KR200417812Y1 - Combustion apparatus - Google Patents

Abstract

The present invention relates to a combustion device. The present invention includes a housing 10 having a combustion chamber 11 formed at an inner end thereof, and a spark plug 15 installed at a rear end of the housing 10 to combust a separate fuel at an early stage of operation to burn the combustion chamber 11. An ignition combustion unit 13 for preheating the inside and performing ignition, a preheating coil tube 20 installed inside the combustion chamber 11 to superheat fuel by heat inside the combustion chamber 11, and the preheating coil tube The injection nozzle 32, which receives the fuel passing through the mixture 20 and the air supplied from the outside, is injected and injected into the combustion chamber 11, and the liquid fuel collected in the injection nozzle 32 is collected in the combustion chamber 11. It is configured to include a regeneration preheating unit 40 to overheat again to the heat of the transfer to the injection nozzle (32). In the combustion apparatus according to the present invention having such a configuration, the combustion of the fuel that is overheated into the combustion chamber is easily carried out, and the fuel that is not overheated is preheated and used to completely burn the supplied fuel. In the combustion chamber, since air and fuel are combusted while forming a vortex, the combustion efficiency is increased.

Combustion, preheating, liquid fuel, complete combustion, regeneration

Description

Combustion apparatus

1 is an exploded perspective view showing the main configuration of a preferred embodiment of the combustion apparatus according to the present invention.

Figure 2 is a cross-sectional view showing the internal configuration of the embodiment of the present invention.

Figure 3 is a perspective view showing the configuration of the preheated coil pipe constituting the embodiment of the present invention.

Figure 4 is an operating state showing the flow of fuel and air in the embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

10: housing 11: combustion chamber

13: ignition burner 14: ignition guide

14 ': support leg 15: spark plug

16: ignition fuel supply pipe 18: combustion air supply pipe

20: preheated coil pipe 22: combustion fuel injection pipe

24: combustion fuel supply pipe 26: air fuel mixing section

29: communication hole 30: nozzle communication tube

32: injection nozzle 34: injection hole

36: stirring blade 40: regeneration preheating unit

42: regeneration injection pipe 44: regeneration supply pipe

The present invention relates to a combustion apparatus, and more particularly, to a combustion apparatus that improves combustion efficiency by enabling complete combustion of a state of fuel supplied to a combustion chamber.

In a combustion apparatus in which liquid fuel is vaporized and mixed with air to combust, the state of vaporized fuel and the ratio of mixed air have a great influence on the combustion efficiency. In other words, it is important that fuel is supplied to the combustion chamber in such a state that fuel can be completely burned in the combustion chamber.

However, in the related art, the temperature of the fuel injected into the combustion chamber through the nozzle is relatively lower than the temperature in the combustion chamber, so that the fuel is not easily dispersed in the combustion chamber and thus the combustion efficiency is relatively low.

As such, it is difficult to completely burn in the combustion chamber, and since fuel and air are continuously supplied by the nozzle, fuel and air that are not combusted may be discharged to the outside of the combustion apparatus. In this case, combustion efficiency is lowered and air pollution due to incomplete sequencing becomes a problem.

Therefore, an object of the present invention is to solve the problems of the prior art as described above, to preheat the fuel supplied to the combustion chamber to make a state capable of complete combustion.

Another object of the present invention is to extract the fuel in the liquid state from the injection nozzle for injecting fuel into the combustion chamber and to preheat again to make it possible to complete combustion.

Another object of the present invention is to allow air and fuel to be combusted while forming a vortex inside the combustion chamber.

According to a feature of the present invention for achieving the object as described above, the present invention has a housing in which a combustion chamber is formed at the inner end and the rear end of the housing is provided with an ignition plug to burn a separate fuel to at least start operation An ignition combustion unit configured to preheat the combustion chamber and to ignite by the flame in which the separate fuel is burned, a preheating coil tube installed inside the combustion chamber to superheat fuel by heat inside the combustion chamber, and the preheating coil tube. Regeneration for mixing the fuel passing through and the air supplied from the outside and injected into the combustion chamber and the fuel in the liquid state collected in the injection nozzle to reheat the heat of the combustion chamber to be used in the injection nozzle It is configured to include a preheating unit.

An air fuel mixing unit is further provided inside the housing, and the air fuel mixing unit is connected to the preheating coil pipe and the combustion fuel supply pipe to receive a superheated and delivered fuel, and combustion air extending from the outside into the housing. Air is delivered through the supply pipe to form air mixed fuel.

A mixed fuel supply pipe extending from the air fuel mixing unit and delivering an air mixed fuel is installed through the center of the injection nozzle, and the mixed fuel supply pipe is installed inside the combustion chamber to supply air mixed fuel to the injection nozzle. It is comprised so that it may be surrounded by the nozzle communicating tube which supplies.

The nozzle communicating tube is supported inside the housing by a stirring blade installed inclined around its outer circumferential surface, the stirring blade forms a vortex in the flame inside the combustion chamber and transfers heat to the nozzle communicating tube.

The preheated coil pipe is a pipe having a cylindrical coil shape, and is installed in a combustion chamber inside the housing tip.

The regeneration preheating unit is installed around the outer surface of the nozzle communication tube, and communicates with the injection nozzle and the regeneration injection tube, and is communicated through the air fuel mixing unit and the regeneration supply tube.

Gas is supplied as fuel to the ignition combustion section, and liquid diesel and bunker seed oil are supplied to the combustion fuel injection pipe.

In the combustion apparatus according to the present invention having such a configuration, the combustion of the fuel that is overheated into the combustion chamber is easily carried out, and the fuel that is not overheated is preheated and used to completely burn the supplied fuel. In the combustion chamber, since air and fuel are combusted while forming a vortex, the combustion efficiency is increased.

Hereinafter, a preferred embodiment of the combustion apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

1 is an exploded perspective view showing the main configuration of the preferred embodiment of the combustion apparatus according to the present invention, Figure 2 is a cross-sectional view showing the internal configuration of the present invention embodiment, Figure 3 constitutes the present invention embodiment The configuration of the preheated coil pipe is shown in perspective view.

As shown in these figures, the housing 10 has a cylindrical shape, and a combustion chamber 11 is formed therein. The housing 10 is not necessarily cylindrical, but preferably cylindrical.

The tip of the housing 10 is opened forward. The rear end of the housing 10 is connected with components for supplying ignition fuel, combustion fuel and air. An air guide 12 is provided inside the housing 10 to supply air to the combustion chamber 11 at a high speed. The air guide part 12 is formed to have a smaller inner diameter than other parts of the housing 10, for example, the combustion chamber 11.

An ignition combustion part 13 is installed at the rear end of the inlet frame 12. The ignition combustion section 13 sets an initial condition for combustion in the combustion chamber 11 at the beginning of the operation of the combustion device and at the same time serves to ignite the combustion fuel.

The ignition combustion section 13 is provided with a cylindrical ignition guide 14 which opens only to one side. The ignition guide 14 is opened in the combustion chamber 11 direction. The ignition guide 14 is supported by a support leg 14 'in the housing 10.

An ignition plug 15 is installed inside the ignition guide 14 from the outside. The spark plug 15 serves to provide a spark for ignition in the ignition combustion section 13.

The ignition fuel supply pipe 16 provides the ignition fuel into the ignition guide 14. The ignition fuel supply pipe 16 provides the ignition fuel to the inside of the ignition guide 14, a plurality may be installed around the rear end of the ignition guide (14). As the ignition fuel supplied through the ignition fuel supply pipe 16, a gas such as LPG is preferably used.

The combustion air supply pipe 18 is installed to penetrate the center of the ignition guide 14 and extend from the rear end of the housing 10 toward the front end. The combustion air supply pipe 18 serves to supply the combustion air to be mixed with the combustion fuel to be described below.

Inside the front end of the housing 10, as shown in FIG. 3, a preheated coil pipe 20 is installed. The preheated coil pipe 20 is made of a metal having a good heat transfer rate and is formed by winding the pipe in a cylindrical coil shape having a diameter that can be installed inside the housing 10.

Combustion fuel injection pipe 22 is connected to the preheating coil pipe 20. In the illustrated embodiment, the combustion fuel injection pipe 22 is connected to the preheating coil pipe 20 through the interior of the housing 10 at the rear end of the housing 10. However, the combustion fuel injection pipe 22 may be connected to the preheated coil pipe 20 by penetrating from the outside of the housing 10 to the inside.

The preheated coil pipe 20 is also connected to a combustion fuel supply pipe 24. The combustion fuel supply pipe 24 serves to supply the superheated fuel to the air fuel mixing section 26 which will be preheated and superheated in the preheating coil pipe 20.

An air fuel mixing unit 26 is installed in the housing 10 so as to communicate with the combustion air supply pipe 18. The air fuel mixing unit 26 is installed in front of the ignition guide 14. Combustion air necessary for combustion is supplied to the air fuel mixing unit 26 through the combustion air supply pipe 18, and superheated combustion fuel is supplied through the combustion fuel supply pipe 24.

The air fuel mixing unit 26 is installed in communication with the mixed fuel supply pipe 28 so as to extend in the combustion chamber 11 direction. Through the mixed fuel supply pipe 28, the combustion fuel and combustion air mixed in the air fuel mixing section 26 (hereinafter referred to as 'air mixed fuel') flows. A plurality of communication holes 29 are formed around the outer circumferential surface of the front end of the mixed fuel supply pipe 28. The communication hole 29 serves to discharge the air mixed fuel.

A nozzle communication tube 30 is installed to surround the mixed fuel supply pipe 28. The nozzle communication tube 30 is located in the combustion chamber 11 center of the housing 10. The air mixed fuel is delivered to the inside of the nozzle communication pipe 30 through the communication hole 29 of the mixed fuel supply pipe 28.

The rear end of the nozzle communication tube 30 is provided with a spray nozzle (32). The injection nozzle 32 serves to inject the air mixed fuel delivered to the nozzle communication tube 30 to the combustion chamber (11). The injection nozzle 32 has a cylindrical shape having a predetermined diameter and is formed with a plurality of injection holes 34 surrounding the edge of one surface thereof. The air mixed fuel is injected into the combustion chamber 11 through the injection hole 34. For reference, the mixed fuel supply pipe 28 passes through the center of the injection nozzle 32.

Stirring blades 36 surrounding the outer surface of the nozzle communication tube 30 is provided. The stirring blade 36 causes the air mixed fuel in the combustion chamber 11 and the air supplied by the separate fan assembly at the rear end of the housing 10 to be stirred while causing vortex. The stirring blade 36 is installed to be inclined at a predetermined angle with respect to the extending direction of the housing 10.

The stirring blade 36 also serves to support the nozzle communicating tube 30 inside the housing 10 and to transfer heat generated in the combustion chamber. The nozzle communication tube 30 is substantially integrated with the injection nozzle 32, the mixed fuel supply pipe 28, and the ignition combustion section (13). Therefore, these unitary components are installed inside the housing 10 by the support legs 14 'and the stirring blades 36. Of course, depending on the design conditions may be further provided with a separate configuration for their support.

The regeneration preheating unit 40 serves to preheat the unvaporized fuel again in the air mixture fuel supplied to the injection nozzle 32. The regeneration preheating unit 40 is installed around the tip of the nozzle communication tube 30 in a coil cylindrical shape. One side of the regeneration preheating unit 40 is in communication with the lower end of the injection nozzle 32 through the regeneration injection pipe 42, the other side is in communication with the air fuel mixing unit 26 through the regeneration supply pipe (44). .

Therefore, the liquid fuel that has dropped to the lower end of the injection nozzle 32 is supplied to the regeneration preheating unit 40 through the regeneration injection pipe 42, and is overheated by the regeneration preheating unit 40. It is supplied to the air fuel mixing section 26 through the regeneration supply pipe (44).

Hereinafter, the operation of the combustion apparatus according to the present invention having the configuration as described above will be described in detail.

In the combustion apparatus of the present invention, combustion occurs first in the ignition combustion section 13 before full combustion. The ignition combustion unit 13 is supplied with a fuel mixed with gas and air through the ignition fuel supply pipe 16. The gas is ignited and combusted by the spark plug 15. At this time, the ignition guide 14 guides the flame generated as the gas is burned toward the combustion chamber. Therefore, the combustion chamber 11 and the surrounding components are heated by the combustion in the ignition combustion section 13.

When the temperature inside the combustion chamber 11 is greater than or equal to a predetermined value, fuel is supplied to the preheated coil pipe 20 through the combustion fuel injection pipe 22. The fuel receives heat from the inside of the preheated coil pipe 20 and becomes overheated to be in a gaseous state and is delivered to the air fuel mixing part 26 through the combustion fuel supply pipe 24. At this time, the temperature of the fuel is about 800 ℃. For reference, the fuel injected through the combustion fuel injection pipe 22 is light oil or bunker seed oil. That is, it is a liquid fuel.

At the same time, air is also supplied through the combustion air supply pipe 18. Therefore, the fuel superheated in the preheated coil pipe 20 and the air supplied through the combustion air supply pipe 18 are mixed in the air fuel mixing section 26 to form an air mixed fuel, and thus a mixed fuel supply pipe. Flows along (28).

The air mixed fuel flows into the nozzle communication pipe 30 through the communication hole 29 formed at the tip of the mixed fuel supply pipe 28. In this process, since the inside of the combustion chamber 11 has a relatively high temperature, the air mixed fuel continues to receive heat.

The air mixed fuel delivered to the nozzle communication tube 30 is injected into the combustion chamber 11 through the injection hole 34 of the injection nozzle 32. The air mixed fuel injected in this way is ignited and burned by the flame provided by the ignition combustion section 13. At this time, the air is supplied to the inside of the housing 10 by a separate fan assembly, and the air flows quickly because the cross-sectional area of the air guide portion 12 is smaller than that of other parts, so that the air flows quickly. It is delivered to the (11) to help the combustion of the air mixed fuel discharged through the injection hole (32). In this combustion process, the stirring blade 36 allows the air to be burned while allowing air to be better mixed with the air mixed fuel so that the flame forms a vortex. At this time, the temperature of the combustion chamber 11 is about 1300 ℃ to about 1350 ℃.

On the other hand, when combustion is started while the air-mixed fuel is injected from the injection nozzle 32, the ignition and combustion unit 13 does not have to occur any more combustion. Therefore, the supply of gas through the ignition fuel supply pipe 16 to the ignition combustion section 13 may be cut off. Of course, the ignition and combustion section 13 may also continue to cause combustion.

In addition, even if combustion is no longer performed in the ignition combustion unit 13, the fuel continuously supplied to the preheating coil pipe 20 is caused by the heat generated by the combustion of the air mixed fuel injected from the injection nozzle 32. Heated.

In addition, some of the fuel may be condensed in the injection nozzle 32. The liquid fuel is dropped into the lower portion of the injection nozzle 32 by its own weight, and the regeneration injection pipe 42 may be used. It is delivered to the regeneration preheating unit (40). The fuel heated again by the heat in the combustion chamber 11 in the regeneration preheating unit 40 is transferred back to the air fuel mixing unit 26 through the regeneration supply pipe 44, mixed with air, and It burns through the process described.

The rights of the present invention are not limited to the embodiments described above, but are defined by the claims, and various changes and modifications can be made by those of ordinary skill in the art within the scope of the claims. It is self-evident.

As described above in detail, in the combustion apparatus according to the present invention, the following effects can be obtained.

First, in the present invention, since the liquid fuel supplied to the combustion chamber is overheated and made into a gas state that can be easily burned, complete combustion of the fuel occurs in the combustion chamber, thereby increasing the efficiency of the combustion device.

In addition, in the present invention, the liquid fuel condensed in the injection nozzle is extracted and preheated, and thus, the fuel is completely burned, and thus, the combustion efficiency of the fuel can be improved, thereby improving thermal efficiency and lowering air pollution.

In addition, in the present invention, the air and fuel are combusted while forming a vortex inside the combustion chamber with a stirring blade. Therefore, since combustion of air and fuel forms a vortex in the combustion chamber, there is also an effect of increasing the combustion efficiency.

Claims (7)

A housing in which a combustion chamber is formed at an inner end thereof; An ignition combustion unit installed at a rear end of the housing and having an ignition plug to combust a separate fuel to preheat the combustion chamber at least at an initial stage of operation and to perform ignition by a spark in which the separate fuel is combusted; A preheating coil tube installed inside the combustion chamber to superheat fuel by heat inside the combustion chamber; An injection nozzle which receives the fuel passing through the preheating coil and the air supplied from the outside and is injected into the combustion chamber; And a regeneration preheating unit configured to overheat the liquid fuel collected in the injection nozzle with the heat of the combustion chamber so that the fuel can be used in the injection nozzle. According to claim 1, wherein the inside of the housing is further provided with an air fuel mixing unit, the air fuel mixing unit is connected to the preheating coil pipe and the combustion fuel supply pipe is supplied with the superheated fuel delivered, the outside of the housing Combustion apparatus, characterized in that for receiving air through the combustion air supply pipe extending inside to form an air mixed fuel. The fuel injection pipe of claim 2, wherein a mixed fuel supply pipe extending from the air fuel mixing part to deliver the air mixed fuel is installed through the center of the injection nozzle, and the mixed fuel supply pipe is installed inside the combustion chamber to provide the injection nozzle. Combustion apparatus characterized in that it is configured to be surrounded by a nozzle communicating tube for supplying air mixed fuel to the furnace. The nozzle communication tube of claim 3, wherein the nozzle communication tube is supported inside the housing by a stirring blade installed inclined around its outer circumferential surface, and the stirring blade forms a vortex in the flame inside the combustion chamber and transfers heat to the nozzle communication tube. Combustion apparatus characterized in that. 5. The combustion apparatus according to any one of claims 1 to 4, wherein the preheating coil pipe is formed in a cylindrical coil shape and is installed in a combustion chamber inside the housing tip. The combustion apparatus according to claim 5, wherein the regeneration preheating unit is installed around an outer surface of the nozzle communication tube, and is communicated through the injection nozzle and the regeneration injection pipe, and is communicated through the air fuel mixing part and the regeneration supply pipe. . 7. The combustion apparatus according to claim 6, wherein gas is supplied as fuel to the ignition and combustion portion, and light oil and bunker seed oil in a liquid state are supplied to the combustion fuel injection pipe.

Images