RU2171434C1 - Method for liquid heating - Google Patents

Abstract

FIELD: heat engineering applicable for liquid heating. SUBSTANCE: a vortex condition of water flow is created in a closed heating circuit in a vortex generator. Before feeding of water to the vortex generator the feeding pipe is influenced by a magnetic field, whose magnetic intensity exceeds the magnetic intensity of the earth's magnetic field, with the aid of an electromagnet. It results in a change of the water structure towards an increase of the supermolecular structures due to acceleration of the natural mechanism of reduction of the supermolecular structures destroyed in the vortex generator. In the vortex generator and braking device the energy of vortex movement of water is converted in thermal energy, and, besides, the supermolecular structures of water are partially destroyed with the aid of vortex movement and release additional "abnormal" energy of water. Hot water from the vortex generator and braking device is directed to radiators, where heat is transferred to the consumer, and the already cooled water from the radiators is directed to the pump inlet, and the heating cycle is repeated again. EFFECT: provided "abnormally" high heat release for associated liquids in the heating systems in the continuous condition by reduction or intensification of this "abnormality" artificially with expenditures of energy for it that are incommensurable with the obtained gain. 2 cl, 1 dwg

Description

 The invention relates to heat engineering and can be used to heat a liquid. Especially effective is the invention in closed circulation circuits for heating buildings.

 A known method of heating a fluid by creating a vortex mode of fluid flow and subsequent conversion of the energy of the vortex motion of the fluid into heat due to the sharp inhibition of the fluid flow [1,2].

 There is also known a method of heating a fluid by creating a cavitation mode of fluid flow and subsequent conversion of the energy of the cavitation mode of fluid flow into heat [3].

 Closest to the proposed one is a method of heating a liquid, mainly in closed circulation circuits of heating, by creating a vortex or (and) cavitation mode of fluid flow and subsequent conversion of the resulting energy into heat [4].

 It should be noted that in all technical solutions [1-4], anomalously high heat dissipation is realized in practice, which is also confirmed in [6].

 The mechanism of this "abnormality" is as follows. Associated liquids, for example, the most common of them, 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 are mainly uncompensated hydrogen bonds with energies from 2.5 to 6.5 kcal / mol.

Purely for water, in [5], a strict relation was obtained between monomeric and associate molecules bound in the form
N _sv / N _ice. = e ^{-500 / RT} , (1)
where N _St. and N _ice. are the concentrations of free molecules with broken hydrogen bonds and associated molecules combined into ice-like structures of ice-like molecular formations, respectively, 500 is the transition activation energy (in cal), R is the gas constant, and T is the absolute temperature.

For water under normal conditions, expression (1) gives the value of the ratio of concentrations of supramolecular structures N _sv. / N _ice. = 0.408 in relative units, for N _St. + N _ice. = 1.

 Considering that according to [1], when 500 mol of energy is destroyed during the destruction of 1 mole of associates, when cavitation shock waves completely destroy all associates of natural water in 1 liter - 0.71 liter, we get Q = 19.72 kcal. However, in dissertation work [7] by computational modeling it was shown that "large" particles are attracted to the surface of the cavitating cavity and dispersed, while small ones are repelled and are capable of coagulating. Therefore, the mandatory presence of the coagulation process will reduce this value by 1/3, which will give 13.15 kcal of "abnormal" heat from 1 liter of water.

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

It has been experimentally proved that in nature, the concentration ratio of supramolecular structures of water that has undergone vortex or cavitation heating is restored within 48-56 hours of exposure in the sump due to the exposure of the associated liquid to the radiant, corpuscular and magnetic energy fields of the Sun and space in general, expressed as N _St. / N _ice. = 0.408.

 Thus, the “abnormally” high heat generation for associated liquids in technical solutions [1–4] can be realized within a rather short time, after which this “anomaly” disappears. Further, all these water heating systems that implement the methods [1-4] 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 provide "abnormally" high heat dissipation for associated liquids in heating systems in a continuous mode by restoring or enhancing this "anomaly" forcibly with the energy costs that are not commensurate with the gain that will make it possible to use this method in an industrial way.

 This problem is achieved by the fact that in the method of heating the liquid, mainly in closed circulation heating circuits, by creating a vortex or (and) cavitation mode of fluid flow and subsequent conversion of the received energy to heat for associated liquids in a moving fluid flow before creating a vortex or ( i) the cavitation regime of the flow forcibly changes the structure of the liquid in the direction of increasing supramolecular structures, for which they act on this liquid with a magnetic field with with an intensity exceeding the intensity of the Earth’s magnetic field. In addition, the lines of the magnetic field should be directed across the direction of fluid movement.

 What is new here is that for associated liquids in a moving fluid stream, before creating a vortex or (i) cavitation flow regime in it, the liquid structure is forcibly changed in the direction of increasing supramolecular structures, for which they are exposed to this liquid by a magnetic field with an intensity exceeding the Earth's magnetic field . In addition, magnetic field lines may direct across the direction of fluid movement.

 Forcibly changing the structure of the liquid in the direction of increasing supramolecular structures, we increase the supply of "abnormal" energy in the liquid, which we will receive in the form of thermal energy during the subsequent destruction of these supramolecular structures using vortex or (and) cavitation effects on the liquid.

 Carrying out this effect in a moving fluid stream before creating a vortex or (and) cavitation flow regime in it, we make a reserve of "anomalous" energy in the liquid just before creating a vortex or cavitation effect, as a result of which this stored energy can transfer into the thermal energy of the liquid.

By acting on the associated liquid with a magnetic field with a strength exceeding the Earth's magnetic field, with the help of this initiator (catalyst) we forcibly significantly accelerate the natural mechanism of restoration of supramolecular structures destroyed in the cavitator (vortex) and, moreover, we are able to shift the ratio N _sv. / N _ice. = 0.408 in the direction of its decrease, which is confirmed by experiments.

This shift N _St. / N _ice. in the direction of its reduction, this allows us to use this method in open systems with water intake from an external source and its subsequent discharge into an external sump due to the additional supply of "anomalous" energy supplied to the swirler or cavitator. It should be noted that this magnetic field is only a catalyst for the natural mechanism of restoration of supramolecular structures, and the energy of this magnetic field is not commensurate with the energy of stored supramolecular bonds, which is also confirmed by experiments.

By directing the magnetic field lines across the direction of fluid motion, according to experimental data, we strengthen the recovery mechanism of supramolecular structures, and this gain becomes maximum when the angle between the magnetic field line and the direction of fluid motion is close to 90 ^o .

 The drawing shows a device that implements the method.

 The heating circulation circuit that implements the proposed method for heating the liquid comprises a pump 1 in series, a supply pipe 2, a swirler 3 with a brake device 4 at its output, radiators 5, connected to the pump 1 by its outputs with the supply pipe 2, around the feed pipe 1. 2, an electromagnet 6 is installed. There is a feed line 7 with a shut-off valve 8 connected to the input of the pump 1.

 The method is implemented as follows.

 In a closed circulation heating circuit in the swirl 3 create a vortex mode of water flow. In the supply pipe 2, before the water is supplied to the swirl 3, it is exposed to a magnetic field, the intensity of which exceeds the earth's magnetic field using an electromagnet 6. This leads to a forced change in the water structure in the direction of increasing supramolecular structures due to the acceleration of the natural mechanism of restoration of the destroyed in the swirl 3 supramolecular structures. In the swirler 3 and the brake device 4, the energy of the vortex motion of the water is converted into heat and, in addition, by using the vortex motion, the supramolecular structures of the water are partially destroyed and additional “anomalous” energy of the water is released. Hot water from the swirl 3 and the brake device 4 is sent to the radiators 5, where heat is transferred to the consumer and the already cooled water from the radiators 5 is sent to the inlet to the pump 1, and the heating cycle is repeated again.

 The authors conducted pilot checks of the proposed method for heating the liquid.

 The source of powerful ultrasonic vibrations for obtaining the cavitation regime of water was the UZG-4M generator, loaded with PMS-2.5 resonant magnetostrictive transducers at 16 kHz, built into the bottom of the cylindrical chamber through which a flow of water with an adjustable pressure was passed. The temperatures and pressures in the chambers were measured with the required accuracy. Water samples were taken taking into account the exposures in the chambers [8]. To measure changes in the concentration ratios of supramolecular structures, a special method was used that reliably determines the change in their ratio within an accuracy of ± 10%. The essence of this special method was to measure the difference in the behavior of treated relatively untreated water taken from samples, either by sedimentation of a colored colloidal solution, or by the filtration rate (the method was tested at the Institute of Physics and Technology at the Laboratory of Doctor of Physical and Mathematical Sciences Yu.N. Petrov in 1990).

The measurement results were as follows:
a) determining the influence of ultrasonic influences of a cavitation nature on the water flow, changing the ratio of Hall concentrations (N _sv / N _ice ) from natural 0.408 to 4 maximum, and the time of free recovery from excited states to the natural ratio of Hall concentrations 0.408, which turned out to be on average from 48 to 56 hours;
b) determination of the effect on the flow of circulating water of a magnetic field acting on this water. In the case of exposure to an external magnetic field, changes in the ratio of Hall concentrations (N _sv / N _ice ) from natural 0.4 to 0.15 and the recovery time of the natural ratio in 18 hours upon removal of this external magnetic effect were obtained;
c) determination of the effect of a magnetic field on the flow of water, on which a cavitation effect was exerted. The combination of successive effects of ultrasonic cavitation and magnetic effects on the water flow made it possible to immediately obtain from the state excited by ultrasound the natural directly in the flow [9].

 Based on the above for the proposed method, a verification experiment was performed.

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 mains electric power spent on heating - 2 kW, was received:
the initial heating rate of 1.5 ^o C in 1 min;
the final heating rate after 2 hours of circulation at a flow rate of 0.2 l / min - 0.5 ^o C in 1 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 in 1 min (when the electromagnet is on).

 These results prove the correctness of the proposed method: if at the beginning of the circulation, while the natural ratio of the supramolecular Hall structures was preserved in water, there were conditions of "anomalous" heating, then as they collapsed, the "anomaly" gradually decreased until it actually disappeared completely, as evidenced by 3 times lower heating rate. And, on the contrary, when exposed to water before creating a cavitation flow regime in it with a magnetic field, the “abnormal” heating rate is maintained.

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

 2. RF patent N 2125215, MKI: F 02 B 29/00, publ. 1999 year

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

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

 5. Hall L. Phys. Rev. 73.775, 1948.

 6. Larionov L.V. and others. Cavitator for hydrophysical heat generators. - Building materials, equipment, technologies of the XXI century, N 2, 1999, p. 34.

 7. Friedman V.N. Thesis for the competition. Ph.D. "Investigation of the possibility of intensification of f / x processes in the event of cavitation in a liquid," p. 62-77, M., 1970.

 8. Eskov-Soskovets V. M. and others. The value of the structure of water in the brewing industry, TSNIITEIP, B2, M., 1975.

 9. Eskov-Soskovets V. M. et al. Prospects for the development of electrophysical methods of processing food products and equipment (review), TSNIITEIL, M., 1977.

Claims (2)

 1. The method of heating a liquid, mainly in closed circulation heating circuits, by creating a vortex or (and) cavitation mode of fluid flow and subsequent conversion of the received energy into heat, characterized in that for associated liquids in a moving fluid flow before creating a vortex or ( i) the cavitation regime of the flow forcibly changes the structure of the liquid in the direction of increasing supramolecular structures, for which they are applied to this liquid by a magnetic field with intensity Witzlaus intensity of the magnetic field of the earth.  2. The method of heating a liquid according to claim 1, characterized in that the lines of the magnetic field are directed across the direction of movement of the liquid.