RU2379815C2 - V torchin's method to generate electric potential and device to this end - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to electrical engineering, particularly, to DC-to-AC conversion and can be used in electronics, measuring and computing hardware etc. Core 1 made from conducting material is arranged in spiral-like magnetic core 2. Aforesaid spiral incorporates DC excitation winding 3. One core end "a" is connected with the winding end, while electric potential is generated on conductor ends "a" and "b". External effects are brought on conductor a and/or magnetic core 2 for electric potential to be used for determining amount of said effects.

EFFECT: higher generated potential.

11 cl, 8 dwg

Description

The claimed method of generating electric potential according to V.V. Torshin is designed to convert direct current to direct current, and devices that implement this method can find application in electronics, measuring and computer technology for testing, as well as in medicine for the diagnosis of various diseases and etc.

A known method of generating electrical potential, called the "Hall sensor", based on obtaining the output voltage when exposed to a semiconductor wafer - the core is a magnetic field. (See, for example. Polytechnical Dictionary / A.F. Belov et al. - M .: Soviet Encyclopedia, 1989, p. 583).

A disadvantage of the known method of generating an electric potential is that the magnitude of the output potential depends on an external magnetic field, which cannot always be controlled.

Closer and adopted as a prototype is Busygin’s method of generating electrical potential and a device for its implementation (see, for example, RF patent No. 2070765, CL H2M 3/02, publ. 12/20/96 in BI No. 35).

The method consists in the fact that an electrically conductive core is placed in the area of the magnetic circuit formed in the form of a spiral equipped with a direct current winding and forming a spiral-shaped spatial magnetic field, and the voltage is obtained at the ends of the core.

The method allows for certain ratios of spiral turns, core length and magnetic field strength to obtain a potential difference at the ends of the conductor.

The disadvantage of this method is that the potential at the output of devices that implement the known method is small, the method itself has limited use and therefore its practical use has not been developed.

The claimed invention is aimed at increasing the generated electric potential and increasing its utilitarian properties.

To achieve the specified result in the method for generating electric potential according to V.V. Torshin in a core made of an electrically conductive material and placed in a magnetic field formed by a spiral-shaped magnetic circuit equipped with an excitation winding supplied from a current source, according to the invention, in the magnetic circuit space a substance is placed as a core, the region of this substance concentrated at one point is connected to a current source supplying the field winding, as a result, an electric potential is obtained from two points of the substance separated by a gap, moreover, the substance and / or the magnetic circuit are affected by an external physical parameter, and the resulting generated electric potential is used to determine the magnitude of this parameter.

In an embodiment of the method, the magnetic circuit is made of spring material, the acting physical parameter is the mechanical force applied to the magnetic circuit, and the resulting electric potential is used to determine the magnitude of the mechanical force.

In an embodiment of the method, the core is made of an electrically conductive material, the external physical parameter is heating from an external heat source, and the resulting electrical potential is used to determine the temperature of the heat source.

In a variant of the method, the body of a biological object is used as the core, the external physical parameter is the metabolic process taking place in the biological object, and the resulting electric potential is used for diagnostic purposes.

In a variant of the method, a photocell is used as the core, the external physical parameter is light, and the resulting potential is used to determine the amount of illumination.

In an embodiment of the method, the tube of the cathode ray device is placed as a core in a magnetic field, the external physical parameter acting on the magnetic circuit is the electric voltage in the field coil, and the resulting potential is used to determine this voltage by light signals on the display screen.

In the embodiment of the technical solution, a nonmetallic tube equipped with metal rims at the edges is placed as a core in a magnetic field, it is filled with water, one tube rim is connected to a current source, the substances dissolved in it are a physical parameter, and the resulting potential is measured on the tube rims, and the measurement results determine the content of substances dissolved in water.

If a substance with electrical conductivity is placed as a core in the space of the magnetic circuit, the region of this substance concentrated at one point is connected to a current source, and the electric potential is obtained from two points of the substance separated by a gap, then the electric potential obtained from two points of the core, in comparison with prototype, multiplied.

Exposure of external physical parameters to the substance and / or magnetic circuit leads to a change in the resulting generated electric potential. These changes can be used to determine the magnitude of this external parameter.

In this case, the external parameter acting on the magnetic circuit can be, in particular, the voltage supplied to the field winding, and the electric potential at the ends of the core is used to measure the applied voltage.

The implementation of the magnetic circuit of the spring material and the impact of external forces on it allows you to use this method to register, for example, the magnitude of the load on the balance, measure pressure in various physical devices, etc.

When heating a core made of an electrically conductive material with an external heat source, the method allows to measure the temperature of the heating element.

If the body of a biological object, for example, of a person, is used as a core, then, after accumulation of certain experimental statistical data, a change in the values of the output voltage in individual parts of the body can be used to obtain various medical diagnostic parameters, for example, to determine the patient’s condition when examined with using the apparatus "polygraph".

If a tube of an electron-beam device is placed as a core in a magnetic field, then by changing the voltage in the field coil, it is possible to influence the flow of electrons in the tube and, thereby, control the light signals on the display screen or determine the magnitude of the voltage applied to the field coil.

If a non-metallic tube is placed in a magnetic field as a core and filled with water, then, according to the measurement results and with the accumulation of certain experimental data, it is possible to determine the water pollution by one or another component.

If a photocell is used as the core, then the external parameter affecting the resulting potential will be light. The resulting potential at the ends of the core is used to determine the amount of illumination. In this case, the current received from the photocell will be significantly higher due to the fact that additional carriers of electric charge appear. Those. The photo effect will be enhanced.

In the device for generating an electric potential, containing an electrically conductive core located in the area of the magnetic circuit, made in the form of a spiral equipped with a direct current winding, according to the invention, one end of the core is connected to the end of the magnetic field winding, and both ends of the core are used to generate electric current.

In an embodiment of the device, the spiral of the magnetic circuit is made in the form of a closed toroidal line, and the core is made of several turns.

In an embodiment of the device, the magnetic circuit spiral is made of soft magnetic material.

In an embodiment of the device, the magnetic core spiral is made of non-ferromagnetic material.

In an embodiment of the device, an electrically conductive material is used as a core.

In an embodiment of the device, a permanent magnet is used as a core.

In a variant of the device, a semiconductor material is used as a core, consisting of two parallel p- and n-type rods isolated from each other, on the one hand, the rods have an electrically connected common point, and the common end of the rods is connected to the field winding, and to obtain electric current serve both free ends.

In a variant of the device, a solenoid wound on a rod is used as the core, and both ends of the solenoid serve as the ends of the conductor.

When a magnetic circuit is made of soft magnetic material, the potential at the system output increases.

If the magnetic circuit is made of non-ferromagnetic material, then the generator has a more flexible design and can be given various configurations.

The execution of the spiral in a closed line, and the core in the form of several turns, can increase the electric potential at the output of the generator.

The use of a semiconductor material as a core contributes to an increase in the value of the output voltage.

If a solenoid is used as the core, then the generator that implements the proposed method imitates a DC transformer at which voltage is obtained at the output of the solenoid.

The method and devices implementing the method of V.V. Torshin are illustrated by 8 figures.

Figure 1 presents a schematic electrical diagram explaining the method of V.V. Torshin.

Figure 2 shows a graph of the relationship between the supply voltage of the field winding and the current of the conductor.

Figure 3 shows an electrical circuit in which a semiconductor material is used as a core.

Figure 4 shows a variant in which the spiral of the magnetic circuit is made of spring material.

Figure 5 shows a diagram of the voltage variation at the output of the core when changing the length of the magnetic circuit under the influence of external forces.

In Fig.6. A schematic electrical diagram is shown in which the spiral of the magnetic circuit is located in a closed line, and the core consists of several turns.

7 there is an electric circuit in which a cathode ray tube is used as a core.

On Fig presents a diagram where a solenoid is used as a core.

The device for generating electric potential (generator) according to the method of V.V. Torshin consists of a core 1 made of electrically conductive material (Fig. 1), around which a spiral of a magnetic circuit 2 is wound, made of soft magnetic material and forming a spiral magnetic field. Excitation winding 3 made of an electrically conductive material is wound on a spiral 2. The winding 3 receives power from a direct current source 4. One end (a) of the core 1 connected to the current source is connected to the end of the electric winding 3, and the electric potential is obtained at both ends (a, b) of the core 1 and measured using a galvanometer 5 (G).

The graph of the output current of the core 1 depending on the supply voltage U of the source 4, connected to the excitation winding 2, has the form of a straight line 6 (figure 2). Moreover, the higher the supply voltage, the greater the output current.

In the embodiment of the technical solution, a semiconductor material (Fig. 3) consisting of two insulated rods 1 ′ and 1 ″ is used as the core. Rod 1 ″ has an n-type structure and rod 1 ″ has a p-type structure. The rods on one side are electrically interconnected at a '. This point is connected to one end of the field winding 3. There is an insulated layer 7 between the rods. A galvanometer 5 or any other meter of electrical signal is connected to the free ends a and b of rods 1 'and 1' '.

In a variant of the technical solution, the spiral 2 of the magnetic circuit is made of non-ferromagnetic material.

In an embodiment of the technical solution, the magnetic circuit 2 is made of spring material (Fig. 3). The magnetic circuit is affected by external forces 8 (F). At the same time, a pressure washer 9 is mounted on the spiral core of the magnetic circuit 2. In the lower part, the magnetic circuit spiral abuts against the stationary washer 10 with a recess 11 for fixing the core 1. In washers 9 and 10, recesses 12 and 13 are provided for the location of the lead wires 14 and 15.

The current graph I, depending on the length L of the core located inside the spiral 2 (figure 4), has the form of a line 16, ascending with increasing height of the magnetic circuit, within the location of the core 1 inside the spiral 2 of the magnetic circuit.

In an embodiment of the technical solution, the spiral 2 of the magnetic circuit is made in the form of a closed line (Fig. 6), and the core 1 is made of several turns located inside a common spiral 2. The connection diagram of the output ends is similar to Fig. 1.

In a variant of the technical solution, the tube 17 of the electron-beam device 18 is placed as a core in the magnetic field of the spiral 2 (Fig. 7). One end a of the tube is connected to the end of the field winding 3. The second end b is the edge of the surface of the display (not shown in FIG.).

In a variant of the technical solution, a non-metallic tube equipped with metal rims at the edges is placed as a core in a magnetic field, and it is filled with water. Rims have electrical contact with water. One tube rim is connected to a current source, the substances dissolved in it are a physical parameter, and the resulting potential is measured on the tube rims and the content of substances dissolved in water is determined from the measurement results. The electrical connection diagram is similar to Fig. 7.

In the embodiment of the technical solution, a permanent magnet is used as the core 1 (not shown in FIG.). The electrical circuit will be similar to FIG. 1.

In a variant of the technical solution, the body of a biological object is used as a core. The electrical circuit will be similar to FIG. 7. In this case, instead of the cathode ray tube, there will be an element of a biological object, for example, a person’s arm or leg or animal’s paw, on which end a will be fixed. The resulting potential is obtained from terminals a and b.

In an embodiment of the device, a coil 19 of a solenoid is wound around the core 1 (Fig. 8). One end c of the coil 19 of the solenoid is connected to the end a of the core and the end of the winding 3 of the magnetic circuit 1. In this case, the differential potential is obtained at the terminals of the coil of the solenoid a and b.

In an embodiment of the technical solution, the core is heated from an external heat source. The circuit diagram is similar to FIG. The resulting potential is obtained from terminals a and b.

In a variant of the method, a photocell is used as a core (not shown in FIG.). The connection diagram is similar to FIG. 1, with the difference that the photocell in the form of an elongated plate, part of which will be exposed to illumination, and the external parameter is light, will be located as the core 1. In this case, the resulting potential is used to determine the amount of illumination.

The dependence of the voltage on the magnitude of the light flux will have the form of a straight line (not shown in Fig.), Ascending as the light flux increases.

The device according to the method of generating electric potential according to V.V. Torshin acts as follows. The appearance of an electric current in a fully open core when exposed to a constant spiral-shaped magnetic field was established by B. Busygin as early as 1990. This effect is somewhat reminiscent of the Hall effect and, apparently, is associated with some features of the movement of electrons in the core under the influence of a specifically distributed magnetic field. However, in the patented method of Busygin B.P. the current in the core was small and could only be detected by highly sensitive devices. With regard to the V.V. Torshin effect, in the experiments, according to the electrical circuits shown in Figs. 1, 3, 6, the devices show a stable and fairly high current, which can be written as a functional dependence I = T _v (V, w ₁ , w ₂ , I _v , L), where I _v is the current in the field winding 3 (Fig. 1), I is the current detected by the device G (5), T _v is the Torshin constant, B is the induction of the spiral magnetic field, w ₁ - the number of turns of the spiral of the magnetic circuit 2 w ₂ - the number of turns of the field winding 3, L - the length of the core 1 placed inside the spiral. In this case, at the ends of the core a and b, a current is recorded (Fig. 2), the value of which directly depends on the supply voltage of the winding 3.

The advantage of the method is that the core 1 and (or) the magnetic circuit 2 can be affected by various external physical parameters and the resulting electric potential can be used to determine the magnitude of these parameters. In other words, the proposed method can be applied in devices for recording various physical quantities. In particular, using the device shown in FIG. 1, it is possible to measure the amount of current flowing through the field winding 3.

When performing the magnetic circuit 2 (Fig. 1) from a soft magnetic material, the potential at the system outlet clamp a and b increases.

If the magnetic circuit 2 is made of non-ferromagnetic material, then the generator has a more flexible design and can be given various configurations.

The execution of the spiral of the magnetic circuit 2 in the form of a closed line (Fig.6), and the core 1 in the form of several turns, can increase the electric potential at the output of the generator.

The implementation of the magnetic circuit 2 of the spring material and the impact on it by external forces (figure 4) allows you to use the effect of V.V. Torshin to register, for example, the magnitude of the load on the balance to measure pressure in various physical devices, etc. In this case, it is sufficient to record the change in the potential difference between clamps a and b.

If a non-metallic tube is placed in a magnetic field as a core and filled with water, then, according to the measurement results and with the accumulation of certain experimental data, it is possible to determine the water pollution by one or another component.

The use of a permanent magnet as the core allows increasing the output potential and changing its value depending on the location of the output clamp relative to the surface of the permanent magnet. In this case, the magnitude and polarity of the potential difference is determined by the position of point b on the surface of the magnet.

The use of a semiconductor material as the core (Fig. 3) contributes to an increase in the value of the output voltage.

If the body of a biological object, for example, a person, is used as the core, then after the accumulation of certain experimental statistical data, the difference in the values of the output voltage in individual parts of the body can be used to obtain some medical diagnostic indicators. For example, a change in the output voltage can be used to register a person’s state when connected to a polygraph apparatus.

If a tube of an electron-beam device is installed as a core in a magnetic field, then by changing the voltage in the field winding 2 (Fig. 7), it is possible to influence the flow of electrons in the tube and, thereby, control light signals on the screen or register minor voltage fluctuations applied to the field winding.

When heating a core made of an electrically conductive material from an external heat source, the generator allows you to measure the temperature of the heating element.

If a photocell is used as a core inside a spiral magnet core, then the external physical parameter will be light, and the resulting potential is used to determine the amount of illumination. In this case, the emf obtained will be higher than the usual photo emf.

Claims (11)

1. A method of generating an electric potential in a core made of an electrically conductive material and placed in a magnetic field formed using a spiral-shaped magnetic circuit equipped with an excitation winding, powered by a current source, characterized in that one end of the core is connected to the end of the excitation winding and the current source, and the electric potential is removed from both ends of the core, and exerting an external influence on the magnetic circuit and / or the core, the magnitude of this electric potential Ala. 2. The method according to claim 1, characterized in that the magnetic circuit is made of spring material, the external force is the mechanical force applied to the magnetic circuit, and the resulting electric potential is used to determine the magnitude of the mechanical force. 3. The method according to claim 1, characterized in that the external effect is expressed in the heating of the core, and the resulting electrical potential is used to determine the temperature. 4. The method according to claim 1, characterized in that the body of the biological object is used as the core, the external action is the process occurring in the biological object, and the resulting electric potential is used for diagnostic purposes. 5. The method according to claim 1, characterized in that as a core in a magnetic field a non-metallic tube is placed, equipped with metal rims at the edges, filled with water, one tube rim is connected to a current source, the substances dissolved in it are an external action, and the resulting the potential is measured on the rims of the tube and the content of substances dissolved in water is determined from the measurement results. 6. Device for generating electric potential, containing a core made of a material that conducts electric current, placed in a magnetic field of a magnetic circuit, made in the form of a spiral, equipped with an excitation winding, powered from a constant current source, characterized in that one end of the core is connected to one the end of the magnetic field excitation winding and a direct current source, and both ends of the conductor are connected to a galvanometer. 7. The device according to claim 6, characterized in that the magnetic circuit spiral is made in the form of a closed toroidal line, and the core is made of several turns. 8. The device according to any one of paragraphs.6 and 7, characterized in that the spiral of the magnetic circuit is made of soft magnetic material. 9. The device according to any one of claims 6 and 7, characterized in that the spiral of the magnetic circuit is made of non-ferromagnetic material. 10. The device according to any one of paragraphs.6 and 7, characterized in that a permanent magnet is used as the core. 11. The device according to claim 6, characterized in that the core is provided with a solenoid, one end of the solenoid is connected to one of the ends of the core, and a galvanometer is connected to both ends of the solenoid.

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