RU66794U1 - SOURCE OF HEAT POWER SUPPLY - Google Patents

Abstract

The utility model relates to heat engineering and is intended primarily for heating various buildings and structures.

The objective of the utility model is to expand the functionality by generating electricity and improving consumer properties by increasing efficiency, improving environmental parameters and reducing the overall dimensions of the heat and power supply source.

The essence of the utility model is to place a furnace for burning chemical fuel and heating surfaces of a device for removing heat inside a chimney.

Description

The utility model relates to heat engineering and is intended primarily for heating various buildings and structures.

A known heat supply system [1], in which the heat source is made in the form of a single-tube heating system of the supplied network water, and the heating is carried out periodically, and in the inter-period time, the water supply is carried out in the opposite direction. A disadvantage of the known heat supply source is the low efficiency (efficiency) of converting chemical energy into thermal energy, in addition, the water supply back and forth requires either structurally complex pumps or a complex electrical circuit for switching the pumps, as a result of which the consumer properties of the known heat supply system are reduced . In addition, such a system often requires a storage tank for storing hot water, which significantly increases the overall dimensions and cost parameters of the known heat supply system.

A known heat supply system [2], in which two heat sources are used, located at opposite ends of the heated room. Under the floor of the heated room there are tubes through which the coolant circulates. The location of the pipes under the floor is chosen in such a way that uniform heating of the floor is ensured. A disadvantage of the known device is the need to use two heat sources simultaneously, which should be located at opposite ends of the heated room.

Closest to the technical nature of the claimed device is a heat supply source [3], containing a furnace in which chemical fuel is burned, resulting in the conversion of chemical energy into thermal energy. Further, gaseous products of combustion (flue gases) pass between the heating surfaces.

a device for removing heat, which leads to heating of the coolant used in the device for removing heat. The heated coolant is used in the prototype for space heating. Flue gases through a horizontal chimney enter the natural draft device (chimney) and are emitted into the atmosphere.

A well-known source of heat and power supply has a number of disadvantages, the main of which are low consumer properties and narrow functional capabilities. The low consumer properties of the described device are due to a number of reasons, the first of which is low efficiency due to heat loss, which is carried away by flue gases into the atmosphere. In addition, the resulting heat energy is also released into the environment, which is caused by the large weight and size parameters of boilers and boiler room equipment. For a boiler room, a separate building or a separate room in a building is required, as a result of which heat losses increase. For the construction of the boiler room and the installation of its equipment, construction materials are consumed and labor costs are required, which increases the cost of the heat supply source. It should also be noted that water vapors present in flue gases enter into a chemical reaction with atmospheric nitrogen present in flue gases, resulting in the formation of nitrous and nitric acids. If solid fuel is used in the heat supply source, in addition to atomic nitrogen, sulfur oxides are also present in the flue gases, which interact with water vapor in the flue gases and form sulfuric and sulfuric acids. These acids enter the environment and form harmful acid rain, which reduces the environmental parameters of a known source of heat and energy. Ecological parameters are also reduced due to the above thermal pollution of the environment. All of these factors reduce the consumer properties of the described device. The narrow functionality of a well-known heat supply source is determined by the fact that it is intended only for generating thermal energy.

The objective of the utility model is to expand functionality by generating electricity and increasing consumer properties by increasing efficiency, improving environmental parameters and reducing the overall dimensions of the heat supply source.

The solution to this problem is provided by the fact that the following improvements are made to the well-known heat and power supply source containing a furnace for burning chemical fuel, a device for removing heat and a chimney (claim 1 of the utility model formula): a furnace for burning chemical fuel and a heating surface of a removal device heat located inside the chimney.

Such a construction of the claimed source of heat and energy supply can significantly reduce its weight and size parameters due to the fact that the furnace for burning chemical fuel and the heating surface of the device for removing heat are located inside the chimney, as a result of which there is no need to build a separate building, premises for placing the necessary equipment, which leads to reduce labor and material costs in the construction of the claimed source of heat and energy. In addition, the efficiency of the described device is increased due to the fact that losses in the environment are reduced with a decrease in the weight and size parameters of the heat supply source. Thus, the reduction of weight and size parameters and increase the efficiency of the device can improve the consumer properties of the claimed utility model.

In the particular case (claim 2 of the utility model formula), the chimney contains a device for condensing water vapor from flue gases.

Such a construction of the chimney can significantly increase the efficiency of the heat supply source by obtaining and using the heat released during condensation of water vapor from the exhaust flue gases and by reducing heat loss with the exhaust flue gases due to lowering their temperature.

In the particular case (claim 3 of the utility model formula), the chimney contains coaxially located inner pipe and outer pipe,

which are connected from below by a disk-shaped plate, from the upper side are connected by a ring-shaped plate, the space between the inner pipe and the outer pipe is divided into first and second cavities by two longitudinal partitions provided with holes, the first cavity is connected to the second cavity by the heating surfaces of the heat removal device.

Such a construction of the heating system allows to increase the efficiency of the heating system due to the fact that heat is transferred to the coolant not only to the coolant located in the heating surfaces of the heat removal device, but also to the coolant located between the inner pipe and the outer pipe, which increases the heat exchange area between coolant and flue gases. Increasing the efficiency of the heating system leads to an increase in consumer properties of the claimed utility model. In addition, due to the use of a double pipe (containing the inner pipe and the outer pipe), there is no need for thermal insulation of the chimney, which reduces the consumption of heat-insulating materials, which reduces the cost of the device by reducing the cost of heat-insulating materials, as well as by reducing time and labor costs for installing the chimney. In addition, the simultaneous removal of thermal energy of flue gases using the heating surfaces of the device for removing heat and using heat transfer through the inner pipe allows to increase the heating area without increasing the weight and size parameters of the chimney and without deteriorating its aerodynamic qualities.

In the particular case (Clause 4 of the utility model formula), a low-temperature fire chamber for burning chemical fuel is used as a furnace for burning chemical fuel.

Such a construction of a furnace for burning chemical fuel can improve the environmental parameters of the inventive heating system due to the fact that the low-temperature furnace for burning chemical fuel during operation creates a temperature insufficient for the formation of atomic nitrogen and sulfur oxides, as a result of which nitrogen, nitrogen, sulfur and sulphurous acid. As a result, pollution is reduced.

environment due to the absence of acid rain, resulting in improved environmental parameters, therefore, the consumer properties of the claimed heat and power supply source are improved.

As a low-temperature furnace for burning chemical fuel, mainly a combination of a furnace for burning chemical fuel and an injection burner placed in the furnace for burning liquid and gaseous fuels can be used. For example, as a low-temperature furnace for burning chemical fuel, a fluidized-bed furnace can also be used, and so on, due to the fact that the volume of the furnace space in the described device is limited, unlike modern boiler units, and does not lead to a significant increase in the overall dimensions devices in general (modern requirements of environmental services for new sanitary standards require an increase in the height of chimneys). Thus, the use of a low-temperature furnace for burning chemical fuel can improve environmental parameters and thereby improve the consumer properties of the claimed device.

In the particular case (claim 5 of the utility model formula), between the heating chamber for burning chemical fuel and the heating surfaces of the heat removal system are the heating surfaces of the second heat removal device.

Such a construction of a heat supply source allows providing serviced rooms with hot water for sanitary needs, as a result of which consumer properties are improved due to an increase in the efficiency of the heat supply source and improvement of its environmental parameters, which is obtained due to the fact that hot water supply is provided and therefore the useless emission of heat into the atmosphere is reduced . In addition, the cooling of the flue gas by the heating surfaces of the second device for removing heat reduces the temperature of the flue gas and does not allow other devices located inside the chimney to overheat, resulting in improved consumer properties of the described device.

In the particular case (claim 6 of the utility model formula), the lateral outer surface of the furnace for burning chemical fuel is provided with heating surfaces of a third heat removal device.

This construction of the furnace for burning chemical fuel allows it to be thermally shielded by the heating surfaces of the third device for removing heat, which reduces the consumption of materials for refractory gunning of the furnace, which increases the consumer properties of the inventive device.

In the particular case (Clause 7 of the utility model formula), a wind electric generator is placed inside the chimney. This option of constructive implementation of the energy supply source will expand its functionality by generating electrical energy and improve consumer properties by increasing efficiency and improving environmental parameters, which is obtained due to a decrease in the speed and temperature of flue gases emitted into the atmosphere. It should be noted that the wind electric generator has a stabilizing effect on the operation of the heat supply source: with an increase in draft in the chimney, the rotation speed of the wind electric generator increases, as a result of which the resistance of the wind electric generator to flue gases increases. At the same time, the speed of the flue gases decreases and their temperature decreases. With a decrease in draft in the chimney, the rotation speed of the wind electric generator decreases. This reduces the resistance to flue gases, which leads to an increase in draft in the chimney. Thus, the wind electric generator, in addition to generating electric energy, performs the function of a stabilizer of the natural draft of the chimney. In addition, due to the production of electric energy, efficiency increases, as a result of which consumer properties are increased and functionality is expanded (the design of the prototype does not allow directly to receive electric energy).

In the particular case (claim 8 of the utility model formula), a device for condensing water vapor comprises a heating surface of a fourth device for removing heat and a trap for condensed water.

Such a construction of a device for condensing water vapor allows you to collect condensed water and then use it for various needs (for example, to generate electricity). During condensation of water from flue gases (the temperature of the flue gases decreases below the dew point), the efficiency of the heat supply source increases due to the generation and use of heat released during condensation of water vapor from the exhaust flue gases and due to a decrease in heat energy losses due to a decrease in the temperature of the flue gases. As a result of this, the consumer properties of the described device are improved.

In the particular case (claim 9 of the utility model formula), the condensed water trap located inside the chimney contains elliptical plates with a cut edge, and in each elliptical plate with a cut edge, the longitudinal dimension A _{1 of} the elliptical plate with a cut edge is selected from the relation :

A ₁ > A ₂ ,

where A ₂ is the semi-major axis of the ellipse, made in the form of an ellipse, the edge of the plate is attached obliquely to the inner part of the inner pipe, the edge of the plate of an elliptical shape with a cut edge located above the opposite edge of the plate of an elliptical shape, and the lower part of each cavity formed by an elliptical plate with a cut edge and adjacent to the inner portion of the chimney, equipped with a drainage pipe. Such a construction of a device for condensing water from flue gases allows you to collect condensed water, send it to the right place through the drainage pipes and use it for the intended purpose. At the same time, consumer properties are improved by increasing the efficiency of the heating system and improving its environmental parameters, which is obtained due to a decrease in the temperature of waste gases emitted into the atmosphere.

In the particular case (claim 10 of the utility model formula), the condensed water trap contains a plate made in the shape of a cone located with its top up, under a plate made in the shape of a cone, a plate made in the form coaxially with the gap is placed

truncated cone, located with its small hole up, the outer diameter of the plate made in the form of a truncated cone is equal to the inner diameter of the chimney, and the cavity formed by the plate made in the form of a truncated cone and the inner part of the chimney adjacent to it is equipped with a drain pipe.

Such a construction of a device for condensing water from flue gases will allow collecting condensed water, directing it to the right place through drainage pipes and using it for the intended purpose. At the same time, consumer properties are improved by increasing the efficiency of the heating system and improving its environmental parameters, which is obtained due to a decrease in the temperature of the flue gases emitted into the atmosphere.

In the particular case (Clause 11 of the utility model formula), the drainage tubes are connected to a generator that converts the kinetic energy of condensed water into electrical energy. Such a construction of the heating system allows to expand its functionality by generating electricity and increasing consumer properties by increasing the efficiency of the heat supply source and improving its environmental parameters, which is obtained due to a decrease in the temperature of the furnace waste emitted into the atmosphere for burning chemical fuel.

After the condensed water leaves the generator, which converts the kinetic energy of the condensed water into electrical energy, the condensed water enters the furnace for afterburning and secondary evaporation, after which the process is repeated. After a series of described cycles, the amount of various impurities in condensed water decreases, which improves environmental parameters and thereby increases consumer properties.

In the particular case (clause 12 of the utility model formula), the surface of the chimney is equipped with a device for converting thermal energy into electrical energy, containing nodes connecting two dissimilar electrically conductive materials. This construction of the heating system allows you to expand its functionality by obtaining

electricity and improve consumer properties by increasing the efficiency of the heating system and improving its environmental parameters, which is obtained due to lower temperatures of the flue gases emitted into the atmosphere.

The essence of the utility model is illustrated by specific, but not limiting the claimed device, examples of specific performance and the accompanying drawings, on which:

- figure 1 shows a cross-section of an embodiment of a structural embodiment of a heat supply source along a longitudinal axis;

- figure 2 shows a cross section shown in figure 1 of the embodiment of the heat source along the transverse axis;

- figure 3 shows a section along the longitudinal axis of a variant of the structural embodiment of the trap of condensed water;

- figure 4 shows a cross-section along the longitudinal axis of a possible embodiment of a trap of condensed water;

Fig. 5 is a drawing explaining an embodiment of using a device comprising nodes connecting two dissimilar electrically conductive materials in a heat supply source;

- figure 6 shows the functional diagram of the connection of electric energy sources in the case of using direct current generators.

The heating energy supply source contains (Fig. 1) a furnace 1 for burning chemical fuel, chemical fuel enters the furnace 1 along line 2, the entrance to which is indicated by an arrow with the number 3. An oxidizing agent (most often air oxygen) enters the combustion region through openings 4 in plate 5 disk form. A furnace 1 for burning chemical fuel is placed inside a chimney containing coaxially arranged inner pipe 6 and outer pipe 7. As a furnace 1 for burning chemical fuel, a low-temperature furnace for burning chemical fuel can be used.

Coaxially located inner tube 6 and outer tube 7 are interconnected on one side by a disk-shaped plate 5, and with

the other side are connected by a ring-shaped plate 8, the space between the inner pipe 6 and the outer pipe 7 is divided (FIG. 2) into the first 9 and second 10 cavities by two longitudinal partitions 11 and 12, the first longitudinal partition 11 having openings 13, and the second longitudinal partition 12 is provided with holes 14. A device for removing heat comprises a first cavity 9, a second cavity 10, a first longitudinal partition 11, a second longitudinal partition 12, an inner pipe 6, and heat transfer tubes 15 that are provided with the inner pipe 6. Heat transfer ennye tubes 15 connect the first chamber 9 with the second cavity 10, moreover, these cavities are connected to openings 13 and 14 in the longitudinal partition walls 11 and 12, respectively. The inlet pipe for the coolant in the device for removing heat is indicated in figure 1 by the number 16, and the arrow indicating the direction of entry of the coolant is indicated by the number 17. The outlet pipe for the coolant is indicated in the figure 1 by number 18, and the arrow indicating the direction of the coolant exit is indicated by 19 .

The source of heat and energy works as follows (figure 1). In the furnace 1 for the combustion of chemical raw materials, a reaction occurs between the fuel (for example, natural gas) and the oxidizing agent (for example, oxygen in the air), as a result of which the waste of this reaction (flue gases) leaves the furnace 1 and goes up inside the inner pipe 6 The heated flue gases from the furnace 1 for burning chemical fuel pass through the heat exchange tubes 15 of the device for removing heat and heats them. The coolant coming through the inlet pipe 16 in the direction of the arrow 17 first enters the first cavity 9 and is heated there by contact with the inner pipe 6, which is heated by flue gases. After that, the heat carrier passes through the heat exchange tubes 15, in which the heat carrier is also heated by heating the heat exchange tubes 15 with flue gases. Next, the coolant enters the second cavity 10, in which the heating medium is further heated due to the heated inner pipe 6. The heating medium can also get from the first cavity 9 into the second cavity 10 through openings 13 and 14, which are equipped with the first and second longitudinal partitions 11 and 12, respectively (figure 2).

The location of the furnace 1 for burning chemical fuel inside the chimney (Fig. 1) increases the efficiency of the heat supply source by increasing the efficiency of the use of thermal energy and reduces the overall dimensions, resulting in improved consumer properties. The use of two coaxially located inner pipe 6 and outer pipe 7 allows you to heat the coolant even before it enters the heat transfer tubes 15, resulting in increased efficiency, thereby reducing heat loss. This leads to an improvement in environmental parameters and, as a consequence, to an increase in consumer properties. The use of a low-temperature furnace eliminates the decomposition of nitrogen dioxide into atomic nitrogen and the formation of sulfur oxides. This prevents the formation of nitric, nitrous, sulfuric and sulfuric acids in the air and water vapor in flue gases. The absence of the formation of various acids improves environmental parameters, thereby increasing consumer properties.

The second device for removing heat (for example, to obtain hot water for sanitary purposes) contains second heat exchange tubes 20 through which the flue gases pass, shown in Fig. 1 by arrows 21, an inlet pipe 22 and an outlet pipe 23. The direction of entry of the second heat carrier into the second device for heat removal is indicated in figure 1 by an arrow with the number 24, and the direction of exit of the second coolant from the second heat removal device is indicated in figure 1 by 25.

The second device for removing heat is as follows. The second heat carrier (for example, sanitary water) enters through the inlet pipe 22 in the direction of the arrow 24 into a container (not indicated in FIG. 1) equipped with second heat exchange tubes 20 through which heated flue gases formed by the furnace 1 for burning chemical fuel pass. In this case, heat is transferred to the second heat carrier, after which it leaves through the outlet pipe 23 in the direction of the arrow indicated by the number 25. Providing hot water supply increases the efficiency of the system by reducing heat loss, resulting in improved consumer properties.

Inside the inner pipe 6 with the help of brackets 26, a wind electric generator 27 is installed (Fig. 1). The direction of the exit of flue gases from the heat supply source is indicated in figure 1 by arrows 28.

Wind electric generator 27 operates as follows (figure 1). Heated flue gases pass through the inner tube 6, rotate the propeller of the wind electric generator 27, which converts the mechanical energy of rotation of the shaft on which the propeller is mounted, into electrical energy. In this case, the exit velocity of heated flue gases decreases after passing through the wind electric generator 27, as a result of which the temperature of the flue gases decreases, as a result of which thermal pollution of the environment decreases, which leads to improved environmental parameters and, as a result, to increased consumer properties. The receipt of electrical energy expands the functionality and improves the consumer properties of the claimed device.

The lateral outer surfaces of the chemical fuel combustion chamber 1 may be provided with heating surfaces of a third heat removal device. In figure 1, the heating surfaces of the third device for removing heat are indicated by the number 29 and depicted in the form of a coil. The coolant of the third heat removal device passing through the heating surfaces 29 cools the side surfaces of the furnace 1 for burning fuel, which reduces the consumption of materials for refractory shotcrete of the furnace 1 for burning chemical fuel, which increases the consumer properties of the heat supply source.

The inventive power source can be equipped with a device located in the upper part of the chimney for condensing water vapor from flue gases. A device for condensing water vapor may contain a heating surface of the fourth device for removing heat and a trap of condensed water (figure 1). In this case, heat exchange tubes 30 can be used, into which a cooled coolant enters through the inlet 31. The direction of the entrance of the cooled coolant into the heat exchange tubes 30 is shown by arrow 32.

After taking heat from the flue gases, the coolant from the tubes 30 exits through the outlet pipe 33. The direction of exit of the coolant from the outlet pipe 33 is shown by arrow 34. Then, the coolant is cooled and flows through the pump into the inlet pipe 31. Water condensed on the heat exchange tubes 30 enters the trap 35 condensed water. From trap 35, condensed water enters the storage tank. The direction of exit of the condensed water is shown in figure 1 by arrow 36.

A possible embodiment of the condensed water trap is shown in FIG. 3. It contains plates 37 of an elliptical shape with a cut edge (in Fig. 3, the cut edge of each plate 37 of an elliptical shape is marked with the letter "C"), and in each plate 37 of an elliptical shape with a cut edge "C", the longitudinal dimension A _{1 of the} plate 37 of an elliptical shape with cut edge "C" is selected from the ratio:

A ₁ > A ₂ ,

where A ₂ is the semi-major axis of the ellipse, made in the form of an ellipse, the edge of the plate 37 is attached obliquely to the inner part of the inner pipe 6, the edge of the plate 37 of an elliptical shape with a cut edge "C" located above the opposite edge of the plate of an elliptical shape, and the lower part of each cavity, formed by the plate 37 of an elliptical shape with a cut edge "C" and the adjacent inner portion of the inner pipe 6 is provided with a drain pipe 38. The described trap of condensed water works as follows. Flue gases passing between the elliptical plates 37 with the cut-off edge “C” reduce their speed and cool to a temperature below the dew point, as a result of which water vapor condenses on the upper and lower parts of the elliptical plates 37 with the cut-off edge “C” . The condensate formed on the upper part of the elliptical plate 37 with the cut-off edge “C” drains through the drain pipe 38 first into the storage tank located in the upper part of the chimney. Next, the water from the storage tank is directed to the converter of kinetic energy of water into electrical energy (the second generator

electrical energy). The condensate formed on the lower part of the elliptical plate 37 with the cut-off edge “C” flows down the inner part of the inner pipe 6 into the drainage tube 38 to the storage tank, and from there to the second electric energy generator. A device for condensing water can reduce the temperature and speed of flue gases, as well as reduce the water content in the waste emitted into the atmosphere, resulting in improved environmental parameters and, as a result, improved consumer properties. The production of electrical energy improves consumer properties due to the increase in efficiency of the claimed device. In addition, the production of electricity expands the functionality of the claimed device.

The second possible embodiment of the condensed water trap is shown in FIG. 4. This embodiment comprises a plate 39 made in the shape of a cone facing upward, under a plate 39 made in the shape of a cone, a plate 40 made in the form of a truncated cone facing upward with its small opening is placed coaxially with the gap, the outer diameter of the plate 40 made in the form of a truncated cone is equal to the inner diameter of the inner pipe 6, and the cavity formed by the plate made in the form of a truncated cone 40 and the inner part of the inner pipe 6 adjacent to it is provided with a drainage tube 41.

The described version of the condensed water trap operates as follows. Condensed water from the heat exchange tubes 30 enters the upper plate 39, made in the form of a cone, facing its top up. After this, condensed water falls on the upper surface of the plate 40, made in the form of a truncated cone, facing upward with its small hole. Then, condensed water through the drainage tube 41 enters the storage tank. From the storage tank, condensed water enters the kinetic energy converter of the water into electrical energy (into the second electric energy generator).

A device for condensing water from flue gases can reduce the temperature and speed of flue gases, as well as reduce the content

water in them, resulting in improved environmental parameters and, as a result, improved consumer properties. Reducing the speed and temperature of the flue gas can increase the efficiency of the heat source. The production of electrical energy improves consumer properties due to the increase in efficiency of the claimed device. In addition, the production of electricity expands the functionality of the claimed device.

The surface of the chimney can be equipped with a device for converting thermal energy into electrical energy, containing nodes connecting two dissimilar electrically conductive materials 42 and 43 (figure 5). These nodes of the connection of two dissimilar electrically conductive materials are connected to the load by wires 44. Due to the temperature difference (on the chimney and on the load) of the nodes of the connection of two dissimilar electrically conductive materials 42 and 43 and the nodes of the connection of wires 44 with the load, a thermal electromotive force occurs (Seebeck effect) , which increases the efficiency of the claimed device and improves its environmental parameters by reducing heat loss, resulting in improved consumer properties. In addition, the production of electricity expands the functionality of the claimed device.

An embodiment of the electrical circuit for connecting electric power sources in the inventive device is shown in FIG. 6, where the following designations are adopted: 45 — a wind electric DC generator, 46 — a second electric DC generator (driven by condensed water), 47 — a DC thermal generator . A wind electric direct current generator 45, a second electric direct current generator 46 (driven by condensed water), and a direct current heat generator 47 are connected in series and connected to a generator 48 generating an alternating current frequency of 50 Hz. The output of the generator 48 is connected to the input of the transformer 49, the output of which is formed by an alternating current with a frequency of 50 Hz and a voltage of 220 watts.

INFORMATION SOURCES

1. The method of heat supply. Auth. testimonial. USSR No. 1812393, prior. from 19.03.90, application No. 4803071/06, publ. 04/30/93 Bul. No. 16, IPC 5 F 24 D 3/08.

2. The heating system of the room. Auth. testimonial. USSR No. 1688052, prior. from 08.22.86, application No. 4108248/06, publ. 10.30.91 Bull. No. 40, IPC 5 F 24 D 5/00.

3. Elliot L. and Wilcox W. Physics. / Per. from English Ed. Prof. A.I.Kitaygorodsky, ed. the second one. - M.: Nauka, Main Edition of Physics and Mathematics. 1967. P.328, Fig. 25.9.

Claims (12)

1. A heat supply source comprising a furnace for burning chemical fuel, a device for removing heat and a chimney, characterized in that the furnace for burning chemical fuel and a heating surface of the device for removing heat are located inside the chimney. 2. The heat supply source according to claim 1, characterized in that the chimney contains a device for condensing water vapor from flue gases. 3. The heat supply source according to claim 1, characterized in that the chimney contains coaxially arranged inner pipe and outer pipe, which are connected from below by a disk-shaped plate, from the upper side are connected by a ring-shaped plate, the space between the inner pipe and the outer pipe is divided into the first and the second cavity with two longitudinal partitions provided with holes, the first cavity is connected to the second cavity by the heating surfaces of the heat removal device. 4. The heat supply source according to claim 1, characterized in that a low-temperature firebox for burning chemical fuel is used as a furnace for burning chemical fuel. 5. The heat supply source according to claim 1, characterized in that between the heating furnace for burning chemical fuel and the heating surfaces of the heat removal system are located the heating surfaces of the second heat removal device. 6. The heat supply source according to claim 1, characterized in that the lateral outer surface of the furnace for burning chemical fuel is provided with heating surfaces of a third heat removal device. 7. The heat supply source according to claim 1, characterized in that a wind electric generator is located inside the chimney. 8. The heat supply source according to claim 2, characterized in that the device for condensing water vapor from flue gases contains a heating surface of the fourth device for removing heat and a trap of condensed water. 9. The heat supply source according to claim 8, characterized in that the condensed water trap located inside the chimney contains elliptical plates with a cut edge, and in each elliptical plate with a cut edge, the longitudinal dimension A _{1 of} the elliptical plate with a cut edge is selected from the ratio: A ₁ > A ₂ , where A ₂ is the semi-major axis of the ellipse, made in the form of an ellipse, the edge of the plate is attached obliquely to the inner part of the inner pipe, the edge of the plate of an elliptical shape with a cut edge located above the opposite edge of the plate of an elliptical shape, and the lower part of each cavity formed by an elliptical plate with a cut edge and adjacent to the inner portion of the chimney, equipped with a drainage pipe. 10. The source of heat energy supply according to claim 8, characterized in that the trap of condensed water is made in the form of a cone located with its top up, under which a truncated cone is located, coaxial to it with a gap, located with its small hole up, while the outer diameter of the truncated cone is the inner diameter of the chimney, and the cavity formed by the truncated cone and the inner part of the chimney adjacent to it is equipped with a drain pipe. 11. The heat supply source according to any one of paragraphs.9 and 10, characterized in that the drainage tubes are connected to a generator that converts the kinetic energy of condensed water vapor into electrical energy. 12. The heat supply source according to claim 1, characterized in that the surface of the chimney is equipped with a device for converting thermal energy into electrical energy, containing nodes connecting two dissimilar electrically conductive materials.