RU2794921C2 - Operation method of condensing gas boiler - Google Patents

Abstract

FIELD: thermal power engineering.

SUBSTANCE: invention can be used in condensing gas boilers adapted for heating water. The invention consists in a method for operating a condensing gas boiler, which includes supplying water to a condensing heat exchange device and to the main heat exchange device, ensuring the movement of gaseous combustion products of combustible gas from bottom to top in the main heat exchange device and from top to bottom in the condensing heat exchange device. Water heating in the main heat exchange device is carried out by the thermal energy of the gaseous products of combustion of the combustible gas, and in the condensing heat exchange device - by the thermal energy of the gaseous products of combustion of the combustible gas and the thermal energy that is released during the condensation of water vapor. Combustion of the combustible gas is carried out under the bell-shaped part of the condensing gas boiler, above the lower edge of the bell-shaped part, and the air necessary for combustion of combustible gas is supplied through at least two air holes, which are located in the bell-shaped part at different distances from the lower edge of the bell-shaped part, at the same time, natural movement of gaseous products of combustion is ensured from bottom to top in the main heat exchange device and from top to bottom in the condensing heat exchange device through the heat exchange parts of the condensing heat exchange device by setting the height of the column of gaseous combustion products of the combustible gas and the average temperature in the column of gaseous combustion products.

EFFECT: increase in reliability and safety of the condensing gas boiler.

4 cl, 12 dwg

Description

The invention relates to thermal power engineering and can be used in the manufacture of condensing gas boilers adapted for heating water.

A method of operation of a condensing hot water boiler is known, which includes supplying water to the heat exchangers of a condensing hot water boiler, one of which is located coaxially to an inflatable gas burner, supplying combustible gas and air to an inflatable gas burner, a condensing hot water boiler, burning combustible gas in a specified volume of a condensing hot water boiler boiler adapted for combustion of combustible gas, obtaining heated gaseous products of combustion of combustible gas, heating water in heat exchange devices of a gas condensing boiler, thermal energy of gaseous products of combustion of combustible gas, and thermal energy that is released during the condensation of water vapor, after which, removal of gaseous products combustion of combustible gas from a condensing hot water boiler [1].

The disadvantages of this method is that it does not provide high reliability of the condensing boiler, and does not provide high safety of the condensing boiler.

The inflatable gas burner has a certain probability of failure. In addition, it is difficult to operate and requires the involvement of highly qualified specialists for its adjustment. Emergency shutdown systems for an inflatable gas burner also have a certain probability of failure. Therefore, there is a certain probability that combustible gas will enter the heated room.

A known method of operation of a gas wall-mounted boiler, which includes the supply of water to the heat exchange device of a gas wall-mounted boiler, the supply of combustible gas to gas burners, a gas wall-mounted boiler, the supply of air to a specified volume of a gas wall-mounted boiler, which is adapted for burning combustible gas, burning combustible gas in a set the volume of a gas wall-mounted boiler adapted for burning combustible gas, obtaining heated gaseous products of combustion of combustible gas, ensuring the movement of gaseous products of combustion of combustible gas, from bottom to top, in the heat exchange device of a gas wall-mounted boiler, heating water in a heat exchange device of a gas wall-mounted boiler, thermal energy of gaseous products combustion of combustible gas, after which, the removal of gaseous products of combustion of combustible gas from a gas wall-mounted boiler [2].

This method ensures high reliability of the gas wall-mounted boiler, and ensures high safety of the gas wall-mounted boiler, because in the event of a failure of the gas burners, and in the event of a failure of the emergency shutdown systems for gas burners, combustible gas will escape into the environment through the chimney and air openings, in a natural way, since the density of the combustible gas used in household heating devices is less than the density of air. But in this method, water vapor is not condensed, which is in the gaseous combustion products of combustible gas, and the thermal energy that is released during the condensation of water vapor is not used to heat water.

The closest is a method of operating a condensing gas boiler, which includes supplying water to the condensing heat exchanger of the condensing gas boiler, and to the main heat exchanger of the condensing gas boiler, supplying combustible gas to at least one gas burner of the condensing gas boiler, supplying air to, at least one gas burner of the condensing gas boiler, combustion of combustible gas, using at least one gas burner of the condensing gas boiler, obtaining heated combustion gases of combustible gas, ensuring the movement of combustion gases of combustible gas, from bottom to top, mainly the heat exchanger of the condensing gas boiler, and from top to bottom, in the condensing heat exchanger of the condensing gas boiler, heating water in the main heat exchanger of the condensing gas boiler by the heat energy of the gaseous combustion products of combustible gas, and heating the water in the condensing heat exchanger of the condensing gas boiler by the heat of the gaseous products of combustion of combustible gas, and thermal energy that is released during the condensation of water vapor, after which, the removal of gaseous products of combustion of combustible gas from the condensing gas boiler through the chimney, as well as the removal of condensate from the condensing gas boiler [3].

The disadvantages of this method is also that it does not provide high reliability of the condensing gas boiler, and does not provide high safety of the condensing gas boiler.

The removal of the combustion gases of the combustible gas from the condensing gas boiler is carried out here by means of a fan, which has a certain probability of failure. This condensing gas boiler uses conventional tubular atmospheric burners. They are reliable in operation, but they also have a certain probability of failure. If any device from the gas supply system of the condensing gas boiler fails, or if any device from the system for removing gaseous products of combustion of combustible gas from the condensing gas boiler fails, combustible gas may enter the heated room. Therefore, the specified hot water boiler can only be used when it is outdoors.

The invention is based on the task, by improving the method of operation of a condensing gas boiler, to increase the reliability of the operation of a condensing gas boiler, and also to increase the safety of operation of a condensing gas boiler, and at the same time, additionally, to increase the average heat energy flux density of gaseous products of combustion of combustible gas, and thermal energy , which is released during the condensation of water vapor into water, through the surface of each of the heat exchange parts of the condensing heat exchange device of the condensing gas boiler, which is in contact with water and / or, in addition, fully ensure the energy independence of the condensing gas boiler.

1. The problem is solved by the fact that in the method of operation of a condensing gas boiler, which includes supplying water to the condensing heat exchanger of the condensing gas boiler, and to the main heat exchanger of the condensing gas boiler, supplying combustible gas to at least one gas burner of the condensing gas boiler boiler, supplying air to at least one gas burner of the condensing gas boiler, burning combustible gas using at least one gas burner of the condensing gas boiler, obtaining heated gaseous products of combustion of combustible gas, ensuring the movement of gaseous products of combustion of fuel gas, from bottom to top, in the main heat exchanger of the condensing gas boiler, and from top to bottom, in the condensing heat exchanger of the condensing gas boiler, heating water in the main heat exchanger of the condensing gas boiler, the heat energy of the combustion gases of the combustible gas, and heating the water in the condensing heat exchanger condensing gas boiler, the thermal energy of the gaseous products of combustion of combustible gas, and the thermal energy that is released during the condensation of water vapor, after which, the removal of gaseous products of combustion of combustible gas from the condensing gas boiler through the chimney, as well as the removal of condensate from the condensing gas boiler , what is new is that combustion of combustible gas is carried out under the hood of the condensing gas boiler, above the lower edge of the bell of the condensing gas boiler, with the help of at least one gas burner of the condensing gas boiler, and the air necessary for burning the combustible gas, is fed through at least two air holes, which are located in the bell-shaped part of the condensing gas boiler, at different distances from the lower edge of the bell-shaped part of the condensing gas boiler, and the movement of gaseous products of combustion of combustible gas, in the main heat exchange device of the condensing gas boiler, is provided from below upward, in a natural way, and the movement of gaseous products of combustion of combustible gas, in the condensing heat exchanger of the condensing gas boiler, is provided from top to bottom, in a natural way, through the heat exchange parts of the condensing heat exchanger of the condensing gas boiler, while the height of the column of gaseous products of combustion of combustible gas moving from bottom to top, in a condensing gas boiler, and the average temperature in the column of gaseous products of combustion of combustible gas moving from bottom to top, in a condensing gas boiler, is set so as to ensure the natural movement of gaseous products of combustion of combustible gas, in a condensing heat exchanger device of a condensing gas boiler, from above down, and ensure the natural movement of the combustion gases of the combustible gas, while removing the combustion gases of the combustible gas, from the condensing gas boiler, through the chimney.

2. New according to claim 1 is that they increase the average density of the thermal energy flux of gaseous products of combustion of combustible gas, and the thermal energy that is released during the condensation of water vapor into water through the outer surface of each of the heat exchange parts of the condensing heat exchange device of the condensing gas of the boiler, which is in contact with water, using internal metal fins of the same or different heights, of each of the heat exchange parts of the condensing heat exchanger of the condensing gas boiler in contact with the combustion gases of the combustible gas, and with water vapor that moves through each of the heat exchange parts of the condensing heat exchanger condensing gas boiler, from top to bottom, naturally.

3. New according to claim 1 is that the output of gaseous products of combustion of combustible gas is provided from the main heat exchange device of a condensing gas boiler through at least one outlet channel, with the highest average speed of movement of gaseous products of combustion of combustible gas, relative to the average speeds of movement of gaseous products of combustion of combustible gas, through other parts of the condensing gas boiler, to the outlet of the condensing gas boiler, through the chimney.

4. New according to claim 1 is that they provide complete energy independence of the condensing gas boiler by heating water, in the main heat exchange device of the condensing gas boiler to the boiling point, with the thermal energy of the gaseous products of combustion of the combustible gas, after which they provide boiling water, in the main heat exchange device condensing gas boiler, also using the thermal energy of gaseous products of combustion of combustible gas, while ensuring the formation of water vapor bubbles near the surface of the main heat exchange device, which is in contact with water, and through which the thermal energy of gaseous products of combustion of combustible gas is transferred to water, ensures the movement of bubbles of water steam, which are separated from the surface of the main heat exchange device that is in contact with water, and through which the thermal energy of the gaseous products of combustion of combustible gas is transferred to water, in the vertical direction, to the upper surface of the main heat exchange device of the condensing gas boiler that is in contact with water, and using the upper the surface of the main heat exchange device of the condensing gas boiler, ensure the movement of water vapor bubbles into the storage steam tank, the main heat exchange device of the condensing gas boiler, where water vapor is accumulated in the storage steam tank, the main heat exchange device of the condensing gas boiler, and create water vapor pressure, and using water vapor pressure, as well as the buoyancy force that acts on water vapor in water, transport hot water and steam from the main heat exchanger of the condensing gas boiler, through the transport device, first from bottom to top, and then from top to bottom, into the heating system, at This ensures that water enters the main heat exchanger of the condensing gas boiler from the condensing heat exchanger of the condensing gas boiler through a check valve.

In FIG. 1 is a schematic vertical sectional view of a condensing gas boiler in which pumping water through the condensing heat exchanger of the condensing gas boiler and further pumping water through the main heat exchanger of the condensing gas boiler is carried out by an electrically powered pump. Light solid arrows indicate the direction of movement of gaseous combustion products of combustible gas in the main heat exchanger of a condensing gas boiler. Dark solid arrows indicate the direction of water flow into the condensing gas boiler, and from the condensing gas boiler. The letter Q indicates the support surface on which the condensing gas boiler is installed. The letter H indicates the height of the column of gaseous products of combustion of combustible gas moving from bottom to top in a condensing gas boiler. The letter L indicates the height of the heat exchange tubes in the main heat exchanger of the condensing gas boiler. The letter Z indicates the height of the condensing heat exchanger of the condensing gas boiler.

In FIG. 2 shows the section A-A shown in FIG. 1. Dark solid arrows indicate the direction of water flow into the condensing gas boiler, and from the condensing gas boiler.

In FIG. 3 shows part of a vertical section through the gas condensing boiler shown in FIG. 1. The letter P indicates the distance between the disk parts of the turbulator, which is located in the heat exchange tube of the main heat exchange device of the condensing gas boiler. The letter XI indicates the height of the outlet chamber of the main heat exchanger of the condensing gas boiler. The letter X2 indicates the height of the inlet chamber of the condensing heat exchanger of the condensing gas boiler.

In FIG. 4 shows part of the section A-A, which is shown in Fig. 2. The letter F indicates the thickness of the inner metal fin of greater height, heat exchange part of the condensing heat exchanger, condensing gas boiler. The letter K indicates the distance between adjacent inner metal ribs of greater height of the heat exchange part of the condensing heat exchange device, between which there is a rib of lower height, of the heat exchange part of the condensing heat exchange device. The letter S indicates the distance between, located opposite each other, internal metal ribs of greater height, the heat exchange part of the condensing heat exchanger, the condensing gas boiler. The letter M indicates the height of the inner metal fin of greater height, the heat exchange part of the condensing heat exchanger, the condensing gas boiler. The letter N indicates the height of the inner metal rib of a smaller height, the heat exchange part of the condensing heat exchanger, the condensing gas boiler. Dark solid arrows indicate the direction of water movement.

In FIG. 5 shows the section B-B shown in FIG. 2. A light solid arrow indicates the direction of movement of gaseous products of combustion of combustible gas through the chimney of a condensing gas boiler. The letter X3 indicates the height of the outlet chamber of the condensing heat exchanger of the condensing gas boiler.

In FIG. 6 shows the section C-C shown in FIG. 2. The letter Y1 indicates the upper part of the inlet air pipe. The letter Y2 indicates the lower part of the inlet air pipe.

In FIG. 7 is a schematic vertical sectional view of a condensing gas boiler, in which pumping water through the condensing heat exchanger of the condensing gas boiler, and further pumping water through the main heat exchanger of the condensing gas boiler, is carried out by means of an electrically powered pump, and in which the combustion gases are vented of combustible gas, from the main heat exchanger of the condensing gas boiler, through at least one outlet channel, with the highest average velocity of the gaseous products of combustion of the combustible gas, relative to the average velocities of the gaseous products of combustion of the combustible gas, through other parts of the condensing gas boiler, to outlet of the condensing gas boiler, through the chimney. Light solid arrows indicate the direction of movement of gaseous combustion products of combustible gas in the main heat exchanger of a condensing gas boiler. Dark solid arrows indicate the direction of water flow into the condensing gas boiler, and from the condensing gas boiler. The letter Q indicates the support surface on which the condensing gas boiler is installed.

In FIG. 8 is a schematic vertical sectional view of a non-volatile condensing gas boiler. Light solid arrows indicate the direction of movement of gaseous combustion products of combustible gas in the main heat exchanger of a condensing gas boiler. Dark solid arrows indicate the direction of water circulation, near the heating pipes of the hot water supply system. The letter Q indicates the support surface on which the condensing gas boiler is installed.

In FIG. 9 shows the section D-D shown in FIG. 8.

In FIG. 10 shows the section E-E shown in FIG. 8. The letter Q indicates the support surface on which the condensing gas boiler is installed.

In FIG. 11 schematically shows a vertical section of a non-volatile condensing gas boiler, in which the gaseous products of combustion of combustible gas are provided from the main heat exchange device of the condensing gas boiler through at least one outlet channel, with the highest average speed of movement of gaseous products of combustion of combustible gas, relative to the average speeds of movement of gaseous products of combustion of combustible gas, through other parts of the condensing gas boiler, to the outlet of the condensing gas boiler, through the chimney. Light solid arrows indicate the direction of movement of gaseous combustion products of combustible gas in the main heat exchanger of a condensing gas boiler. Dark solid arrows indicate the direction of water circulation, near the heating pipes of the hot water supply system. The letter Q indicates the support surface on which the condensing gas boiler is installed.

In FIG. 12 schematically shows a heating system with a non-volatile condensing gas boiler.

The method is carried out as follows. Water is supplied to the condensing heat exchanger of the condensing gas boiler 1 from the heating system through the inlet pipeline 2, which contains the connecting assembly of the inlet pipeline 3. After that, water is supplied to the main heat exchanger of the condensing gas boiler 4, through the outlet pipe of the condensing heat exchanger 5, and along the inlet pipe of the main heat exchange device 6. The outlet pipe 5 and the inlet pipe 6 are connected to each other by means of a flange connection 7 (Fig. 1-4). The flange connection 7 may comprise a rubber gasket made of conventional rubber. From the main heat exchange device 4, water is supplied to the heating system through the outlet pipeline 8, which contains the outlet pipeline connection 9. The water supply to the heat exchange devices 1 and 4 is carried out using a pump, with electric power supply 10. In Fig. 1, 2, 4, the directions of water movement are indicated by dark solid arrows.

To heat water in heat exchange devices 1 and 4, combustible gas (natural gas) is supplied to at least one gas burner of the condensing gas boiler 11. The number of gas burners And depends on the power of the condensing gas boiler itself, and on the power of each of gas burners 11. FIG. 1, 7, 8, 11, a condensing gas boiler is shown, in which two cylindrical atmospheric gas burners with a power of 7 kW each are installed. It is advisable to use cylindrical atmospheric gas burners. They are simple in design and reliable in operation. The gas supply to the burner, or burner 11, is carried out through a gas pipeline (not shown in the figure).

To burn combustible gas, air is supplied to the burners 11. Air is supplied to the burners 11 through an inlet air pipe 12 containing a horizontal partition 13. The horizontal partition 13 divides the air pipe into two parts, the upper part, which is indicated by the letter Y1, and the lower part , which is denoted by the letter Y2 (Fig. 6).

From the bottom of the inlet air pipe Y2, air is supplied to the lower air inlet pipe of the inlet pipe 14, and from the upper part of the inlet air pipe Y1, the air is supplied to the upper air inlet pipe of the inlet pipe 15, with stable operation of the condensing gas boiler.

From pipe 14, air is supplied through the lower additional air pipe 16. From pipe 15, air is supplied through the upper additional air pipe 17. Branch pipes 14 and 16 are interconnected by means of a flange connection 18. Branch pipes 15 and 17 are interconnected by means of a flange connection 19 ( Fig. 1, 2, 6, 7, 8, 9, 10, 11). Flange connections 18 and 19 may contain rubber gaskets made from conventional rubber.

From additional nozzles 16 and 17, air is supplied to the burners 11, through the lower air hole of the bell piece 20, and through the upper air hole of the bell piece 21. (In Fig. 1, 7, 8, 11, hole 21 is indicated by dotted lines.) Lower additional air pipe 16 is connected to the bell part of the condensing gas boiler 22, using a flange connection 23. The upper additional air pipe 17 is connected to the bell part of the condensing gas boiler 22, using a flange connection 24 (Fig. 10). Flange connections 23 and 24 may contain rubber gaskets made of conventional rubber.

The air holes 20 and 21 are located in the hood of the condensing gas boiler 22, at different distances from the bottom edge of the bell of the condensing gas boiler.

Combustion of combustible gas by means of at least one gas burner 11 is carried out under the bell piece of the condensing gas boiler 22, above the lower edge of the bell piece of the condensing gas boiler.

Combustion of combustible gas produces heated combustion gases of combustible gas, which mainly include carbon dioxide (CO2), water vapor (H2O), and free nitrogen N2. The temperature of the gaseous combustion products of the combustible gas at the gas burner 11 can reach 1200°C.

The thermal energy of the gaseous combustion products of the combustible gas heats the water in the main heat exchanger of the condensing gas boiler 4, and in the condensing heat exchanger of the condensing gas boiler 1. In the condensing heat exchanger of the condensing gas boiler 1, the water is also heated by the thermal energy that is released during the condensation of water vapor , which is formed during the combustion of combustible (natural) gas, and is in the flow of gaseous combustion products of combustible gas.

To this end, the combustion gases of the combustible gas are provided with movement, from bottom to top, in the main heat exchanger of the condensing gas boiler. In FIG. 1, 7, 8, 11, the direction of movement of the gaseous products of combustion of the combustible gas, in the main heat exchange device of the condensing gas boiler 4, is indicated by light solid arrows.

Further, the movement of gaseous products of combustion of combustible gas from the main heat exchange device 4 is provided through the outlet chamber of the main heat exchange device of the condensing gas boiler 25, the transition gas tube 26, and the inlet chamber of the condensing heat exchange device of the condensing gas boiler 27, to the condensing heat exchange device of the condensing gas boiler 1.

The transition gas pipe 26 is connected by metal welding to the cover of the outlet chamber of the main heat exchanger of the condensing gas boiler 28, and is connected by metal welding to the cover of the inlet of the condensing heat exchanger of the condensing gas boiler 29. The cover 28 is connected to the main heat exchanger of the condensing gas boiler. boiler 4 using a flange connection 30. Cover 29 is connected to the condensing heat exchanger of the condensing gas boiler 1, using a flange connection 31 (Fig. 3, 9).

In the condensing heat exchanger of the condensing gas boiler 4, the movement of gaseous products of combustion of combustible gas, from top to bottom, into the outlet chamber of the condensing heat exchanger of the condensing gas boiler 32 (FIG. 5) is ensured.

Further, the movement of gaseous combustion products of combustible gas from the outlet chamber of the condensing heat exchanger of the condensing gas boiler 32 is provided to the outlet gas tube 33. The outlet gas tube 33 is also supplied with condensate (condensed moisture) from the condensing heat exchanger 4. The outlet gas tube 33 must be made of stainless steel. The condensate is removed from the gas outlet pipe through the condensate pipe 34, which is connected to the pipe 33 by metal welding, and through the condensate hose 35, which can be made of acid-resistant rubber, and which is connected to the pipe 34 (Fig. 5). Pipe 34 must be made of stainless steel.

The tube 33 is bent downwards, in order to better accumulate in it, and remove condensate from it.

The tube 33 is connected to the cover of the outlet chamber of the condensing heat exchanger of the condensing gas boiler 36 by metal welding. And the cover 36 is connected to the condensing heat exchanger of the condensing gas boiler 1 by a flange connection 37. The cover 36 must be made of stainless steel. Flange connection 37 is similar to flange connections 30 and 31 (FIGS. 4, 5). Flange connections 30, 31, and 37 may contain graphite flange gaskets (PFG).

The outlet chamber of the main heat exchanger of the condensing gas boiler 25 may have a height X1 ranging from 20 mm to 50 mm. Height X1, more than 50 mm, is not appropriate, since this will unreasonably increase the material consumption of the main heat exchange device 4. Height X1, less than 20 mm is also not appropriate, since this will significantly increase the aerodynamic resistance to the flow of gaseous combustion products of combustible gas. Similarly, the inlet chamber of the condensing heat exchanger of the condensing gas boiler 27 may have a height X2 ranging from 20 mm to 50 mm. and the outlet chamber of the condensing heat exchanger of the condensing gas boiler 32 may have a height X3 ranging from 20 mm to 50 mm (FIGS. 3, 5). Increasing the height X2 and X3, more than 50 mm, is not advisable, since it is unreasonable to increase the material consumption of the condensing heat exchange device 1. Reducing the heights X2 and X3, less than 20 mm, is also inappropriate, since this will significantly increase the aerodynamic flow resistance to gaseous combustion products of combustible gas.

Further movement of the gaseous products of combustion of combustible gas, from the outlet gas pipe 33, is provided to the connecting pipe of the chimney rough 38, and then to the chimney 39. From the chimney 39, the gaseous products of combustion of the combustible gas are removed to the environment. The branch pipe 38, as well as the chimney 39, must be made of stainless steel. All metal parts of a condensing gas boiler that can somehow come into contact with condensate should be made of stainless steel, since the condensate contains acids that adversely affect the durability of metal parts.

Chimney pipe connection 38, connected to the gas outlet pipe 33, through the hood of the condensing gas boiler 22, using a flange connection 40. Chimney pipe connection 38, also connected to the chimney pipe 39, using an oblique flange connection 41. flange connections 40 and 41 must contain gaskets made of acid-resistant rubber, or graphite flange gaskets (PFG).

An oblique flange connection 41 makes it possible to hermetically connect the outlet gas pipe 33 to the chimney pipe 39, without moving both the condensing gas boiler itself and the chimney pipe 39. a gas boiler. This can be very useful when installing a condensing gas boiler in an apartment building.

The flue pipe 39 is installed in the inlet air pipe 12, and is connected to the inlet air pipe 12 by means of a flange connection 42 (Fig. 2, 5). The chimney 39, and the chimney rough connecting pipe 38, may have a slight angle of inclination towards the outlet gas pipe 33, in order to drain additional condensate into the pipe 33, which may form in the chimney pipe 39, and in the chimney pipe 38 connecting pipe.

The main heat exchanger of the condensing gas boiler 4, and the condensing heat exchanger of the condensing gas boiler 1, are fixed to the parts of the inner support frame of the condensing gas boiler 43, which are supported by the base plate 44, and are fixedly connected to the base plate 44 by metal welding.

The base plate 44 rests on the parts of the outer support frame of the condensing gas boiler 45, which are also fixedly connected to the base plate 41, by metal welding.

Attached to the base plate 44 is the hood of the condensing gas boiler 22 through a sealing gasket, which may be made of ordinary rubber, and with screws.

Cap part 22 may contain a window made of transparent heat-resistant material for visual observation of the operation of gas burners 11.

All pipelines of the condensing gas boiler passing through the base plate 44 are sealed in the base plate 44 (not shown in FIG.). This will further reduce the likelihood of gas leakage from under the hood 22 into the heated room, in the event of an emergency, or malfunctions in the operation of the condensing gas boiler.

Adjusting screw supports 46 are attached to the details of the outer support frame of the condensing gas boiler 45 by metal welding. eleven).

In the main heat exchange device of the condensing gas boiler 4, the movement of gaseous combustion products of combustible gas is ensured from the bottom up, in a natural way. In the condensing heat exchanger of the condensing gas boiler 1, the gaseous products of combustion of the combustible gas are also allowed to flow from top to bottom in a natural way through the heat exchange parts of the condensing heat exchanger of the condensing gas boiler 47.

To do this, set the height of the column of gaseous products of combustion of combustible gas, moving from bottom to top, in a condensing gas boiler, and for this, set the average temperature in the column of gaseous products of combustion of combustible gas, moving from bottom to top, in a condensing gas boiler, such as to ensure the natural movement of gaseous combustion products of combustible gas, in the condensing heat exchanger of the condensing gas boiler 1, from top to bottom, and ensure the natural movement of the combustion gases of the combustible gas, from the condensing gas boiler, through the chimney 39, while removing the combustion gases of the combustible gas.

Transportation of the combustion gases of the combustible gas in the condensing gas boiler is carried out using a buoyant force that acts on the column of hot combustion gases of the combustible gas, and which is directed upwards.

In FIG. 1, the height of the column of gaseous products of combustion of combustible gas moving from bottom to top, in a condensing gas boiler, from at least one gas burner 11, to the highest point of the inner surface of the transition gas tube, is indicated by the letter H. This height H can be approximately 1000- 1100 mm, at an average temperature of gases in the column 600-700 ° C, for a condensing gas boiler with a power of about 15 kW. The main heat exchange device 4 is made of steel by metal welding.

A similar method of transporting gases is used in a device called the "siphon" by the Siemens brothers [4].

But what is new here, first of all, is that the method of transporting gases indicated in the source of information [4] is used in a condensing gas boiler, the method of operation of which is claimed. In addition, in a condensing gas boiler, this method is complicated by the fact that when transporting gaseous products of combustion of combustible gas, thermal energy is taken from the gaseous products of combustion of combustible gas, in the main heat exchange device of the condensing gas boiler 4, and in the condensing heat exchange device of the condensing gas boiler. boiler 1, into the water that is heated. And in the condensing heat exchanger of the condensing gas boiler 1, they also provide condensation of water vapor, which is in the flow of gaseous combustion products of combustible gas, with the selection of its thermal energy into water.

In the main heat exchanger of the condensing gas boiler 4 shown in FIG. 1, the transportation of gaseous combustion products of combustible gas is carried out through the heat exchange tubes of the main heat exchange device of the condensing gas boiler 48, into which turbulators are inserted, each of which contains a metal rod 49, on which metal disks 50 are fixed (Fig. 1, 2, 3, 4 ). It is possible to use turbulators of other designs, but the turbulators indicated in FIG. 1, 2, 3, 4 provide soot accumulation on the metal discs 50, which reduces soot accumulation on the surface of each of the heat exchange tubes 48 that is in contact with the combustion gases of the combustible gas. Soot on the surface of each of the heat exchange tubes 48, which is in contact with the combustion gases of the combustible gas, reduces the heat energy flux into the water of the main heat exchange device of the condensing gas boiler 4. The heat exchange tubes 48 are also steel.

The height of the heat exchange tubes 48, in the main heat exchange device of the condensing gas boiler, in FIG. 1 is denoted by the letter L. This height should be such as to ensure the exit from the main heat exchange device 4 of the combustion gases of the combustible gas at a temperature of about 300°C.

The material from which the condensing heat exchanger of the condensing gas boiler 1 is made is cast iron. The condensing heat exchanger 1, together with the heat exchanger parts of the condensing heat exchanger of the condensing gas boiler 47, is made of cast iron by casting a metal into a mould. The temperature of the gaseous combustion products of the combustible gas, about 300°C, at the outlet of the main heat exchange device 4, is due to the fact that at high temperatures and significant thermal loads on the cast iron parts, cracks in the cast iron parts may occur. In this case, the height L can be from 100 mm to 200 mm. Meanwhile, the height of the condensing heat exchanger of the condensing gas boiler Z may be 400 mm to 500 mm.

The condensing heat exchanger of the condensing gas boiler 1 may have at least one side steel cover 51, which is connected to the condensing heat exchanger 1 by a flange connection 52. The cover 51 is necessary for the internal periodic cleaning of the condensing heat exchanger 1.

Similarly, the main heat exchanger of the condensing gas boiler 4 may have at least one side steel cover 53, which is connected to the main heat exchanger 4 by a flange connection 54. The cover 53 is necessary for the internal periodic cleaning of the main heat exchanger 4 (Fig. 4).

The movement of water in the condensing heat exchanger 1, which is shown in FIG. 1-4 and 7 are provided by the pump 10 from bottom to top, through the bottom hole of the condensing heat exchanger 55, and the top hole of the condensing heat exchanger 56, against the direction of movement of the combustion gases of the combustible gas. The movement of water between the heat exchange parts of the condensing heat exchanger of the condensing gas boiler 47 is provided by baffles 57 (FIG. 4). In FIG. 4, the movement of water in the condensing heat exchanger 1 is indicated by dark solid arrows.

The movement of water in the main heat exchanger 4, which is shown in FIG. 1-4 and 7 are provided by the pump 10 from top to bottom, through the upper opening of the main heat exchanger 58, and the lower opening of the main heat exchanger 59, against the direction of movement of the combustion gases of the combustible gas.

The movement of water in the condensing gas boiler, with the help of pump 10, is opposite, relative to the movement of gaseous products of combustion of combustible gas. This provides the greatest temperature difference between the temperature of the water in the heat exchangers 1 and 4, and the temperature of the combustion gases of the combustible gas. And this, in turn, increases the density of the thermal energy flux into water, through a unit area of the surface of the heat exchange device 1, which is in contact with water, and through a unit area of the surface of the heat exchange device 4, which is in contact with water. And this reduces the material consumption of heat exchange devices 1 and 4, a condensing gas boiler, the method of operation of which is claimed.

When the gas burners 11 are turned on, the hot gaseous combustion products of the combustible gas rise up and fill first the main heat exchanger of the condensing gas boiler 4. At the same time, cold air is forced out of the main heat exchanger 4, as into the chimney 39, through the condensing heat exchanger 1 , and into the upper part of the inlet air pipe, marked with the letter Y1, through the upper air hole of the cap part 2.1. The stable operation of the condensing gas boiler begins after the height of the combustible gas column moving from bottom to top in the condensing gas boiler is established, and after the average temperature is established, in the column of combustible gas products moving from bottom to top in the condensing gas boiler, such to ensure the natural movement of the combustion gases of the combustible gas, in the condensing heat exchange device of the condensing gas boiler 1, from top to bottom, and to ensure the natural movement of the combustion gases of the combustible gas, when removing the combustion gases of the combustible gas, from the condensing gas boiler, through the chimney 39 .

In the event that the combustion gases of the combustible gas cannot move completely or partially through the heat exchange devices 1 and 4 of the condensing gas boiler, into the chimney 39, due to a malfunction of the condensing gas boiler, the gases of combustion of the combustible gas will move up , under the bell piece of the condensing gas boiler 22, and fill the space under the bell piece of the condensing gas boiler 22. And further, the combustion gases of the combustible gas will move to the top of the inlet air pipe, marked Y1, through the top air hole of the bell piece 21. Air the at least one gas burner 11 will, in this case, enter only through the lower air hole of the hood 20, and through the lower part of the inlet air pipe, marked Y2. That is, emergency circulation of gaseous products of combustion of combustible gas and air will take place. This will lead to heating of the emergency switch off the supply of combustible gas 60, in the condensing gas boiler, which is located under the cap part 22, above the heat exchangers 1 and 4 (Fig. 12). And this will lead to the termination of the supply of combustible gas to the condensing gas boiler. The emergency switch off the supply of combustible gas 60 may contain a bimetallic plate made of metals that have different coefficients of thermal expansion. Emergency shutdown of the supply of combustible gas, it is advisable to carry out when the sensor 60 is heated to a temperature of 110-120°C.

In the case when there was a complete attenuation of the combustion of combustible (natural) gas in the condensing gas boiler, and the gas continues to flow into the gas burners 11, then the combustible gas will also move up, under the bell-shaped part of the condensing gas boiler 22, and fill the space under the bell-shaped part of the condensing gas boiler 22. (The combustible (natural) gas has a density lower than that of air.) Then, the combustible gas will move to the top of the inlet air pipe, marked Y1, through the upper air hole of the bell-shaped part 21, and exit into the surrounding environment outside the heated room.

To improve the safety of the condensing gas boiler, you can even use a separate air pipe, instead of the upper part of the inlet air pipe, marked with the letter Y1 (not shown in the figure). A separate air pipe can be directly connected to the top opening 21 via a cap piece 22.

By ensuring the movement of gaseous products of combustion of combustible gas, in a condensing gas boiler, to the outlet of a condensing gas boiler, in a natural way, without using a fan, increase the reliability of the operation of the condensing gas boiler, and increase the safety of the operation of the condensing gas boiler.

By using the condensing gas boiler cap 22, a backup, emergency route for air and gases is created through the inlet air pipe portions Y1 and Y2, and thus further enhances the operation safety of the condensing gas boiler.

In order to further increase the average heat energy flux density of naturally moving combustible gas combustion gases and the heat energy that is released when water vapor is condensed into water, through the surface of each of the heat exchange parts, the condensing heat exchange device, the condensing gas boiler 47 that contacts with water, use internal metal fins of the same or different heights, in each of the heat exchange parts of the condensing heat exchange device of the condensing gas boiler, which are in contact with the gaseous products of combustion of combustible gas, and with water vapor that move through each of the heat exchange parts of the condensing heat exchange device of the condensing gas boiler boiler 47, top to bottom, naturally.

In FIG. 4 shows the heat exchange parts of the condensing heat exchanger of the condensing gas boiler 47, which have internal metal fins of various heights. Between the ribs of greater height 61, there are ribs of lower height 62. Between two ribs of greater height 61, there is one rib of lower height 62 (Fig. 4).

The height of the ribs 61 may be in the range of 10 to 20 mm, and in FIG. 4 is marked with the letter M. This is due to the fact that the height M, less than 10 mm, is impractical, since this will significantly reduce the average density of the thermal energy flux into the water, and the height M more than 20 mm will unnecessarily increase the material consumption of parts 47 and the condensation heat exchange device 1.

The height of the ribs 62 may be in the range of 3 to 5 mm, and in FIG. 4 is denoted by the letter N. This is also due to the fact that the height of the ribs N, less than 3 mm, is impractical, since this will significantly reduce the average density of the thermal energy flux into the water, and the height N, more than 5 mm, will unnecessarily increase the aerodynamic resistance of the flow of gaseous products of combustion of combustible gas, through parts 47, condensing heat exchanger 1.

When using ribs of different heights, it is possible to set the distance between the ribs to 61 K, ranging from 10 to 20 mm. A distance K of less than 10 mm will unnecessarily increase the aerodynamic resistance of the flow of gaseous combustion products of combustible gas. A distance K of more than 20 mm will unreasonably increase the material consumption of parts 47 and the condensing heat exchange device 1. The distance between oppositely located ribs 61, in part 47 in FIG. 4 is denoted by the letter S. This distance provides turbulent mixing of the more heated gaseous products of combustion of the combustible gas, and less heated gaseous products of the combustion of combustible gas (with those that have already given up part of the thermal energy to the water). The distance S should not exceed 5 mm, otherwise it will unnecessarily increase the material consumption of parts 47 and the condensing heat exchanger 1.

The thickness of each of the ribs 61 and 62, F, however, should not exceed 5 mm. Otherwise, it will unnecessarily increase the material consumption of parts 47 and the condensing heat exchanger 1. (In Fig. 4, the letter F denotes the thickness of the fin 61.) The recommended thickness F is not more than 4 mm. This allows the distance between rib 61 and rib 62 to be set to 3 mm.

A distance K of 3 mm, when using ribs of the same height, not less than 10 mm high (ribs 61), will significantly increase the aerodynamic resistance of the flow of gaseous combustion products of combustible gas between the ribs during their natural movement. This will significantly reduce the average density of the thermal energy flux into the water.

Without the use of fins of lower height 62, a distance K of 10 mm between fins 61 will also result in a decrease in the average thermal energy flux density into water, due to a decrease in the surface area in parts 47 that is in contact with the combustion gases of the combustible gas.

Therefore, the use of ribs of different heights in parts 47 can provide the highest density of thermal energy flow into water, during the movement of gaseous combustion products of combustible gas, in a natural way. (Greater density of thermal energy flux into water than when using ribs of the same height.)

In addition, the use of ribs in the heat exchange parts, the condensing heat exchanger, the condensing gas boiler 47 will increase the average flux density of heat energy that is released when water vapor condenses into water. The condensate will accumulate in the space between the surfaces of the ribs 61 and 62 and the other surface of the part 47 which is in contact with the combustion gases of the combustible gas. In this case, the condensate will not be evenly distributed over the surface in contact with the combustion gases of the combustible gas, such as inside round pipes. The accumulation of condensate here will be due to the forces of the surface tension of the liquid.

Water (condensate) has a much lower thermal conductivity than cast iron. An increase in the average density of the thermal energy flux, which is released during the condensation of water vapor into water, is achieved by the fact that water (condensate) covers the surfaces of the fins 61 and 62, which are in contact with the gaseous products of combustion of combustible eider, with a film of thinner thickness than the inner surfaces of round pipes .

The accumulation of condensate also contributes to its flow down, in the parts 47, and removal from the condensing gas boiler.

Close is the method of selection of thermal energy from water vapor, specified in the source of information [5].

The ribs 61 and 62 may have various forms of rounded surface, which, for example, are indicated in the sources of information [6] and [7].

The increase in the average density of the thermal energy flux of the gaseous products of combustion of the combustible gas moving naturally, and the thermal energy that is released during the condensation of water vapor into water, through the surface of each of the heat exchange parts, the condensing heat exchange device, the condensing gas boiler 47, which is in contact with water , will reduce the material consumption of the condensing heat exchanger of the condensing gas boiler 1, without reducing the power of the condensing gas boiler.

In order to further increase the reliability and safety of operation of the condensing gas boiler, the gaseous products of combustion of combustible gas are provided to exit the main heat exchange device of the condensing gas boiler through at least one outlet channel 63, with the highest average speed of movement of gaseous products of combustion of combustible gas, relative to average speeds of movement of the products of combustion of combustible gas, through other openings of other parts of the condensing gas boiler, to the outlet 13 of the condensing gas boiler, through the chimney 39 (Fig. 7, 11).

The movement of the combustion gases of the combustible gas, through the outlet channel 63, provides the pressure of the column of hot combustion gases of the combustible gas, in the main heat exchange device of the condensing gas boiler 4. The pressure of the combustion gases of the combustible gas, in the main heat exchange device of the condensing gas boiler 4, provides a buoyancy force acting on hot gaseous combustion products of combustible eider, from bottom to top.

The highest average velocity of the gaseous products of combustion of the combustible gas, from the exhaust channel 63, is provided by using the smallest cross-sectional area of the exhaust channel 63, compared with the cross-sectional area of the transition gas tube 26, compared with the total cross-sectional area of \u200b\u200ball heat exchange parts of the condensing heat exchanger of the condensing gas boiler 47, as well as in comparison with the cross-sectional areas of the original gas tube 33, pipe 38, and chimney 39. All cross-sections of these parts of the condensing gas boiler lie in a plane that is perpendicular to the direction of movement of gaseous products of combustion of combustible gas.

When the gaseous products of combustion of combustible gas move through heat exchangers 1 and 4, as well as other parts of a condensing gas boiler, their pressure differs little from atmospheric pressure. Therefore, the movement of gaseous products of combustion of combustible gas through heat exchangers 1 and 4, as well as others details of a condensing gas boiler, it is possible to model as the movement of fluid in a hydraulic press.

According to the method of operation of the hydraulic press, the ratio of the cross-sectional area of the outlet passage 63 and the cross-sectional area of the flue pipe 39 determines the coefficient of increase in the force acting on the combustion gases of the combustible gas that move in the flue pipe in the direction of their removal from the flue pipe.

Similarly, the ratio of the cross-sectional area of the exhaust channel 63, and the total cross-sectional area of all heat exchange parts of the condensing heat exchanger of the condensing gas boiler 47, also determines the coefficient of increase in the force acting on the combustion gases of the combustible gas, in the direction of their movement into the chimney 39. combustion products of combustible gas that move through the parts 47, in the condensing heat exchange device 1, this force is directed from top to bottom, against the action of the buoyancy force.

A similar way of gas movement is indicated in the source of information [8]. Here, too, the cross-sectional area of the central ridge of the room furnace B is smaller compared to the cross-sectional area of the annular trough C, and compared to the cross-sectional area of the nozzle 1). All these cross-sections here also lie in a plane that is perpendicular to the direction of movement of gases.

New, in the method which is claimed, is already the fact that the method of movement of gases indicated in the source of information [8] is used to ensure the natural movement of gaseous combustion products of combustible gas in a condensing gas boiler.

An additional increase in the force acting on the gaseous products of combustion of combustible gas, in the direction of their movement into the chimney 39, and in the direction of their removal into the environment, from the chimney 39, will further increase the reliability and safety of the condensing gas boiler.

This is especially important in the event of an emergency in the operation of a condensing gas boiler, when there is a complete attenuation of burners 11, and combustible (natural) gas continues to flow into burners 11. In this case, it is possible to completely remove the combustible (natural) basin from the condensing gas boiler, through the chimney 39, into the environment.

In FIG. 7 shows a condensing gas boiler in which the main heat exchanger 4 is entirely welded from steel parts. Indicated in FIG. 7, the main heat exchanger 4 does not include a side steel cover 53. This simplifies the structure of the main heat exchanger 4, and reduces its cost.

The use of the outlet channel 63 instead of the heat exchange tubes of the main heat exchange device of the condensing gas boiler 48, into which the turbulators are inserted, also simplifies the design of the main heat exchange device 4 and reduces its cost.

When using the exhaust port 63, the temperature of the combustion gases of the combustible gas, at the outlet of the exhaust port 63, should not exceed 600°C. This will unnecessarily increase the heat load on the cast iron of the condensing heat exchanger of the condensing gas boiler 1, and on the steel parts of the condensing gas boiler in contact with the combustion gases of the combustible gas before they enter the heat exchange parts of the condensing heat exchanger of the condensing gas boiler 47.

In order to avoid a significant heat load on the cast iron of the condensing heat exchange device of the condensing gas boiler 1, and to maintain the above method of movement of gaseous combustion products of combustible gas, it is advisable to use heat exchange tubes 48 in the main heat exchange device 4. But, at the same time, the total area of all annular slots, between each of the heat exchange tubes, and the metal discs 50, should be close to the cross-sectional area of the outlet channel 63, which lies in a plane perpendicular to the direction of movement of the combustion gases of the combustible gas. That is, in this case, it is also necessary to ensure that the combustion gases of the combustible gas exit from the main heat exchange device of the condensing gas boiler 4 with the highest average speed of the combustion gases of the combustible gas, relative to the average speeds of the combustion gases of the combustible gas, through other openings. condensing gas boiler, to the outlet of the condensing gas boiler, through the chimney 39.

Also, when implementing the proposed method, additionally, the energy independence (independence from power supply) of the condensing gas boiler is fully ensured by heating the water in the main heat exchange device of the condensing gas boiler 4 to the boiling point, with the thermal energy of gaseous products of combustion of combustible gas.

After heating the water in the main heat exchanger of the condensing gas boiler 4 to the boiling point, the thermal energy of the gaseous products of combustion of the combustible gas is used to boil the water in the main heat exchanger of the condensing gas boiler 4 using the thermal energy of the gaseous products of combustion of the combustible gas. When water boils, bubbles of water vapor are formed near the surface of the main heat exchange device 64, which is in contact with water, and through which the thermal energy of gaseous products of combustion of combustible gas is transferred to water. Surface 64, for example, is the outer surface of the heat exchange tubes of the main heat exchanger of the condensing gas boiler 48, or, for example, the outer surface of the outlet duct 63.

And when water boils, provide movement of water vapor bubbles, which are separated from the surface of the main heat exchange device 64, which is in contact with water, and through which the thermal energy of the gaseous products of combustion of combustible gas is transmitted, in the vertical direction, to the upper surface of the main heat exchange device of the condensing gas boiler 65, which is in contact with water (Fig. 3, 7, 8, 11).

Using the upper surface of the main heat exchanger of the condensing gas boiler 65, the movement of water vapor bubbles into the storage steam tank 66 of the main heat exchanger of the condensing gas boiler is provided (Fig. 8-11).

Water vapor is stored in a steam storage tank, the main heat exchanger of the condensing gas boiler 66, and pressurized with water vapor.

Using the steam pressure, and using the buoyancy force that acts on the water vapor in the water, hot water and steam are transported from the main heat exchange device of the condensing gas boiler 4 through the transport device, which includes the outlet check valve 67, first from the bottom up , and then from top to bottom, into the heating system (Fig. 8, 11). At the same time, water is supplied to the main heat exchanger of the condensing gas boiler 4 from the condensing heat exchanger of the condensing gas boiler 1 through the inlet check valve 68 (Fig. 8, 9, 11). The outlet check valve 67 and the inlet check valve 68 ensure that water flows through the heat exchangers of the condensing gas boiler 1 and 4 in only one direction.

The upper surface of the main heat exchanger of the condensing gas boiler 65 may be sloped such as to facilitate the movement of water vapor bubbles into the steam storage vessel 66. Such a slope of the surface 65 is indicated in FIG. 8 and FIG. eleven.

A similar way of transporting hot water and water vapor is indicated in the sources of information [9], [10], [11], [12]. What is new here is that the method of transporting hot water and steam indicated in the sources of information [9], [10], [11], [12] is used to ensure non-volatile operation of a condensing gas boiler.

The transportation of hot water and water vapor from the main heat exchanger of the condensing gas boiler 4, first from the bottom up and then from the top down, is carried out through the tube 69 to the outlet pipeline 8. The tube 69 may have a smaller inner diameter relative to the inner diameter of the outlet pipeline 8. When transporting water and water vapor, it is advisable to set the average speed of movement of water and water vapor in the tube 69, from 0.6 m/s to 1.0 m/s. At such speeds, significant water turbulence occurs, which contributes to its better mixing with steam [13].

Transportation of water and water vapor is carried out in the heating system, the schematic diagram of which is shown in Fig. 12.

From the original pipeline 8, hot water and steam are supplied to the input heating radiator 70. From the input heating radiator 70, hot water and steam are supplied to other radiators of the heating system, sequentially, from one to the other (not shown in Fig.) . And at the end, from the outlet heating radiator 71, chilled water is supplied to the condensing gas boiler, through the inlet pipeline 2.

It is advisable to supply hot water and water vapor to the heating radiator through the bubbler 72, which ensures the crushing of water vapor bubbles, and heating the water in the heating radiators with “hot” water vapor.

Heating radiators that have a surface temperature of more than 45°C must contain protective grilles or protective screens that allow natural air movement through the heating radiators, and at the same time prevent direct human contact with the surface of the heating radiator.

An increase in the surface temperature of heating radiators accelerates the heating of the heated room to the set temperature, and reduces the time to heat the heated room to the set temperature. In a condensing gas boiler, this will further reduce the gas consumption for space heating.

Turning on and off the condensing gas boiler in automatic mode is carried out using a working sensor for turning on and off the combustible gas supply 73. The working sensor for turning on and off the combustible gas supply 73 may contain a bimetallic plate made of metals that have a different coefficient of thermal expansion, and can be completely independent of the power supply. The working sensor 73 may also have a mechanical control device that will provide control at what water temperature, in pipeline 2, at the inlet to the condensing heat exchanger 1, to turn on the supply of combustible gas to the burners 11, and at what water temperature, in pipeline 2, at the inlet to the condensing heat exchanger 1, turn off the supply of combustible gas to the burners 11. The water temperature, when the burners 11 are turned on, should not be less than the set air temperature in the heating room. And the temperature of the water, when the burners 11 are turned off, should not be more than 50°C. Otherwise, it will unnecessarily reduce the heat output of the condensing heat exchanger 1.

The heating system, which is shown schematically in Fig. 12, contains an expansion tank 74. When using water transfer pumps, in a condensing gas boiler, both dependent on electric power and independent of electric power, an expansion tank 74 can be installed in an apartment of a multi-storey building. It is expedient to connect the expansion tank 74 to the heating system before the chilled water enters the condensing heat exchanger 1. In this case, the temperature of the water in the expansion tank 74 and in pipeline 2 will differ little from each other, which will reduce the circulation of water between pipeline 2, and expansion tank 74.

The use of a water-steam heating system makes it possible to use all the advantages of water and steam heating systems in it.

In FIG. 8 and FIG. 11 is a schematic vertical sectional view of non-volatile gas condensing boilers, each of which contains a hot water heating pipe 75, which is connected to the hot water inlet pipe 76, and to the hot water outlet pipe 77.

Hot water pipes 76 and 77 are also indicated in FIG. 9. The inlet pipe of the hot water supply system 76 contains a connecting node 78. The outlet pipe of the hot water supply system 77 contains a connecting node 79.

The heating tube 75 is located in the main heat exchange device of the condensing gas boiler 4. The dark solid arrows indicate the directions of water circulation, at the heating tube of the hot water system 75. That is, the non-volatile condensing gas boilers, which are shown in Figs. 8-11 are double-circuit. Water heating for hot water supply is carried out here by the thermal energy of water, in the main heat exchanger of the condensing gas boiler 4.

Unlike existing wall-mounted gas boilers, which, for example, is indicated in the source of information [2], when a condensing gas boiler is turned off, the method of operation of which is claimed, there are small leakages of thermal energy into the environment. This is due to the fact that the heated air in the condensing gas boiler accumulates under the hood of the condensing gas boiler 22.

Thus, the method of operation of the condensing gas boiler, which is claimed, allows you to increase the reliability of the condensing gas boiler, as well as increase the safety of the condensing gas boiler, and at the same time, additionally, increase the average heat energy flux density of the gaseous combustion products of combustible gas, and thermal energy , which is released during the condensation of water vapor into water, through the surface of each of the heat exchange parts of the condensing heat exchange device of the condensing gas boiler, which is in contact with water and / or, in addition, fully ensure the energy independence of the condensing gas boiler.

EXAMPLE OF SPECIFIC IMPLEMENTATION

The method of operation of the condensing gas boiler has been tested in laboratory conditions.

Specified in the materials of this application, the method of movement of gaseous products of combustion of combustible gas, in a condensing gas boiler, was used and tested in a device called "siphon" by the Siemens brothers [4]. A similar method of gas movement is also used in self-blown gas generators. As well as the practical suitability of this method of gas movement is confirmed in the source of information [8].

The practical suitability of the method for extracting thermal energy from the gaseous products of combustion of combustible gas, as indicated in the materials of this application for the invention, and the thermal energy released during the condensation of water vapor, is confirmed in the sources of information [5], [6], [7].

The practical suitability of the method of pumping a water-steam mixture, indicated in the materials of this application for the invention, is confirmed in the sources of information [9], [10], [11], [12].

INFORMATION SOURCES

1. Patent for the invention of the Russian Federation No. 2495335, F24H 1/00 (2006.01), published on 10.10.2013, bul. No. 28.

2. Utility model patent of the Russian Federation No. 110460, F24H 1/08 (2006.01), published on November 20, 2011, bul. No. 32.

3. Patent for the invention of the Russian Federation No. 2578361, F24H 1/00 (2006.01), published on 03/27/2016, bul. No. 9.

4. Professor V.E. Groom - Grzhimailo, "Flame furnaces", a publication of the Thermal Engineering Institute named after professors V.I. Grinevetsky and K.V. Kirsha, Moscow, 1925, p. 11 (Application to the flame of the laws of hydrostatics.), http://narod.ru/disk/3863051001/Grum-Grjimailo.djvu.html

5. USSR author's certificate No. 307258, F28b 1/02, F28f 1/12, F28f 1/14, F28d 1/04, published 06/21/1971, Bull. No. 20. http://www.findpatent.ru/

6. Patent of Ukraine for the invention No. 107640, F24H 1/00 (2005.01), F24H 1/12 (2006.01), published on January 26, 2015, Bull. No. 2.

7. Patent of Ukraine for the invention No. 107641, F24H 1/00 (2005.01), F24H 1/12 (2006.01), published on January 26, 2015, Bull. No. 2.

8. Patent for the invention of the USSR No. 1219, class 36a, published on May 31, 1926 http://www.findpatent.ru/

9. Patent for the invention of the Russian Federation No. 2173434, F24H 1 /) 8 (2000.01), F25B 29/00 (2000.01), F04F 1/04 (2000.01), published on September 10, 2001, Bull. No. 25.

10. Patent for the invention of the Russian Federation No. 2406040, F24H 1/08 (2006.01), published on December 10, 2010, Bull. No. 34.

11. Patent for the invention of the Russian Federation No. 2633870, F24H 1/08 (2006.01), published on 10/18/2017, Bull. No. 29.

12. Four-stroke steam-water pump PVNK 1-10

13. P.H. Kamenev, A.N. Skanavi, V.N. Bogoslovsky, A.G. Egiazarov, V.P. Shcheglov, Heating and ventilation. Textbook for universities, in 2-h, Part 1, Heating, 3rd Edition, revised and supplemented, Moscow, Stroyizdat, 1975, p. 148. http://rudic.ru/page/otoplenie-i-ventiljacija-v-dvuh-chastjah-bogoslovskij-vn-chast-1-i-2

Claims (4)

1. A method of operating a condensing gas boiler, which includes supplying water to a condensing gas condensing boiler heat exchanger and a main heat exchanger of the condensing gas boiler, supplying combustible gas to at least one gas burner of the condensing gas boiler, supplying air to at least at least one gas burner of a condensing gas boiler, combustion of combustible gas, using at least one gas burner of a condensing gas boiler, obtaining heated combustion gases of combustible gas, ensuring the movement of combustion gases of combustible gas, from bottom to top, in the main heat exchange device condensing gas boiler, and from top to bottom, in the condensing heat exchanger of the condensing gas boiler, heating the water in the main heat exchanger of the condensing gas boiler with the thermal energy of the combustion gases of the combustible gas, and heating the water in the condensing heat exchanger of the condensing gas boiler with the thermal energy of the combustion gases of the combustible gas and thermal energy that is released during the condensation of water vapor, after which the removal of gaseous products of combustion of combustible gas from the condensing gas boiler through the chimney, as well as the removal of condensate from the condensing gas boiler, characterized in that the combustion of combustible gas is carried out under the cap part of the condensing gas boiler , above the lower edge of the bell-shaped part of the condensing gas boiler, with the help of at least one gas burner of the condensing gas boiler, and the air necessary for burning combustible gas is supplied through at least two air holes, which are located in the bell-shaped part of the condensing gas boiler. gas boiler, at different distances from the lower edge of the cap part of the condensing gas boiler, and the movement of gaseous products of combustion of combustible gas, in the main heat exchange device of the condensing gas boiler, is provided from the bottom up in a natural way, and the movement of gaseous products of combustion of combustible gas, in the condensing heat exchanger of the condensing of the gas boiler is provided from top to bottom in a natural way, through the heat exchange parts of the condensing heat exchanger of the condensing gas boiler, while the height of the column of gaseous products of combustion of combustible gas moving from bottom to top in the condensing gas boiler, and the average temperature in the column of gaseous products of combustion of combustible gas moving from bottom to top, in a condensing gas boiler, is installed so as to ensure the natural movement of combustion gases of combustible gas in the condensing heat exchanger device of a condensing gas boiler from top to bottom, and to ensure the natural movement of combustion gases of combustible gas when removing gaseous combustion gases of combustible gas from a condensing gas boiler through the chimney. 2. The method according to claim 1, characterized in that the average density of the thermal energy flux of the gaseous products of combustion of combustible gas and the thermal energy that is released during the condensation of water vapor into water through the outer surface of each of the heat exchange parts of the condensing heat exchange device of the condensing gas boiler is increased , which is in contact with water, using internal metal fins of the same or different heights, of each of the heat exchange parts of the condensing heat exchanger of the condensing gas boiler in contact with the combustion gases of the combustible gas, and with water vapor that moves through each of the heat exchange parts of the condensing heat exchanger of the condensing gas boiler gas boiler, from top to bottom, naturally. 3. The method according to claim 1, characterized in that the gaseous products of combustion of combustible gas are provided from the main heat exchange device of the condensing gas boiler through at least one outlet channel, with the highest average speed of movement of gaseous products of combustion of combustible gas, relative to average speeds movement of gaseous products of combustion of combustible gas, through other parts of the condensing gas boiler, to the outlet of the condensing gas boiler, through the chimney. 4. The method according to claim 1, characterized in that it ensures complete energy independence of the condensing gas boiler by heating the water in the main heat exchange device of the condensing gas boiler to the boiling point with the thermal energy of the gaseous products of combustion of the combustible gas, after which the water is boiled, in the main heat exchange device of the condensing gas boiler, also using the thermal energy of the gaseous products of combustion of the combustible gas, while ensuring the formation of water vapor bubbles, near the surface of the main heat exchange device, which is in contact with water, and through which the thermal energy of the gaseous products of combustion of the combustible gas is transferred to water, ensures the movement of water vapor bubbles , which are separated from the surface of the main heat exchange device that is in contact with water, and through which the thermal energy of the gaseous products of combustion of combustible gas is transferred to water, in the vertical direction, to the upper surface of the main heat exchange device of the condensing gas boiler that is in contact with water, and using the upper the surface of the main heat exchanger of the condensing gas boiler, ensure the movement of water vapor bubbles into the storage steam tank, the main heat exchanger of the condensing gas boiler, where water vapor is accumulated in the storage steam tank of the main heat exchanger of the condensing gas boiler, and create water vapor pressure, and, using water vapor pressure, as well as the buoyancy force that acts on the water vapor in the water, transport hot water and steam from the main heat exchanger of the condensing gas boiler, through the transport device, first from the bottom up, and then from the top down, to the heating system, while provide water inlet to the main heat exchanger of the condensing gas boiler, from the condensing heat exchanger of the condensing gas boiler, through the check valve.

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