RU2726643C1 - Method for increasing heat energy generation in heat carrier - Google Patents

Abstract

FIELD: heat power engineering.

SUBSTANCE: invention relates to heat engineering and can be used for heating of greenhouses, livestock farms, poultry farms, industrial and residential premises of agro-industrial complex and other industries. Heater pipes at inlet and outlet are isolated from pipes of heat consumer by dielectric connecting pipes, to inductance coils electric capacitance and active resistance are connected, values of which are calculated for required thermal efficiency and experimentally corrected, inductance coils with electric capacitance and active resistance form resonant electromagnetic LCR-oscillatory circuit, heat carrier is pumped in its electromagnetic resonance field, during passage of which water molecules are split into hydrogen and hydroxyl ions with their subsequent reunion into water molecules and release into heat carrier of additional heat energy.

EFFECT: disclosed is a method of increasing heat energy generation in a heat carrier.

1 cl, 1 tbl

Description

The invention relates to heat power engineering and can be used to heat greenhouses, livestock, poultry enterprises, industrial and residential premises of the agro-industrial complex and other industries.

Heating of heat transfer fluids is widely used for various purposes, including for heating buildings and structures in many countries of the northern hemisphere. And the heating of the coolant is carried out using the heat of combustion of various fuel materials (wood and wood waste, coal, oil products, hydrocarbon gases) and using electric heating devices.

A known method of heating a liquid heat carrier, implemented, for example, in electric electrode (ion) heating boilers "Galan". Heating of the coolant in them occurs by the method of ionization of the coolant, i.e. breaking the molecules into positive and negative ions, which move in the form of an electric current to the negative and positive electrodes with the frequency of the network current, while releasing their energy on the electrodes. The heat carrier is ethylene glycol with water or treated water. The electrical resistance of the coolant decreases as it heats up, electrical currents increase and the boiler gradually reaches the calculated electrical and thermal power. The efficiency of Galan boilers in converting electricity into heat is close to 100%. At the same time, 1 kWh of electricity consumption by the boiler theoretically releases 860 kcal of thermal energy or 3.6 × 10 ³ kJ.

F.M. Kanarev water electrolytic cells were created with the release of thermal energy by 29135.8% in comparison with the cost of electricity for resonant electromagnetic splitting of water molecules. On this basis, the "Vodoelektromobil" was created, which does not consume any energy from the outside. (Kanrev FM Beginnings of physical chemistry of the microworld. Monograph. Eighth edition, Krasnodar, 2007.- 753 p. Section 14. Water is a source of thermal energy, pp. 568-639. Section 15. Water is a source of hydrogen, p. 640- 683. Page 678, table 69, the values of the energy efficiency of the water electrolysis process according to the oscilloscope readings - 29135.8%. Http://Kanarev.innoplaza.net; http: //www.new-physicscom/ http: // peswiki. com / index.php / Directory: Kanarev_Electrolysis)

F.M. Kanarev Theoretical foundations of physical chemistry of nanotechnology. Second edition. Krasnodar, KGAU, 2008, 676 p. Section 6.12, pp. 265-273.

F.M. Kanarev Theoretical foundations of the physical chemistry of the microworld. Textbook. 6th edition. Russia, August 2012; Section 8.13. Energy of molecules of oxygen, hydrogen and water , pp. 146-150; Section 8.14. Water clusters and their binding energies, pp. 150-153, /http://www.micro-world.su/.

One of the resonant frequencies of absorption and emission of electromagnetic radiation and acoustic vibrations of liquid water is 25 Hz (table 3.17, p. 218 and table 3.18, p. 221 of the book by Y. P. Rassadkin. Water is ordinary and not ordinary. M .: "Gallery STO" , 2008.- 840 p.). And the frequency of the alternating current of the industrial power grid and the resonant electromagnetic field at the induction heater at Altair-P LLC is 50 Hz. This frequency ratio indicates the possibility of a resonant effect of an alternating electromagnetic field from an industrial power grid on the splitting of water molecules. Table 8.4 (p. 587) of Yu.P. Rassadkin's books. data on 31 generators of thermal energy are given, where additional energy, in comparison with the cost of pumping water through the generators, is created in the processes of cavitation with the splitting of water molecules. In these generators, the efficiency factor according to 18 literature sources ranges from 0.82 to 25.7.

Since 2010, portable physical generators of electricity by the Tbilisi architect Tariel Kapanadze have been known ( Patent WO 2008/103129 A1 dated 28.08.2008).

The closest to the claimed method, taken as a prototype, is a method carried out in an installation for heating bitumen according to the USSR author's certificate No. 1286671, IPC E 01C 19/08, 1985

The known method consists in the electromagnetic effect on the coolant from the inductance coils. Pieces of solid bitumen are introduced into the heated pipes, the induction coils are connected to the industrial power grid, the bitumen is melted, the heating elements are turned off, the melt is removed from the pipes and the same operations are repeated cyclically.

The disadvantage of this known method is limited application, narrow functional focus, low productivity due to cyclic, rather than continuous operation. Thermal calculations for the consumption of electricity and heat generated for melting bitumen at this unit were not carried out.

The technical problem of the present invention is to increase the generation of heat in the heat carrier in excess of 100% of the consumed energy.

The technical result is achieved by the fact that in the method of increasing the generation of thermal energy in the coolant, which consists in the electromagnetic effect on the coolant, according to the invention, the heater pipes at the inlet and outlet are isolated from the pipes of the heat consumer by dielectric connecting pipes, the electric capacitance and active resistance are connected to the heater inductors , the values of which are calculated for the required thermal performance and are corrected experimentally, inductors with electrical capacitance and active resistance form a resonant electromagnetic LCR-oscillatory circuit, pump the coolant in its electromagnetic resonance field, during the passage of which water molecules are split into hydrogen and hydroxyl ions, followed by reuniting them into water molecules and releasing additional thermal energy into the coolant.

The method is implemented by such actions.

Steel pipes of the heater at the inlet and outlet are insulated from the pipes of the circulating heat supply system with dielectric connecting pipes. Electrical capacitance and active resistance are connected to the inductance coils on the heater pipes, all values of which are calculated for the required thermal performance and are specified experimentally. Inductors together with capacitors and active resistances form an electromagnetic resonant LCR oscillatory circuit. They include him in a permanent job. The heat carrier is heated by the electromagnetic resonance field of the coils. The coolant is pumped through the resonant electromagnetic field of the heater. Splitting water molecules into hydrogen and hydroxyl ions is carried out, causing them to absorb energy from the space outside the heater. The subsequent reunification of ions into water molecules is carried out with the release of the energy absorbed by the ions into the coolant and thereby increase the generation of thermal energy in the coolant over 100% of the energy consumed.

The technical result of the method consists in the release of thermal energy by an induction heating boiler at Altair-P LLC (Zelenograd) in the amount of 169-215% of the estimated electricity consumption, i.e. when 1 kWh of electricity is consumed in the boiler, not 860, but 1453 - 1849 kcal of heat are released.

These performance indicators of an induction boiler at Altair-P LLC are comparable to the efficiency coefficient of well-known cavitation heat generators manufactured in the Russian Federation and in several countries abroad since the end of the last century (Source: Rassadkin Yu.P. “Ordinary and non-ordinary water”. - M .: "Gallery STO", 2008. - 840 p., Table 8.4 on page 597).

The generation of additional heat in the electromagnetic, cavitation mechanochemical and other physical methods of splitting water molecules is due to the following. For the physical splitting of a water molecule into hydrogen and hydroxyl ions, an energy of 248 kJ / mol is required. After splitting the water molecule, the remaining parts of it have electrons with uncompensated bonds, but they cannot be in this state. For their stability, both electrons in the parts of the split water molecule absorb photons with an energy of 248 kJ / mol, and in total 496 kJ / mol, become stable, active and reunite the parts of the split water molecule. When these parts are reunited, their electrons radiate into the water the electromagnetic energy absorbed by them, but no longer needed by them, equal to 496 kJ / mol. Hence, having spent only 248 kJ / mol in physical impact on each water molecule, they radiate 496 kJ / mol into water and receive additional energy of 248 kJ / mol. Hence, the increase in the caloric content of the processes of physical splitting of water molecules is due to prof. F.M. Kanarev by the return action of electrons "of the split parts of water molecules.

The method of increasing the generation of thermal energy in the coolant by electromagnetic action on it is confirmed by the thermal engineering calculations carried out on July 18, 2007 by the specialists of Intellect LLC of the MEPhI-system subdivision at the Moscow Engineering Physics Institute: Ph.D. Dresvina M.A. and Ph.D. Popov Yu.A.

In the first test of these specialists, an induction boiler weighing 150 kg with the symbol INNA-3 at Altair-P LLC heated 35 kg of water for 180 seconds. At the same time, a 44.8 kW boiler consumed 8064 kW of electricity, and the water and metal of the installation heated up from 20 ° C to 83 ° C due to the 13633.2 kJ of thermal energy received in the heater. Hence, in this test, according to the calculations of the testers, the thermal efficiency of the boiler was 169%.

In another test of the same specialists, the entire workshop of Altair-P LLC was heated with the same INNA-3 boiler. The measurement results are shown in Table 1.

Calculations have obtained the values of heat absorbed by the structure of the shop Q ₁ , the contents in it Q ₂ , as well as the electricity consumed for heating the entire shop Qe: Q ₁ = 158 466 kJ; Q ₂ = 172 234 kJ; Qe = 153 780 kJ.

Hence, according to the calculations of the testers, the efficiency of the heater was:

(158 466 kJ + 172 234 kJ): 153 780 kJ = 2.1504

Conclusion of the specialists of Intellect LLC of the MEPhI-system subdivision at MEPhI: thermal engineering calculations showed that the thermal efficiency of an induction resonant heater at Altair-P LLC (Zelenograd) can be 1.69 ... 2.15.

Table 1.

In 2018, the implementation of the method was carried out already in two production workshops of LLC Altair-P (Andreevka microdistrict, Zelenograd; E-mail: altairps@mail.ru). Here, in heating systems, due to the electromagnetic effect on the heated heating water, from 1986 to December 25, 2019, an increased amount of heat energy, up to 215%, is released, confirmed by the heat engineering calculations of Intellect LLC, and there are no signs of corrosion in the pipes.

Claims (1)

A method for increasing the generation of thermal energy in a coolant, which consists in an electromagnetic effect on the coolant from inductance coils, characterized in that the heater pipes at the inlet and outlet are insulated from the heat consumer's pipes with dielectric connecting pipes, the electrical capacitance and active resistance are connected to the heater inductance coils, the values which are calculated for the required thermal performance and are corrected experimentally, inductors with electrical capacitance and active resistance form a resonant electromagnetic LCR-oscillatory circuit, pump the coolant in its electromagnetic resonance field, during the passage of which water molecules are split into hydrogen and hydroxyl ions, followed by their reunification into water molecules and the release of additional heat energy into the coolant.