an engine. This element is replaced and converts energy constantly. The device is designed in such a way that the output power is less.

Modern scientists Barbosa and Leal have built a unique energy generator that has an efficiency of 5000%. Today this design, description, characteristics of operation and process are not known, due to the fact that the device is not patented. The circuit of Barbosa and Leal's free energy generator is designed in such a way that the operation produces a small turn of power. When the apparatus is started, the output energy exceeds the input level. A small prototype generates 12 kW while using 21 watts.

The most famous ways to generate free power

The most popular are the works of Nikola Tesla. He was one of the first scientists to work on free energy generator circuits. He was involved in the development of wireless communications. It was based on flat coils with a magnetic field inside. As a result, the transformer has asymmetric mutual inductance. If you connect a load to the output circuit, this will not affect the power consumed by the primary winding.

During his work, Tesla began to pay attention to the transformer operating at resonance. Converted power into efficiency, which should have been more than one. To create such a circuit, I used single-wire designs. It was Tesla who created the term “free vibrations” and in his studies pointed to sinusoidal oscillations in an electrical circuit. Tesla's works are still famous today. Free energy has many followers.

Followers of Tesla

Some time after the famous scientist, other researchers and inventors began to create and develop free generators. In the last century, in the 20-30s, researcher Brown developed unsupported traction using electrical forces. He quite clearly and structuredly described the process of obtaining driving power using

After Brown, Hubbard's inventions gained popularity. In his device, pulses were triggered in the coil, due to which the magnetic field rotated. The power generated was so strong that the entire system could do useful work. Niederschot later created an electricity generator consisting of a radio receiver and a non-inductive coil.

A little later, Cooper worked with similar elements. This researcher's free energy generator scheme was to use the phenomenon of induction without a magnetic field. To compensate for the last element, coils with a specific spiral or two wire winding were used. The principle of the device was to create power in the secondary circuit, bypassing the primary winding. In addition, the description of the device indicated unsupported motive power in space. From Cooper's point of view, gravity is the polarization of atoms. He also argued that the coils, which would be designed specifically, would be able to produce a field, would not shield, and would have a number of similar parameters and characteristics to the gravitational field.

Modern view of free energy

From the point of view of physical science, the concept of free energy cannot exist. This question is rather philosophical or religious. However, as the practice of some famous scientists shows, the energy of the system is constant. Upon closer examination, it is clear that power is released and returned back. Thus, the flow of energy through gravity and time is not visible to outside observers. That is, if a process above three spatial dimensions is created, then free movement occurs.

Joule was interested in such inventions. The practicality of this device is obvious to the consumer. For energy production, the existence of working free energy generator circuits can result in large losses, due to the fact that the distribution is centralized and controlled.

Later, the concepts of free generators and similar theories were put forward by scientists Adams, who built a motor, Floyd, a scientist who calculated the state of matter in an unstable form. These scientists had many inventions, designs and theories. Many successful devices could work for the benefit of humanity.

However, not all scientists and inventors succeeded in science and similar designs. Many novice researchers conduct their experiments, but few achieve success. True, recently one Internet user had the idea of repeating Tesla’s invention. As a result, the user "Shark" had his free energy generator circuit recreated. Moreover, it also functioned correctly. In addition, many engineers claim that it is possible to create a free energy generator circuit using a cooler. This proves that the great minds of the past could obtain electricity even without specific devices.