WO2006009484A1 - Method for producing thermal energy and device for carrying out said method - Google Patents

Abstract

The invention relates to methods for producing thermal energy. The inventive method and device for producing thermal energy are based on the use of universe physical space anisotropy by transferring energy to a substance in a space active area wherein the gradient value of a total cosmological potential module AΣ(grad |AΣ|) is other than zero. Said active space area is formed in a liquid in the form of a cavitation area covered by a magnetic field, and the liquid which passed thorough the active area is transferred along a circular circuit in association with modification of the total vector potential AΣ on the liquid motion trajectory. Said invention makes it possible to develop ecologically clean plants for producing thermal energy those thermal power ranges from a minimum value near a kilowatt to a maximum value of hundreds and thousands kilowatts, thereby making it possible do not burn combustible for heating.

Description

 METHOD FOR PRODUCING THERMAL ENERGY AND INSTALLATION FOR ITS IMPLEMENTATION

The invention relates to energy, in particular, to methods for producing thermal energy using the anisotropy of the physical space of the Universe, and can be used to create heat energy systems.

A known method of heating a liquid using the energy of nuclear reactions during the collapse of cavitation bubbles, in which to achieve a high speed of collapse of cavitation bubbles, a cavitation zone is formed in a liquid at a static pressure of 0.5-2.5 MPa (5-25 atm) with excitation in fluid pressure fluctuations with a pressure peak up to 40 MQa (400 atm) [1]. In this method, the heating of the liquid is accompanied by a sharp increase in the background radiation, which makes it unsafe for the environment. There are also known methods for producing thermal energy, the use of which does not increase the background radiation.

A known method of producing thermal energy from mechanical with the accumulation of the received thermal energy by a liquid due to its contact with the heating working bodies of the heat generator. A device that implements such a method is, for example, a friction heater described in [2], in which the working bodies are heated by friction of the end surfaces of a rotating and stationary disks immersed in a heat accumulator tank filled with a heated fluid. Utilization of the generated heat energy can be carried out using typical heat power plants containing heat exchangers, paths of fluid heated and supplied to the consumer, hydraulic pumps with drives, pipelines and hydraulic valves. The heat generator operates in a mode close to laminar, and therefore is very reliable in operation. However, it has low power density and low thermal productivity, while the amount of thermal energy received is equivalent to the amount of supplied mechanical energy.

There is also known a method of heating gas and liquid due to the vortex effect, in which energy is transferred from the central region of the flow to the periphery and the flow is divided into cold and hot parts, the latter of which can be used for heat supply [3].

и используют поле природных источников векторного потенциала Земли и Солнца [4]. В известном способе в активной зоне силовое воздействие производят на вещество, вся масса которого находится в плазменном агрегатном состоянии, при этом формируют стационарное плазменное образование в виде тора, а вещество в плазменном состоянии поддерживают, пропуская его через электродуговой или иной плазменный генератор. Данный способ по своей технической сущности является наиболее близким к заявленному и принят за прототип. Для своей реализации известный способ требует использования плазменных генераторов мощностью до 1 МВт и выше, что ограничивает применение данного способа высокоэнергетическими установками типа ракетных двигателей. Для малоэнергетических систем, например, систем теплоснабжения отдельного дома или отдельно стоящей группы зданий, данный способ неприемлем, так как невозможно поддерживать в устойчивом состоянии маленький плазменный тор.There is also a known method of producing thermal energy, using the anisotropy of the physical space of the Universe (fluctuations in the structure of physical space), which includes the force acting on a material body when it moves, at least, on a part of the path of motion in a region of space with a lower potential with respect to the cosmological vector potential A ₁ . the value of the total vector potential A _∑> in this case, in the indicated area of space create an active zone of space with a non-zero value of the gradient of the modulus of the total potential

and use the field of natural sources of the vector potential of the Earth and the Sun [4]. In the known method in the active zone, a force is applied to a substance, the entire mass of which is in a plasma state of aggregation, while a stationary plasma formation is formed in the form of a torus, and the substance is supported in a plasma state by passing it through an electric arc or other plasma generator. This method in its technical essence is the closest to the claimed and adopted as a prototype. For its implementation, the known method requires the use of plasma generators with a capacity of up to 1 MW and above, which limits the application of this method to high-energy installations such as rocket engines. For low-energy systems, for example, heating systems of a separate house or a separate group of buildings, this method is unacceptable, since it is impossible to maintain steady state small plasma torus.

A number of thermal power plants are known in which cavitation is used for heat production. Most of them have a liquid-filled circulation loop in which a horizontal centrifugal pump, a heat generator, including a device for forming a cavitation zone, and a heat extraction device for the consumer are installed (see, for example, [I]). The heat generation efficiency (the generation of thermal energy is greater than the energy supplied to the installation) in known installations is achieved due to nuclear reactions during the collapse of the cavitation cavity, which makes these installations environmentally unsafe.

и используют поле природных источников векторного потенциала, согласно изобретению, в качестве материального тела используют жидкость, активную зону пространства формируют в жидкости в виде кавитационной зоны с наложением на кавитационную зону магнитного поля, перемещают жидкость, прошедшую активную зону, по контуру с изменением суммарного векторного потенциала А_∑ на траектории движения жидкости, при этом, по крайней мере, на части траектории жидкость перемещают вдоль градиента гравитационного поля Земли с формированием в контуре за активной зоной восходящего и нисходящего потоков жидкости.The problem to which the present invention is directed, is to expand the capabilities of the method of producing thermal energy and to develop a plant for producing thermal energy using the anisotropy of the physical space of the Universe, by expanding the range of the level of generated thermal power in the region of low thermal loads, up to 1-5 kW . Another objective of the invention is to develop a method for producing thermal energy using the anisotropy of the physical space of the Universe, which provides convenient power control over a wide range of power changes. An additional objective of the invention is the maximum use in the production of thermal energy of the possibilities of natural sources of the total vector potential of the planet Earth, in particular its gravitational and magnetic fields, and artificially generated sources of vector potential, for example, artificial magnetic fields. Another objective of the invention is the development of an environmentally friendly method for producing thermal energy using the anisotropy of the physical space of the Universe. The stated technical problems are solved by the fact that in the known method of generating thermal energy, which includes the force acting on a material body when it moves, at least on a part of the path of movement in the space region with a reduced total vector value relative to the cosmological vector potential A _r potential A _∑ , while in this region of space create an active zone of space with a non-zero value of the gradient of the modulus of the total potential

and using the field of natural sources of the vector potential, according to the invention, a liquid is used as a material body, the active zone of space is formed in the liquid in the form of a cavitation zone with a magnetic field superimposed on the cavitation zone, the fluid passing the active zone is moved along the circuit with the total vector potential changing _Σ a liquid on a trajectory of motion, wherein at least a portion of the fluid path is transferred along the gradient of the gravitational field of the earth to form a loop of core ascending and descending liquid streams.

In this case, in the upward flow of the circuit, the liquid is moved up with a height difference of at least 2.6 m.

In addition, for the movement of fluid in the circuit, a centrifugal pump is used with specific energy expenditures Y (W / l) in one pump stage, satisfying the ratio:

0 <Y <39 - 3X ₉ where X is the number of stages of the centrifugal pump, an upward flow of liquid is formed directly above the centrifugal pump, and at the pump inlet, the static pressure of the liquid is maintained below the pressure of formation of the cavitation zone when flowing around the centrifugal pump vanes. In this case, the movement of the liquid along the circuit is carried out at a static pressure exceeding the vapor pressure of the liquid vapor by 5-500 kPa.

In addition, the liquid in the circuit is moved in the plane of the Earth’s magnetic meridian, while at the entrance to the centrifugal wheel vanes, the liquid is moved parallel to the lines of force of the Earth’s magnetic field.

In this case, an additional cavitation zone is created at the outlet of the centrifugal pump in an upward fluid flow with a magnetic field with a magnetic induction of 0.05 to 10 mT (0.5-100 G) applied to the cavitation zone.

Moreover, the effect on the liquid is carried out by a magnetic field with the orientation of its magnetic induction vector at angles from 40 to 60 ° with respect to the direction of the vector A _n or with the orientation of its magnetic induction vector at angles from 80 to 100 ° with respect to the direction of the vector A _n or orientation of the vector of its magnetic induction at angles from 120 to 140 ° with respect to the direction of the vector A _n

In addition, in the main cavitation zone, the process of cavitation in a liquid is carried out in a magnetic field with magnetic induction from 0.05 to 10 mT (0.5-100 G).

Moreover, the effect on the liquid is carried out by a magnetic field with the orientation of its magnetic induction vector at angles from 40 to 60 ° with respect to the direction of the vector A _n or with the orientation of its magnetic induction vector at angles from 80 to 100 ° with respect to the direction of the vector A _n or orientation of the vector of its magnetic induction at angles from 120 to 140 ° with respect to the direction of the vector A _n

In addition, at least 0.2 m ^{3 of} liquid is poured into the closed loop. In relation to the installation for generating thermal energy, the stated technical problems are solved by the fact that in the installation containing a liquid-filled circulation loop in which a horizontal centrifugal pump, a heat generator including a device for forming a cavitation zone and a heat extraction device for a consumer, according to the invention, are filled the liquid circulation circuit is located vertically above the centrifugal pump and includes interconnected lying in the same vertical the surface of the pipeline upward and downward fluid flows, while the device for the formation of the cavitation zone is installed at the inlet of the upstream pipeline.

In this case, the upward fluid flow pipeline is made at least 2.6 m high. In addition, the axis of the centrifugal pump is oriented parallel to the lines of the Earth's magnetic field.

In this case, the pipelines of the ascending and descending fluid flows are smoothly interconnected at the upper point.

In addition, the device for the formation of the cavitation zone is made in the form of an adjustable ultrasonic wave generator installed at the outlet of the centrifugal pump, while the installation is equipped with a magnetic field source covering the indicated cavitation zone, the magnetic force lines of which are directed along the upward fluid flow pipeline. In this case, the heat extraction device to the consumer is made in the form of a recuperative heat exchanger installed in a circulation loop behind the upward liquid flow pipeline.

The essence of the invention lies in the fact that in the active zone in the substance form many small-scale plasma tori, using as the basis for the formation of small-scale plasma torus cavitation cavity in a liquid. Cavitation (see, for example, [5, 6, 7]) refers to physical phenomena, the use of which is currently actively developing, despite the incompletely developed theory of the physics of cavitation processes. It is known that in the microregion of collapse of the cavitation cavity, high pressures and temperatures are observed [6, p. 177]. Sparking from electric discharges and luminescence are also noted, indicating the presence of positive and negative ions in the collapsing cavitation bubble. The presence of ions is also confirmed by the influence of electric and magnetic fields on cavitation [8, p. 227]. Positive and negative ions in the cavitation cavity form a kind of plasma microcloud used in the proposed method. The cavitation zone includes many small cavitation cavities. When a magnetic field is applied to the cavitation zone, each of the cavitation cavities is transformed upon collapse into a plasma microtor. By its nature, the plasma microtor does not differ from the plasma torus in the prototype method and it implements the same mechanism for converting the anisotropic properties of the Universe into thermal energy. The movement of the fluid that has passed the active zone along the contour with a change in the total vector potential A _∑ on the trajectory of the fluid, creates regions with a gradient of A _∑ , by changing the value of which it is possible to increase and decrease the degree of heating of the fluid. Moving the fluidity along the gradient of the Earth’s gravitational field allows the most use of the Earth’s strongest natural source of influence on the total vector potential A _∑ and, accordingly, on the particles of matter in the core — the Earth’s gravitational field. In this case, the formation of upward and downward fluid flows in the circuit behind the active zone provides the most significant use of changes in the potential of the Earth's gravitational field. The cavitation intensity, the number of cavitation cavities, can be easily controlled from the outside without significant energy consumption, which makes the proposed method promising for use in low-energy thermal installations, significantly expanding the scope of application of the proposed method and installation for its implementation.

The movement of fluid in the upward flow of the circuit up with a height difference of at least 2.6 m ensures the efficient generation of thermal energy in the circuit with more thermal energy than the energy spent on moving the fluid along the circuit. The upper limit of the height of fluid upward movement is determined by the pressure of the pump pumping the fluid along the circuit and the hydraulic resistance of the circuit.

The use for the movement of fluid in the circuit of a centrifugal pump with a specific energy consumption of Y (W / l) in one stage of the pump, satisfying the ratio:

О <Y <39 - ЗХ, where X is the number of stages of the centrifugal pump, with the formation of an upward flow of liquid directly above the centrifugal pump, and maintaining the static pressure of the liquid at the inlet of the pump below the pressure of formation of the cavitation zone when the centrifugal pump flows around the blades, provides the contour of the natural cavitation zone on the blades of a centrifugal pump, which makes it possible to obtain thermal energy only through the use of natural sources of the vector potential of planet Earth ( gravitational and magnetic fields).

The movement of the liquid along the circuit at a static pressure exceeding the vapor pressure of the liquid by 5–500 kPa ensures that the heat release in the circuit will not be accompanied by nuclear reactions and, therefore, there will be no increase in the radiation field, which makes the proposed method environmentally friendly. The movement of fluid in the circuit in the plane of the Earth’s magnetic meridian, while at the entrance to the centrifugal wheel vanes, the fluid moves parallel to the lines of force of the Earth’s magnetic field, maximizing the use of the Earth’s magnetic field.

The creation of an additional cavitation zone at the outlet of the centrifugal pump in an upward fluid flow with the application of a magnetic field with magnetic induction from 0.05 to 10 mT (0.5-100 G) on the cavitation zone makes it possible to increase the heat release intensity in the circuit and simplifies the regulation of heat generation in the liquid.

The claimed changes in the orientation angles of the magnetic induction vector with respect to the direction of the vector A ₁ . provide an effective conversion of the anisotropy of the physical space of the Universe into heat. The method can be carried out without using the Earth’s natural magnetic field if the artificially created cavitation zone is placed in a magnetic field with magnetic induction from 0.05 to 10 mT (0.5-100 G), which makes it possible, if necessary, to arbitrarily orient the installation relative to the Earth’s magnetic field. In this case, the claimed changes in the orientation angles of the magnetic induction vector with respect to the direction of the vector A ₁ . also provide an efficient conversion of the anisotropy of the physical space of the Universe into heat.

When using in a closed loop at least 0.2 m ^{3 of} liquid, all particles of liquid exposed to

large gradients -, to the initial (calm) state. dh

Execution of a liquid-filled circulation loop in the form of upward and downward fluid flows connected to each other and lying in the same vertical plane with their location vertically above the horizontal centrifugal pump and the installation of an upward flowing device at the inlet of the device to form the cavitation zone of the heat generator makes it possible to use cavities of the cavitation zone to form many small-scale plasma tori for converting the anisotropic properties of the Universe into thermal energy.

The implementation of the pipeline upward fluid flow with a height of not less than 2.6 m allows you to most effectively use the gradient of the gravitational field of the Earth. The upper limit of the height of the upstream pipeline is determined by the pressure of the centrifugal pump and the hydraulic resistance of the circuit.

Orientation of the axis of the centrifugal pump parallel to the lines of the Earth's magnetic field ensures its most efficient use. The smooth conjugation of pipelines of upward and downward fluid flows between themselves at the upper point provides minimal hydraulic resistance and a high coefficient of heat dissipation.

The inclusion in the installation of the device for the formation of the cavitation zone, made in the form of an adjustable ultrasonic wave generator installed at the outlet of the centrifugal pump, and equipping the installation with a magnetic field source covering the specified cavitation zone, the magnetic force lines of which are directed along the upward liquid flow pipeline, intensifies heat generation and gives the ability to regulate the cavitation process and, accordingly, the heat release in the circuit.

The implementation of the device for the selection of heat to the consumer in the form of a recuperative heat exchanger installed in the circulation loop behind the upward liquid flow pipeline, makes it possible to organize heat supply to any consumer, including remote from the installation without interfering with the heat release in the circuit.

The technical result from the use of the invention is the possibility of manufacturing environmentally friendly plants for generating thermal energy with a minimum thermal power of one kilowatt and with a maximum thermal power of hundreds and thousands of kilowatts, which will allow to refuse from burning fuel for heating.

Figure l shows a schematic diagram of a heat power plant that implements the proposed method; figure 2 shows a schematic diagram of the formation and dynamics of the plasma region during the collapse of the vacuum cavitation cavity (two successive positions of the cavitation cavity are shown); Fig. 3 shows a diagram of the polarization of the magnetic moments of elementary particles during the collapse of a vacuum cavitation cavity; figure 4 shows the results of experimental verification of the method.

The heat power plant includes a horizontal centrifugal pump 1 with an electric drive 2, included in the liquid-filled circulation circuit 3, having pipelines 4 and 5 of upward and downward fluid flows lying in the same vertical plane, a tank 6 and a supply pipe 7 connecting the tank 6 to the inlet of the centrifugal pump. The circulation circuit 3 is located above the centrifugal pump. Pipelines 4 and 5 are smoothly interconnected at an upper point. The pipeline 4 of the upward fluid flow has a height of not less than 2.6 m. In the experimental setup, the height of the pipe 4 changed in the heat generation mode from 2.6 to 4 m. At the outlet of the centrifugal pump, a device for the formation of a cavitation zone is installed, which is an adjustable 8 ultrasonic generator waves with the control unit 9. The 8 ultrasonic wave generator is placed in a magnetic field that is generated by a magnetic field source, for example, a magnetic coil 10 with a power supply 11. The axis of the centrifugal pump is oriented in the South-North direction along the lines of force of the Earth’s magnetic field, and the circulation loop 3 itself is located in the plane of the Earth’s magnetic meridian. A cavitating centrifugal pump, together with the Earth's magnetic field, turns the pump inlet section into a heat generator that converts the energy of the cosmological vector potential A _r into heat. A section of the pipeline 4, on which the ultrasonic oscillation generator 8 and the magnetic coil 10 are mounted, forms a second heat generator. A recuperative heat exchanger 12 for heat extraction to the consumer is installed on the pipeline 5 for the downward fluid flow. The circulation circuit is equipped with a flow controller 13. The experimental setup was equipped with devices for monitoring its operation, including a thermometer 14, which measures the temperature of the liquid in the tank 6.

на несколько порядков превышает аналогичную характеристику окружающего пространства, что способствует преобразованию энергии космологического векторного потенциала A_r в тепловую.When operating in heat generation mode, a centrifugal pump 1 pumps water along the circulation circuit 3 with a given flow rate. Water enters the inlet of the centrifugal pump 1 in a zone in which the absolute value of the vector of the total vector potential is equal to A _∑ ι, flows around its blades and a natural cavitation zone 15 with many separate cavitation cavities forms on the back side of the blades. The cavitation zone is the active zone of space in which heat energy is released. Since the axis of the centrifugal pump 1 is oriented in the South-North direction, the water at the pump inlet flows parallel to the lines of force of the Earth’s magnetic field, and when the cavitation cavities collapse under the influence of the magnetic field, plasma microtors are formed that move along the lines of force of the Earth’s magnetic field with a stream of water. When the cavitation cavity collapses, a zone is formed in which the gradient of the modulus of the total potential

several orders of magnitude higher than the similar characteristic of the surrounding space, which contributes to the conversion of the energy of the cosmological vector potential A _r into heat.

The section of the pipeline at the outlet of the centrifugal pump, equipped with a generator 8 of ultrasonic vibrations and a magnetic coil 10, where the absolute value of the vector of the total vector potential is A _∑ χ, works similarly. The water treated in cavitation zones rises up along the gradient of the Earth’s gravitational field with a change in the absolute value of the vector of the total vector potential A _∑ from A _{∑ \} or A _∑ ι to A ^, which contributes to an increase in heat generation in the circulation circuit 3. The released heat is transferred to the consumer through recuperative heat exchanger 12. It is also possible the inclusion of the consumer directly into the circulation circuit. In accordance with the proposed method, the production of thermal energy is carried out in the following way. At any point in space simultaneously there are various fields (gravitational, magnetic, electric, etc.), each of which has its own effect on A _∑ . The experiments carried out by the authors to study the collapse of vacuum cavitation cavities arising in a centrifugal pump or cavitator, which, as a rule, have the shape of spherical bubbles, in natural and artificial magnetic fields showed that when the bubble collapses, plasma microregions 16 and closed electric currents 17, i.e. a plasma microregion is formed, which is penetrated by the lines of force 18 of the magnetic field, for example, the Earth's magnetic field. For convenience, in FIG. 2, the lines of force 18 are shown orthogonally to the figure. When the cavitation cavity collapses, the direction of collapse is shown by arrow 19, the diameter of the plasma region decreases, compressing in a natural way the magnetic field, for example, the geomagnetic field of the Earth, forming zone 20 with an increased gradient of the total vector potential A _∑ (vector 21).

When the plasma microregion 16 collapses in an external magnetic field, a micromotor 22 with a circular current flow is formed (Fig. 3 shows three micromotors 22 having three different orientations relative to the cosmological potential vector A _r in accordance with three different orientations of the external magnetic field). The ring currents of the micromotor 22 generate their own magnetic field, in which the magnetic moment vector M 23 is directed perpendicular to the plane of the torus. Under the influence of a magnetic field, the magnetic moments of elementary particles are polarized, so that the vectors 24 of their magnetic moments are oriented parallel to the vector 23. In the presence of a gradient of the total vector potential A _∑ , a force F acts on any material object with mass either directed along the vector A _n or cone with a solution of ~ 100 ° (for a detailed explanation see below, as well as in [9, 10, H]). The figure also shows the angles of the optimal direction of the magnetic field (80 ° - 100 °) with respect to the force F. Heating of the liquid in the circulation loop is associated with the existence of global anisotropy of the physical space of the Universe [9].

In this work, it is noted that the world around us (space, time and elementary particles) arises as a result of the dynamics and interaction of special discrete objects that have an internal vector property. These objects are called bouons. The expression for them has the following form:

где A_r & 1,95-10 Гс-см - модуль космологического векторного потен- циала (фундаментальной векторной константы, введенной в работе [9] и в ряде других работ).Φ (ι) = A _r -X (i), where X (i) is the "length" of the bouon - a real (positive or negative) quantity, depending on the index / = 0, 1, 2, ..., k,. .. is the quantum number of the quantity Ф (ϊ). Vector A _τ is a vector potential that takes only two values in magnitude:

where A _r & 1.95-10 G-cm is the module of the cosmological vector potential (the fundamental vector constant introduced in [9] and in a number of other works).

If the objects interact, then in reality the expression for the bouons always includes some total potential A _∑ , which is always modulo less than | A _G |, i.e. Φ (i) = A _∑ • X (i). (i.e., in reality, the expression for describing the bouon has the form Ф (i) = А _∑ -X (i)).

It is shown that the masses of all elementary particles are proportional to the modulus of the vector A _∑ , therefore, if we reduce A _{∑ in} any way (due to the vector potential of the current or magnetic field, Coulomb potential or gravitational potential), then any material object with mass will act force F, first experimentally discovered in [10], which pushes this object out of the region of weakened vector potential.

This force is representable by a complex series of changes in ΔА _∑ . The first term of the expansion of this series in ΔA _∑ gives the following physical dependence of the force F on ΔA _∑ :

F = N- 2m _ve c ² - λ ₁ ² - ΔA _∑ ^^, (1) dx where x is the spatial coordinate of the observed three-dimensional space R ₃ ;

N is the number of stable particles in the liquid volume (electrons, protons, neutrons);

2m _ve c ² — intrinsic energy (residual potential energy ~ 33 eV) [9] of four-contact interaction of buons, which forms the geometric space of an elementary particle; λι is the first coefficient of the force series F.

According to experiments [11] in the second equatorial coordinate system, the vector A ₁ . has the following coordinates: right ascension α = 293 ° + 10 °, declination δ = 36 ° ± 10 °. The force F acts on the cone 5 around the vector A ₁ . with a solution of "100 ° and the vector A _r .

Since the vacuum cavitation spherical bubbles dAA _Σ have dimensions of several microns, the value - in them can reach significant values dx due to the smallness of x. Moreover, the value AA & B • x (the estimate was made on the basis of the expression B = rotA taken from Yu [12, p. 219]) is not large, since B on the Earth is ~ 0.4 G, and x for the bubble is ~ 10 ^'3 - 10 ^"4 cm. From the law of conservation of magnetic energy locked in the plasma formation of a cavitation bubble, it can be shown that when the bubble collapses, the magnetic field B grows according to the law:

B = B ₀ - (I ₀ Zl ₁ ) ³¹² , 15 where B ₀ is the external magnetic field;

I ₀ - the characteristic size of the bubble at its birth; Z ₁ - bubble size at the time of disappearance.

Then, if I ₀ = 10 ^"3 , Z ₁ = 10 ^{" 7} , then B at B ₀ = 0.4 G (geomagnetic field) will be 0.4-10 ⁶ G. The values of B can be significantly

20 more with smaller Z ₁ Using these fields, the magnetic moments of electrons and other elementary objects can be rotated,

for example, ions, and obtaining values - at the level of 10 ¹⁴ -10 ¹⁶ G in dx neighborhood of elementary objects.

Studies by the authors showed that the substance

“Remember” it

(i.e., carries this information in its coordinate system about the gradient A _{∑ of the} order of several minutes). Thus, if along the trajectory of the object,

having been in the zone of significant -, there will be a change in AA _∑ due to dx due to the vector potentials of the magnetic system of the Earth or the Sun, Coulomb or gravitational potential, then the magnitude of the force F can become significant.

If the particles of water that have been in the cavitation zone move along the gradient of the Earth’s gravitational field, as well as from the South to the North or in the opposite direction with respect to the magnetic poles of the geomagnetic field, then AA _∑ will change along their trajectory by the value В-г, where g - distance traveled by objects in the indicated directions (South “→ North). If B = 0.4 G, g «100 cm, then AA _∑ ∞ 40 Tc-CM.

The value ΔА _∑ can vary in time and in space due to changes in currents in the Earth’s magnetosphere and ionosphere by significant values arising from various fluctuations in the density and magnetic field in the solar wind. According to [13], a geomagnetic storm grows in about minutes. The value of B changes by 30 γ, where γ = 10 ^"5 G. Due to the enormous size of the Earth's magnetosphere ~ 10 R _E , where R _E is the radius of the Earth, AA _{величина} in these phenomena can reach ~ 10 ⁶ G-cm.

Let us evaluate the change in A _∑ due to a change in the gravitational field of the Earth during the movement of an object along the gradient of the gravitational field of the Earth.

где т - масса частицы; v - скорость;This estimate can be obtained by equating the contribution of the terms included in the Lagrangians [14, p. 70, p. 293], corresponding to the gravitational and electromagnetic interaction of the electron for the nonrelativistic case.

where t is the mass of the particle; v is the speed;

A is the vector potential; φ is the gravitational potential; e is the elementary charge; c is the speed of light; k is a coefficient determined from the theory of buons [9] in accordance with the assumption that we can influence with probability 1 due to a change in ΔА _∑ only the part of the mass associated with the formation of the physical space of an elementary particle, i.e. by 33 eV, from the intrinsic energy of the proton (m _p c ² ), neutron (m _p c ² ), electron (m _e c ² ). For a water molecule containing 26 stable particles, the coefficient k is 5-KG ⁸ -l (Г ¹⁵ 5 5-l (Г ^23. In the extreme case of lifting water of mass m to a height h, expression (2) can be written as:

kmgh = -, (3) with where g is the acceleration of gravity.

From (3) we obtain an estimate of the change ΔA _∑ »A due to the gravitational field for the masses of elementary particles of water in the form: m tШЁL ± ₍₄₎ е - v

For a volume of water with a mass of 250 kg, h = 2.5 m and v = 4 m / s, we have ΔА _∑ - 4.7-10 ⁵ G-cm. As can be seen, this estimate ΔА _{∑ is} comparable and even somewhat less than that of a magnetic storm. The extreme capabilities of the proposed method can be estimated by assuming that all elementary particles of water participated in the production of thermal energy. If in equation (1), which describes the force F, substitute N∞ 10 ²⁹ (the number of stable elementary particles in water

weighing 250 kg), ΔА _∑ = 10 ⁵ G-cm., ^ - ^ - at the level of 10 ¹⁴ G., λi "10 ^{" 12} dx

(Gf-cm) ^"1 (obtained in experiments on high-current magnets [9]), then we will get the force F at the level of 10 ⁹ H. The work done by such a force when lifting water to a height of 2 m will be equal to" 2-10 ¹⁰ J. This value is two orders of magnitude higher than the energy required to heat the indicated volume of water at 100 ⁰ C (10 ⁸ J). This estimate is naturally very high (since it was assumed that all elementary particles of water were in the cavitation zone), but the above calculation shows that the energy associated with the force F is quite enough to carry out the percent essa water heating.

To confirm the claimed method, the authors conducted a series of experiments (about 120) with installations having different volumes of capacity 14 for liquids (20 l, 35 l, 46 l, 190 l, 200 l, 210 l, 251 l) with different heights of water rise (a telescopic device was used to smoothly change the height from 0.8 to 2.6 m from the cutoff of the water pump). The results of experiments with the installation having a vertical circulation circuit located in the plane of the Earth’s magnetic meridian are presented in FIG. 4. The active zone of the heat generator was located at the entrance to the centrifugal pump and was a natural cavitation zone on the blades of a centrifugal pump, in which the fluid flowed parallel to the lines of force of the Earth's magnetic field. During the experiments, the temperature in tank 6 was recorded - graph I and power consumption - graph P. The measurement results determined the rate of heating of the fluid - graph III, the change in the thermal energy of the fluid (heat dissipation in the fluid) - graph IV and the coefficient K equal to the ratio produced in the circuit of thermal energy to power consumption, - graph V, which also indicates the numerical values of K, calculated at control points.

The average fluid heating rate was 0.53 deg / min, which corresponds to K = 1.08. During the experiment, a surge in the rate of heating of the liquid to 0.74 deg / min was observed, which corresponds to K = 1.6. The radiation background at the facility remained unchanged and did not exceed the natural background. An analysis of the experiment showed that a burst in the heating rate correlates in time with a geomagnetic storm associated with a solar flare. The observed phenomenon confirms the possibility of a change in heating in the considered heat power plants depending on the geomagnetic situation and the physical nature of the proposed method for converting electric energy into heat, since changes A _∑ due to a slight violation of the potentiality of the gravitational field (4.7-10 ⁵ G) are very close with changes A _∑ due to changes in the geomagnetic situation in the vicinity of the Earth (1O ⁶ Fc). Thus, using natural sources of the vector potential of the Earth and the Sun, it is possible to obtain an increase in thermal energy from 5 to 60% relative to the consumed power with complete environmental safety of the installation.

When a second core is formed in the loop — the installation of a cavitator and a magnetic coil at the outlet of a multistage centrifugal pump — it is possible to obtain a heating rate of 1.5–2 deg / min and higher, which corresponds to K> 3.

Maintaining the specific energy expenditures Y in a centrifugal pump in accordance with the number of X stages in the pump with the fulfillment of the condition 0 <Y <39 - ZX ensures that the coefficient K> 1 is achieved in the installation, ensuring the efficient operation of the installation in heat generation mode. Sources of information taken into account when filling out the application:

1. Kladov A.F. "Method of energy production", patent of the Russian Federation JVb 2054604 from 02.20.1996 on the application JNb 93033524/25 from 02.07.1993, MPK: F24J 3/00, G21B 1/00.

2. Dobrov M.G. "Friction engine", USSR copyright certificate JNb 1627790 of 02.15.1991 on the application JN ° 4694602/06 of 05.24.1989, IPC: F24J 3/00.

3. Potapov Yu.S. "Heat generator and device for heating a liquid", patent of the Russian Federation JVb 2045715 from

10/10/1995. by application JNb 93021742/06 of 04/26/1993, IPC: F25B 29/00.

4. Baurov Yu.A., Trouble G.A., Danilenko I.P., Ogarkov V.M. "A method of producing energy and a device for its implementation", patent of the Russian Federation JNb 2147696 dated 04/20/2000 according to the application JNb

98111700 from 06/18/1998, IPC: F03G 7/00, H05H 1/54.

5. Pernik A. D. Problems of cavitation. - 2nd ed., Ext. and corrected. L .: Shipbuilding, 1966.

6. Knepp R., Daily J., Hammit F. Cavitation. Translation from English under the editorship of B.I. M .: World, 1974.

7. Pierce And .. Cavitation. Translation from English under the editorship of L.A. Epstein. M .: Mir, 1975.

8. Physical Encyclopedia, vol.2, p.227.

9. Bauróv Yu.A. On the Structural Offshore Vacuum Apd and the Advanced OptiP Nature (Theoru, Exrept Ap Arrlisatiops). Nova

Sciepse, NY, 2000. Yu. Baurov Yu.A.,. Klimepko E. Yu, Norvikov SI Exterptal observatiop of Srace tagis apisotoru. Phs. Lettt. A v. 162, 1992, p. 32. 11. Baurov Yu.A., Timofeev IB, Chernikov BA, Chalkin SI. Experimental studies of spatial anisotropy radiation pulsed plasma torch. - "Applied Physics", 2002, JYO 4, p. 48-57; Phs. Lettt. A. 311 (2003), p.512-523.

12. Tamm I.E. Fundamentals of the theory of electricity. 8th ed., M.: Science, 1996.

13. Hess V. Radiation belt and magnetosphere. M .: Atomizdat, 1972.

14. Landau L.D., Lifshits E.M. Field theory. M .: Science, 1967.

Claims

CLAIM 1. A method of producing thermal energy, including the force acting on a material body during its movement, at least on a part of the path of movement in the region of space with a lower potential with respect to the cosmological vector potential A ₁ . the value of the total vector potential A- _∑ , while in this region of space create an active zone of space with a non-zero value of the gradient of the modulus of the total potential

and use the field of natural sources of vector potential, characterized in that a liquid is used as a material body, the active zone of space is formed in the liquid in the form of a cavitation zone with a magnetic field superimposed on the cavitation zone, the fluid that has passed the active zone is moved along the contour with a change in the total vector a _Σ potential on the trajectory of motion of a fluid, wherein at least a portion of the fluid path is moved along the earth's gravitational field gradient forming a loop for su- zone ascending and descending liquid streams. 2. The method according to claim 1, characterized in that in the upward flow of the circuit, the liquid is moved up with a height difference of at least 2.6 m. 3. The method according to claim 2, characterized in that for the movement of fluid in the circuit, a centrifugal pump is used with specific energy consumption Y (W / l) in one pump stage, satisfying the ratio: 0 <Y <39 - ZX, where X is the quantity stages of a centrifugal pump, an upward flow of liquid is formed directly above the centrifugal pump, and at the pump inlet, the static pressure of the liquid is maintained below the pressure of formation of the cavitation zone when flowing around the blades of a centrifugal pump. 4. The method according to p. 3, characterized in that the movement of the fluid along the circuit is carried out at a static pressure exceeding the vapor pressure of the vapor by 5-500 kPa. 5. The method according to p. 3, characterized in that the liquid in the circuit is moved in the plane of the Earth’s magnetic meridian, while at the entrance to the centrifugal wheel vanes, the liquid is moved parallel to the lines of force of the Earth’s magnetic field. 6. The method according to claim 5, characterized in that in the upward flow of fluid create an additional cavitation zone at the outlet of the centrifugal pump with a magnetic field with magnetic induction from 0.05 to 10 mT (0.5-100 G) applied to the cavitation zone. 7. The method according to claim 6, characterized in that the effect on the liquid is carried out by a magnetic field with the orientation of its magnetic induction vector at angles from 40 to 60 ° with respect to the direction of the vector A _g . 8. The method according to claim 6, characterized in that the effect on the liquid is carried out by a magnetic field with the orientation of its magnetic induction vector at angles from 80 to 100 ° with respect to the direction of the vector A _τ . 9. The method according to claim 6, characterized in that the liquid is exposed to a magnetic field with the orientation of its magnetic induction vector at angles from 120 to 140 ° with respect to the direction of the vector A _g . 10. The method according to claim 2, characterized in that the process of cavitation in a liquid is carried out in a magnetic field with magnetic induction from 0.05 to 10 mT (0.5-100 G). 11. The method according to claim 10, characterized in that the effect on the liquid is carried out by a magnetic field with the orientation of its magnetic induction vector at angles from 40 to 60 ° with respect to the direction of the vector A _τ . 12. The method according to claim 10, characterized in that the effect on the liquid is carried out by a magnetic field with the orientation of its magnetic induction vector at angles from 80 to 100 ° with respect to the direction of the vector A _x . 13. The method according to claim 10, characterized in that the effect on the liquid is carried out by a magnetic field with the orientation of its magnetic induction vector at angles from 120 to 140 ° with respect to the direction of the vector A _τ . 14. The method according to any one of claims 1 to 13, characterized in that at least 0.2 m ^{3 of} liquid is poured into the closed loop. 15. Installation for generating thermal energy, containing a liquid-filled circulation loop, in which a horizontal centrifugal pump, a heat generator including a device for forming a cavitation zone, and a heat extraction device for a consumer are installed, characterized in that the liquid-filled circulation loop is located vertically above the centrifugal pump and includes interconnected lying in the same vertical plane pipelines of upward and downward fluid flows, with that the device for the formation of the cavitation zone is set to the upstream inlet conduit. 16. The installation according to clause 15, wherein the upward fluid flow pipe is made not less than 2.6 m high. 17. Installation according to claim 15, characterized in that the axis of the centrifugal pump is oriented parallel to the lines of the Earth's magnetic field. 18. Installation according to claim 15, characterized in that the pipelines of the upward and downward fluid flows smoothly interconnected at an upper point. 19. Installation according to clause 15, wherein the device for the formation of cavitation zone is made in the form of an adjustable an ultrasonic wave generator installed at the outlet of the centrifugal pump, while the installation is equipped with a magnetic field source covering the indicated cavitation zone, the magnetic force lines of which are directed along the upstream pipeline ! LIQUIDS. 20. Installation according to any one of paragraphs.15-19, characterized in that the device for heat extraction to the consumer is made in the form of a regenerative heat exchanger installed in a circulation loop behind the upward fluid pipe.