RU2371260C2 - Three-phase electromagnetic wave oscillator - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention relates to electrical engineering and can be used for generating electromagnetic oscillations. The three-phase oscillator has a three-phase winding, each phase of which is made from insulated wire from two parts, formed by turning one part of a doughnut coil 180° about the other and displaced from each by 90°. Either coils of each phase from the insulated wire can also be fixed equidistant from each other on the surface of a metal cone, the angle of the peak of which is 90°. The three-phase oscillator allows for moving material in space, which gives rise to a force field with gravity properties. The force field manifests itself as ordinary magnetism. Operation of the oscillator is based on combining displacements in space, arising from electromagnetic oscillations which vary in space and time with the speed of light.

EFFECT: wider operational capabilities of the oscillator.

5 cl, 4 dwg

Description

From the course of electrical engineering it is known: an electromagnetic field has energy, mass and momentum. Field perturbations propagate in vacuum at a tremendous speed, but it would be wrong to assume that electromagnetic waves are the movement of energy in a void, since in nature there is no void and there is no energy without matter. However, if vacuum (space) is considered as matter of an undetermined structure that exhibits elastic properties, then the possibility of directional movement of a part of space with the absorption of energy, mass and the number of motions of an electromagnetic wave is not excluded. The motion of a part of space is a manifestation of the dynamic properties of matter of an unknown structure.

A three-phase radiator of electromagnetic waves, hereinafter referred to as possible in the text, can be abbreviated as a “three-phase radiator", a device that allows directional movement of matter of an unknown structure. Studies of matter of an undetermined structure, moved by a three-phase radiator, will expand the understanding of the world, the nature of things and phenomena. The moving volume of matter of an unknown structure during the experiments had a forceful effect on various objects. The force effect is manifested as unusual magnetism during the operation of a three-phase radiator at frequencies of 200-1000 Hertz. During the experiments, a strong connection was observed between the activity of the electric field generated by the three-phase radiator and atmospheric phenomena. The discovered effect gives reason to suppose the use of a three-phase radiator when finalizing as an element of a weather forecasting device or a device for climate change.

Using a three-phase radiator, it is possible to investigate the possibility of creating aircraft capable of moving in space at great speed, exhibiting the dynamic properties of matter of an unknown structure.

Devices similar to a three-phase radiator are not considered in the educational literature on electrical engineering, as well as in literature related to physics. Magazines, newspapers and other sources of information, television and radio broadcasts did not mention devices moving matter of an unknown structure (which contain space, including vacuum).

Disclosure of the invention.

A three-phase radiator performs the function of a converter of electromagnetic waves in an electric circuit into electromagnetic waves propagating in space. In this case, the effect of adding displacements of the conditional parts of matter of an unknown structure caused by electromagnetic oscillations of each phase, three-phase EMF system is achieved.

From a training course in electrical engineering it is known: a three-phase EMF system allows you to get a rotating magnetic field. However, rotation represents movement around an axis, and movement around a conditional point can be achieved in a different way. It is known that to give a piece of plasticine or other plastic mass to the shape of a ball, it is necessary to roll it between two planes or palms of the hands. The mechanics of movement at first glance is simple, but it does not fit into the concept of rotation. To study and observe the movement, you can use a small rubber or plastic ball with a diameter of, for example, seven centimeters. To better observe the movement, it is enough to put several marks on the surface of the ball. Stick a few small pieces of colored insulating tape on different sides of the surface of the ball. Rolling the ball between the palms of the hands, we can observe how the control marks of the insulating tape are shifted around the ball’s conditional center in a certain direction. The effect of displacement is achieved as a result of the addition of torques emanating from the planes of the palms of the hands.

By adding the moments of the rotating electromagnetic fields, it is possible to achieve the effect of the displacement of part of space (matter of an unknown structure). If, as a result of the addition of the moments of rotating electromagnetic fields, part of the space moves in a certain direction, then we can talk about a dynamic process. Electromagnetic waves do the work by moving matter of an undefined structure in a certain direction. A three-phase radiator can be considered as a "stator", the part of the space representing the matter of an undefined structure performs the function of the "rotor". The frequency of rotation of the body around the conditional axis is significantly limited, the ability to withstand mechanical destruction of the structure by centrifugal forces. The displacement rate of matter of an unknown structure may be close to the speed of light. However, one should not forget that the rotation around the conditional axis and the displacement around the conditional point are different in nature of the origin of the movement, although they can be very similar.

Before proceeding to the disclosure of the observed effects and phenomena during the experiments, it is necessary to consider the features of a three-phase emitter. The windings of a three-phase emitter in space relative to each other, are shown in figure 1. The windings are located on the faces of a conditional cube, arbitrarily located in space. For a better perception, the windings are spaced in space with conditional faces corresponding to the cube. The joints of the turns are indicated by numbers and letters. The windings are represented by one turn for each phase. The beginning of the winding corresponds to the letter designation of phase A, B, C, three-phase EMF system. The end of the winding is indicated by the letter O. The windings of a three-phase emitter are made of copper wire coated with varnish. In the electrical circuit, the windings can be connected in a star or delta.

When connecting a three-phase emitter to an electric circuit with a three-phase EMF system and subsequent adjustment, the following effects and phenomena were observed. A three-phase radiator, hung on a thread, is attracted with equal strength to conductors and dielectrics. As dielectrics were used - glass, polyethylene, wood, porcelain, pieces of ice water. Metals as conductors - steel, copper, lead, aluminum and their alloys. It is established that the strength of the interaction between the three-phase emitter and the objects used in the experiments does not depend on the area of these objects, as well as the material of which they consist. However, the interaction force increases significantly with an increase in the mass of objects close to the switched on three-phase emitter, and with an increase in the frequency of currents in the three-phase EDE system. The range of frequencies used in the experiments ranged from 200 to 1000 Hertz. The purpose of the experiments was to detect a field exhibiting unusual magnetism, and its study. The theoretical justification for the existence of a field with the properties of gravity was first formulated in 1992. The theory of gravity subsequently changed, refined and refined, provided for consideration to various publications, but has never been published. Experiments on detecting a field with the properties of gravity have been conducted since 1997. Positive results were obtained at the end of 1999. A piece of beech board measuring 45 × 15 × 2 cm, approaching a three-phase radiator, is equally attracted from all sides. When approaching three boards of the same size, stacked together in a stack, the force of attraction increased. In another case, an empty plastic bottle approached a three-phase emitter suspended on a thread. The deviation angle was noticed. Then the bottle was filled with water and again approached the three-phase emitter. The deflection angle increased significantly. In experiments, an ordinary hammer was often used. The hammer consisted of a shock part, steel and a handle made of wood, the material is apple tree. When approaching various parts of the hammer of a three-phase radiator, an adhesion effect arose. The three-phase emitter adhered equally to both the impact part of the steel hammer and the wooden handle. The experiments used objects made of non-ferrous metals and their alloys, as well as pieces of ice of water, which were also attracted to the vibrator. Both plates of lead, copper, aluminum and steel of various shapes and weights adhered to the three-phase emitter, as well as kitchen utensils — spoons, pans, pans. However, when two three-phase emitters connected in parallel to one generator came closer, a repulsive effect was observed. The repulsion effect was observed when the permanent magnet and the three-phase radiator came closer together. The ferromagnet was tied to a thin thread and was used as a construction plumb. The repulsion effect was observed from all sides.

The experiments used metal filings formed as a result of machining steel cutters with an abrasive. Metal filings were scattered across a sheet of paper and approached a three-phase emitter in order to detect the presence of magnetic field lines. A sheet of paper with scattered metal filings adhered to a three-phase emitter. However, no changes were observed on a sheet of paper with metal filings. Metal filings used in various sizes.

The steel core placed inside the three-phase emitter parallel to the conventional plane formed by the conditional points indicated by the letters a, b, c (Fig. 1) did not significantly change magnetism. However, the same core, turned perpendicular to the conventional plane, indicated by the letters a, b, c, and passing through the center of a three-phase emitter, led to the disappearance of magnetism. The heating of the steel core and windings of the device took place.

When metal objects came closer to a three-phase emitter, a spark discharge was observed, accompanied by a characteristic crack. The sparking effect was not stable. During the week, in experiments with the same three-phase emitter and metal objects, spark discharges of different strengths were observed. On some days of the week, the sparking effect disappeared, and on other days, sparking intensified. Several cases were noted when spark discharges were observed in a gap of approximately 8 mm between the windings of a three-phase radiator and an aluminum frying pan with a diameter of 250 mm. The approach of the same device to a grounded conductor, a heating radiator was also accompanied by a spark, but the gap barely exceeded 1 mm. The time interval between electric discharges was observed. The time between flashes was less than 2 seconds. The voltage on the rectifier device of the generator did not exceed 15 volts according to the testimony of a voltmeter for measuring voltage in electrical circuits of direct current (figure 2). It is noted that spark discharges precede the approach and passage above the venue of experiments of cyclones that determine the weather from the Atlantic Ocean to the Ural Mountains. The results of observations were compared with weather reports for Europe and Russia. Strong spark discharges precede a sharp change in atmospheric pressure. The onset of atmospheric pressure observed by the barometer was noticed 10 hours after the experiments. Subsequently, the passage of atmospheric cyclone fronts with precipitation and a strong gusty wind was observed.

In the days when the spark was observed, during the experiments an electric field was discovered on ungrounded and not connected to metal objects located at a distance of up to 5 meters from a working three-phase emitter. In the experiments, an indicator screwdriver was used to check for voltage in electric networks up to 250 volts. Touching the edge of a screwdriver to ungrounded and uninsulated metal objects weighing a few grams was accompanied by a glow of the indicator light. The closer metal objects were to the three-phase emitter, the brighter the glow of the bulb inside the handle of the screwdriver. The reason for checking for the presence of electric fields was the case of electric shock when a person accidentally touches an uninsulated part of a metal object located near a switched-on three-phase radiator.

The implementation of the invention.

For the implementation of the invention, the movement of matter of an unknown structure, it is necessary to carry out measures for the manufacture of a three-phase emitter of electromagnetic waves and the assembly of a unit generating EMF of a given frequency, the detection and study of the field exhibiting magnetism.

The manufacture of a three-phase emitter can be made in the following way. Winding in the amount of 3 pieces is made of copper wire coated with varnish and a diameter of 0.07 mm. For the manufacture of the winding, a ring coil with a number of 250 turns is initially wound. The beginning of the coil is marked with a short supply of wire 10-15 cm, and the output length is 120-150 cm. The turns of the wire are wound manually, compactly on a glass jar with a diameter of 70 mm. Then the winding with a given number of turns is carefully removed and pulled together with cotton thread No. 10, or glued with narrow strips of 5-6 mm insulating tape. The turns of the winding are pulled together at four points arbitrarily selected around the circumference. From the winding in the form of a ring by twisting 180 ° of one second part, we get a figure resembling the number 8. The winding in the form of a figure eight consists of two inextricably linked ring coils. If currents flow around one half of the figure eight clockwise, then the other in the opposite direction. The places of contact of the winding turns in the center of the figure eight are additionally insulated with a piece of insulating tape and tightly pulled together with cotton thread No. 10. A cotton thread is several times threaded first into one hole formed by a loop of coils, then into another hole of the winding. The ends of the thread are pulled together and tied in a knot. The hanging ends of the thread are cut at a distance of 3-5 mm from the node. Then the two halves of the eight must be moved by hand so that between the rings there is an angle of 90 °, (figure 1). Subsequently, the angle is maintained due to the stiffness of the copper wire. At this stage, the manufacturing process of one winding can be completed. Above, two more windings are made by the above method. Three windings are made of one material and one geometric shape. The direction of the incoming and outgoing turns in the windings must match (figure 1). The three-phase emitter is assembled by bringing any two windings closer to contact (Fig. 1). In the places of contact indicated by numbers, the windings are tied with cotton thread No. 10. One end of a cotton thread is threaded several times through the openings of the windings, and the other is held by hand. The thread is pulled together and tied to a knot, first around one point of contact of the windings, then around the next. All hanging ends of the cotton thread are cut at a distance of 3-5 mm from the knot. Instead of threads, a narrow strip of insulation tape measuring 3-4 mm wide and 20-30 mm long can be used. A third approaches the connected two windings, in places of contact it is fastened with threads or stripes of tape. When assembling a three-phase emitter, special attention should be paid to the compliance with figure 1 of the incoming and outgoing turns in the windings. In case of improper assembly and inclusion in the electric circuit, heating of the windings is possible, followed by destruction of the insulation of the wires. Burnt windings in further experiments, as practice has shown, is inappropriate to use. The ends of the winding of a three-phase emitter, before being included in the electric circuit, can be connected in a star or triangle. The connection points of the wires are protected, soldered with tin and insulated with tape. Most often in experiments, windings with a star connection were used. When connecting the star windings, the long ends of the wires were laid out on a flat surface, untangled, aligned and soldered at the zero point at a distance of 120 cm, and the short ends were connected to the linear wires using clamps or soldered with tin at a distance of 7 cm from the three-phase radiator. Lead brackets were used as clamps. A 60-watt soldering iron was used to solder the wire connections with tin. When connecting the windings into a triangle, the ends of the wires that marked the output were shortened to 10 cm. Places of soldering wires when connected to a triangle of windings were made at a distance of 7 cm from a three-phase radiator.

As a current source with a three-phase EMF system, an automobile generator of the G-222 type was used. The automobile generator was brought into working condition using an electric motor connected to an electrical network with a voltage of 220 volts and a current frequency of 50 hertz. In the experiments, to change the rotational speed of the generator rotor, several electric motors with a power of 250-600 watts were alternately used. A change in the generator speed was also achieved through the use of various pulley diameters of 30-140 mm. The generator rotor was driven by a V-belt drive. A generator with an electric motor was placed and mounted on one portable platform. The platform is a sheet of plywood 10 mm thick, 400 mm wide and 800 mm long, located on supports, two bars with dimensions 50 × 50 × 800 mm. Several pieces of rubber, 12 mm thick, were attached to the bars to reduce vibration and noise. A generator with an electric motor was shifted to one edge of the platform. The V-belt transmission belt was located above one side of the 800 mm platform, which made it possible to arrange devices and circuit elements along the other. Switches, bulbs with bullets, capacitors, resistances, a voltmeter, and wire clips were attached to the platform. The battery capacity of 55 ampere · hours was located next to the platform.

Before the experiments, a three-phase radiator was hung on cotton threads. For the device, when connecting the windings with a star, one end of the thread was tied to the place of soldering at the zero point, the other end of the thread to the ring fixed to the ceiling. The distance from the floor to the three-phase radiator, as well as the distance to the reinforced concrete walls, was more than 40 cm. For electrical communication between the generator and the three-phase radiator, a standard two-wire telephone wire up to 15 meters in length was used. Double-folded telephone wire provides connection to three phases and the generator zero point. The zero wire was not used in most experiments, see figure 2.

After assembly and installation, in accordance with the electrical circuit, figure 2, all the elements were experiments. The purpose of the experiments was to detect a field exhibiting unusual magnetism and its study. The experiments were carried out in the lobby of a multi-storey building at an air temperature of 18-25 ° C both in the summer and in the winter season. Before starting the generator, the platform, the connections of the wires and the three-phase radiator were inspected. The reliability of the fasteners of all elements of the electrical circuit was tested both on the platform and beyond. Unsecured objects and parts were removed from the platform. Near a three-phase emitter, at a distance of 1-2 m, objects were placed that were subsequently used in experiments to detect a field exhibiting unusual magnetism. The start of the installation, generating EMF, occurred in the following sequence (figure 2). The tumbler turned on the generator rotor power from the battery, the glow of the control lamp from 5 watts confirmed the passage of current in the electrical circuit. After 2-3 seconds, a switch from the 220 volt electric network started an electric motor, which drives the generator rotor. The voltage in the electric circuit of the generator after starting the electric motor can be judged by the readings of the voltmeter and the brightness of the glow of the control lamp. After 10-30 seconds, using a batch switch, a three-phase radiator was switched on in the electric circuit of the generator. During operation of the power plant, it is not allowed to turn off and then turn on the battery in the electric circuit, this can cause a breakdown of the generator windings or valves of the device that converts currents. A three-phase radiator can be turned off repeatedly by a batch switch to change the resistance in the linear wires, and then turned on in the generator circuit without stopping the power plant. The hammer turned out to be the object most often used in experiments as a probe for the presence of magnetism. The presence of two components, the impact part of the steel hammer as a conductor and the dielectric of the handle made of wood, made it possible to quickly establish a field exhibiting unusual magnetism. The shock metal part was initially approaching the three-phase emitter, the wooden handle protected from electric shock in case of observation of sparking. The length of the handle of the hammer used in the experiments did not exceed 40 cm. The weight of the impact part of the hammer was 400 grams. The distance from the impact part of the hammer to the hand holding the handle was at least 10 cm. After the impact part of the hammer came closer to the three-phase emitter, the rotation turned 180 °, the handle approached. Reactions, deviation angles were compared. The hammer approached smoothly, without creating air flows, both with the shock part and with the handle, to the three-phase emitter, but not earlier than 2-3 minutes after connecting to the generator circuit. The approach was made before touching, but the swaying and repulsion of the three-phase emitter by the tested objects was not allowed. If there was a deviation of the three-phase emitter to meet the hammer, then the rapprochement was carried out before sticking. The deflection angle was observed at the time of adhesion. Then the hammer slowly moved in the opposite direction, the angle was noticed at the moment of detachment of the previously adhered three-phase emitter. The angles of deviation from the vertical of the three-phase emitter, caused by the approximation, and then the removal of various materials, were compared. The insignificant difference in the compared deflection angles of the three-phase radiator for both steel and wood testified to the presence of a field exhibiting unusual magnetism. With the total length of the wires and cotton thread from the three-phase radiator to the attachment point to the ceiling equal to 2 meters, a deviation from the vertical was observed from 0 to 50 cm. In the absence of signs of magnetism, settings were made. In one case, the resistance in the linear wires was changed (figure 2). Resistors with a higher resistance by the selection method were included in the electrical circuit. The three-phase radiator was turned off, the resistor was replaced, the generator was turned on in the electric circuit, without stopping the installation.

In another case, the frequency of currents was changed by increasing the rotation speed of the generator rotor due to the selection of various pulley diameters or by replacing an electric motor having a higher rotor speed. The experiments were repeated after each change in the electrical circuit to detect a more or less active field exhibiting magnetism, a hammer was always used as a probe. When a field exhibiting magnetism was detected, various objects, both conductors and dielectrics, approached the three-phase emitter. Effects and phenomena were observed and compared for different materials and sizes of objects. From the conductors, plates 2 × 100 × 150 mm in size, material steel, lead, copper and aluminum approached the three-phase emitter. The plates were held, and pliers with insulated handles were used. Cans, bottles, pans, pans, cutting boards and other objects used in everyday life in the kitchen, as well as pieces of ice of water, were approaching a three-phase emitter. The presence of the effect of adherence to various objects of a three-phase emitter made it possible to consider the presence of a field exhibiting unusual magnetism caused by the movement of matter of an unknown structure. The parameters at which unusual magnetism, resistance in the linear wires, the frequency of the currents of the three-phase EMF system, and also the test unit, which is a three-phase radiator, were observed, were remembered. In subsequent experiments, the results were compared.

Along with the sticking effect, a repulsive effect was discovered when the three-phase radiator approaches the permanent magnet, as well as another three-phase radiator connected in parallel with the generator. In one case, a 8 × 12 × 25 mm rectangular permanent magnet approached like a plumb line tied to strands. When the permanent magnet approached as a plumb line with a three-phase radiator hung on the threads, the ferromagnet turned around, and none of the poles was directed in its direction. As the magnet approached, the three-phase emitter deviated in the opposite direction. The maximum deviation in the plane parallel to the surface of the earth during the observation reached 10 mm. When the two three-phase radiators hung on the threads came closer, the turning effect was not noticed, and the repulsion effect could be observed by the angle of deviation from the vertical. In another case, a permanent magnet or a second three-phase emitter were mounted on the end of a wooden battens 10 × 15 × 1500 mm. When approaching a permanent magnet fixed to the end of the rail or a second three-phase radiator with the first hanging on the strands, a repulsion effect was observed from all sides.

It was noted that for two or more three-phase radiators located nearby, the activity of the field exhibiting unusual magnetism did not change significantly. Three-phase emitters of electromagnetic waves connected to a single generator did not mutually amplify or suppress individually created fields exhibiting unusual magnetism.

During the experiments, spark discharges were noticed in the air gap between a three-phase radiator and non-insulated surfaces of metal objects. Initially, a hammer was used as a probe. The hammer took on a wooden handle and approached the steel part to the windings of the included device. At a distance from 100 mm to 0, the approach came at a speed of approximately 10 mm / s; the approach speed was universal for all materials and objects used in the experiments. In the case of observing sparking, in order to determine the air gap and the power of the electric discharge between the test units, the approach speed during repeated experiments was slowed down. It is noted that the spark discharge does not substantially depend on the approaching steel part of the hammer, rib, or plane. A similar effect was observed for other metals, but the air gap and brightness of spark discharges increased significantly with increasing conductivity of the materials used in the experiments. For example, for the steel part of the hammer and the three-phase radiator, an electric discharge was observed in the air gap of less than 1 mm, and the gap between the object made of an aluminum-based alloy was more than 1 mm. An electric discharge was observed between the points at the smallest distance between the uninsulated surface of a metal object and the windings of a three-phase emitter made of varnished wire. Special devices and instruments for accurate measurement of air gaps, in which an electric discharge was observed as a spark, were not used. With daily repeating of experiments for a week with the same test units, an unstable electric field was noticed around a three-phase radiator. The time interval between electric discharges, as well as the air gap in which they were observed, varied during the week. As a result of observations, a strong connection was observed between the activity of the electric field generated by the three-phase radiator and atmospheric phenomena. Passing over the place of conducting cyclone experiments, determining the weather in vast territories, coincided with the activity of the electric field around a three-phase radiator. The electric field increased depending on the approach of a more or less active cyclone. The phenomenon of the connection of electric fields with atmospheric phenomena has not been studied. Nevertheless, according to the activity of electric fields around a three-phase radiator, it is possible to predict the weather for the next 10 days, the probability is up to 85%. The observation results were compared with weather reports for Russia and Europe, which had a significantly lower percentage of the probability of weather forecasts. If the presence of an electric field around a three-phase emitter can be judged by the presence of a spark, then the presence of an electric field on metal surfaces can be judged by the glow of an indicator light inside a screwdriver used as a probe for the presence of a phase for electric networks up to 250 volts. The closer metal objects were to the three-phase emitter, the brighter the glow of the indicator light was observed. In the days when a spark was not observed near a three-phase emitter, an electric field on metal surfaces was not detected with an indicator screwdriver.

During the experiments, all objects close to the three-phase emitter were held by the hand. It was noticed that after the experiments, itching of the skin appeared. The most active points of irritation like itching were manifested in open areas of the body, in most cases on the hands. After scratching at one point after a while, itching appeared in another. After the suspension of the experiments, the itching and discomfort disappeared after 7-10 days.

The three-phase emitter of figure 1, having the shape of a conditional cube, is the first and simple element of an electrical circuit that allows you to detect a force field exhibiting unusual magnetism. Subsequently, by selection and samples of various combinations of the location of the windings in space, as well as changes in the electrical circuit, a force field was discovered that exhibits unusual magnetism in other conditional geometric figures. For example, windings of a three-phase emitter made in the above-described manner, assembled differently, represent another conditional geometric figure. The windings shown in Fig. 1 are brought together by the connection points indicated by the letters a, b, c, to one conditionally common point. The turns of the beginning of three windings form a conditional pyramid, at the base of which lies an isosceles triangle. The turns of the windings of the mirror-conditional plane passing through the junction at one conditional point form a second pyramid. The joint at one common conditional point is fixed using cotton thread No. 10. The turns of the beginning and ends of the windings are leveled along the corresponding edges of the conditional pyramids and in the places of contact are also connected by a thread. Before being included in the electric circuit, the windings are connected into a star or triangle. Before conducting the experiments, a three-phase radiator, regardless of the geometric shape, in most cases was hung on a thin cotton thread. Subsequently, inclusion in the electric circuit was carried out, followed by a study of the fields. The presence or absence of a field exhibiting unusual magnetism was experimentally determined, as for the first three-phase emitter.

The appearance of the third emitter is a conditional pyramid, on the planes of which lie ring coils, and at the base is a plate of metal. The metal plate may be in the shape of a triangle, circle, or other shape. The coils are first attached to each other, since the incoming turns in figure 1 are connected. Then the coils are attached to a metal plate. Fastening was carried out in some cases by gluing coils in places of contact with a sticky strip plate. In another case, holes were punched or drilled in the plates in certain places and the coils were tied with cotton thread.

The ability to use eddy currents is implemented in the design of the fourth version of a three-phase emitter. The design of the device represents the following appearance. On one of the two cones, made of a metal plate, three ring coils are fixed, equally spaced from each other. The angle at the apex of the cones was 90 °. The cones were fastened together at the base, while the peaks were mirrored in opposite directions. When connected to an electric circuit around a three-phase emitter, fields were discovered that exhibit unusual magnetism. If for the first three-phase emitter spark discharges were observed in the gap between the windings and an approaching metal object, for the fourth an electric discharge was observed when the conductors approached different sections of the cones. As various objects, conductors, and dielectrics approached different parts of the cones, a sticking effect was observed. Cones were made of non-ferrous metals.

The fifth three-phase radiator possessed the same properties as those considered above, but had a design feature. If on the above models the windings were placed on top of the cones and plates, then at the fifth they were located inside the figure and were covered with metal on all sides. Outwardly, the three-phase emitter looked like a cone, in which the base is closed. For the manufacture of the cone and the base, metal sheets cut from an aluminum can were used. Ring coils, the diameter of which was less than 1/3 of the diameter of the plate lying at the base, were mounted on the inner surface of the cone. Fasteners were pre-marked so that the coils were equally spaced from each other and were as close as possible to the base of the cone. The divergence angle in the cone from the top to the base was close to 90 °. The wires that make up the electrical circuit are threaded through the hole into the cone. The hole was pre-drilled at the top of the cone or the center of the plate lying at the base. A sheet of metal covering the base of the cone was fastened.

In addition to changing the design of the three-phase emitter, various options for incorporating into the electric circuit were used. Figure 3 shows a diagram of the inclusion in the electric circuit of two three-phase emitters using capacitors of different capacities by the selection method. Figure 4 shows the inclusion in the electric circuit of a three-phase emitter using inductive coils. The inclusion in the electric circuit through the capacitors by the selection method turned out to be very laborious, the fields exhibiting unusual magnetism around the three-phase emitter were weak, no sparking was observed. Inclusions through inductive coils with mutual induction and additional resistances made it possible to observe active interactions, manifested as unusual magnetism between conductors and a three-phase radiator, and spark discharges, which were much stronger than when using resistances.

When conducting experiments with various designs of three-phase emitters, it was found that in order to move matter of an unknown structure and observe unusual magnetism, the following conditions must be created:

- a given sequence of repetition of electromagnetic disturbances in the windings of a three-phase emitter,

- a given angle of intersection of the directions of magnetic induction,

- a given frequency of field disturbances and their magnitude in amplitude in the electrical circuit.

The lack of material resources makes it difficult to conduct a study of the field exhibiting unusual magnetism around three-phase emitters, as well as other manifestations discovered experimentally. Nevertheless, work on the improvement of three-phase emitters and the electrical circuit continues.

A brief description of the figures.

Figure 1. This figure shows a schematic model of the location of the windings of a three-phase emitter relative to each other. The windings are separated in space and depicted in one turn for each phase, indicated by the letters A, B, C. The beginning of the first ring is determined by the arrow from the phase letter indicated. The connection points of the windings during the assembly of a three-phase radiator are indicated by numbers from 1 to 9. The contact points of the conditional rings of one winding are indicated by the letters a, b, c. The wire connecting the windings to the zero point, the star connection, is indicated by the letter O.

Figure 2. This figure shows a circuit diagram of a three-phase radiator with a generating device, where 1 is the generator rotor, 2 is the generator stator, 3 is the valve block, 4 is the capacitor, 5 is a voltmeter, 6 is a rechargeable battery, 7 is an electric bulb, 8 - toggle switch, 9 - packet switch, 10 - resistance, 11 - three-phase emitter, 12 - motor stator winding, 13 - fuse, 14 - capacitor block, 15 - electric motor switch, wires connecting the above elements are indicated by a continuous line, bu kwami A, B, C clamps on the stator of the generator.

Figure 3. The inclusion in the electrical circuit of two three-phase emitter using capacitors, where: 16 - capacitors selected for one emitter; 11 - the first three-phase emitter; 17 - capacitor selected for the second emitter; 18 - switch; 22 - second three-phase emitter; A, B, C, O - designations of a three-phase EMF system with a zero wire.

Figure 4. The inclusion in the electrical circuit of a three-phase emitter through inductive coils with mutual induction, where: 19 - resistors with variable resistance; 20 - inductive coils with mutual induction; 11 - three-phase emitter; 21 - resistors with large unchanged resistance.

Claims (6)

1. A three-phase emitter of electromagnetic waves, comprising a three-phase winding, each phase of which is made of an insulated wire of two parts, formed by turning 180 ° of one part of the ring coil relative to the other and shifted 90 ° relative to each other. 2. The three-phase emitter according to claim 1, characterized in that the phases of the three-phase winding are located on the faces of the cube. 3. The three-phase radiator according to claim 2, characterized in that the coils of adjacent phases are fastened together. 4. The three-phase emitter according to claim 1, characterized in that the first phase coils form a triangular pyramid, and the second phase coils form a second triangular pyramid so that the junction of the pyramids is connected. 5. A three-phase emitter of electromagnetic waves, containing a three-phase winding, each phase of which is made in the form of coils of insulated wire, mounted at an equal distance from each other on the surface of a metal cone, the vertex angle of which is 90 °. 6. The three-phase emitter according to claim 5, characterized in that it is provided with a second metal cone, the metal cones being connected by bases.

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