RU2477824C1 - Hot-water boiler - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: proposed hot-water boiler includes a housing with a furnace, water-wall panels, a gas duct and a water-tube heat exchanger made of tubes in the form of a coil, which are connected with taps; the housing walls are located with a gap relative to panels; tubes are located as to height at least in two parallel rows in a staggered order in the furnace above burners; tube ends are installed in the front and rear panels with possibility of being moved relative to them during heating; taps are taken beyond the furnace boundary and located between water-wall panels and the front and rear boiler water walls; burners are of injection type and located horizontally in a row in the furnace bottom part and connected to a gas header located between the front wall and the front water-wall panel and connected to an automation unit with a pressure sensor and a temperature sensor located in the furnace, and gas duct is installed on top water-wall panel closer to the rear water-wall panel.

EFFECT: improving maintainability and reliability of hot-water boiler with simultaneous improvement of its efficiency due to reduction of heat losses at water heating.

4 dwg

Description

The invention relates to the field of heat engineering and can be used for heating residential buildings, buildings for communal household and industrial purposes, having a heating system with a water coolant.

A well-known hot water boiler containing a housing with a firebox, an injection gas burner, a gas duct and a water jacket covering the firebox and gas duct (see US patent No. 6561182, class F24H 1/20, 05/13/2003).

The disadvantages of this device are the low manufacturability, low maintainability and, as a result, the design of the hot water boiler that is difficult to operate.

Closest to the invention in technical essence is a hot water boiler, comprising a housing with a firebox with shielding panels, a gas duct, and a water pipe heat exchanger made in the form of a coil with horizontal, finned and connected by taps pipes, and from the input side the coil is connected to the supply pipe, and from the exit side - to the branch pipe (see certificate for utility model RU No. 29125, class F24H 1/40, 04/27/2003).

This boiler has a relatively simple design. However, the location of the furnace, convection surface and gas duct along the horizontal axis leads to significant axial dimensions, which in some cases leads to the need to increase the area of the room where this boiler is operated. In addition, the location of all the pipes of the coils entirely inside the boiler makes it difficult to monitor the condition of the welded joints at the point of connection of the bends, which complicates the maintenance of this boiler.

The problem to which the invention is directed, is to increase the maintainability, reliability and efficiency of the boiler.

EFFECT: increased maintainability and reliability of a hot water boiler with a simultaneous increase in its efficiency due to a decrease in heat losses during its transfer to water heated in a water heat exchanger.

The problem is solved, the technical result is achieved due to the fact that the hot water boiler includes a housing with a firebox with shielding panels, a gas duct, and a water pipe heat exchanger made in the form of a coil with horizontal, finned and connected by taps pipes, and from the input side the coil is connected to the pipe inlet and outlet side - to the branch pipe, the housing is made rectangular with front, rear, upper and two side walls located with a gap relative to the corresponding screens of anizing panels, the pipes are arranged in height in at least two parallel rows in a staggered pattern in the furnace above the burners, the pipe ends are installed one in the front and the second in the rear shielding panels with the ability to move relative to them when heating or cooling, the bends are outside the furnaces are located between the shielding panels and the front and rear walls of the boiler, the inlet and outlet pipes are removed from the furnace through the rear shielding panel and the rear wall of the housing, the burners are injection, they are located horizontally in a row at the bottom of the furnace and connected to a gas manifold located between the front wall and the front shielding panel and connected via a gas pipeline to the automation unit with a pressure sensor and a temperature sensor located in the furnace, openings are made in the lower, located under the burners, shielding panel supply from below to atmospheric air burners, and the gas duct is installed on the upper shielding panel closer to the rear shielding panel.

Figure 1 presents a General view of the boiler.

Figure 2 presents a rear view of the boiler with a partially removed rear wall.

Figure 3 presents a front view of the boiler with the front, upper and side walls removed.

Figure 4 presents a front view of the boiler with the front, upper and side walls, as well as the upper and side shielding panels removed.

The water boiler includes a housing 1 with a furnace 2 with shielding panels: front 3, rear 4, top 5, two side 6 and bottom 7, a gas duct 8, and a water tube heat exchanger 9 made in the form of a coil with horizontal, finned and connected by taps 10 pipes 11. On the input side, the coil is connected to the supply pipe 12 and on the output side to the pipe connection 13. Housing 1 is made rectangular with front 14, rear 15, upper 16 and two side 17 walls located with a gap relative to the corresponding shielding panel she 3, 4, 5 and 6. The pipes 11 in height are located at least in two parallel rows in a checkerboard pattern in the furnace 2 above the burners 18. The ends of the pipes 11 are installed one in the front 3 and the second in the rear 4 shielding panels with the possibility movements relative to them during heating or cooling. Taps 10 are removed outside the furnace 2 and are located between the shielding panels: front 3 and rear 4 and front 14 and rear 15 walls of the boiler. The nozzles of the inlet 12 and outlet 13 are removed from the furnace 2 through the rear shielding panel 4 and the rear wall 15 of the housing 1. The burners 18 are injection, arranged horizontally in a row at the bottom of the furnace 2 and connected to a gas manifold 19 located between the front wall 14 and the front a shielding panel 3 and connected via a gas pipeline 20 to the automation unit 21 with a pressure sensor and a temperature sensor located in the furnace (not shown in the drawings). In the lower screening panel 7 located under the burners 18, openings 22 are made for supplying atmospheric air to the burners 18 from below, and the gas duct 8 is installed on the upper screening panel 5 closer to the rear screening panel 4.

Thanks to the proposed design solution, the finned tubes 11 of the water-tube heat exchanger 9 can freely extend without creating any stresses, withstanding an unlimited number of heating and cooling cycles. The design is made collapsible with easily removable walls of the boiler body, which does not require additional restoration of insulation and can reduce the time for technological inspection and repair of the boiler.

The hot water boiler operates as follows.

Mains water through the inlet pipe 12 enters the pipes 11 of the water-tube heat exchanger 9. Having passed sequentially through the pipes 11, the heated water through the branch pipe 13 is supplied to the consumer. The finned tubes 11 of the water-tube heat exchanger 9 are mounted with the possibility of movement relative to the shielding panels 3 and 4, which makes it possible to compensate for the loads arising due to the linear elongation during heating of the pipes 11. The water in the pipes 11 of the water-tube heat exchanger 9 is heated by the flue gases generated by the combustion of gas in the burners 18. Flue gases wash the finned tubes 11 and then leave the furnace 2 through the gas duct 8.

This boiler has the following advantages:

- the boiler is convenient in operation and maintainable, since any failed pipe or part of the flow distributor can be freely dismantled and replaced with a new one directly in the boiler room without special devices;

- finned tubes of a water-tube heat exchanger can freely extend without creating any stresses;

- the design of the heat exchanger provides for the possibility of sudden cooling and heating of pipes without the occurrence of mechanical stresses, withstanding an almost unlimited number of heating and cooling cycles;

- the boiler furnace has a minimum aerodynamic drag, which allows selecting burners of a smaller size and reducing the noise level when the burner is operating at full power;

- collapsible design of the boiler walls does not require additional restoration of insulation and reduces repair time;

- pipe bends moved outside the furnace to facilitate access during repair and technological inspections.

This water tube boiler was tested on the basis of LLC "Plant of boiler equipment", Tuymazy.

Claims (1)

A hot water boiler, comprising a housing with a firebox with shielding panels, a gas duct and a water tube heat exchanger made in the form of a coil with horizontal finned and connected by taps, the coil is connected from the input side to the inlet pipe and from the outlet side to the outlet pipe, characterized in that the casing is made rectangular, with front, rear, upper and two side walls located with a gap relative to the corresponding shielding panels, the pipes are arranged in height at least in two parallel rows in a staggered pattern in the furnace above the burners, the ends of the pipes are installed one in the front and the second in the rear shielding panels with the ability to move relative to them when heating or cooling, the bends are outside the furnace and are located between the shielding panels and the front and rear the walls of the boiler, the inlet and outlet pipes are removed from the furnace through the rear shielding panel and the rear wall of the housing, the burners are made of injection, are arranged horizontally in a row at the bottom of the furnace and are connected to to the collector located between the front wall and the front shielding panel and connected via a gas pipeline to the automation unit with a pressure sensor and a temperature sensor located in the furnace, in the lower shielding panel located under the burners there are holes for supplying atmospheric air from below to the burners, and the gas duct is mounted on the top shielding panel closer to the rear shielding panel.

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