RU169893U1 - WATER BOILER - Google Patents

Abstract

The utility model relates to the field of heat engineering and can be used for heating residential buildings and other buildings. The task to which the utility model is directed is to reduce the hydraulic resistance of the boiler and, as a result, increase its efficiency, reduce operating costs, increase reliability. The technical result is achieved by reducing the hydraulic resistance of the heat exchanger and creating a turbulent flow of water inside the pipes of the heat exchanger. A water boiler, including a housing 1 with a furnace 2 with shielding panels (3, 4, 6, 7), a gas duct 8 and a water pipe heat exchanger 9, the pipes of which are arranged in height in two parallel rows 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, taps 12 are outside the furnace and are located between the shielding panels and the front and rear walls of the boiler, and the boiler heat exchanger is formed by two horizontal pipes (collectors) of supply 10 and return 11 and connected horizontally to them with finned and interconnected pipes 12. Return manifold 11 has a metal spiral inside, which is connected on one side through flange 14 to collector flange 15. The free ends of the supply manifold 17 and return manifold 18 have removable flange plugs 19 for servicing the boiler . The boiler body is made in the form of a rectangular parallelepiped with a back 20, top 21, two side 22 and front 23 walls having a layer of thermal insulation. The ends of the collectors with flanges 15, 16, 17, 18 are led out through the rear wall of the boiler body, while the collectors 10, 11 themselves are located between the shielding rear panel 4 and the rear wall of the boiler 20. Grooves 24 for supplying atmospheric air are made in the bottom shielding panel 7. The boiler is controlled and the parameters of the boiler room are controlled through a freely programmable controller 27 installed on the top panel of the boiler 21. 12 cp f-ly, 5 ill.

Description

The utility model relates to the field of heat engineering and can be used for heating residential buildings, communal, domestic and industrial buildings, 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 (RU 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.

A water-heating boiler is known, including 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 pipes, and from the input side the coil is connected to the supply pipe, and from the output side to the pipe connection ( 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 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 tube 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 output side - to the branch pipe (utility model RU 2477824 C1, class F24H 1/40 07/06/2011).

The disadvantage of the prototype is the design of the heat exchanger of the boiler in the form of a single coil having a large hydraulic resistance. The energy spent on overcoming the high hydraulic resistance of a single coil reduces the boiler efficiency.

The task to which the utility model is directed is to reduce the hydraulic resistance of the boiler and, as a result, increase the efficiency of the boiler.

The technical result is an increase in boiler efficiency by reducing the hydraulic resistance of the heat exchanger, creating a turbulent flow of water inside the pipes of the heat exchanger.

The problem is solved, and the technical result is achieved due to the fact that the hot water boiler includes a heat exchanger made in the form of two horizontal pipes (collectors) of water supplied from the boiler (supply) and water returned to the boiler (return) with horizontal finned connected to them and pipes connected by taps in such a way that the decrease in the hydraulic resistance of the boiler by splitting the water flow into parallel flows is combined with ensuring a sufficient passage speed ode through the heat exchange tubes. The number of loops formed by horizontal finned tubes connected to the supply and return manifolds is calculated, including, in accordance with the required boiler output. The return collector is connected at one end to the pipe of the water returned to the boiler through the connecting flange of the metal spiral, which creates a turbulent flow of water inside the entire heat exchanger, intensifying the heat exchange process. The supply manifold is connected at one end to the nozzle for receiving hot water from the boiler. The free ends of the feed manifold and return manifold have removable flange caps and are used to service the boiler. A device for flushing the boiler heat exchanger from scale is connected to the free ends of the return manifold and the supply manifold in accordance with the boiler maintenance cycle. The collectors of the boiler have the possibility of axial connection with the collectors of similar boilers, creating a single cascade of boilers along the axis of the collectors, while reducing the dimensions of the boiler room.

The claimed utility model is illustrated by drawings.

In FIG. 1 shows a general view of a boiler.

In FIG. 2 is a rear view of the boiler with the rear wall removed.

In FIG. 3 shows a front view of the boiler with the front, top and side walls removed.

In FIG. 4 shows a front view of the boiler with the front, top and side walls, as well as the top and side shielding panels removed.

In FIG. 5 shows the heat exchanger of the boiler.

The hot 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, the duct pipe 8 and the tube heat exchanger 9, FIG. 5, formed by two horizontal pipes (collectors) of supply 10 and return 11 and connected to them by horizontal finned and interconnected by branches 12 pipes 13, the collector of return 11 has a metal spiral inside, which is connected on one side through flange 14 to collector flange 15 and, on the other hand, with a pipe for returning water to the boiler, the supply manifold 10 is connected through the flange 16 at one end to the hot water intake pipe from the boiler, the free ends of the supply manifold 17 and the return manifold 18 dissolved removable stub flange 19 for maintenance of the boiler. The boiler body is made in the form of a rectangular parallelepiped with a rear 20, upper 21 and two side walls 22 having a thermal insulation layer and located as close as possible to the shielding surfaces of the boiler, and a front wall 23 having partial thermal insulation and a partial air gap with a front shielding surface 3, the feed headers 10 and return 11 are removed from the furnace through the rear shielding panel 4, the ends of the collectors with flanges 15, 16 are led out through the rear wall of the housing 20 to the right side of the boiler, and the ends with flanges 17, 18 to the left side of the boiler, while the collectors 10, 11 themselves are located between the shielding rear panel 4 and the rear wall of the boiler 20. Grooves 24 are made in the lower shielding panel 7 for supplying air from below, and the duct pipe 8 is mounted on the upper shielding panel 5. B the furnace of the boiler 2 is a burner 25, selected in proportion to the required power and furnace geometry of the boiler. To do this, a hole is cut out in the front shielding panel 3 and fasteners are provided depending on the type of burner used. The gas train, which also includes gas solenoid valves 26, is selected and placed on the boiler depending on the type of burner (s) used. The boiler is controlled and the parameters of the boiler are controlled through a freely programmable controller 27 installed on the top panel of the boiler 21 and having the option of weather-dependent cascading steps of the boiler burner (or several burners in the cascade), as well as remote monitoring and control of the boiler via the Internet, via SMS messages or radio channel. The front shielding panel of the boiler has a hole under the burner plate 28.

The hot water boiler operates as follows. Mains water through a metal spiral with a flange 14 first falls into the collector of the return 11, taking the turbulent nature of the movement through the spiral, and then is distributed through the pipes of the tube heat exchanger 13. Depending on the number of loops connected to the collectors 11 and 10, formed by horizontal finned tubes 13 and by bends 12, the number of parallel flows of water passing through these loops formed by horizontal finned tubes 13 and bends 12 varies. This connection allows you to adjust (correctly ive) the hydraulic resistance of the heat exchanger compared to a heat exchanger made in the form of a single coil, where adjustment (adjustment) is impossible. A small metal spiral with flange 14 breaks the laminar flow of water, turning it into a turbulent one, thereby intensifying the heat transfer process. Passing through the finned tubes 13, heated water enters the supply manifold 10 and then is supplied to the consumer. The finned tubes 13 of the water-tube heat exchanger are mounted with the possibility of movement relative to the shielding panels, which makes it possible to compensate for the stresses arising from linear elongation during heating of the pipes. The water in the pipes of the water-tube heat exchanger is heated by the flue gases generated by the combustion of gas in the furnace. Flue gases wash the finned tubes 13 and then leave the furnace through the flue pipe 8. The temperature of the water depending on the outdoor temperature or the air temperature in the heated rooms is controlled by the controller 27 by turning on / off the thermostat circuits of the gas valves 26 of the burner stages of the boiler 25 or, in in case of using burners with infinitely adjustable gas supply, by controlling the burner itself by supplying a control signal to the burner control unit.

This boiler has the following advantages:

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

- the boiler is convenient in operation and maintainable, since for maintenance of the burner it is not necessary to remove the shielding panels of the boiler, but rather remove the entire burner by disconnecting the burner plate from the front shielding panel of the boiler;

- 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;

- the front shielding panel of the boiler has the ability to install various types of burners;

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

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

- the design of the heat exchanger of the boiler has a low hydraulic resistance, which increases the efficiency of the boiler;

- due to the presence of collectors, the boiler is convenient in operation: for washing the boiler, it is not necessary to disconnect the pipes from the supply and return pipes, for this purpose the free ends of the collectors are used;

- boiler collectors have the ability to connect to collectors of similar boilers, creating a single cascade of boilers along the axis of the collectors, while reducing the size of the boiler room;

- due to the presence of a freely programmable controller, the boiler has the ability to logically control the temperature of the water leaving the boiler, depending on the requirements of the consumer, as well as the ability to remotely control and control the boiler;

- thanks to the availability of a freely programmable controller, the boiler is easily integrated into existing boiler houses, while the consumer has the opportunity to systemically control the electric drives of the boiler units in a single controller program logic.

The hot water boiler can be manufactured on standard equipment using modern materials and technologies.

Claims (13)

1. A hot water boiler, comprising a rectangular housing with front, rear, upper and two side walls, located with a gap relative to the shielding panels, with a furnace, gas duct and a water pipe heat exchanger, the pipes of which are arranged in height in two parallel rows in the furnace above the burners, the ends of the pipes one is installed in the front and the second in the rear shielding panels, the taps are led outside the firebox and are located between the shielding panels and the front and rear walls of the boiler, the burner is located at the bottom of the firebox and It is connected to a gas manifold located between the front wall and the front shielding panel and connected via a gas pipeline to an automation unit with a pressure sensor and a temperature sensor located in the furnace, the gas duct is installed on the upper shielding panel, characterized in that the boiler heat exchanger is formed by a supply manifold and a return manifold and connected to them by horizontal finned and interconnected by means of branches by pipes. 2. The hot water boiler according to claim 1, characterized in that the boiler burner is made as a single removable element, which includes at least one burner cylinder and a flat steel segment to which this cylinder is fixed, and the burner itself is mounted with a stove to the front screen panel boiler. 3. The hot water boiler according to claim 1, characterized in that the supply and return manifolds are made in the form of two pipes with the possibility of welded connection of finned pipes through bends. 4. The boiler according to claim 1, characterized in that the return manifold contains a metal spiral inside. 5. The hot water boiler according to claim 1, characterized in that the supply and return manifolds are connected to a certain number of finned horizontal pipes located in planes perpendicular to the collector plane. 6. The boiler according to claim 1, characterized in that the supply and return manifolds are located between the rear shielding panel of the boiler and the rear wall of the boiler. 7. The hot water boiler according to claim 1, characterized in that the ends of the collectors are brought out to the right and left through the rear wall of the boiler. 8. The boiler according to claim 1, characterized in that the free ends of the feed collector and return manifold are equipped with removable plugs for servicing the boiler. 9. The hot water boiler according to claim 1, characterized in that the boiler body is made in the form of a rectangular parallelepiped with a front, back, top and two side walls having thermal insulation. 10. The hot water boiler according to claim 1, characterized in that it has a freely programmable control and monitoring controller, which is located on the upper wall of the boiler. 11. The boiler according to claim 1, characterized in that the front shielding panel of the boiler has an opening for the burner plate. 12. The boiler according to claim 1, characterized in that the flue pipe is located in the center of the upper shielding panel. 13. A water boiler according to claim 1, characterized in that grooves for air passage are made in the lower shielding panel located under the burners.

Images