RU213225U1 - WATER BOILER - Google Patents

Abstract

The utility model relates to boiler technology and can be used in rectangular hot water boilers. The boiler contains a boiler base, a furnace, the space of which is limited by a furnace grate, front and rear screens, ceiling and side furnace screens, the latter of which are made in the form of tube panels hydraulically connected to the corresponding upper and lower longitudinal collectors of the boiler, with the possibility of sequential ascending and downward movement of water along them, as well as two convective blocks, including at least four convective gas ducts, equipped with heat exchange surfaces containing bundles transversely streamlined by tube collectors, hydraulically connected to the longitudinal collectors of the boiler, the lower longitudinal collectors of the boiler are connected by transverse collectors placed on the front and rear fronts of the boiler, while the heat exchange surfaces located in the convective gas ducts contain rectilinear transversely streamlined in-line tube bundles containing vertical risers, each of which is connected to the corresponding upper and lower longitudinal collectors of the boiler, each vertical riser is divided by horizontal partitions into vertical sections, the ends of which are connected with the second and third pair of longitudinal collectors of the boiler, while its upper and lower interfaces with the mentioned collectors are blocked by end caps, under the rear screen there is a collector of the acute blast, made of a pipe with fixed nozzles, located at an angle of two tiers. The technical result of the claimed technical solution is to increase the efficiency of the boiler when burning hard, brown coal and reduce heat loss with exhaust gases. 8 ill.

Description

The utility model relates to boiler technology and can be used in rectangular hot water boilers.

Known hot water boiler (RU 2124678, publ.: 01/10/1999), containing a housing placed in it a firebox with rear, ceiling and side framing screens from heat exchange pipes, as well as convective screens from heat exchange pipes installed in convective gas ducts parallel to the side framing screens , moreover, the pipes of all screens are connected to the corresponding collectors, and the collectors of the convective and side framing screens are equipped with transverse partitions, while the convective gas ducts are separated by an L-shaped gas guide partition, the vertical shelf of which is located coaxially with the first transverse partition along the water flow of the upper convective collector, and its the horizontal shelf is located in the central part of the convective gas duct and is made with a length corresponding to the distance between the transverse partitions of the upper convective manifold, while the upper manifolds of the convective screens are connected to the upper manifolds of the side framing screens, the lower collets which are connected to the bottom manifold of the rear screen, the upper manifold of which is the rear manifold of the overhead screen. Convective flues are separated from the combustion chamber by partitions. The disadvantage of the known design is the low heat output of the boiler.

The closest in technical essence to the claimed boiler is a convective block of a hot water boiler (RU 2566465, publ.: 10/27/2015 Bull. No. 30), containing two convective gas ducts equipped with heat exchange surfaces containing transversely streamlined tube bundles hydraulically connected to the longitudinal collectors of the boiler , differs in that the heat exchange surfaces located in the convective gas ducts contain rectilinear transversely streamlined in-line tube bundles containing vertical risers, each of which is in communication with the corresponding upper and lower longitudinal collectors of the boiler, and each vertical riser is divided by horizontal partitions into vertical sections, each of which is in communication with horizontal tube bundles, the ends of which are in communication with a freely sliding riser, the ends of which are in communication with the second pair of longitudinal boiler collectors, while its upper and lower interfaces with the mentioned collectors are blocked by end partitions and, and on the sliding riser, at least one cut is made, muffled by the second end partitions placed with a gap to each other, in addition, in the next pair of heat exchange surfaces, the vertical riser and the freely sliding riser are interchanged, in addition, the convective gas ducts in the lower part are connected with each other by the cavity of the sedimentation chamber of fly ash. In addition, the top and bottom of the free-sliding pine riser to each other. In addition, the length of the tubes in the horizontal tube bundles is the same. The disadvantage of the known design is the low heat output of the boiler.

The task to be solved by the proposed technical solution is to increase the thermal performance of the boiler.

To solve the task, the boiler contains a boiler base, a furnace, the space of which is limited by a furnace grate, front and rear screens, ceiling and side furnace screens, the latter of which are made in the form of pipe panels hydraulically connected to the corresponding upper and lower longitudinal collectors of the boiler, with the possibility of successive upward and downward movement of water through them, as well as two convective blocks, including at least four convective gas ducts, equipped with heat exchange surfaces containing bundles transversely streamlined by tube collectors, hydraulically connected to the longitudinal collectors of the boiler, the lower longitudinal collectors of the boiler are connected by transverse collectors located on the front and rear fronts of the boiler, while the heat exchange surfaces located in the convective gas ducts contain rectilinear transversely streamlined in-line tube bundles containing vertical risers, each of which communicated with the corresponding upper and lower longitudinal collectors of the boiler, and each vertical riser is divided by horizontal partitions into vertical sections, the ends of which are connected with the second and third pair of longitudinal collectors of the boiler, while its upper and lower interfaces with the said collectors are blocked by end caps, under the rear screen there is a manifold of the system of sharp blast, made of a pipe with fixed nozzles, located at an angle in two tiers.

The technical result of the claimed technical solution is to increase the efficiency of the boiler when burning hard, brown coal and reduce heat loss with exhaust gases.

The utility model relates to water-tube hot water boilers with a thermal output of up to 4 MW and is aimed at increasing the productivity of a water-tube boiler, reduces harmful emissions into the atmosphere, simplifies the design of the boiler and increases the service life, and can be used in heat supply systems for industrial and residential buildings.

The lower longitudinal collectors of the boiler are connected with the longitudinal collectors located on the front and rear fronts of the boiler, and serve as jumpers for transporting the coolant between the sections. The sections are equipped with plugs to change the flow direction. Under the rear screen there is a manifold of the sharp blast system, made of a pipe with fixed nozzles, located at an angle of two tiers. The flow formed by the nozzles improves heat transfer in the radiant part of the hot water boiler, this is achieved by increasing the residence time of flue gases, as well as their speed, creating flow turbulence. The convective part of the boiler is equipped with rotary chambers, which are located in the convective gas ducts, contain rectilinear transversely streamlined in-line tube bundles, having four passes. The reduction of harmful emissions into the atmosphere is achieved by the complete combustion of fuel in the combustion chamber of the boiler, the lengthening of the path of flue gases and separation in the convective part of the boiler, the simplification of the design and the increase in the life of the boiler due to the reduction of ash wear and eolian drift on the pipes in the convective part of the boiler, which also gives increase in heat transfer. A more complete use of the heat of flue gases is also achieved by creating a countercurrent-cross current along the gas and heated medium (water) with a multi-pass change in the direction of the flow of media. The intensification of convective heat transfer contributes to a deeper cooling of the heating medium in the furnace, which leads to an increase in its reliability.

The utility model is illustrated by drawings, which show:

- in Fig. 1 shows the side view of the boiler

- in Fig. 2 shows the front view of the boiler

- in Fig. 3 shows a top view of the hot water boiler;

- in Fig. 4 shows a sectional view of the hot water boiler from the front;

- in Fig. 5 shows a top sectional view of a hot water boiler;

- in Fig. 6.7 shows sections of a hot water boiler;

- in Fig. 8 shows the hydraulic diagram of the hot water boiler.

The boiler is made in a light brickwork, contains a furnace 1, a base 25 of the boiler, a space that is limited by a furnace grate 2. The furnace grate 2 is designed for burning fuel (a fixed grate can be used, a mechanized furnace with a screwing bar, a straight-running belt furnace and etc.). The boiler also contains front 3, ceiling 4 and rear 5 screens, two side 6 and 7 (left and right) convection blocks.

The front screen 3 and the ceiling furnace screen 4 are made in the form of an L-shaped panel of horizontal and vertical pipes, the ends of which are connected by risers 14, 15, 16 with a water supply unit 27 to the boiler. The rear screen 5 is presented in the form of a pipe L-shaped panel with transverse rectilinear collectors 17, 18 and a water outlet 19 from the boiler. Under the collector 18 there is a collector of the system of sharp blast 35, made of a pipe with fixed nozzles, arranged at an angle in two tiers.

Side 7 furnace screens are made as convective blocks, hydraulically connected with the corresponding upper 8 and lower 9 longitudinal collectors of the boiler with the possibility of successive upward and downward movement of water through them.

The convective block 11 includes two convective flues 20, which are divided into four gas passages. The gas ducts are separated from each other by finned tube panels 21, mounted in the space of the convective block 7, provided with appropriate openings for the passage of gases. The heat exchange surfaces of the convective block contain transversely streamlined tube bundles 22 hydraulically connected by the longitudinal collectors of the boiler. The heat exchange surfaces of the convective block contain vertical risers 23, each of which is in communication with the upper 8 and bottom 9 longitudinal collectors of the boiler, and each vertical riser 23 is separated by horizontal partitions 24.

Gas ducts 12 ensure the movement of gas to the outlet gas window 26. There are vertical risers 13 for pumping water. Water moves through the pipe 27 of the water inlet along the screens 4, horizontal pipes 28, pipes of the front screen 29, horizontal pipes 30 of the boiler base, through the pipes 31 along the lower 9 and 10 longitudinal collectors, side 6 furnace screens, through the rolls 33 enters the rectilinear collector 17 and the lower collector 18 into the water outlet assembly 19.

Mechanical cleaning of pipe surfaces of convective gas ducts is carried out through removable hatches 31 and 32, made on the front and rear fronts of the boiler. To clean the boiler, an ash removal channel 34 is provided in the lower part.

The claimed device works as follows.

The boiler is mounted on a base 25, installed under the longitudinal lower collectors 9. The furnace grate 2 and its units have an independent body and a support frame, and can be mounted and dismantled, if necessary, without violating the installation position of the boiler. The combustion of fuel is carried out in a known manner on the furnace grate 2.

Flue gases, under the influence of sharp blast nozzles, which swirl the flow, wash the screens from the space of the furnace 1, enter the convective block 11. Its convective gas ducts 12 provide first downward and then upward movement of gases to the outlet gas window 26 and further into the vortex cyclone, equipped with an entrainment return system. In the process of moving gases, the latter give up their heat to the water pumped through the vertical risers 13. In this case, the water in the heat-removing elements moves as follows: enters through the pipe 27 of the water inlet into the boiler, then enters the cavity of the ceiling screen 4, then through the longitudinal horizontal pipes 28 (ceiling screen) enters the cavity of the front screen 29, from where it enters the horizontal pipes 30 of the boiler base, then, through the coils 31, it is transferred to the lower 9 and 10 longitudinal collectors of the boiler, and passes through the side 6 furnace screens of the boiler in two symmetrical flows, making lifting downward movements along the sections formed in the vertical risers 15 by horizontal partitions 16. Further, water through the rolls 33 enters the rectilinear collector 17, located at the rear screen 4 of the boiler, is redirected through pipes to the lower collector 18 and to the hot water outlet assembly 19 (which is designed for dispensing hot water from the boiler).

Mechanical cleaning of pipe surfaces of convective gas ducts is carried out through removable hatches made on the front and rear fronts of the boiler 31, 32. Removal of slag and ash from the furnace 1 can be carried out in various ways, depending on the design of the combustion device. In this technical solution, in the presence of a direct-running mechanical furnace, slag is discharged into the ash removal channel 34.

Claims (1)

Hot water boiler containing the base of the boiler, the furnace, the space of which is limited by the furnace grate, front and rear screens, ceiling and side furnace screens, the latter of which are made in the form of tube panels hydraulically connected to the corresponding upper and lower longitudinal collectors of the boiler, with the possibility of sequential ascending and downward movement of water along them, as well as two convective blocks, including at least four convective gas ducts, equipped with heat exchange surfaces containing bundles transversely streamlined by tube collectors, hydraulically connected to the longitudinal collectors of the boiler, characterized in that the lower longitudinal collectors of the boiler are connected transverse collectors placed on the front and rear fronts of the boiler, while the heat exchange surfaces located in the convective gas ducts contain rectilinear transversely streamlined in-line tube bundles containing vertical risers, each of which is connected with the corresponding upper and lower longitudinal collectors of the boiler, and each vertical riser is divided by horizontal partitions into vertical sections, the ends of each riser are connected with the second and third pair of longitudinal boiler collectors, while its upper and lower interfaces with the said collectors are blocked by end caps, under the rear screen there is a collector of the system of sharp blast, made of a pipe with fixed nozzles, located at an angle of two tiers.

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