RU2171435C1 - Device for liquid heating - Google Patents

Abstract

FIELD: heat engineering, applicable for liquid heating in closed circulating heating systems of buildings with an circulating heating systems of buildings with an independent heating source. SUBSTANCE: cavitation condition of water flow is created in a closed circulating circuit in cavitation heat generator, as a result, heat is liberated in it. Hot water from the heat generator is directed to the primary circuit of the heat exchanger, where heat through a wall is transferred to the water circulating in the heat consumption system. The already cooled down water of the heating circuit is directed to the delivery pump and further, through a pipe- line, to the inlet of the heat generator. Before the inlet to the heat generator water is subjected to action by magnetic field with the aid of a magnet, thus the, natural mechanism of change of the water structure destroyed in the heat generator is accelerated. Thus, an opportunity appears for the device to operate in a continuous duty with a constant receipt of "abnormal" heat. EFFECT: provided "abnormally" high heat release for associated liquids in the heating systems in the continuous conditions by reduction of intensification of this "abnormality" artificially with low expenditures of energy. 3 cl, 3 dwg

Description

 The invention relates to heat engineering and can be used for heating liquids and, in particular, in closed circulating heating systems of buildings with an autonomous heating source.

 A device for heating a liquid is known, comprising a heating circuit including a pressure pump, a vortex heat generator, and a heat exchanger. Here, the heating of the fluid occurs due to the inhibition of the fluid in the vortex heat generator [1].

 A device for heating a liquid is known, comprising a heating circuit including a pressure pump, a cavitation heat generator, and a heat exchanger. Here, the heating of the fluid occurs due to cavitation of the fluid in the cavitation heat generator [2].

 Closest to our proposed device is a fluid heating device containing a heating circuit including a pressure pump, a cavitation or (and) vortex heat generator, a heat exchanger, and a heat consumption system associated with a heat exchanger [3].

 In this device, the heat generator can work both as a vortex and as a cavitation one, and as both together. The heat exchanger here is the simplest - in the form of a heat accumulator - a tank where cold water from the consumer is mixed with heated water from the heat generator.

 It should be noted that in all technical solutions [1], [2], [3], in addition to the standard heat release in a vortex or cavitation heat generator, anomalously high heat release is also realized, which is also confirmed in [5]. And although the author of US patent N 5188099, who built the installation with "anomalous" heat, considers this to be mysticism, in our opinion, there is nothing supernatural in this.

 The fact is that associated liquids, such as water, have complex supramolecular structures in which individual molecules partially form associate associations and coexist in dynamic equilibrium. Moreover, for each equilibrium natural state characterized by a certain set of thermodynamic parameters, there always exists its own concentration ratio with respect to each other. The reason for the associations is mainly uncompensated hydrogen bonds with energies from 2.5 to 6.5 kcal / mol. When these equilibria are changed by external influences in the direction of decreasing the internal stored energy, the difference is released in the form of anomalous heating.

 Theoretically, the heating system of the prototype can continuously generate “abnormal” heat (without taking into account the restoration of the destroyed associate structures) for a certain time until they are completely destroyed when the supramolecular associate structures are closed. “Abnormal” heat can be generated in the heating system - the prototype, if running natural water is taken into the system and after heat transfer is discharged anywhere, if only it does not appear again at the point of water intake into the system.

 Thus, the “anomalously” high heat release for associated liquids in technical solutions [1], [2], [3] can be realized within a rather short time, after which this “anomaly” disappears. Further, all these water heating systems [1], [2], [3] will continue to work without "abnormal" heat generation or in order to have this "abnormal heat generation" these systems must be turned off so that this "abnormality" is restored in a natural way .

 The objective of the invention is to ensure the operation of the device with an "abnormally" high heat generation for associated liquids in continuous heating systems, ways to restore or even enhance this "anomaly" forcibly with low energy costs, incomparable with the gain that will make it possible to use this device in an industrial way.

 This problem is achieved in that in a device for heating a liquid containing a heating circuit including a pressure pump, a cavitation or (and) vortex heat generator, a heat exchanger, and a heat consumption system associated with a heat exchanger, the heat exchanger is made at least double-circuit with separate the wall of the circuits in which the primary circuit is included in the heating circuit, and its secondary circuit is communicated with the heat consumption system, the heating circuit is closed, and in front of A magnet is installed in the heat generator, while the intensity of its magnetic field is higher than the intensity of the magnetic field of the earth.

 In addition, in the device, the primary circuit of the heat exchanger is made combined with the heat generator, and the heat generator itself is made in the form of two coaxial shells with spiral channels and pins between them, and the secondary circuit of the heat exchanger communicated with the heat consumption system is placed inside the inner shell of the heat generator.

 What is new here is that the heat exchanger is made of at least double-circuit with wall-separated circuits, in which the primary circuit is included in the heating circuit, and its secondary circuit is communicated with the heat consumption system, the heating circuit is closed, and on its pipe before entering a heat generator has a magnet whose magnetic field is higher than the earth’s magnetic field.

 In addition, it is possible that in the device the primary circuit of the heat exchanger is made combined with the heat generator, and the heat generator itself can be made in the form of two coaxial shells with spiral channels and pins between them, and the secondary circuit of the heat exchanger communicated with the heat consumption system is placed inside the inner shell heat generator.

 By making the heating circuit closed, it becomes possible to have a liquid with constant properties in the heating circuit, and, therefore, the operation of the entire device in time will be stable.

 Having performed the heat exchanger with double-circuit with wall-separated circuits, in which the primary circuit is included in the heating circuit, and the secondary circuit is communicated with the heat consumption system, in this case we have a heating circuit with a relatively small volume of liquid, which is separated by a wall of the heat exchanger from a liquid of already large volume, used in the heat consumption system. In this small volume, we can easily provide the desired purity of the liquid, and hence the high stability of its properties, affecting the operability of the proposed heating device according to this invention, as for the secondary circuit, then the stability of the properties of the liquid does not matter much.

 By installing magnets in the pipeline of the heating circuit, according to experimental data, we significantly accelerate the natural mechanism of restoration of supramolecular structures that are destroyed further in the cavitator.

 By installing a magnet in the pipeline before entering the heat generator, we carry out the influence of a magnetic field on the moving fluid flow before creating a vortex or cavitation flow regime in it and, thereby, make a preliminary supply of “anomalous” energy in the liquid just before the heat generator, in which this stored energy water can go into heat.

 By combining the primary circuit of the heat exchanger with the heat generator, we have almost two in the dimensions of one unit, and here the heat loss is also less.

 It also reduces the dimensions and heat loss that the heat generator can be made in the form of two coaxial shells with spiral channels and pins between them, and the secondary circuit of the heat exchanger is placed inside the inner shell of the heat generator.

In FIG. 1 shows a longitudinal section of a device;
in FIG. 2 is a longitudinal section of a device in which the heat generator is made in the form of two coaxial shells;
in FIG. 3 is a view A of the channels of the heat generator of FIG. 2.

 The device for heating the liquid contains a closed heating circuit 1, including a pressure pump 2, a cavitation heat generator 3, a dual-circuit heat exchanger 4, with circuits 6 and 7 divided by a wall 5. For the heat exchanger 4, the primary circuit 6 is included in the heating circuit 1, and with the heat consumption system in the secondary circuit 7 is communicated by the swinging pump 9. A magnet 11 is installed on the pipeline 10 before entering the heat generator 3, while the channel 12 of the pipeline 10 and the tension lines of the magnet 11 are directed across each other.

 The heat generator 3 can be made in the form of two coaxial shells 13 and 14, rigidly interconnected by radial walls 15, forming spiral channels 16. In the channels 16 between the walls 15 pins 17 are placed. In this case, the primary circuit 6 of the heat exchanger 4 is combined with the heat generator 3, and its secondary circuit is in the form of an internal cavity of the shell 13, in which the input and output are looped by pipelines through the pump 9 and the heat consumption system 8.

 In a closed heating circuit 1 in a cavitation heat generator 3, a cavitation mode of water flow is created and heat is generated in it, in addition, by means of cavitation, the supramolecular structures of water are partially destroyed and additional “anomalous” energy of water is released. The water heated in the heat generator 3 is sent to the primary circuit 6 of the heat exchanger 4, where heat is transferred through the wall 5 to the water, which is circulated by the pump 9 in the heat consumption system 6. Already cooled water from the heating circuit 1 is sent to the pressure pump 2, and then through the pipeline 9 to the input 10 of the heat generator 3. Before entering 10 into the heat generator 3 using a magnet 11, water is exposed to a magnetic field, the magnitude of which exceeds the magnetic field of the earth, accelerating the natural mechanism of If the water structure changes in the direction of increasing the supramolecular structures that are destroyed in the heat generator 3, the water structure is restored and the already restored water is supplied to the heat generator 3. Thus, it becomes possible to operate the device in a mode with constant production of "anomalous" heat.

 In the case when the heat generator 1 is made in the form of two coaxial shells 13 and 14 with spiral channels 16 formed by radial walls 15 using pins 17, a cavitation mode of water flow is created and heat is generated in it. This heat is transferred to the liquid through the shell 13 and is pumped by the pump 9 to the heat consumption system 8. Here, the primary circuit of the heat exchanger 5 is combined with the heat generator 3. It should be noted that the spiral channels of the heat generator increase the heat generation due to the rotation energy of the heated fluid entering the heat consumption system 8.

 A test experiment was performed for the proposed device.

When the water circulated in the circuit, the cavitator - load - magnetic reducer (supply pipe around which an electromagnet is installed) - again the cavitator (with continuous circulation) with a total amount of water in the circuit of 20 l and the mains electric power spent on heating - 2 kW, was received:
the initial heating rate of 1.5 ^o C / min;
the final heating rate after 2 hours of circulation at a flow rate of 0.2 l / min - 0.5 ^o C / min (when the electromagnet is off);
the final heating rate after 2 hours of circulation at a flow rate of 0.2 l / min - 1.5 ^o C / min (when the electromagnet is on).

 These results prove the operability of the proposed device.

 When the electromagnet is on, and, therefore, when exposed to water before creating a cavitation regime of the magnetic field in it, the "abnormal" heating rate is maintained. And vice versa - when the electromagnet is off, if at the beginning of the circulation there were conditions of "anomalous" heating, then as they collapsed, the "anomaly" gradually decreased, as evidenced by a 3 times lower heating rate.

Sources of information
1. RF patent N 2045715, MKI F 02 B 29/00, publ. 1995 year

 2. RF patent N 2132025, MKI F 02 B 29/00, publ. 1999 year

 3. RF patent N 2131094, MKI F 02 B 29/00, publ. 1999 year

 4. Larionov L.V. et al. Cavitator for hydrophysical heat generators, the journal "Building materials, equipment, technologies of the 21st century", 1999, N 2, p. 34.

 5. Eskov-Soskovets V.N. et al. Prospects for the development of electrophysical methods of processing food products and equipment, Central Research Institute of Electrical Engineering (Review), M., 1977

Claims (3)

 1. A device for heating a liquid containing a heating circuit, including a pressure pump, a cavitation or (and) vortex heat generator, a heat exchanger and a heat consumption system associated with a heat exchanger, characterized in that the heat exchanger is made of at least two-circuit with wall-separated circuits, in which the primary circuit is included in the heating circuit, and its secondary circuit is communicated with the heat consumption system, the heating circuit is closed, and on its pipe before entering the heat generator mounted magnet with an intensity greater than the earth's magnetic field intensity.  2. The heating device according to claim 1, characterized in that the primary circuit of the heat exchanger is made combined with the heat generator.  3. The heating device according to claims 1 and 2, characterized in that the heat generator is made in the form of two coaxial shells with spiral channels and pins between them, and the secondary circuit of the heat exchanger, in communication with the heat consumption system, is placed inside the inner shell of the heat generator.

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