UA47535C2 - Method of heat producing - Google Patents

Abstract

An invention relates to the heat techniques, particularly, designated for a water warming without a fuel burning. A heat for the water warming is obtained by forming a vortex water movement and ensuring a cavitation mode of its flowing with a resonance amplification of the induced acoustic vibration in this flow, and by supplying the water in the flow with a temperature of 63 °С, and better with 63-70 temperatures. The water warming up to 63 °С in advance is recommended to perform by the heat, produced in the same way of the water circulation in a closed loop without intake of the produced heat.

Description

Description of the invention

The invention belongs to heat engineering, in particular to methods of obtaining heat, which occurs differently than in 2 as a result of burning fuels.

There are known frictional methods of obtaining heat for heating liquids, which consist in the fact that heat is obtained as a result of the friction of solid bodies against each other or against the liquid, which are set in motion in a vessel with liquid. For example, according to A.S. USSR Mo1627790, MKV E243/00, Bul. Mob, 1991

Hydrodynamic (jet) methods of heating liquids are also known, in which heat is obtained due to the action of 710 jets of liquid on each other or on mechanical obstacles placed in the path of the jet. At the same time, a part of the kinetic energy of the jets is converted into heat both due to the friction of their flow against obstacles and due to impact actions during cavitation processes that occur in this case. (Akunov V. Jet mills. - M.:

Mechanical engineering, 1967, -299 p.|.

The disadvantage of these methods is that due to the low efficiency of the equipment used and energy losses, the output 72 of thermal energy carried by the heated liquid is lower than the consumption of electrical or mechanical energy consumed by the pump that injects the liquid into the device for carrying out the method. That is, the heating efficiency is less than one.

But in recent years, a number of methods of obtaining heat have appeared, the efficiency of which is greater than one. The most effective of them is the method that was described in Koldamasov A.M. Journal of technical physics, 1991, vol. 61, Mo2, p. 188-190). It consists in the fact that up to 195 heavy (deuterium) water is added to the water, which has been purified from salts to a specific resistance of 10 11. 1014 Ohm.m. (the operation of adding heavy water is described in the publication (A. Koldamasov. Nuclear reactor on the table - "Tehnika - molodezhy", 2000, Moi, p. 131) and with the help of a gear pump, which develops a pressure of up to 7 MPa, this water is fed into a chamber connected to the pump (a segment of a pipe made of glass or Plexiglas), in which there is an insert made of plexiglass or other dielectric material with a hole (spindle) in it, which is coaxial with the entire chamber and has a diameter of 1 - 2 mm.When water passes through the spinner, it itself swirls (o) into a turbulent flow.

At the same time, cavitation occurs near the edges of the hole, and it is amplified resonantly. For this, the speed of rotation of the gear pump is selected such that shocks in the water, which occur when each pair of 20 teeth of the pump gears close and are repeated at a frequency of 1 - 5 kHz, enter into resonance with the own sound oscillation of the water column between the pump and the liner. At the same time, a glow appears near the edges of the die opening, which is caused by electrical phenomena accompanying cavitation. X-ray radiation is also emitted from the area of luminescence, the dose rate of which near the camera reaches Imkr/sec at the energy of y-quanta up to

0,33 MevV, as well as neutron radiation with a neutron flux density near the surface of the chamber (at a distance of "10 cm in.

From the spinneret) up to 40 cm'g/sec at neutron energy up to ZMev. "Her

The last circumstance indicates that nuclear reactions between the nuclei of deuterium atoms take place in the area of luminescence: 2Ддя2Д о. ЗНе я п я 3.26MeVv (1) « - s The water after the spinneret turns out to be heated, while it is supplied to the pump inlet at room temperature.

Water calorimetry indicates that with a pump power of 10 kW, the water coming out of the spinneret carries up to 200 kW;" thermal power.

The appearance of additional heat, the amount of which according to the publication (A. Koldamasov. "Technology - youth", 2000,

MO, p. 131 is almost 20 times more than the amount of heat that could appear due to the conversion into heat of the mechanical energy of the movement of the water supplied by the pump, can be explained only by the release of energy of the nuclear reactions taking place at the same time. But with the output of neutrons with a total intensity of "1 Osek", which 7 was registered experimentally, the output of thermal energy, which is obtained due to the nuclear reaction (1), according to 1 with the equation of this reaction, cannot exceed 5 x 10 W. This indicates that that the appearance of additional heat not s 50 can be explained only by reaction (1). It is not excluded that other nuclear reactions are also taking place at the same time, which are not accompanied by neutron radiation, but emit additional heat. More details about what specific nuclear reactions can occur under of these circumstances, it is said in the book (Potapov Yu.S., Fominsky L.P. Eddy energy and cold nuclear synthesis from the standpoint of the theory of motion. - Chisinau-Cherkassy; "OKO-Plus", 2000. - 397 si.

"Hot water" coming out of the described device is sent to a heat exchanger, where the received heat is removed from it, for example in the form of warm water for heating residential premises, or by evaporating ammonia to bring its steam into the rotation of a turbogenerator that produces secondary electricity. And the highly pure (namely) water that has cooled in the heat exchanger is sent for further treatment with the help of ion-exchange resins and is returned through a closed circuit to the vessel, from which it is again fed by a pump into the chamber with the spinneret. 60 The disadvantage of this method is the need to constantly purify the water that circulates along the mixed circuit in order to maintain its specific resistance within 1011 - 1014 Ohms. And ion-exchange resins, with the help of which cleaning is carried out, usually do not tolerate high temperatures. Therefore, before feeding it to the aftertreatment device, the water is additionally cooled to room temperature, or attempts are made to cool it to such a temperature in the heat exchanger that removes the generated heat from it, which is directed to beneficial use. For this, low-boiling liquids, such as ammonia or freon, are used as heat carriers of the secondary circuit. Cooling the water in the heat exchanger to room temperature also leads to a reduction in the consumption of high-purity water in the working circuit, which reduces the load on the water treatment device.

The second disadvantage of the known method is the increased level of neutron and X-ray radiation, which make this method radiation dangerous and require the presence of biological protection against ionizing radiation. A decrease in neutron yield is observed when adding heavy water to high-purity water, which is used in the described method. But at the same time, the output of the produced heat also decreases.

The closest known technical solution (prototype) to the proposed solution is the method of obtaining heat, which was described in the patent of the Russian Federation Mo2045715, MKV E25829/00 by Yu.S. Potapov, published on October 10, 1995 in Byul. Mo28. According to this method, water of any purity (for example, technical water) using a pump that develops a pressure of up to 5 barm. the inlet auger of the vortex tube, the water is swirled into a vortex flow, which is directed into the cylindrical part of the vortex tube, where the water 7/5 moves, rapidly rotating, from its cold inlet to the hot outlet. At the hot end of the vortex tube, in front of its opening, a braking device is placed, which has several ribs radial to the axis of the tube.

They are fixed on the central sleeve, which is coaxial with the pipe. When the rotation of the vortex flow of water is slowed down, cavitation occurs on the edges of this device. The sound vibrations accompanying it are amplified at frequencies resonant with the own frequencies of the sound vibrations of the water column in the cylindrical part of the vortex tube as in the resonator. At the same time, cavitation intensifies and developed sonoluminescence occurs. As a result of these effects, as well as as a result of friction against the walls of the pipe and the braking device, the water heats up, and at the exit from the vortex tube, its temperature rises. It can rise up to the boiling point of water.

At the same time, the consumption of electricity consumed by the motor of the pump that supplies water to the vortex tube is only 0.7 - О0.8 kW for each kW of produced thermal power, which is carried by hot water. This indicates that nuclear fusion reactions also take place in the described heat generator, which has already been put into serial production at some CIS enterprises and is produced in dozens of modifications for heating residential and industrial premises and obtaining hot i) water for domestic and technological needs , which lead to the appearance of additional heat. But the registered output of neutrons during the operation of the Potapov vortex heat generator does not exceed the level of the natural background, and the dose level of ionizing radiation from the vortex tube of the heat generator does not exceed the level of the natural background by much (3 - 4 times lower than the maximum permissible dose of NRB-87 radiation safety standards in force for the population not related to ionizing radiation in their professional activities). This ensures radiation safety during use of the heat generator in yu

Potapova Calculations of the energy output of nuclear reactions that take place in the vortex tube of the heat generator are carried out in the book (Potapov Yu.S., Fominsky L.P. Vortex energy and cold nuclear energy

Synthesis from the standpoint of motion theory. - Chisinau-Cherkassy: "OKO-Plus", 2000, 397 p), confirm the possibility of obtaining the indicated amount of additional heat with such a registered output of y-radiation.

The hot water coming out of the vortex tube of the heat generator can either be directly supplied to the hot water consumer (in the shower, kitchen, sink, etc.), or heat can be removed from it using a heat exchanger, and the water itself can be returned through a closed loop to the pump inlet for resupply into the vortex tube of the heat generator. "

In the first case, there is no need for a heat exchanger and the coefficient of heat utilization increases. Therefore, consumers more often use the first scheme, which is also easier to implement and use. With her

And at the input of the heat generator pump, fresh water is constantly supplied, which has a room temperature or even lower temperature and? (temperature of tap water).

The disadvantage of the described known method is the comparatively low efficiency of water heating. Thus, according to the data of many years of experience in the operation of vortex heat generators "YUSMAR" (TU U24070270, 0001-96), for which there is a certificate of Ross KO МХОЗ С 00039 dated 03.01.98., the ratio of thermal power produced by these heat generators to electric power, that they consume (the so-called efficiency) does not exceed 1.7,

Which is much lower than the efficiency of Koldamasov's experimental setup, described above, but not put into serial production due to its indicated shortcomings.

The efficiency of water heating by a vortex heat generator increases when heavy water is added to its water, as described in M.M. Vagytsi, M.R. Kogeib5ku, A.V. Kygpeiv, U.5 Roiar, M.R. Mikiiekkiu. , Memegpip sp M.M., Zashpigi E.E., KogaiKemisp M.O., Tiepkom A.E./LSSE-6, Osioreg 1996, darap, r.387-3914. But the increase in heat output is accompanied by an increase in the output of neutrons from the vortex tube to a value that exceeds the natural background. This increases the radiation hazard of the heat generator and requires the use of expensive and scarce heavy water additives.

The invention is based on the task of obtaining heat by changing and specifying the interval (F, temperature of water used for heat production, ensuring an increase in the efficiency of heat production and reducing the radiation hazard of neutron irradiation while simultaneously simplifying the technological process of water preparation. 60 This task is achieved by the fact that in the known method of obtaining heat, which consists in the formation of a vortex flow of water and ensuring the cavitation mode of its flow with resonant amplification of sound vibrations arising in this flow, water is fed into the vortex flow at a temperature above 63"C, preferably at 63 - 706.

The set task is also achieved by pre-heating the water to a temperature of 637"C using heat that is obtained in the same way during the circulation of water in a closed circuit without removing the heat that is obtained from it.

On the basis of experimental data, it was found that with a gradual increase in the temperature of the water supplied to the entrance of the vortex tube of the heat generator, the efficiency of its heat production increases by a leap when the temperature reaches 63"C and remains the same at a further increase

The temperature of the water supplied to the entrance of the vortex tube, up to the boiling point of water. This leads to a decrease in electricity consumption by the electric motor of the heat generator pump. The revealed effect is probably due to the fact that at the boss temperature there are extrema on the graphs of the dependence of the adiabatic compressibility of water and the speed of sound in it on the temperature. (see, for example |Domrachev G.A. et al. "Journal of Physical Chemistry". 1992, vol. 6b, Mo, pp. 851-855.1. When the specified temperature is exceeded, these values 70 begin to change with increasing temperature already in the opposite direction in which they changed up to this temperature. In addition, in the same publication it is indicated that when the temperature of water increases, fewer ice-like molecular associates (H 2O)ep remain in it, and at 65"С they are all broken by the thermal movement of molecules All this, apparently, somehow reduces the probability of a nuclear reaction occurring in water (1) and increases the probability of nuclear reactions taking place in it:

RyaYALNzhe--» 2D Me k 1.953 MeV (2) and DR -» ZNe х х х 5.49 MeV (3) or 2D ker» ZT Me 5.98 MeV (4)

Nuclear reactions (2) and (4) were previously unknown to physicists and were described for the first time in a book (Y.S. Potapov, Fominsky

L.P. Eddy energy and cold nuclear fusion from the standpoint of the theory of motion. - Chisinau-Cherkassy!: "OKOPlyus", 2000, - 397 p.).

As a result of reaction (2), which is accompanied by emission of neutrinos Ме, the synthesis of red deuterons 2D occurs from the nuclei of protium atoms "H, protons Р and electrons е", which exist in water molecules. The synthesized deuterons are partially consumed in reactions (3) and (4), resulting in the formation of nuclei of helium-3 and (o) tritium ZT atoms, which remain in the water along with the rest of the deuterons. And neutrinos and hard y-quanta with energy up to 5.49 MeV, which are born at the same time, are emitted from water. Nuclear reactions (2) and (3) are probably the main source of additional heat, which is produced by a heat generator and goes to heat water, because in reaction (4) almost all the energy of this reaction is carried away by emitted neutrinos, which are practically not retained substance and fly through water, the walls of devices and any obstacles. It can be assumed that with an increase in the temperature of water i) above 63"C, the rate of nuclear reactions (2) and (3), which lead to the synthesis of non-radioactive deuterium and helium-3, especially increases. At the same time, the probability of nuclear reaction (1), which is accompanied by the radiation of neutrons that are especially dangerous for human health, remains small.

Hard y-radiation with a quantum energy of 5.49 MeV, which is born during a nuclear reaction (3), was "registered experimentally during the operation of a vortex heat generator on ordinary water |Potapov Yu.S.,

L.P. Fominsky Vortex energy and cold nuclear fusion from the standpoint of the theory of motion. - Chisinau-Cherkassy: "OKO-Plus", 2000, - 397 p.). But these y-quanta carry out a low dose level of ionizing radiation even directly next to the vortex tube of the heat generator, because they have a long distance in water and in air. Therefore, the increase in the intensity of nuclear reactions (C) during the implementation of the proposed invention is accompanied by some increase in the dose of ionizing radiation, but when using ordinary water in vortex tubes, it does not exceed the most permissible radiation safety standards of NRB-87 for the population, not related to in his professional activity with ionizing radiation. At the same time, the intensity of neutron radiation from the vortex tube is almost

It does not grow and remains at the level of the natural background. The proposed invention eliminates the need to add heavy water to the water used in the operation of the Koldamasov device, which makes it workable when working on ordinary - distilled water of high purity and thereby simplifies the technology of water preparation. At the same time, the output of neutron radiation during the operation of the Koldamasov device decreases to the level of the natural background, which reduces the radiation hazard. All this ensures the achievement of the set task of the invention. o The lower limit of the recommended temperature interval of 63"C for water fed into the vortex flow, c, was chosen for the reasons that at a water temperature below 63"C, the increase in efficiency is not observed with increasing water temperature. The upper limit is actually equal to the boiling temperature of water, because up to this temperature the efficiency of the heat generator remains as high as at 63"C. But the closer the temperature of the water fed into the vortex flow is to its boiling temperature, the lower it remains operating temperature range for heating this water with the received heat, and the greater the required water consumption for

F) it removes heat from the heat generator. And this, when implementing the method in Koldamasov's device, leads to an increase in the required power of the pump and an increase in the consumption of expensive high-purity water. And the bandwidth of the spinneret in this device is limited. For these reasons, the recommended temperature range of the water supplied to the vortex flow is limited from above to a temperature of 70"C.

The pre-heating of water to a temperature of 63"C proposed by the second clause of the invention with the heat produced in the same heat generator during the circulation of water in it in a closed circuit without removing the heat received from it allows to abandon the need to use additional heating sources (electric heaters, etc.), which simplifies the technological scheme of water preparation and the design of the installation. 65 The following operations are carried out to obtain heat according to the proposed method: 1. Take ordinary water of technical or other purity. Water of increased purity, which has a specific resistance of 1071 --

1014 Ohm.m, used only when implementing the method using Koldamasov's device, which was described in the Journal of Technical Physics, 1991, vol. 61, Mo2, p. 188 - 190), or similar to it. 2. The prepared water is heated to 63 - 70"C. The heating can be carried out by an electric heater that works at the expense of Joule heat, or with the help of another heat source. But it is better to heat the water with the heat that is obtained by the proposed method during the circulation of this water in a closed circuit without 3. Fill the water vessel of the Potapov vortex heat generator with heated water, which was described in the patent of the Russian Federation Mo2045715 MKV G25829/00, published on October 10, 1995 in Bull. . Koldamasova. 5. By selecting the amount of water pressure, the speed of rotation of the pump, or the length of the water column in front of the spinneret or in the vortex tube, the cavitation regime of the vortex flow is ensured and with resonant amplification in this 75 stream of sound vibrations arising in it. 6. They direct the heated water that comes out of the device for obtaining heat to a heat exchanger, with the help of which they remove the received heat from this water and use it at the heat consumer, or use the heated water directly at the consumer. 7. The water that has cooled in the heat exchanger is returned through a closed circuit to the water vessel, from where it is fed again by a pump to the device for forming a vortex flow. When using the Koldamasov device, before returning the water to the vessel, it is cleaned to maintain the specific resistance within 0171-1074 Ohm, m. 8. Measures are taken so that the water in the vessel of the device does not cool down to a temperature below 63"С.

Example 1. Take ordinary fresh water of technical purity at room temperature in the amount of 100 liters with 29 | fill with it the vessel for water and the entire first (working) circuit of the vortex heat generator "Yusmar-2M" (9 (TU U 24070270, 001-96), which was described in the patent of the Russian Federation Mo2045715 MKV G25829/00. Using a pump of the brand 1ЧГ 12, 5/50-4-2 of this heat generator, which has an electric motor with a power of 4 kW, supplies water from the vessel to the entrance of the vortex tube of the heat generator, similar to the well-known Ranke vortex tube, developing a pressure of up to 1000 m. In the spiral of the vortex tube, the water flow is twisted into a vortex flow , which enters further into the 30 cylindrical part of the vortex tube, which has a diameter of 7 mm and a length of 80 mm. In it, the vortex flow, rotating, "Z moves along the walls of the tube to its hot end, in front of the opening of which a braking device is installed. It consists of a sleeve , coaxial with the pipe, and 8 ribs - steel plates welded to it, located in the plane of the pipe axis, radial to this axis. cavitation occurs at the edges of the ribs. Sound vibrations that

Zo are born thanks to it, are amplified at the resonant frequency of 1.9 kHz, which corresponds to the frequency of the own sound M vibrations of the water column in the vortex tube, which works as a resonator. At the same time, the sonoluminescent glow of the water in the pipe occurs and it warms up. The water coming from the vortex tube, heated to a temperature slightly higher than the initial temperature, is returned through the pipeline to the water vessel, from where it is fed again by a pump to the entrance of the vortex tube of the heat generator. Circulating in this way along a closed circuit, the water is gradually heated by the heat produced by the heat generator. With a total mass of water in a closed circuit of 100 kg, the rate of its heating is 4"C for every 5 minutes of operation of the heat generator at a water temperature at the entrance of the vortex tube up to "63"C. When the temperature of the water in the vessel with water reaches 63"C, the heating rate of water rises sharply without increasing the consumption of electricity by the pump motor and remains the same high with a further increase in the temperature of the water in the vessel with the initial water up to the boiling temperature of water at a given pressure (100"C with the lid of the neck of the vessel with water open, due to which the pressure in it equal to that of the atmosphere).The results of measuring the growth rate of water temperature in a vessel with initial water with -I operating time of the heat generator are given in Table 1, which shows and calculated from the results of these measurements the values of the efficiency of the heat generator. of the closed circuit for the time between two measurements to the cost of electrical energy that (4) 90 consumes there is a heat generator pump engine during this time. The results of the experiments are confirmed by the test protocol, a copy of which is attached. sl Example 2. The same water as in example 1 is taken, and all the operations described in example 1 are carried out on it, with the exception that after heating the water in the working circuit of the heat generator to 907C, this water is not directed immediately into the vessel of the day of the initial water , and it is fed through the pipeline to the heat exchanger, where it gives part of 22 of its teshia to tap water, which is fed with a flow rate of 160 liters per hour to the second circuit of the heat exchanger and

GF) are heated there from room temperature (20"C) to 60"C. Heated water from the second circuit is used for household needs in the laundry room. And the water of the primary (working) circuit, cooled in the heat exchanger to 86 - 887C, is returned through the pipeline to the vessel of the initial water, from where it is pumped again with the help of a pump into the vortex tube of the heat generator. 60 Example 3. Take the same water as in example 1 and heat it to a temperature of 63 - 657"C with the help of an electric heater that produces joule heat. Then pour this water in the amount of 100 liters into the vessel for the initial water and into the working circuit heat generator "Yusmar-2M". All other operations are carried out in the same way as in example 2, and the same results for the production of teap are obtained as in example 2.

Example 4. They take the same water as in example 1, and perform all operations in the same way as in example 1, with the exception that they use the Yusmar-ZM heat generator, which has a pump with the power of an electric motor

11 kW After the temperature of this water reaches 707C, it is sent through the pipeline to the water heating system of the cottage. When the water passes through the water heating radiators and with their help gives part of its heat to the air of the cottage premises, it returns through the pipeline to the vessel for initial water already at a temperature of 65 - 67"C. From the vessel of initial water, it is again fed into the vortex with the help of the pump of the heat generator heat generator pipe. After entering the working mode (707С), the heat generator produces 22 kW of thermal power. At the same time, its efficiency reaches 2.

Example 5, They take ordinary distilled water (bidistillate) without any additives | with the help of ion-exchange resins, it is purified to increase the specific resistance of this water to electric current to 102 ohms. With the help of an electric boiler that produces joule heat, this water is heated to the temperature T 4 indicated in table 2, and this water is poured in the amount of 20 liters into the vessel of the initial water of the installation

Koldamasova, which is described in |ZhTP, 1991, T.61, Mo2, and 188-190). The gear pump of this installation, which has an electric motor that consumes power up to 5 kW, pumps water from the specified vessel into the chamber (a section of plexiglass pipe) that is connected to the pump, and develops a pressure of up to 7 MPa in it. In the chamber there is an insert made of ebonite 75 plate, which has a thickness of 25 mm and a hole in it with a diameter of 2 mm. When water passes under pressure through this hole, it spontaneously swirls on the irregularities of the hole into a turbulent flow. At the same time, cavitation occurs near the inlet edge of the hole. The water that has passed through this hole is sent through the pipeline to the second vessel for water, where its temperature To is measured at the exit from the pipeline. By changing the voltage on the electric motor of the pump, the speed of rotation of the pump gears is selected such that the shocks of water that occur when each pair of gear teeth close and are repeated with a frequency adjustable within 1 - 5 kHz, enter into resonance with their own ultrasonic oscillations of the water column in the chamber between the pump and the insert ("2 kHz). The moment of the beginning of the resonance is fixed by the appearance of a bright glow of water near the entrance edges of the hole in the tab, which can be seen through the transparent body of the camera. X-ray radiation also comes from the area of the glow, the dose rate of which, measured by the RUP-1 universal dosimeter at successive time intervals after the release of He into resonance, is shown in Table 2. At the same time, the output of neutron radiation recorded by the same dosimeter does not exceed the natural background for the entire time of experiments. Table 2 shows that when the temperature of the water supplied to the chamber is lower than 63"C, the water heating efficiency in this device, which is defined as the ratio of the thermal energy acquired by the water during the time between two consecutive measurements, to the amount of electrical energy that consumed by the engine of the gear pump in the same time, depends little on IF) of the initial water temperature and is 3.4. And when the initial water temperature exceeds 63 "С, the efficiency increases sharply and remains the same even with a further increase in water temperature up to its boiling point. IF) and

Parameters and results for example 1 « working time, minutes 0|10/20| with yao/ voi va va| in5| vv/vv| oh that's it

Water temperature, 002025 36/44 52 50525652 Bya vv vv 05 25 55, 1 Efficiency, "А АЯ а ла 15 20 222222 2222 22) " -

Table 2 c g» temteratreseditiso 20305050 in 05

Temperature control os Z 509 11111

Claims (2)

The formula of the invention is 50 sp. 1. The method of obtaining heat by forming a vortex flow of water and ensuring the cavitation mode of its flow with resonant amplification of sound vibrations arising in this flow, which is distinguished by the fact that water is fed into the vortex flow at a temperature above 63"С , better at 63-7076. 2. The method according to claim 1, which differs in that the preliminary heating of water to a temperature of 63"С is carried out with heat, which is obtained in the same way during the circulation of water in a closed circuit without removing heat from it, which is obtained by GF) (name) Official Bulletin " Industrial property". Book 1 "Inventions, useful models, topographies of integrated microcircuits", 2002, M 7, 15.07.2002. State Department of Intellectual Property of the Ministry of Education and Science of Ukraine. b5