RU165521U1 - SOLID FUEL HEATING BOILER - Google Patents

Abstract

1. A solid fuel heating boiler, comprising a housing with a cavity for a coolant in it with inlet and outlet nozzles, doors for loading fuel and servicing the boiler, a combustion chamber with an exhaust nozzle, a variable-length air supply pipe that is connected to the atmosphere on one side and provided on the other hand with an air distributor, characterized in that the air distributor is made in the form of a bunch of L-shaped pipes equipped with holes and closed with a screen on top. A heating boiler according to claim 1, characterized in that the pipe of variable length is made in the form of a telescopic. 3. A heating boiler according to claim 1, characterized in that the pipe of variable length is provided with holes in the housing connecting the internal cavity of the pipe to the combustion chamber. 4. The heating boiler according to claim 1, characterized in that the holes in the L-shaped tubes of the beam are made on the vertical and horizontal sections of these pipes. The heating boiler according to claim 1, characterized in that the horizontal sections of the L-shaped pipes communicate with the air supply pipe. The heating boiler according to claim 1, characterized in that the vertical sections of the L-shaped pipes are provided with holes in the walls and lower ends. The heating boiler according to claim 1, characterized in that the total area of the openings in the pipe casing for air supply and in the L-shaped pipes of the air distribution bundle are in the ratio: - the total area of the openings of the vertical sections of the pipe bundle is 60-80% of the total area of openings for air supply of the pipe and the holes of the air distributor; - the total area of the holes of the horizontal sections of the tube bundle is 10-20% of the total area of the holes for the air supply of the pipe and holes

Description

The utility model relates to energy and can be used to heat individual and industrial premises and other technological needs.

A well-known solid fuel water boiler comprising a combustion chamber mounted vertically and made in the form of a round or polygonal cylinder in the double wall of which a container filled with water is formed (RF patent for utility model No. 104290). An air supply pipe is inserted in the upper part of the combustion chamber, made in the form of a telescopic structure, ending with an air distributor. A common opening was made in the side of the boiler body for loading fuel, removing ash, servicing the combustion chamber and the air supply device to the combustion area, hermetically sealed by two doors, one of which is designed to ignite the boiler and briefly monitor the combustion process, the other to load combustion chamber of the boiler with fuel and maintenance of the combustion chamber and air supply device. The upper door is made with approaching the lower one, which prevents accidental opening of the lower door and spilling of burning fuel. The air supply pipe consists of at least two links, in the connections of which slots are made for supplying air, which ensures the combustion of the flue gases generated after combustion of the fuel in the combustion chamber.

The disadvantage of the analogue is the inconvenience of loading the boiler with fuel, since to open the lower door of the load, you must first open the upper door, which is made with the approach to the lower door, which, during operation (burning of the fuel) of the boiler is fraught with additional heat loss from hot gases intended for heating (water) in the water cavity of the boiler.

Also known is a heating boiler containing a combustion chamber, in the double wall of which a container filled with water is formed with a smoke outlet, fuel loading and ash removal holes, water inlet and outlet pipes (Eurasian patent No. 005303). The combustion chamber is installed vertically and made in the form of a round or polygonal cylinder, in the upper part of which a hole is made, into which a freely moving up and down air supply pipe is inserted, ending with an air distributor based on fuel, while the air distributor is made in the form of a hollow disk, in the upper part of which there is a tip for connecting to the air supply pipe, and in the lower part - the head, while in the peripheral part of the disk, in the narrow end of the head and on the side turn At the end of the head, as well as in the tip, holes are made that communicate with the internal cavity of the air distributor. The area of the air distributor is 0.3-0.5 of the cross-sectional area of the combustion chamber. The air supply pipe is made in the form of a telescopic structure. The distributor supplies air to the combustion chamber in proportion: 40-60% is supplied to the combustion center; 10-30% is supplied to the edges of the combustion zone; above the combustion area - 20-40%

The design of the boiler according to Eurasian patent No. 005303 is closest to the claimed utility model and is selected as a prototype.

The disadvantage of the prototype is the design of the head in the lower part of the air distributor, which provides air only to the central part of the burning fuel, which does not allow for efficient combustion of fuel remote from the center of the combustion chamber and located closer to the walls of the coolant chamber.

The objective of the claimed utility model is to increase the heat transfer surface of the solid fuel boiler burning in the combustion chamber by expanding the combustion zone (combustion center) of the fuel.

The technical result of the claimed utility model is to increase the efficiency of the boiler.

The claimed technical result is achieved by the fact that the heating boiler contains a combustion chamber with a hole for exhaust gas, in the double wall of which a cavity is formed with pipes for supplying and removing coolant, fuel loading and ash removal holes, the combustion chamber is installed vertically and made in the form of a cylinder or polygonal prism, in the upper part of which a hole is made for the passage of air into the air supply pipe, ending with an air distributor.

The distributor on the air supply pipe, which rests on the fuel during operation of the boiler, is made in the form of a bunch of L-shaped pipes equipped with holes for supplying air to the fuel combustion zone and to the zone above the combustion zone. The horizontal sections of the L-shaped pipes communicate with the air supply pipe and through their openings in the walls supply air to the zone above the combustion zone. The vertical sections of the L-shaped pipes, communicating with the horizontal sections, through the holes in the walls and at the ends supply air to the combustion zone. A flat disk-shaped screen is placed above the bunch of L-shaped pipes, which provides air supply to the combustion zone and above the combustion zone, preventing air from entering the gas afterburning zone. Air is supplied to the gas afterburning zone through openings in the air supply pipe, which is configured to change its length, for example, telescopic or bellows, during the operation of the boiler. These openings for the passage of air into the combustion chamber provide the combustion of flue gases, once again increasing the temperature of the coolant in the cavity of the coolant.

The applicant is a developer of design documentation and a manufacturer of such boilers. During research and development work, he experimentally established that the most efficient operation of the boiler is achieved by distributing air entering the combustion chamber through openings in the pipe body for air supply and through openings in the L-shaped tubes of the air distributor beam, as follows:

- 60-80% of air is supplied to the combustion zone (through the openings of the vertical sections of the tube bundle);

- 10-20% of air is supplied to the area above the combustion zone (through the holes of the horizontal sections of the tube bundle);

- 10-20% of air is supplied to the gas afterburning zone (through holes in the casing of the air supply pipe).

Based on the above air flow rates by zones, the total area of the holes for each zone was determined:

- the total area of the holes of the vertical sections of the pipe bundle is 60-80% of the total area of the holes for supplying pipe air and the holes of the distributor;

- the total area of the holes of the horizontal sections of the pipe bundle is 10-20% of the total area of the holes for supplying pipe air and the holes of the distributor;

- the total area of the holes in the casing of the air supply pipe is 10-20% of the total area of the holes for supplying air to the pipe and the holes of the distributor.

To increase air flow through the air supply pipe, the boiler can be equipped with a fan installed at the inlet of the air supply pipe, for example, in an air heating chamber, in the lower end of which a pipe for supplying air to the combustion chamber is fixed, and the upper end through the hole communicates with the atmosphere. In a particular case, the air pump is installed in the air intake hole in the upper part of the air heating chamber.

To increase the efficiency of fuel combustion, the boiler can be equipped with a blower located in the lower part of the combustion chamber, on the grate of which solid fuel is loaded. Air enters the blower through a channel connecting the blower to the air heating chamber.

In FIG. 1 is a longitudinal section through a boiler, FIG. 2 - a fragment of a longitudinal section of the boiler in the area of the channel connecting the air heating chamber with the blower, in FIG. 3 is a top view ѕ of the air distributor from above, in FIG. 4 is a bottom view of the air distributor.

The heating boiler contains a housing 1 with a cavity 2 located inside it for the coolant, which through the inlet 3 and outlet 4 pipes communicates with the heating system of the room. The housing 1 is equipped with doors 5, 6 for filling fuel and servicing the combustion chamber 7. In the upper part of the combustion chamber 7 there is a hole 8 in which a variable length pipe 9 is inserted to supply air to the combustion chamber 7. The pipe 9 can be made, for example, telescopic (sections 9.1, 9.2, 9.3). The exhaust flue gases are removed through the pipe 10 in the upper part of the boiler body 1. A pipe 9 of variable length in its lower part is equipped with an air distributor 11, which consists of a bunch of L-shaped pipes 12, equipped with holes 13 for supplying air to the fuel combustion zone and to the zone above the combustion zone. Holes 13.1 are located on the vertical sections of the L-shaped tubes of the beam and at the ends of these pipes, Holes 13.2 are located on the horizontal sections of the L-shaped tubes of the beam. Above the bundle of L-shaped pipes there is a flat disk-shaped screen 14. A fan 15 is placed at the inlet of the pipe 9 for supplying air to the combustion chamber 7. In the pipe body 9 with openings 9.1, 9.2, 9.3 holes 16 are made for supplying air to the gas afterburning zone. To heat the cold air entering the pipe 9 through the cold air pipe 17, a chamber 18 for heating the air can be used, which is located in the upper part of the combustion chamber 7 on the exit path of the exhaust hot flue gases. Exhaust flue gases are removed from the combustion chamber through the exhaust pipe 10. At the bottom of the boiler there is a blower 19 with a grate 20. The blower 19 is connected by a channel 21 to the air heating chamber 18.

The operation of the boiler.

Before loading the boiler with solid fuel, for example wood, the air distributor 11 rises in a known manner, for example, using a cable (not shown) and folding the telescopic pipe 9, in the upper position. Through the doors 5, 6, the fuel is put into the combustion chamber 7. After the fuel is laid, the air distributor 11 is lowered onto the fuel and ignited. During fuel combustion, air from the pipe 9 through the openings 13.1 of the vertical sections of the tube bundle 12 is distributed in the fuel combustion zone, supporting the combustion of the maximum fuel layer over the area, which also emits carbon monoxide CO. Through the holes 13.2 of the horizontal sections of the tubes of the beam 12, the incoming air is distributed in the area above the burning fuel under the screen 14, providing the primary combustion of carbon monoxide. The CO remaining in the flue gas burns out while mixing with the air entering through the openings 16 in the pipe 9, above the screen 14 - in the afterburning zone. The fuel combustion rate can be increased by providing air pressurization into the pipe 9, placing a fan (air pump) in front of the pipe 18. When heating the air (before it enters the pipe 9) in the air heating chamber 18, the combustion efficiency of the fuel in the combustion chamber 7 also increases. the air pump 18 can be placed at the air inlet 17 into the air heating chamber 18. The more efficiently the fuel burns in the combustion chamber, the greater the heat transfer to the cavity of the coolant 2, the higher the temperature of the coolant, the higher the efficiency of the heating boiler. If the boiler is equipped with a blower 19, then solid fuel is placed on the grate 20. The heated air from the air heating chamber 18 enters from below through the channel 21 to the fuel on the grate 20 and, thus, increases its combustion efficiency.

The ROCs carried out by the applicant showed its increased operational characteristics compared to the prototype and proved the industrial applicability of such a design.

Claims (15)

1. A solid fuel heating boiler, comprising a housing with a cavity for a coolant with inlet and outlet nozzles located therein, doors for loading fuel and servicing the boiler, a combustion chamber with an exhaust nozzle, a variable-length air supply pipe communicating with the atmosphere on one side and provided on the other hand with an air distributor, characterized in that the air distributor is made in the form of a bunch of L-shaped pipes equipped with holes and closed with a screen on top. 2. The heating boiler according to claim 1, characterized in that the pipe of variable length is made in the form of a telescopic. 3. The heating boiler according to claim 1, characterized in that the pipe of variable length is provided with holes in the housing connecting the internal cavity of the pipe to the combustion chamber. 4. The heating boiler according to claim 1, characterized in that the holes in the L-shaped tubes of the beam are made on the vertical and horizontal sections of these pipes. 5. The heating boiler according to claim 1, characterized in that the horizontal sections of the L-shaped pipes communicate with the air supply pipe. 6. The heating boiler according to claim 1, characterized in that the vertical sections of the L-shaped pipes are provided with holes in the walls and lower ends. 7. The heating boiler according to claim 1, characterized in that the total area of the holes in the pipe body for supplying air and in the L-shaped pipes of the beam of the air distributor are in the ratio: - the total area of the holes of the vertical sections of the tube bundle is 60-80% of the total area of the holes for supplying pipe air and the holes of the air distributor; - the total area of the holes of the horizontal sections of the tube bundle is 10-20% of the total area of the holes for supplying pipe air and the holes of the air distributor; - the total area of the holes in the casing of the air supply pipe is 10-20% of the total area of the holes for supplying air to the pipe and the holes of the air distributor. 8. The heating boiler according to claim 1, characterized in that the screen is made in the form of a flat metal plate. 9. The heating boiler according to claim 7, characterized in that the screen is disk-shaped. 10. The heating boiler according to claim 1, characterized in that an air pump is placed in front of the air supply pipe. 11. The heating boiler according to claim 10, characterized in that the air pump is made in the form of a fan. 12. The heating boiler according to claim 1, characterized in that the boiler is equipped with an air heating chamber. 13. The heating boiler according to claim 10, characterized in that the air pump is located in the air heating chamber. 14. The heating boiler according to claim 1, characterized in that the boiler is equipped with a blower. 15. The heating boiler according to claim 14, characterized in that the blower is connected to the air heating chamber by a channel.

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