KR20090036209A - Boiler heat exchange directly from combustion heat - Google Patents

Abstract

The present invention relates to a boiler and to a boiler having improved heat efficiency as compared with a conventional boiler which performs heat exchange by directly contacting combustion heat and boiler heating water (water) to exchange heat through an indirect water pipe.

The present invention provides a boiler having excellent heat efficiency by making heat exchange by directly contacting the heating water with the heat of combustion of the boiler generated by burning the fuel, and the heat exchanger from the combustion heat to easily manage the inside of the combustion chamber by excluding water pipes In order to provide a boiler which performs heat exchange directly from the heat of combustion, which achieves a primary heating water heating in the upper part of the combustion chamber and a second heating contacting the heating heat and the heating water in the lower part of the combustion chamber, thereby increasing heat exchange efficiency. Forms a cylindrical chamber 10 and forms an internal compartment of an empty space, and forms a combustion chamber 20 spaced apart from the upper chamber above the compartment to form a burner 22 under the combustion chamber, from the combustion chamber 20 The hot air chamber 24 for discharging the combustion heat downwardly and discharged is provided, and the heating water tank 30 is disposed above the hot air chamber 24. By forming a plurality of mixing nozzles 40 for mixing the bottom heating water of the water chamber 10 and the combustion heat of the hot air chamber 24 to discharge the outlet of the mixing nozzle to the heating water tank 30 It is characterized in that the boiler to form a heat exchange directly from the heat of combustion, characterized in that to form the exhaust pipe 14 from the top of the tank 30 of the heating water mixed with heat to obtain the heat-exchanged heating water.

Description

Boiler which accomplishes a direct heat exchange}

The present invention relates to a boiler, and more particularly, to a boiler having improved thermal efficiency as compared with a conventional boiler which performs heat exchange by directly contacting combustion heat and boiler heating water (water) to exchange heat through an indirect water pipe.

In general, a boiler is known to achieve heat exchange by circulating water into a heating water pipe by burning fuel for the purpose of controlling an indoor temperature.

In order to improve the thermal efficiency of the boiler, there have been improvements in various combustion control devices as well as mechanical structures such as burners, flues, combustion chambers and water pipes.

However, all conventionally known boilers have a structure in which the combustion heat generated in the combustion chamber is applied to the water pipes, and the heat is indirectly heat-exchanged with the heating water flowing through the water pipes. There are disadvantages.

The water pipe is made of a metal material and heat exchanges with the heating water by heat conduction of the metal. The material of the water pipe is mainly copper or iron-based metal, but no matter how excellent the heat conduction is selected, the indirect heat exchange method is used. Loss is inevitable and thermal efficiency is inevitably reduced.

The present invention has been made to solve the problems of the prior art as described above has the following object.

The present invention provides a boiler having excellent thermal efficiency by performing heat exchange by directly contacting heating water with combustion heat generated by burning a fuel.

The present invention is to provide a boiler in which the heat exchange is performed directly from the heat of combustion, which is easy to manage inside the combustion chamber, excluding water pipes.

The present invention is to provide a boiler that performs heat exchange directly from the heat of combustion that the heat exchange efficiency is increased by performing the primary heating water heating in the upper combustion chamber and the second heating contacting the heating heat and the heating water in the lower combustion chamber.

The present invention made to achieve the above object is a combustion chamber for mixing and supplying combustion combustion air and fuel from the outside of the combustion chamber, a heated heating water tank provided in the center of the water pipe and the water pipe surrounding the combustion chamber, and the inside of the combustion chamber The fuel is combusted to form a first heat exchange with the water pipes in the upper part of the combustion chamber, and the burned hot air moves downward to the hot chamber to make heat exchange by contacting the transferred combustion hot air and heating water through a mixing nozzle, and the heat exchanged heating water is recalled. It is to form a boiler to generate and supply the heating water is made to flow up the spiral guide plate to the top of the heating water tank.

The spiral induction plate embedded in the heating water tank increases the heat exchange residence time of the heating water and is provided to separate the water by aeration of the hot air bubbles contained in the heating water at the top of the induction plate.

According to the present invention made as described above, while heating the hot air by burning the fuel directly in contact with the heating water to mix the heating water and hot air, followed by heat exchange in the upper combustion chamber followed by the heating water and the mixing nozzle in the secondary hot chamber As the heat exchange is performed through the heat exchanger, the heat exchange efficiency is greatly increased as compared with the conventional boiler which performs indirect heat exchange, and thus has a very useful effect as a boiler.

Hereinafter, a technical configuration as a specific embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a cross-sectional view showing the overall configuration of the present invention, FIG. 2 is an enlarged cross-sectional view of the main portion of the mixing nozzle of the present invention, FIG. 3 is an enlarged cross-sectional view of the line "A"-"A" of FIG. 2, and FIG. It is sectional drawing which shows the modified embodiment about a nozzle part.

The present invention forms the chamber 10 of the tubular body as shown in Figures 1 to 3 and forms an inner compartment of the empty space and forms a combustion chamber 20 spaced apart from the upper chamber above the compartment to form a burner 22 below the combustion chamber. And a hot water chamber 24 for discharging and discharging the combustion hot air downward from the combustion chamber 20, and forming a heating water tank 30 on the hot water chamber 24. Heating water mixed with the heat formed by forming a plurality of mixing nozzles (40) for mixing the bottom heating water and the combustion heat of the hot air chamber 24 to discharge the outlet of the mixing nozzle to the heating water tank (30) The exhaust pipe 14 is formed from the upper portion of the tank 30 to the outside to form a boiler that performs heat exchange directly from the heat of combustion to obtain the heat-exchanged heating water.

The heat-exchanged water in the upper portion of the heating water tank 30 is heated and circulated through the circulation motor (M) to recover and recirculate to the upper portion of the water chamber 10.

In order to transfer the heat of combustion of the combustion chamber 20 to the combustion chamber below the water chamber 10, the gas and the combustion air, which are fuels, are mixed and mixed by the mixing compressor 50, and the burner is kept in the compression tank 52 while keeping the compressed mixer in the compression tank 52. It is made to supply a fixed amount to 22.

The heating water tank 30 has a spiral guide plate 32 embedded therein in close contact with the wall of the tank, so that the heating water flows upward while flowing along the spiral guide plate, and the upper portion of the guide plate 32. There is provided a fine perforated bubble removing net 34, such as a mesh.

The mixing nozzle 40 is a heating water induction pipe 42 for discharging the heating water at a lower pressure from the lower side of the water chamber 10, and wrapped in an annular shape along the outer circumference of the heating water induction pipe from the hot air chamber 24 It forms a nozzle structure consisting of a hot air induction pipe 44 installed so that the heat is mixed at the tip of the nozzle by the discharge pressure of the heating water.

The hot air induction pipe 44 of the mixing nozzle 40 is installed around the heating water induction pipe 42 may be made by partitioning its interior into a plurality of compartments (45).

Partitioning the hot air induction pipe 44 into a plurality of compartments is made to form a small droplet mixed with the heat.

On the other hand, the present invention may be made by further configuring a funnel-shaped cap 46 inclined in the same manner as the nozzle inclination angle at the discharge tip of the mixing nozzle 40 as shown in FIG.

Unexplained reference numeral 60 denotes a non-return ballast for preventing the back flow of the mixer and adjusting the discharge pressure of the gas.

The operation of the present invention as described above will be described in more detail below.

In the boiler of the present invention, the heat exchange is made by directly contacting the heated heat and the heating water.

To this end, the flue heat from which the combustion heat of the combustion chamber 20 is discharged is primarily transferred to the upper portion of the tubular water chamber 10 to form heat exchange, and the combustion heat is introduced downward into the heat chamber 24. Mixing with the heating water acts to discharge to the exhaust pipe 14 via the heating water tank (30).

The tubular water chamber 10 surrounding the outside of the combustion chamber 20 is forcibly circulated through the heating water with a circulation motor M, and the heat exchanged heating water is collected in the heating water tank 30.

Looking at the heat exchange action, the heat generated by combustion in the combustion chamber 20 is naturally transferred to the heat chamber 24 by the pressure introduced from the external compression tank 52 and the pressure lowered by being mixed with the heating water and discharged. It is filled with hot combustion heat.

In this state, the heating water pressurized and fed by the circulation motor (M) pressure flows into the heating water induction pipe 42 and is discharged to the heating water tank 30 by the tip nozzle action of the mixing nozzle 40. As the flow rate increases by the action, the hot air is mixed while sucking the heat from the tip of the hot air induction pipe 44 on the outer circumference thereof, and the hot air is discharged in the form of collected water droplets (see FIG. 2).

As the heat and heating water are mixed, the heating water temperature rises and heat exchange occurs, and in order to keep the heat exchange time from the heat as high as possible, the rise of the hot water droplets rises as it flows along the linear guide plate 32 and delays. As long as the heat exchange is made continuously.

The volume of the heating water induction pipe 30 and the hot water induction pipe 44 of the mixing nozzle 40 may be adjusted to the capacity of the boiler, and the number of nozzles may also be increased or decreased according to the capacity of the boiler.

The heating water exchanged through the mixing nozzle 40 rises along the helical guide plate 32 and reaches the top of the guide plate so that hot air bubbles are aerated by the bubble removing network 34 to separate the gas and separate combustion exhaust gas. Is discharged to the outside along the exhaust pipe (14).

In addition, according to the present invention, heat droplets that provide heat exchange to the heating water are preferably formed so that the heat exchange efficiency is increased, so that the heat induction pipe 44 is partitioned into the compartment 45 to reduce the discharge heat, and the cap at the tip of the nozzle ( In the case of adding 46), the heat discharged can be separated small, thereby increasing heat exchange efficiency.

In the present invention, even if a strong boiler is introduced into the exhaust pipe without any harmful combustion or incombustibility due to the inflow of draft into a conventional boiler, the inflow of outside air is not directly introduced into the combustion chamber through an exhaust port. It is made and functioned so that it can operate regardless of the back wind.

The present invention is used as a boiler for providing heating to a room or a facility, and is configured to achieve heat exchange while mixing the heat of combustion and the heating water by direct contact with each other.

1 is a cross-sectional view as an overall configuration diagram of the present invention.

Figure 2 is an enlarged cross-sectional view of the main portion of the mixing nozzle of the present invention.

3 is an enlarged sectional view taken along line "A"-"A" in FIG.

FIG. 4 is a cross-sectional view of a modification of the portion of the mixing nozzle of FIG. 2; FIG.

*** Explanation of symbols for the main parts of the drawing ***

10: chamber 14: exhaust pipe

20: combustion chamber 22: burner

24: hot room 30: heating water tank

32: guide plate 34: bubble removing network

40: mixed nozzle 42: heating water induction pipe

44: heat guide pipe 45: compartment

46: Cap 50: Mixing Compressor

52: compression tank

Claims (7)

In the boiler which burns fuel and heats heating water, A combustion chamber configured to combust and supply air and fuel by mixing compression supply outside the combustion chamber; A water pipe of a tubular body surrounding the outside of the combustion chamber, It consists of a heated heating water tank provided in the center of the water pipe, The fuel is combusted in the combustion chamber to form a first heat exchange with the water pipe at the upper part of the combustion chamber, and the combusted hot air moves downward to the hot chamber to make heat exchange by contacting the transferred combustion heat and heating water through a mixing nozzle. Boiler for direct heat exchange from the heat of combustion, characterized in that the heating water is made to flow to the upper portion of the heating water tank by flowing back along the spiral guide plate to generate the heating water. The method of claim 1, wherein the boiler forms a water chamber 10 of a cylindrical body, forms an internal compartment of an empty space, forms a combustion chamber 20 spaced apart from an upper water chamber above the compartment, and forms a burner 22 under the combustion chamber. , A hot air chamber 24 is disposed to discharge combustion heat from the combustion chamber 20 and discharged downward, and a heating water tank 30 is formed on the hot air chamber 24 so that the bottom surface water of the water chamber 10 and A plurality of mixing nozzles 40 for mixing the combustion hot air of the hot air chamber 24 is formed to discharge the outlet of the mixing nozzles to the heating water tank 30, the tank of the heating water mixed with heat A boiler for directly exchanging heat from combustion heat, characterized in that the exhaust pipe 14 is formed from the top to the outside to obtain heat exchanged heating water. The compression tank 52 of claim 2, wherein the gas and fuel, which are fuels, are mixed and compressed by the mixing compressor 50 to transfer the combustion heat of the combustion chamber 20 to the combustion chamber below the water chamber 10. Boiler that performs heat exchange directly from the heat of combustion, characterized in that it is made to supply a certain amount to the burner 22 while storing in. The method of claim 2, wherein the heating water tank 30 is built in the spiral guide plate 32 in close contact with the tank wall therein so as to rise while moving the flow path of the water along the spiral guide plate, the guide plate Boiler for direct heat exchange from the heat of combustion, characterized in that the upper part of the 32 is provided by a fine perforated bubble removing net 34, such as a mesh. The method of claim 2, wherein the mixing nozzle 40 is a heating water induction pipe 42 for discharging the heating water at a hydraulic pressure from the lower side of the water chamber 10 and the outer circumference of the heating water induction pipe from the hot air chamber 24 Forming a nozzle structure consisting of a hot air induction pipe 44 installed to wrap in an annular along the boiler to form a heat exchange directly from the heat of combustion, characterized in that the heat is mixed at the tip of the nozzle with the discharge pressure of the heating water. The method of claim 2, wherein the hot air induction pipe 44 of the mixing nozzle 40 is installed around the heating water induction pipe 42, the interior of the combustion heat, characterized in that divided into a plurality of compartments 45 Boiler for direct heat exchange. The boiler according to claim 6, further comprising a funnel-shaped cap 46 inclined at the discharge tip of the mixing nozzle 40 in the same manner as the nozzle inclination angle.

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