WO2007040423A1 - Method for realising energy by means o a reciprocating motion and a device for converting and releasing energy in liquid media - Google Patents

Abstract

The invention relates to methods for producing an action on a fluid medium flow and can be used in hydrodynamic engineering, mainly, in heat-exchange and mass-exchange devices. The inventive method consists in forming a primary working fluid body flow outside of a heat generator space area, in translationally moving said primary flow, in applying an external disturbing action on the fluid body flow inside the heat generator space, in forming secondary fluid body flows and in leading the working fluid body flow in a discharge direction, wherein the primary flow is formed in a pipeline whose diameter is equal to the diameter of the heat generator input socket. The inventive energy-releasing device comprises a vortex tube, hydrodynamic converters which are used for converting the fluid medium motion and are embodied in the form of cones on the vortex tube ends, a flow former whose symmetry axis is coaxial with the longitudinal axis of the vortex tube and a flow splitter, which is embodied in the form of a plate whose surface is arranged in a parallel position with respect to the longitudinal axis of the vortex tube, wherein the vortex tube is provided with spiral grooves embodied on the internal wall of the cylindrical sector thereof which is made of a laminated plastic and is provided with a metal jacket.

Description

 Description of the group of inventions

A method of energy release by means of rotational-translational motion of a liquid and a device for converting and releasing energy in liquid media.

A method of energy release through rotational - translational motion of a liquid. The invention relates to methods for influencing a fluid flow and can be used in hydrodynamics, mainly in heat and mass transfer apparatuses. The invention also relates to the field of heat engineering. It can be used in heat generators providing heat supply to large systems of high and medium pressure, as well as in devices for heating liquids, used mainly for various heating systems, for example, in heating systems of buildings and structures, as well as in hydrocarbon production.

The invention is known “A method of producing heat and a device for its implementation)), W patent RU 2242684, publ. 2004.12.20, IPC F24JЗ / 00, in which the preformed flow of the liquid coolant is accelerated to a directed vortex state, for which, in a limited space, the target coolant flow rate is reached by the surface of the swirl working body. The invention is used to directly convert mechanical energy into thermal energy, increase the efficiency of conversion of rotational energy to thermal energy, and simplify the design of a heat generator. However, the proposed method requires preliminary heating of the liquid, which reduces the efficiency and increases the energy consumption for the implementation of the process. In this method, the liquid is transferred to the vapor-gas mixture, which also leads to a decrease in the efficiency of conversion of rotational energy into thermal energy.

The invention is known “A method of producing thermal energy and a heat generator for its implementation)), application RU ₃ Xa 2003132417, publ. 2005.05.10, IPC F25B29 / 00, according to which the production of thermal energy in liquid media carried out by converting the energy of a moving fluid into thermal energy, for which the moving flow of a liquid medium is subjected to continuous and intense swirling. However, in this method, the efficiency of converting rotational energy into thermal energy is low. The invention is known “A method of increasing the efficiency of the process of heat generation in a cavitation vortex heat generator)), application RU 99110395, publ. 2001.03.20, IPC F24JЗ / 00 according to which a vortex flow is generated in a vortex heat generator. The energy of the stream is converted into thermal energy. However, only a cavitation flow is used, in which the conversion is carried out by the collapse of cavitation cavities formed in the cavitation zone of the working channel and the simultaneous conversion of the kinetic energy of rotation of the stream exiting the working channel to potential. In this case, the resonance effect is not used, which leads to a decrease in the efficiency of conversion of rotational energy into thermal energy.

The invention is known “Method of intensification of the working process in vortex cavitation apparatus)), patent RU, N ° 2212596, publ. 2001.02.20, IPC F24JЗ / 00, in accordance with which the fluid flows through an axisymmetric channel of variable cross-section and: creates stream lines transverse to the main flow for vortices with cavitation cavities. In this case, only cavitation flow and the simultaneous conversion of the kinetic energy of rotation of the stream exiting the working channel into potential are used. In this case, the resonance effect is not used, which leads to a decrease in the efficiency of conversion of rotational energy into thermal energy. The closest to the proposed technical solution is the invention "Method of creating a system of flows)), patent RU, Na 2086812, publ. 1997.06.27, IPC F15D1 / 00 F 15Dl / 14, according to which the flow is formed outside the spatial region of the primary fluid flow, the flow has a translational motion, the primary flow is formed with a longitudinal translational motion, an external perturbation is applied to the fluid to form the interaction zone within the spatial region, form the interaction products in the form of a stream, carry out the removal of this stream from the spatial region in the direction of flow. However, the scope of this invention is plasmatrons. In addition, in this method not apply flow inhibition and do not apply cavitation in the vortex flow zone. In addition, the invention minimizes the interaction zone of the flow on the limiting medium, first of all, on the walls of the designed devices and creates a flow system that minimizes the influence of the interaction zone and interaction products on the limiting medium without the use of flow-converting devices located near the interaction zone. Those. solves another technical problem.

Known methods of heat generation due to the result of the acceleration of the fluid flow, converted by braking in the working fluid. However, these systems cannot efficiently convert the total effective energy of a liquid into heat. Part of the energy, which is characterized as the specific potential energy, as well as the internal energy of the liquid, is not used in the converters or is not fully used. Internal energy is called, for example, the thermal energy of a compressible fluid or chemical energy. (See Feynman Lectures in Physics. R. Feynman, P. Leiton, M. Sands, Mir Publishing House, 1977, p. 239-248).

The technical result of the proposed method is to increase the conversion efficiency of the total specific energy (hydrodynamic pressure) of a fluid working fluid (TPT) into thermal energy, as well as an increase in heat transfer to the heat carrier.

This technical problem is solved as follows. With the method of energy release by means of rotationally applied motion of a liquid, a primary flow of a fluid working fluid (TPT) is formed. In this case, the formation is carried out outside the spatial region of the heat generator. The primary flow is given translational motion, an external perturbing effect is imposed on the flow of the fluid working fluid inside the space of the heat generator, secondary flows of the fluid working fluid are formed, and the flow of the fluid working fluid (TPT) is diverted in the flow direction. The proposed method is characterized in that the primary flow is formed in the pipeline, the diameter of which is equal to the diameter of the inlet pipe of the heat generator and is, for example, from 50 mm to 120 mm, and the primary flow has the characteristics of a laminar, straight flow. They give it a rotational - translational (vortex) motion at a speed provided the pressure in the pipeline is from 3 atm to 140 atm, the translational flow of the TPT flow is provided in the direction of the longitudinal axis of the heat generator due to the pipeline coaxially located with the heat generator, and the rotational one is provided through the vortex plate of the inlet nozzle and / or screw grooves located on the inner surface of the inlet nozzle, and at the same time compress the flow to obtain a speed that ensures the formation of cavitation flow at the output of the inlet nozzle. This speed depends on the pressure in the TPT and the density of the medium. (See D.A. Gershgal. V.M. Fridman “Ultrasonic Technological Equipment)), ed. Z-e,“ Energy ”, Moscow, 1976, p. 123-125.) So for example, for the case in question, this is the speed provided by 3 atm. Accelerate TPT along the helical surfaces of the helical channel to V ₁ and yts with simultaneous separation of the TPT into several, at least 2, flat jets moving along the helical grooves along the longitudinal axis of the cylindrical part of the helical nozzle of the heat generator, forming secondary cavitation flows, which are superimposed by ultrasonic fluctuations from the walls of the heat generator to obtain a standing wave in the secondary cavitation flows. Secondary cavitation flows are converted into a simple turbulent flow, in which ώ ₂ tends to 0, with simultaneous sharp braking to a speed equal to V ₂ provided that the difference in speeds (V ₁ - V ₂ ) = Δ V is observed, which ensures TPT is heated to the required temperature, and subsequent expansion to obtain a pressure equal to the pressure of the primary stream. In this case, the fluid working fluid (TPT) at the inlet to the pipeline has a viscosity equal to or less than the viscosity of water at T = 20 ° C, and in the cylindrical part of the screw channel of the heat generator it reaches the state of maximum achievable yield strength for this TPT, provided there is no vaporization in TPT.

The proposed method is as follows.

From the buffer region, at the outlet of which, in the pipeline, the primary flow of TPT is formed, translational motion is imparted by the centrifugal pump TPT and through the pipeline the primary flow of TPT, having the characteristics of a laminar, rectilinear flow, enters the inlet pipe of the heat generator. The pipeline and the inlet pipe of the heat generator have the same diameters. At the inlet of the heat generator, a hydrodynamic converter is installed, which is made, for example, as a screw nozzle with a vortex plate of the inlet nozzle. The vortex plate is in cross section a curved plate, which corresponds, for example, to the geometrical location of the points of the sinusoid. The swirling of the flow, in particular, occurs due to the narrowing of the inlet nozzle, and also on its inner surface there may be helical grooves providing for the swirling of the translational fluid stream. (See Feynman Lectures in Physics. R. Feynman, P. Leighton, M. Sands,

Publishing house "Mir", 1977, c.239-248., Formula for the circulation of a jet of liquid.) As a result of the passage of TPT through the nozzle, the flow receives a rotational - translational motion. Since the flow under the pressure of the pipeline is directed along the axis of the hydrodynamic transducer, a directed accelerated movement is imparted to it by the nozzle, and the vortex movement is provided by a vortex plate and / or screw grooves in the nozzle. In addition, due to the cone-shaped nozzle, tapering to the cylindrical part of the heat generator, the flow is additionally twisted and compressed until hydrodynamic cavitation forms on the shear vortex plate. The TPT stream is divided, for example, into two cavitation flows, which form flat jets in the cylindrical part of the heat generator. Plane jets are formed due to the passage of flow between the walls of the nozzle and the vortex plate. Further, flows in the form of flat cavitation jets are accelerated in the helical surfaces of the cylindrical part of the heat generator. Due to the pulsating nature of the cavitation jets, which are also additionally superimposed by ultrasonic vibrations from the volume resonator and the resonance plate, secondary cavitation flows are formed in which standing waves are formed. As a result, the total specific energy of the flow or its hydrodynamic pressure substantially increases.

Then, the jets with an external disturbance superimposed on them, for example, by means of a brake plate, which operates on the front cut both as a resonant platinum and as a brake plate, are converted into a simple turbulent flow in which the angular velocity ώ ₂ tends to 0, and the translational the flow rate decreases to a speed of V _2, thereby releasing the flow energy in the form of heat. With the above conversion of the stream, the efficiency of converting the energy of the stream to heat significantly increases in accordance with the formula: En = mώ ₂ R / 2 + mV _2/2 + E ext., Where

En is the total specific energy of the flow

Eun. - specific internal energy of the flow ώ - angular cyclic velocity of rotation of the mass of the stream m - mass of the stream

V - linear flow rate

R is the radius of rotation of the stream

In this case, the most complete transfer of the specific potential energy of the flow and internal energy occurs, due to which the efficiency is significantly increased. This is a consequence of the formula for the complete work performed on a liquid between two sections, which shows an increase in the energy of the mass of the liquid as it passes from one section to another. (See see

Feynman lectures in physics. R. Feynman, R. Leighton, M. Sands, Publishing House

Mir, 1977, p. 239-248.) P ₁ A ₁ V ₁ A t - P ₂ A ₂ V ₂ A t = AM (E ₂ - Ei), where

E ₁ - the energy of a unit mass of fluid in the cross section A ₁

E ₂ - the energy of a unit mass of fluid in the cross section A ₂

Or the total energy of a unit mass of liquid can be described by the formula

E = V ₂ V ² + φ + U, where V Г V ^{2 "} kinetic energy of a unit mass of fluid φ - potential energy

U is an additional term representing internal energy

It can be seen from this equation that an increase in the flow velocity (kinetic energy) on the right-hand side violates the equality, for the conservation of which it is necessary to reduce the internal and potential energy. Therefore, when the flow is inhibited, not only the kinetic and potential energies of the liquid are transformed, but also the internal energy is transferred, i.e. increases the efficiency of the process with the proposed combined conversion. And, therefore, in the proposed method, the rotational-translational motion of the fluid flow (vortex motion) is the initiator of the transfer of internal energy from the fluid.

Then carry out the flow of the fluid working fluid (TPT) in the direction of flow. In this case, the pressure in the stream is equalized to the pressure of the primary stream. Thus, the result of the heat generated in the output nozzle is the conversion of the kinetic, potential and internal energy of the rotational-translational motion of the fluid flow due to the inhibition of the cavitation flow with a resonant disturbance superimposed on it. In other words, this heat is generated by the kinetics of the flow, in which additional heat is released due to cavitation and the energy of standing waves generated by resonance. Thus, the method implements the principle of an ultrasonic hydrodynamic emitter, a vortex transducer, and a cavitation effect. As a result, a combined method of heat generation is implemented, thereby achieving the claimed technical result.

A device for converting and releasing energy in liquid media or a heat generator is intended to implement a method of energy release through rotational - translational motion of a liquid while converting the kinetic energy of a rotating stream, cavitation processes in a stream and resonant processes in a standing wave, into heat. In the proposed device, the rectilinear fluid flow by the inlet nozzle of the device is converted into accelerated rotational-translational motion (vortex), then accelerated in a screw channel with subsequent braking of the resonance plate. The invention is known "Method of generating energy and a device for its implementation (options)", application RU, Xa 2003107803, publ. 2004.10.20, MIZH F24JЗ / 00, the device of which consists of a housing with inlet outlet pipes and a diffuser. However, the incoming stream is twisted due to the tangential supply of water, which leads to significant energy losses during the conversion process.

The invention is known “A method of producing heat and a device for its implementation)), JNi patent RU 2242684, publ. 2004.12.20, IPC F24JЗ / 00, the device of which includes a sealed capacity of the swirl, nozzles for the supply and selection of liquid coolant, a sound and heat insulating casing. Moreover, there is a space between the casing and the housing, as well as the active zone of the coolant and the passive zone of the coolant. However, the device is too complicated and expensive. It is not possible to increase the efficiency of conversion of rotational energy into thermal energy. The invention is known as “Thermoreceptor and device for heating liquids)), patent RU, JCha 2045715, publ. 1995.10.10, IPC F25B29 / 00, comprising a housing, a motion accelerator, a brake device. The device is intended for heating directly in the pipeline viscous liquids such as oil in order to reduce the viscosity of the liquid, to ensure heating of the liquid. However, with acceleration and deceleration of the viscous fluid itself, it is impossible to achieve effective conversion of kinetic energy into thermal energy. In addition, the input fluid flow is supplied tangentially, and in the operating modes of the heat generator there is a high working pressure developed in the housing, which reaches 1000 atm, which significantly complicates the device and reduces its efficiency.

The closest technical solution to the proposed device is the invention of "a fluid heater", N ° patent RU, N ° 2255267, publ. 2005.06.27, IPC F17D1 / 18, F25B29 / 00, containing a vortex tube, the ends of which are equipped with hydrodynamic transducers of fluid motion, a flow former is installed at the end of the vortex tube relative to it, the housing of hydrodynamic transducers of fluid motion is made in the form of sockets at the ends of the vortex tube , a flow former, the axis of symmetry of which is coaxial with the longitudinal axis of the vortex tube and a flow divider made in the form of a plate, the surface of which is parallel to the longitudinal axis of the vortex tube. Designed for installation in pipeline transport systems. However, the incoming stream is twisted due to the tangential supply of water, which leads to significant energy losses during the conversion process. In addition, the hydrodynamic converters are very complex, which also leads to the loss of thermal energy in non-productive sections of the heat generator. In addition, the energy released during cavitation processes was not used.

At present, vortex heat generators are used for direct energy conversion from rotational - translational motion to heat. To convert the energy of a turbulent jet into the energy of acoustic waves, hydrodynamic emitters are used, which also use resonance phenomena. However, no attempt was made to create a heat generator design combining these three effects, which would be used to increase the conversion efficiency, as the total specific energy of the flow, as well as the specific potential energy of the flow and the internal energy of the flow in particular.

The technical result of the proposed design is to increase the power of the heat generator without reducing efficiency, simplifying the design, reducing energy loss during the release of thermal energy and energy removal through the coolant.

This technical result is achieved due to the fact that the device for converting and releasing energy in liquid media (either a hydrodynamic converter or a heat generator) consists of a vortex tube (1), hydrodynamic transducers of fluid motion (TPT) made in the form of cones (2, 3) at the ends of the vortex tube, flow former (4), the axis of symmetry of which is coaxial with the longitudinal axis of the vortex tube (1), the flow divider (5), made in the form of a plate, the surface of which is parallel to the longitudinal axis of the vortex tube. The proposed device is characterized in that the vortex tube, which simultaneously serves as a volume resonator, is made with helical grooves (6) on the inner wall of the cylindrical part, made of elastic laminated plastic and, for example, helical grooves are made inside a plastic screw insert. The vortex tube is equipped with a metal casing (7), covering with a gap “a” the outer surface of the vortex tube (1), the length of the cylindrical part “L” of the vortex tube refers to the diameter of its cylindrical part “d”, as 1 to 3 (or the length of the cylindrical part of the vortex tube is a multiple of its diameter), which ensures the formation of the TPT vortex flow in the vortex tube while ensuring the cavitation regime of the vortex flow and its resonant amplification. The hydrodynamic converter at the inlet of the vortex tube is made in the form of a cone-shaped screw nozzle (2), the outer part of which is connected flush with the vortex tube (1). The cone is also made, for example, of laminated plastic, inside which a flow former (8) is placed, which is made in the form of a plate having a helical surface and is placed in the inlet cone of the hydrodynamic transducer in front of the active zone of the heat generator, and the hydrodynamic transducer at the outlet (3) of the vortex tube made in the form of a flow divider (5), which simultaneously works as a resonant plate and as a braking device, flush with the cylindrical part of the vortex tube in front of the outlet cone (3) hydrodynamic transducer, which is located in turn, in front of the passive zone of the heat generator and is coaxially connected to the pipeline (9). The proposed technical solution is illustrated by the drawings, which depict: In FIG. 1 - shows a longitudinal section of a device for converting and releasing energy in liquid media;

In FIG. 2 - shows a cross section of the inlet nozzle with a flow former; In FIG. 3 - shows a cross section of the outlet nozzle with a flow divider. The proposed heat generator is arranged as follows. The pipeline (9) is rigidly connected to the casing (7) of the heat generator, which is made of metal. Inside the casing (7) is placed a vortex tube (1), which is made of elastic laminated plastic. An input cone (2), which is also made of plasmass, is placed in a vortex tube at its inlet end. The output cone (3) can be placed both directly on the output part of the vortex tube (1), and in the casing (7) of the heat generator. The output cone can be made of both plastic and metal. Between the vortex tube and the casing of the heat generator there is an adjustable clearance “a”, which provides resonant vibrations of the vortex tube in the casing (7). In this case, the casing does not enter into resonant vibrations, and only the vortex tube oscillates, forming a standing wave without sound transmission. Thus, the vortex tube acts as a cavity resonator. Inside the inlet cone of the vortex tube and in the cylindrical part of the vortex tube there are grooves (6) located along the vortex tube along a screw. These grooves allow the movement of cavitation plane jets along the vortex tube. Inside the inlet cone (2) there is a hydrodynamic fluid transducer, which is made in the form of a screw plate screwed (8). It is mounted flush with a part of the inlet cone connected to the cylindrical part of the vortex tube. Using a transducer, a TPT laminar jet, for example water, is twisted, in the inlet cone it is additionally twisted and accelerated, and also due to the passage between the cone walls and the plate, it is divided into 2 flat jets, which then move along the helical in the cylindrical part of the vortex tube. The input hydrodynamic converter can be made, for example, in the form of two or more plates, forming several flat flows. Due to the transfer to the TPT jets, oscillations from the cavity resonator, as well as due to disruption of the jets from the edge of the plate of the inlet hydrodynamic transducer, for example, two cavitational flat jets that dispersed and twisted to the required values move inside the cylindrical part of the vortex tube. These flows develop the total specific energy of the jet due to translational-vortex motion, cavitation processes inside the jets and due to the application of resonance effects from the volume resonator and from the flat resonator, which form a standing wave in the jets, increasing the accumulated specific total energy of the stream or increasing the hydrodynamic the pressure. At the exit from the cylindrical part of the vortex tube, flush with its outlet end, a brake plate (5) is installed, which is made flat, placed along the longitudinal axis of the vortex tube. It also acts as a flat resonator, transmitting a resonant effect on the TPT stream. Due to the passage of plane cavitation jets with a standing wave formed in them through the braking device, which is also the output hydrodynamic converter, the jets are mixed and broken into a simple turbulent flow, which is then inhibited in the output cone of the heat generator due to expansion, releasing the maximum amount of kinetic and potential energy flow. In this case, the most efficient transition of the specific potential energy of the flow occurs. Thus, the technical result of this technical solution is provided.

The specified device works by combining the effects of a hydrodynamic transducer, a vortex heat generator, and a tap generator based on cavitation processes. Structurally, the imposition of resonance oscillations on the jet of water is ensured by fastening with a gap a vortex tube in the casing of the heat generator. In order for a standing wave to form in the TPT jets, it is necessary to fulfill the condition described by the formula: Cavitation cavities pulsate with a frequency determined by Smith's formula: F = l / πd d / Зχ P ₀ / ρ, where

P ₀ - pressure in the medium surrounding the cavity X - heat capacity of the gas in the bubble p - density of the medium d - diameter of the bubble To comply with the conditions for the occurrence of a standing wave, it is required that the length of the cylindrical part is a multiple of its diameter.

At the outlet of the heat generator, a simple turbulent flow in the outlet pipe is gradually inhibited and established, becoming a flow with a steady motion, smoothly changing its movement, i.e. laminar. The mechanism of the combined effect with plate and vortex transducers in hydrodynamic transducers is described in D.A; Hershgal. V. M. Fridman "Ultrasonic technological equipment)), ed. Z-e," Energy ", Moscow, 1976, p. 123-125. However, when using a combination of the above methods of extraction, a qualitatively new effect of energy release appears in which the rotational-translational motion of the fluid flow (vortex motion initiates the extraction of internal energy from the fluid. This achieves the claimed technical result and significantly increases the power of the heat generator without reducing efficiency.

Claims

The formula of the group of inventions

A method of energy release by means of rotational-translational motion of a liquid and a device for converting and releasing energy in liquid media.

1 A method of energy release by means of rotational-translational motion of a liquid, which consists in the formation of a primary flow of a fluid working fluid, the formation is carried out outside the spatial region of the heat generator, the primary flow is translational, impose an external disturbing effect on the flow of the fluid working fluid inside the heat generator space, form secondary flows of a fluid working fluid and divert the flow of a fluid working fluid in the expired direction characterized in that the primary flow is formed in the pipeline, the diameter of which is equal to the diameter of the inlet pipe of the heat generator, and is equal to from 50 mm to 120 mm, the flow having the characteristics of a laminar, rectilinear flow, giving it a rotational - translational motion at a speed provided by a pressure of a pipeline from 3 atm to 140 atm, while the forward flow of the fluid working fluid flow is provided in the direction of the longitudinal axis of the heat generator due to the pipeline coaxially located with the heat generator, and in expansion - by screw cutting in the inlet nozzle and / or vortex plate of the inlet nozzle and at the same time in the inlet nozzle, compress the flow until a speed is achieved that ensures the formation of cavitation flow at the outlet of the inlet nozzle, accelerate the fluid working medium along the helical surfaces of the helical channel to V ₁ and ώ ι with the simultaneous separation of the fluid working fluid into several, at least 2, flat jets moving along the helical grooves along the longitudinal axis of the cylindrical part of the screw nozzle of the heat generator, forming secondary cavitation flows, which are superimposed by ultrasonic vibrations from the walls of the heat generator to obtain a standing wave in the secondary cavitation flows, convert the secondary cavitation flows into a simple turbulent flow in which the angular velocity ώ g tends to 0 with simultaneous sharp braking to a speed equal to V ₂ at provided that the velocity difference (V] - V ₂₎ = Δ V, providing heating of the working fluid flowing to the desired temperature, and subsequent expansion until a pressure equal pressur th primary stream. at In this case, the fluid working fluid at the inlet to the pipeline has a viscosity equal to or less than the viscosity of water at T = 20 ° C, and in the cylindrical part of the screw channel of the heat generator reaches the state of yield strength that is most achievable for a given fluid working fluid, provided that there is no vaporization in the fluid working fluid the body.

2. A device for energy release, consisting of a vortex tube, hydrodynamic transducers of fluid motion, made in the form of cones at the ends of the vortex tube, a flow former, the axis of symmetry of which is coaxial with the longitudinal axis of the vortex tube and flow divider, made in the form of a plate, the surface of which parallel to the longitudinal axis of the vortex tube, characterized in that the vortex tube is made with helical grooves on the inner wall of the cylindrical part of the elastic laminated plastic and is equipped with a metal with a casing covering the outer surface of the vortex tube with a gap, the length of the cylindrical part of the vortex tube is a multiple of its diameter, which ensures the formation of a vortex flow of a fluid working fluid in the vortex tube while ensuring the cavitation regime of the vortex flow and its resonant amplification, the hydrodynamic converter at the entrance of the vortex tube in the form of a cone-shaped nozzle, the outer part of which is connected flush with the vortex tube, inside of which there is a flow former, which once placed in the inlet cone of the hydrodynamic transducer in front of the active zone of the heat generator, and the hydrodynamic transducer at the exit of the vortex tube is made in the form of a flow divider placed flush with the cylindrical part of the vortex tube in front of the output cone of the hydrodynamic transducer, which is placed in front of the passive zone of the heat generator and coaxially connected to the pipeline.

3. The device for energy release according to claim 2, characterized in that the helical grooves are made inside the plastic screw insert of the heat generator.

4. The device for energy release according to claim 2, characterized in that the length of the cylindrical part of the vortex tube refers to the diameter of its cylindrical part as 1 to 3.

5. The device for energy release according to claim 2, characterized in that the hydrodynamic transducer is made of laminated plastic.

6. The device for energy release according to claim 2, characterized in that the flow former is made in the form of a flat plate having a helical surface.

7. The device for energy release according to claim 2, characterized in that the flow former is made in the form of a groove placed on the inner surface along a helical line.