RU2187763C1 - Hot-water boiler - Google Patents

Abstract

FIELD: heat power engineering, applicable in boiler units, mainly in self-contained and roof- mounted boiler rooms. SUBSTANCE: the hot-water boiler has a casing with a cover, burner fastened in the central part of the cover, the casing accommodates a water reservoir, furnace, flue gas rotary chamber and fire tubes communicating through the inlet sections with the flue gas rotary chamber, and through the outlet ones-with the flue gas header connected to the chimney, water header positioned in the bottom part of the boiler, heating elements in the form of tubes, each positioned in the fire tube form of tubes, each positioned in the fire tube with an annular gap, the inlet ends of the heating elements are connected to the water supply pipe-line, and the outlet ends - to the boiler water reservoir. According to the invention, gas flow turbulators are installed in the ducts formed by the annular gaps between the heating elements and the fire tubes, the gas flue rotary chamber is formed by the bottoms of the water reservoir and furnace, the inlet ends of the heating elements are connected to the water supply pipe-line through the water header, and the outlet ends - directly to the water reservoir, the water header is formed by the bottoms of the boiler and furnace, and the flue gas header - by the boiler cover and the water reservoir surfaces facing the cover. EFFECT: enhanced efficiency of heat pick-up, simplified construction, reduced mass and overall dimensions of the boiler. 4 cl, 3 dwg

Description

 The invention relates to a power system and can be used in boiler units, mainly in stand-alone and roof boiler rooms.

 Known vertical water boiler [1] containing placed in the body of the furnace, the central gas duct and water jackets located concentrically in each other with the formation of gaps for the passage of gases. One gap is connected in series with the gas collector and with the chimney. The housing is bounded by top and bottom bottoms. The cold water supply pipe is connected to the lower bottom, and the hot water discharge pipe is connected to the upper bottom. When heated, the water rises into the cavity of the upper bottom, where the mixing of flows having an uneven temperature takes place, after which it enters the consumer’s hot water pipeline.

 The disadvantage of this device is its low reliability due to uneven heating of individual sections of the boiler, as well as the complexity and high metal consumption of the structure, due to the need to organize numerous channels for the passage of flue gases.

 Also known is a hot water boiler [2], containing a sealed housing filled with water, inside of which there is a firebox, heat and smoke pipes. To intensify heat transfer, smoke tubes are equipped with screw inserts that contribute to the turbulization of flue gases, which improves heat transfer.

 The disadvantage of this boiler is the complexity of the design, as well as the inefficient use of the heat of the burned fuel due to the small heating surface, since only the outer walls of the flame and smoke tubes are involved in the heating of the water.

 The closest set of essential features to the proposed technical solution is a hot water boiler [3]. The boiler contains a housing with a lid and a burner fixed in the central part of the lid. The body contains a water volume, a combustion chamber, a rotary flue gas chamber formed by the boiler lid and the end part of the water volume facing the lid, smoke tubes communicated by the inlet sections with the flue gas rotary chamber, and the outlet pipes with the flue gas collector connected to the chimney , a water collector located in the bottom of the boiler, and heating elements. The latter are made in the form of Field tubes. Each outer pipe of the heating element is placed with some clearance in the smoke tube. The inner pipes of the heating element with the inlet ends are directly connected to the water supply pipe, and the outlet ends of the outer pipes are connected to the water collector. The cavity of the water collector is connected by a pipeline to the water volume of the boiler, equipped with a discharge pipe.

 The known device allows to increase heat removal due to a sufficiently developed area of the heated surface.

 The disadvantages of the device include the low efficiency of heat removal, the relative complexity of the design and, as a result, the increased weight and dimensions of the boiler.

 The lack of heat removal efficiency is due to the following.

 Firstly, the water entering through the supply pipe into the inner pipes of the heating elements, moving through them, is heated by the water located in the annular gap between the outer and inner pipes, which is ineffective, since there is no direct contact of the water with the heat of the flue gases. Further, at the exit from the inner pipe of the heating element, the direction of water movement is reversed, it enters the channel formed by the annular gap between the pipes of the heating element and, moving along it, is heated by the heat of the flue gases. However, with this organization scheme, the gas flow and flue gases in the smoke pipe move in the same direction, and this reduces the heat transfer efficiency, since it is known that the heat transfer is greater when the heating medium is heated up and down.

 In addition, in the design of the boiler, with the exception of installing heating elements inside smoke tubes, no special means are provided for increasing the efficiency of heat removal.

 Finally, the heated water is cooled when moving from the water collector to the water volume through a pipe outside the boiler.

 The complexity of the device is due to the complexity of the design of the heating elements, the need to install partitions to organize the cavity of the flue gas collector, the presence of a special pipeline for moving water from the water collector to the water volume.

 The implementation of the heating elements in the form of Field pipes, the presence of the indicated partitions and the pipeline increase the mass of the device, and the latter - and its dimensions, as it is located outside the boiler body.

 The technical result of the invention is to increase the efficiency of heat removal, simplifying the design, reducing the weight and dimensions of the boiler.

 The specified technical result is achieved in that in a water boiler containing a housing with a lid, a burner fixed in the central part of the lid, a water volume, a combustion chamber, a rotary flue gas chamber and smoke tubes communicated by the inlet sections with a rotary flue gas chamber, and weekend - with a flue gas collector connected to the chimney, a water collector located in the bottom of the boiler, heating elements in the form of pipes, each of which is placed with an annular gap in the smoke a pipe, wherein the inlet ends of the heating elements are connected to the water supply pipe and the outlet ends to the boiler water volume, according to the invention, gas flow turbulators are installed in the channels formed by annular gaps between the heating elements and the smoke tubes, the rotary flue gas chamber is formed by the bottoms of the water volume and the combustion chamber, the inlet ends of the heating elements are connected to the inlet pipe through a water collector, and the exhaust ones directly to the water emu, wherein the water reservoir is formed by the bottoms of the boiler and the combustion chamber and the flue gas collector - cover of the boiler and facing the cover surfaces of the water volume.

 In addition, the gas flow turbulators are made in the form of annular protrusions on the inner surface of the smoke pipe, placed at an equal distance from each other along its length.

 The protrusions can be formed by annular extrusions of the material of the smoke tube.

 Gas flow turbulators can also be made in the form of annular protrusions on the outer surface of the heating element, placed at an equal distance from each other along its length.

 The given set of essential features made it possible to organize the optimal scheme of gas and water flows in the boiler. The main heat transfer from flue gases to water is carried out in a counterflow of heating and heated media.

 The placement of gas flow turbulators in the channels formed by annular gaps between the heating elements and the smoke tubes significantly (2-2.5 times) increases the efficiency of heat removal. The implementation of turbulizers in the form of annular protrusions on the inner surface of the smoke tube or the outer surface of the heating element is most appropriate when they are placed in a narrow space of the annular gap.

 In addition, due to the above implementation and the relative positioning of the boiler elements, while ensuring the participation of both external and internal surfaces of the smoke tubes in the heat transfer, it was possible to significantly simplify the device and reduce its weight and dimensions.

 The invention is illustrated by graphic materials, where figure 1 shows a schematic representation of a General view of the boiler; figure 2 - remote element I in figure 1; figure 3 - remote element I in figure 1 with a variant of placement of the gas flow turbulators.

 The hot water boiler contains a housing 1 with a cover 2. In the central part of the cover 2 there is a gas burner 3. In the housing 1 there is a water volume 4, a combustion chamber 5, a rotary chamber 6 of flue gases, smoke tubes 7. The inlet sections of the smoke tubes 7 are in communication with a rotary chamber 6 flue gases formed by the bottoms of the water volume 4 and the combustion chamber 5, and the weekend with a collector 8 flue gases. The flue gas collector 8 formed by the boiler cover 2 and the surfaces of the water volume 4 facing the cover 2 is connected to the chimney (not shown in the drawings). In the bottom of the boiler there is a water collector 9 formed by the bottoms of the boiler and the combustion chamber 5. The boiler is equipped with heating elements 10 in the form of pipes, each of which is placed with an annular gap 11 in the smoke pipe 7. The inlet ends of the heating elements 10 are connected to the water supply pipe 12 through the water collector 9, and the exhaust ones directly to the water volume 4. In the channels formed by the annular gaps 11, gas flow turbulators are installed. The latter are made in the form of annular protrusions 13 mounted either on the inner surface of the smoke tubes 7 or on the outer surface of the heating elements 10, and are placed at an equal distance from each other along the length of the channels. In order to simplify and improve manufacturability in the first case, the protrusions are formed by annular extrusions of the material of the smoke tube 7.

 The operation of the boiler is as follows.

 After filling the boiler’s water system, a gas burner 3 is ignited. As the water heats up, water is supplied through the supply pipe 12 to the water collector 9, in communication with the inlet ends of the heating elements 10, and enters directly into the water volume 4. After passing the water volume 4, water flows through the outlet pipe to the consumer.

 Hot flue gases generated during the operation of the gas burner 3, heat the water, passing sequentially the combustion chamber 5, the rotary chamber 6 formed by the outer surface of the heating elements 10 and the inner surface of the smoke tubes 7 ring channels with gas flow turbulators placed in them, and a collector 8 flue gas associated with a chimney.

 Thus, the preliminary heating of the water is carried out in the water collector 9 and the heating elements 10, while inside the heating elements 10, the heating is carried out directly from the heat of the flue gases. Turbulization of the gas stream in the channels formed by the annular gaps 11 intensifies this process. From the heating elements 10, water enters directly into the water volume 4, when passing through which the main heating of the water occurs. Since heat transfer in this section of water passage occurs under conditions of direct contact and counterflow of heating and heated media, as well as turbulization of the flue gas stream, the heat transfer efficiency increases significantly.

The implementation of the proposed technical solution for a hot water boiler allows heat removal under conditions when:
- in the process of heat transfer, both external and internal surfaces of the smoke tubes are involved, while almost the entire volume of flue gases passes through the zone of active heat transfer;
- water throughout its entire path is heated directly from the heat of the flue gas stream;
- due to the turbulization of the flue gas flow, the heat transfer process has been intensified both at the stage of preliminary and basic heating of water;
- the main heat removal is carried out in countercurrent heating and heated environments.

Sources of information
1. RF patent 2052733, IPC F 24 H 1/24, publ. 1996 year

 2. Copyright certificate of the USSR 1543183, IPC F 22 B 7/12, publ. 1987 year

 3. RF patent 2116579, IPC F 24 H 1/00, 1998 - prototype.

Claims (4)

 1. A water boiler comprising a housing with a lid, a burner fixed in the central part of the lid, a water volume, a combustion chamber, a rotary flue gas chamber, and smoke tubes communicated by the inlet portions with the rotary flue gas chamber and the outlet sections with a flue gas collector associated with the chimney, a water collector located in the bottom of the boiler, heating elements in the form of pipes, each of which is placed with an annular gap in the smoke pipe, with the inlet ends of the heating element They are connected to the water supply pipe, and the exhaust pipes are connected to the boiler water volume, characterized in that gas flow turbulators are installed in the channels formed by annular gaps between the heating elements and the smoke tubes, the flue gas rotary chamber is formed by the bottoms of the water volume and the combustion chamber, and the inlet the ends of the heating elements are connected to the inlet pipe through a water collector, and the outlet ones are directly connected to the water volume, while the water collector is formed by bottoms of la and a combustion chamber, a flue gas collector - the boiler cover and to the lid facing surfaces of the water volume.  2. The boiler according to claim 1, characterized in that the gas flow turbulators are made in the form of annular protrusions on the inner surface of the smoke tube, placed at an equal distance from each other along its length.  3. The boiler according to claim 2, characterized in that the protrusions are formed by annular extrusions of the material of the smoke tube.  4. The boiler according to claim 1, characterized in that the gas flow turbulators are made in the form of annular protrusions on the outer surface of the heating element, placed at an equal distance from each other along its length.

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