KR101392413B1 - A waste oil combusting device - Google Patents

Abstract

The present invention relates to a waste oil evaporating combustion furnace, and is to obtain a high-efficiency waste oil combustor allowing waste oil to be recycled as an energy source, maximizing combustion efficiency, and minimizing the discharge of harmful gases. The waste oil evaporating combustion furnace according to the present invention comprises: an inner combustion furnace shaped into a hollow cylinder, and having multiple holes; and an outer combustion furnace having multiple holes, and surrounding the inner combustion furnace, wherein the outer combustion furnace and the outer surface of the inner combustion furnace have a certain space therebetween. The inner combustion furnace receiving fuel allows the fuel to be combusted therein, and then the fuel is combusted again between the inner combustion furnace and the outer combustion furnace so that the combustion efficiency can be improved, wherein the outer combustion furnace has flame guide rods at the holes thereof so that flames can be guided to be closed to the wall of a combustion chamber.

Description

A waste oil combusting device}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a combustion furnace, and more particularly, to a waste oil-fired combustion furnace capable of efficiently vaporizing highly viscous fuel such as waste oil to use as fuel.

The waste oil generated in modern society will be seriously polluted if the collection and treatment are not performed properly, so careful treatment is needed. Generally, waste oil generated at factories and car repair shops is collected and incinerated at regular intervals.

On the other hand, waste oil can be regarded as being incinerated because there is no recycling means that can be recycled as energy. Because it is highly viscous and contains a large amount of foreign substances, it is not suitable for use as a fuel for a heating device such as a boiler.

There have been attempts to burn waste oil and use it as an energy source. There has been an attempt to recycle the waste oil by removing it from the waste oil and refining it and then using it as a fuel for a heating device such as a boiler. Representative patent registration No. 10-0544948 (Jan. 13, 2006) has an "oil burner".

An object of the present invention is to provide a highly efficient waste oil combustor capable of maximizing combustion efficiency and minimizing the discharge of harmful gas by burning waste oil while inducing vaporization of waste oil.

The present invention provides a combustion furnace which has a dual structure and maximizes burning efficiency by effectively burning waste oil while vaporizing the waste oil, thereby achieving the above object.

According to the present invention, it is possible to obtain heat energy by burning highly viscous fuel including waste oil, and effectively burn the fuel while vaporizing the fuel during combustion, thereby obtaining a combustion furnace in which the combustion efficiency is maximized.

1 is a perspective view showing a preferred embodiment of a waste oil-fired combustion furnace according to the present invention,
FIGS. 2A and 2B are cross-sectional views showing a preferred embodiment of a waste oil-fired combustion furnace according to the present invention;
FIG. 3 is a cross-sectional view illustrating a state in which an injector for injecting fuel and air is installed in a waste oil-fired combustion furnace according to the present invention.
4 is an exemplary view showing a state in which a waste oil-fired combustion furnace according to the present invention is installed inside a combustion chamber,
5A and 5B are views showing a state in which combustion is performed in a waste oil evaporative combustion furnace according to the present invention,
6 is an exemplary view showing a state in which a flame-inducing rod is formed in a waste oil-fired combustion furnace according to the present invention,
7 is an exemplary view showing a state in which a waste oil vaporized combustion furnace in which a flame guide rod is formed is installed inside a combustion chamber.

In order to maximize the combustion efficiency and to minimize the discharge of harmful gas, the waste oil burner of the present invention is provided with an inner hollow cylinder and a plurality of holes And an outer combustion furnace formed with a combustion furnace and a plurality of holes to form a predetermined space between the inner combustion furnace and the outer combustion furnace to surround the inner combustion furnace, And a combustion inducing rod is formed in the hole formed in the external combustion furnace to induce the flame to the vicinity of the wall surface of the combustion chamber.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described in detail with reference to the accompanying drawings. FIG. 1 is a perspective view showing a preferred embodiment of a waste oil fired combustion furnace according to the present invention, and FIGS. 2a and 2b are sectional views showing a preferred embodiment of a waste oil fired combustion furnace according to the present invention.

The waste oil fired combustion furnace 100 according to the present invention includes an internal combustion furnace 110 and an external combustion furnace 120 surrounding the internal combustion furnace 110. The internal combustion furnace 100 and the external combustion furnace 120 are formed into an empty container having an inlet open and a bottom 130 closed. At this time, the internal combustion furnace 110 and the external combustion furnace 120 may be formed to share the floor 130.

The internal combustion furnace 110 and the external combustion furnace 120 may have the same shape but different sizes. That is, the inner combustion furnace 110 having a cylindrical shape is formed to be smaller than the outer combustion furnace 120 having a cylindrical shape and accommodated in the outer combustion furnace 120. Accordingly, when the inner combustion furnace 110 is formed in the outer combustion furnace 120, a certain space is formed between the outer surface of the inner combustion furnace 110 and the inner surface of the outer combustion furnace 120.

The body of the internal combustion furnace 110 is preferably formed in a cylindrical shape, and the external combustion furnace 120 preferably has a cylindrical shape. This is a constitution for allowing the flame to spread and evenly spread.

The internal combustion furnace 110 includes at least one internal combustion furnace 110. In the present invention, the external combustion furnace 120 surrounds one internal combustion furnace 110. However, It is also possible. When two or more internal combustion furnaces 110 are provided, the smaller size of the internal combustion furnaces 110 may be arranged in a large size.

A plurality of holes 112, 122 and 132 are formed in the internal combustion furnace 110 and the external combustion furnace 120. The holes 112, 122, and 132 are paths through which flames and combustion gases are generated while the fuel is burned.

The flame is discharged through the hole 112 formed in the wall surface of the internal combustion furnace 110 and the hole 132 formed in the bottom 130. As a result, The flame emitted into the hole 112 formed in the wall surface reaches the space between the internal combustion furnace 110 and the external combustion furnace 120 and is then burnt again so that the hole 122 formed in the external combustion furnace 120 and the bottom 130 through holes 132 formed therein. As a result, the combustion is performed two times in sequence, and combustion close to complete combustion is performed, so that the combustion efficiency can be improved.

The holes 112 formed in the wall surface of the internal combustion furnace 110 and the holes 122 formed in the wall surface of the external combustion furnace 120 are staggered from each other. As a result, the flame emitted from the internal combustion furnace 110 strikes against the wall surface of the external combustion furnace 120, so that the flame and the combustion gas are effectively crushed and spread evenly, and as a result, the combustion is promoted.

Here, the hole 122 formed in the wall surface of the external combustion furnace 120 is formed to be larger than the number of the holes 112 formed in the wall surface of the internal combustion furnace 110. It is considered that the size of the internal combustion furnace 110 is formed to be smaller than that of the external combustion furnace 120 and that the internal combustion furnace 110 is maintained at a high temperature / high pressure. Preferably 25 to 40% more.

It is preferable that the hole 132 formed in the bottom 130 is not formed at the portion where the fuel injected from the internal combustion furnace 110 collides. So that the injected fuel can be burnt to the inside of the internal combustion furnace 100 while being crushed by colliding with the bottom 130 to be burned.

Meanwhile, as described above, the holes 112, 122, and 132 may be formed on both the wall surface and the floor 130, but may be formed only on the wall surface as shown in FIGS. 2B and 5B. This is a configuration that can be selectively adopted as needed.

The internal combustion furnace 110 and the external combustion furnace 120 allow the diameter of the inlet to be smaller than the diameter of the body. It is possible to maximize the internal temperature and pressure when combustion occurs in the internal combustion furnace 110 and the external combustion furnace 120, thereby improving the combustion efficiency .

When the diameter of the inlet is smaller than the diameter of the body, the inner combustion furnace 110 and the outer combustion furnace 120 are formed so that the inlet of the inner combustion furnace 110 is accommodated inside the inlet of the outer combustion furnace 120 . This configuration is such that the internal combustion furnace 110 is completely accommodated in the external combustion furnace 120, which helps to maximize the temperature and pressure inside the internal combustion furnace 110.

Hereinafter, the use state of the waste oil combustor 100 according to the present invention described above will be described.

FIG. 3 is an exemplary view showing a state in which an injector for injecting fuel and air is installed in a waste oil-fired combustion furnace according to the present invention, and FIG. 4 is an exemplary view illustrating a state in which a waste oil-fired combustion furnace according to the present invention is installed inside a combustion chamber.

In the waste oil-fired combustion furnace 100 according to the present invention described above, the injector 200 for injecting fuel and air is used by being coupled to the inlet.

The injector 200 is provided with a pipe for supplying air, a pipe for supplying waste oil, and a pipe for supplying fuel used for preheating the waste oil fired combustion furnace 100 to a temperature sufficient to burn the post-ignition waste oil A nozzle for injecting fuel and air is formed toward the internal combustion chamber 110 and is installed by being connected to the inlet of the external combustion chamber 120 when installed in the waste oil combustion furnace 100. At this time, the injector 200 is provided with a coupling plate 210 having a plate shape and formed with a plurality of holes, so that it is preferable that the coupling plate 210 is coupled while blocking the inlet of the external combustion chamber 120. When the fuel is burned, The temperature and the pressure inside the furnace 100 can be raised.

The waste oil combustion combustion furnace 100 according to the present invention for supplying fuel and air by the injector 200 and burning the waste oil is installed in a known combustion chamber 300 separately provided as shown in FIG. .

Hereinafter, the process of burning the fuel in the waste oil-fired combustion furnace 100 according to the present invention will be described. 5A and 5B are views showing a state in which combustion is performed in a waste oil-fired combustion furnace according to the present invention.

Fuel with high viscosity such as waste oil is not easily ignited and combustion is not performed when the temperature inside the waste oil combustion furnace 100 is low. Therefore, it is necessary to preheat the waste oil so that the waste oil can be burned smoothly.

To do this, the diesel or kerosene is injected like air and burned and preheated. When the internal combustion furnace 110 and the external combustion furnace 120 rise to an appropriate temperature through the preheating process, the supply of fuel for preheating is stopped and the waste oil is supplied together with air to be burned. At this time, since the internal combustion furnace 110 is preheated to a high temperature, even if it is a waste fuel or a highly viscous fuel, it is easily ignited and burned.

When the supply of the waste oil is started through the injection device 200, the waste oil injected through the nozzle collides with the bottom 130 of the internal combustion furnace 110 and is dispersed into the internal combustion furnace 110, and is vaporized and burned rapidly. It burns like an explosion. The flames generated during the combustion are discharged through the holes 112 formed in the wall surface of the internal combustion furnace 110 and the holes 132 formed in the bottom 130. The discharged flames are discharged again through the external combustion furnace 120, It collides with the inner wall surface and is burned again while being dispersed. Then, the flame is discharged to the outside through the hole 122 formed in the wall surface of the external combustion furnace 120 and the hole 132 formed in the bottom.

According to the above, the primary combustion is performed in the internal combustion furnace 110, and the unburned fuel and gas are secondarily combusted in the space between the internal combustion furnace 110 and the external combustion furnace 120, Combustion is performed. Therefore, fuel with high viscosity such as waste oil can be effectively burned to obtain thermal energy.

FIG. 6 is an exemplary view showing a state in which a flame-inducing rod is formed in a waste-oil-fired combustion furnace according to the present invention, and FIG. 7 is an example of a state in which a waste-oiled combustion furnace in which a flame-

As shown in the drawing, the flue gas induction rod 150 is formed in the waste oil evaporation combustion furnace 100 according to the present invention, so that the flame can be discharged adjacent to the inner wall surface of the combustion chamber 300.

The flame inducing rod 150 is installed in the hole 122 formed in the combustion furnace 100 and can be detachably attached by being screwed together. The flame inducing rod 150 is formed only in a part of the hole 122 It is possible to give.

As shown in FIG. 7, since the flame inducing rod 150 is formed, the flame can be emitted while the fuel is burned near the inner wall surface of the combustion chamber 300, and thus the wall surface of the combustion chamber 300 can be rapidly heated It is possible to heat the hot water or hot water pipe heated by the combustion chamber 300 more effectively by providing the combustion chamber 300 so as to surround the combustion chamber 300.

100: Combustion furnace,
110: internal combustion furnace, 112: hole,
120: external combustion furnace, 122: hole,
130: bottom, 132: hole,
150: flame guide rod, 200: injection device.

Claims (7)

A plurality of holes are formed in the inner combustion furnace 110 to form a predetermined space between the inner combustion furnace 110 and the inner combustion furnace 110, Including the surrounding external combustion furnace 120,
When the fuel is supplied, the combustion is performed in the internal combustion furnace 110, and then the combustion is performed again between the internal combustion furnace 110 and the external combustion furnace 120 to improve the combustion efficiency,
Wherein a flame inducing rod (150) is formed in an opening formed in the external combustion furnace (120) to induce the flame to the vicinity of the wall surface of the combustion chamber (300). The method according to claim 1,
Wherein the inner combustion furnace (110) and the outer combustion furnace (120) are formed to have diameters smaller than the diameter of the body, thereby maximizing internal temperature and pressure. 3. The method of claim 2,
Wherein the inlet of the internal combustion furnace (110) is formed to be received inside the inlet of the external combustion furnace (120), thereby maximizing the temperature and pressure inside the internal combustion furnace (110). The method according to claim 1,
Wherein no holes are formed in the central portion of the bottom of the internal combustion furnace to cause the fuel injected into the internal combustion furnace to be crushed and burned while bumping against the bottom. Combustion furnace. delete The method according to claim 1 or 4,
The holes formed in the internal combustion furnace 110 and the holes formed in the external combustion furnace 120 are staggered from each other so that flames emitted from the internal combustion furnace 110 are struck against the wall surface of the external combustion furnace 120 Waste oil combustion furnace. The method according to claim 1 or 4,
Wherein a hole formed in the external combustion furnace (120) is formed by 25 to 40% more than the number of the holes (122) formed in the internal combustion furnace (110).

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