RU74452U1 - AUTONOMOUS SOURCE OF HEAT ENERGY - Google Patents

Abstract

The utility model relates to heat engineering. The essence of the technical solution consists in supplying the first chamber with a transparent window, connecting the upper parts of the first and second containers with each other, supplying them with a circulation hole and using mirrors directing the radiant flux to the transparent window, while the energy of the radiant flux after passing through the transparent window is absorbed by a moving absorbing coolant. The technical result consists in increasing consumer properties by increasing the efficiency and increasing output power. 1 n.a. P. f-ly, 2 ill.

Description

The utility model relates to heat engineering and can be used for space heating, heating liquids, for example, pool water, and for accumulating heat in tanks filled with coolant.

Numerous options for heaters are known, for example, described in [1], in which the coolant is placed in the tank, and the bottom of the tank is heated by the combustion products of the fuel. A disadvantage of the known technical solutions of this type is the low efficiency - a lot of heat generated during the combustion of fuel is wasted.

There are various options for devices for transferring thermal energy from the products of fuel combustion to the coolant using a bundle of heat exchange tubes [2]. In smoke-type (fire-tube) systems of this type, the heat carrier washes heat exchange tubes along which the products of fuel combustion move, in water-tube systems heat carrier flows through the heat exchange tubes, and the products of fuel combustion pass between the tubes. The disadvantage of such systems is low efficiency, since the heat exchange between the combustion products and the coolant is carried out only through the surface of the heat exchange tubes.

There are various options for devices in which the production of electrical energy is carried out by solar panels, for example, [3]. The use of such devices for generating thermal energy is associated with large energy losses, since in this case the energy is double converted: first, the energy of the radiant flux is converted into electrical energy, after which the electrical energy is converted into thermal energy.

There are various options for devices for converting radiant energy into thermal energy, for example, [4], in which this conversion is carried out by transferring energy from a heated plate

to heat exchange tubes built into the heated plate through which the coolant circulates. A disadvantage of the known devices is the low efficiency of the conversion of radiant energy into thermal energy due to the fact that the transfer of thermal energy occurs only through the wall of the heater.

Various versions of solar heaters are known, for example, [5, 6], in which transparent windows, covers, covers, etc. are used. In these devices, transparent elements are used to reduce heat losses and heat energy is transferred to the coolant only through the wall of the heater. A disadvantage of the known devices is the low efficiency of the conversion of radiant energy into thermal energy due to the fact that the transfer of thermal energy occurs only through the wall of the heater.

The closest in technical essence to the claimed device is the technical solution described in [7] and containing the first capacity connected in the circulation circuit in the form of a channel in the heating element, the second capacity in the form of a storage tank and circulation pipelines. The flow of radiant energy heats the heating element, which, in turn, heats the mobile absorbing heat carrier. The heated mobile absorbing heat carrier is sent to the storage tank, and from it to consumers. The cooled mobile heat carrier enters the channel of the heating plate, after which the operation cycle is repeated. A disadvantage of the known technical solution is the low consumer properties due to the low efficiency and low power output. The low efficiency is due to the fact that in the known device the radiant stream heats the heating plate, then this thermal energy passes to the mobile absorbing heat carrier through the channel walls, in which the mobile heat-absorbing heat carrier is located. Low power output due to the great complexity of manufacturing a known device with a large area of the heating element.

The objective of the utility model is to increase consumer properties by increasing the efficiency and increasing output power.

The solution of the problem in accordance with claim 1 of the utility model formula is ensured by the fact that the following improvements are made to an autonomous source of thermal energy containing a first tank, a second tank and a lower circulation pipe connected to the circulation circuit, while the circulation circuit is filled with a moving absorbing coolant: it additionally contains N primary mirrors, N secondary mirrors, the first wall of the first container is provided with a transparent window, the upper parts of the first and second containers are connected to I am waiting and equipped with a circulation hole, the lower circulation pipe is equipped with a valve, the transparent window is located in the path of the radiant flux, i.e. the primary mirror is located in the path of the radiant flux, i.e. the secondary mirror is located in the path of the radiant flux reflected from the ith primary mirror, reflected from i- of the secondary mirror, the radiant flux is directed to a transparent window, where 1≤i≤N, N = 1, 2, 3, ...

This construction of an autonomous source of thermal energy provides an increase in consumer properties by increasing the efficiency and increasing output power. The increase in efficiency is due to the fact that the absorption of radiant energy is carried out by a movable absorbing coolant located in the first chamber, resulting in an increase in the efficiency of use of radiant energy compared to the prototype, in which the absorption of radiant energy of the sun is carried out by the wall of the heating chamber, which, in turn, , heats the mobile absorbing heat carrier. The increase in output power is due to the fact that the primary and secondary mirrors increase the power of the radiant flux incident on the transparent window.

Thus, the claimed technical solution has higher consumer properties than the prototype.

In the particular case, in accordance with paragraph 2 of the utility model formula), the second tank is equipped with a heat exchange system. Such a construction of an autonomous source of thermal energy expands the scope of its application: the presence of a second circuit allows, for example, the use of water in it for cooking and hygienic procedures, since there are no absorbing additives in the water passing through the second circuit that are part of the mobile absorbing coolant circulating in the first circulation circuit.

The essence of the utility model is illustrated by a description of a specific, but not limiting, claimed technical solution, an embodiment, and the accompanying drawings, in which:

- figure 1 shows a cross section of an autonomous source of thermal energy;

- figure 2 shows the placement of primary and secondary mirrors.

An autonomous source of thermal energy contains a first tank 1, a second tank 2, a lower circulation pipe 3, while the upper parts of the first 1 and second 2 tanks are interconnected and provided with a circulation hole 4. The first tank 1, the second tank 2 and the lower circulation pipe 3 are connected into the circulation circuit, which is filled with a movable absorbing heat carrier 5. The first wall of the first tank 1 is equipped with a transparent window 6, and the inner surface of the third wall of the first tank 1 is equipped with a reflector 7. The second tank Two contain a heat exchange system 8. The lower circulation pipe 3 is provided with a valve 9. The first container 1, the second container 2 and the lower circulation pipe 3 are provided with thermal insulation 10.

An autonomous source of thermal energy comprises a circulation pump including a solar battery 11 and electric lamps 12, the output of the solar battery 11 being connected to the input of electric lamps 12. Electric lamps 12 are placed inside the first container 1 in its lower part. The circulation circuit is equipped with a heat accumulator 13. The flux of radiant energy is indicated at 14, a transparent window 6 is located in the path of the radiant flux 14, i-e primary mirror 15 is located

in the path of the radiant flux 14, the i-e secondary mirror 16 is located on the path of the radiant flux reflected from the i-th primary mirror 15, the radiant flux reflected from the i-th secondary mirror 16 is directed to the transparent window 6.

Autonomous heat source works as follows. The flux of radiant energy 14, for example, from the Sun, after passing through a transparent window 6 in the first tank 1 passes through a movable absorbing coolant 5, where the radiant flux 14 is absorbed. That part of the radiant flux 14 that has not been absorbed by the movable absorbing coolant 5 falls on the reflector 7 is reflected from it and again passes through the movable absorbing coolant 5, while the energy of the radiant flux 14 is also absorbed by the movable absorbing coolant 5. Thus, the radiant flux twice It passes through the movable absorbing heat medium 5, thereby increasing the amount of energy absorbed.

The mobile absorbing heat carrier 5, having absorbed the energy of the radiant flux 14, is heated and moves upward in the first tank 1, as shown by the arrow in FIG. 1, after which the heated mobile absorbing heat carrier 5 through the circulation hole 4 enters the second tank 2, where it washes the heat exchange system 8 and gives its thermal energy passing through the heat exchange system 8 to the mobile coolant of the second circuit. In this case, the movable absorbing heat carrier 5 is cooled and moves down the second tank 2, as shown by the arrows in FIG. 1, then passes through the lower circulation pipe 3 to the lower part of the first tank 1, after which the process is repeated. The valve 9 allows you to adjust the speed of the moving absorbent coolant 5, depending on operating conditions.

To increase the efficiency of an autonomous source of thermal energy and accelerate its output, the operating mode can be turned on by a circulation pump, which in the described embodiment is designed as follows. The solar battery 11 converts radiant flux energy into electrical energy, which in electrical

lamps 12 are converted into thermal energy. This thermal energy is transferred to the movable absorbent heat carrier 5, as a result of which the heated movable absorbent coolant 5 rises up the first tank 1, which increases the circulation rate of the movable absorbent coolant 5 in the circulation circuit. An increase in the circulation speed of the mobile absorbing heat carrier 5 in the circulation circuit increases the efficiency of the autonomous source of thermal energy and accelerates its output to the operating mode.

Due to the fact that the Sun is constantly moving relative to the Earth, it is necessary to periodically or constantly change the spatial position of the primary 15 and secondary 16 mirrors so that the maximum power of the radiant flux passes through the transparent window 6.

INFORMATION SOURCES

1. Eliot L., Wilcox W. Physics. M .: Nauka, 1967. P.327.

2. Isachenko V.P., Osipova V.A., Sukomel A.S. Heat transfer. M .: Energy, 1969. C.211, 419.

3. Solar generator. Auth. testimonial. USSR No. 1825071, prior, from 04.04.90, publ. 02/20/96 Bull. No. 5, IPC 6 F24J 2/00.

4. Solar collector. Auth. testimonial. USSR No. 1815526, prior, from 08.20.90, publ. 05/15. 93 bul. No. 18, IPC 5 F24J 2/08, 2/38.

5. Solar collector tank with a transparent casing. U.S. Patent No. 4,520,795, publ. 06.06.85 t.1055 No. 1, IPC 3 F24J 3/02, NKI 126-443.

6. A heating system using solar energy. Japanese application No. 60-25705, publ. 06/19/85 No. 5-643, IPC F24J 2/04.

7. Solar water heater. Auth. testimonial. No. 1814003, prior, from 03.19.91, publ. 05/07/93 Bul. No. 17, IPC 5A24 2/20.

Claims (2)

1. An autonomous source of thermal energy containing connected to the circulation circuit, the first tank, the second tank and the lower circulation pipe, while the circulation circuit is filled with a movable absorbing coolant, characterized in that it further comprises N primary mirrors, N secondary mirrors, the first wall of the first tank equipped with a transparent window, the upper parts of the first and second containers are interconnected and provided with a circulation hole, the lower circulation pipe is equipped with a valve, transparent it is located in the path of the radiant flux, i.e., the primary mirror is located in the path of the radiant flux, i.e. the secondary mirror is located in the path of the radiant flux reflected from the i-th primary mirror, the radiant flux reflected from the i -th secondary mirror is directed to the transparent window, where 1≤i ≤N, N = 1, 2, 3, ... 2. The autonomous source of thermal energy according to claim 1, characterized in that the second tank is equipped with a heat exchange system.