KR102176942B1 - Combustion device for stove - Google Patents

Abstract

The present invention relates to a combustion apparatus for a stove, comprising: a combustion cylinder 100 in which an air inlet hole 120 is formed, and a heat air cylinder 200 that is erected in the combustion cylinder 100 and through which air is introduced through the lower portion. Including, by filling and burning solid fuel in the space between the inner wall of the combustion cylinder 100 and the outer wall of the hot air cylinder 200, a rising air flow is generated inside the hot air cylinder 200 and the hot air is discharged to the outside. The present invention relates to a combustion apparatus for a stove capable of maximizing a heating effect by rapidly diffusing and promoting a convection phenomenon.

Description

Combustion device for stove}

The present invention relates to a combustion apparatus, and in particular, to a combustion apparatus for a stove capable of supplying hot air by filling and burning charcoal.

Various combustion devices have been proposed for use in stoves. These include firewood combustion devices and pellet combustion devices. Such a conventional combustion apparatus is formed to generate radiant heat by burning fuel in a predetermined space, that is, a cylinder of a predetermined standard provided to enable combustion to generate radiant heat.

(Document 1) Korean Patent Application Publication No. 10-2015-0071319 (July 7, 2005)

Conventional combustion apparatuses simply focus on generating heat and are insufficient to promote convection. Accordingly, an object of the present invention is to obtain a combustion apparatus capable of improving the heating effect by maximizing the convection phenomenon to promote circulation of hot air.

In the present invention, including a combustion cylinder in which at least one air inlet hole is formed, and a hot air cylinder erected in the combustion cylinder through which air is introduced through a lower portion, solid fuel is filled and burned in the space between the inner wall of the combustion cylinder and the outer wall of the hot air cylinder. As a result, the above object is achieved by proposing a combustion apparatus for a stove in which an ascending air flow is generated and the hot air is diffused.

According to the present invention, the heating effect can be maximized by promoting convection by rapidly diffusing hot air, and it is possible to reduce smoke generation while improving the calorific value by helping complete combustion.

1 is an exemplary view of a combustion apparatus according to the present invention,
2 is an exploded view of the combustion apparatus according to the present invention,
3 is a cross-sectional view of a combustion apparatus according to the present invention,
Figure 4 is an exemplary view showing in cross section the state of use of the combustion apparatus according to the present invention.

In the present invention, in order to obtain a combustion device capable of improving the heating effect by maximizing the convection phenomenon to promote circulation of hot air,

Including a combustion cylinder in which at least one air inlet hole is formed and a hot air cylinder that is erected in the combustion cylinder and through which air is introduced through a lower portion, a hot air cylinder by filling and burning solid fuel in the space between the inner wall of the combustion cylinder and the outer wall of the hot air cylinder It is proposed a combustion device for a stove in which an ascending air flow occurs inside and hot air is discharged to the outside.

Hereinafter, the present invention will be described in detail with reference to FIGS. 1 to 4 in the accompanying drawings.

1 is an exemplary view of a combustion apparatus according to the present invention, FIG. 2 is an exploded view of a combustion apparatus according to the present invention, and FIG. 3 is a cross-sectional view of a combustion apparatus according to the present invention.

As shown, the combustion apparatus according to the present invention includes a combustion cylinder 100 having an empty cylinder shape and a hot air cylinder 200 accommodated in the combustion cylinder 100.

The combustion vessel 100 is formed so that external air can be introduced into the interior. To this end, the air inlet hole 120 is formed, and at least one air inlet hole 120 is formed at a predetermined position, so that the air required for combustion can be supplied. It is preferable that the air inlet hole 120 is formed in the lower part of the combustion cylinder 100.

The hot air cylinder 200 is formed in a column shape with an empty inside, and is formed so that external air can be introduced into the inside. The inflow of external air may be achieved by drilling the through hole 220 in the lower portion of the hot air cylinder 200, but is not limited thereto, and the lower end may be opened to allow air to flow into the open inlet.

The hot air cylinder 200 may be formed to be thinner toward the top. As shown, in the case of forming a cylindrical shape, the diameter decreases toward the top. Of course, it does not have to be linearly thin, and it is possible to form only the upper part thinner. This structure is a configuration for increasing the speed when the hot air generated inside the hot air cylinder 200 rises and is discharged to the outside.

A tornado guideway 240 is formed on the inner wall of the hot air cylinder 200. The whirlwind induction road 240 is formed in a spiral shape obliquely in the upper direction along the inner circumferential surface of the hot air cylinder 200, and may be formed to protrude or may be formed as a concave groove. According to this configuration, when a rising airflow is formed inside the hot air cylinder 200, it whirls and rises by the tornado 240, and as a result, the speed of the hot air discharged to the outside of the hot air cylinder 200 increases. It will spread more widely.

The combustion apparatus according to the present invention described above may further include a dropping network 300 forming a certain space on the inner floor of the combustion vessel 100. The drop net 300 is formed to form a regular interval with the inner floor of the combustion tank 100, and as shown, a leg portion bent down at the edge of the metal net is formed to be inserted into the combustion tank 100 Can be. When the combustion cylinder 100 is formed in a cross-sectional square shape, an example is a structure in which both edges of the square-shaped net are bent downward to form a bridge.

The drop network 300 formed as described above supports the solid fuel filled in the combustion vessel 100. In addition, it is possible to support the lower end of the hot air cylinder 200, so that a certain space is formed between the solid fuel and the hot air cylinder 200 and the inner bottom of the combustion cylinder 100. At this time, the hot air cylinder 200 has a structure in which the lower end is open, and the air inlet hole 120 formed in the combustion cylinder 100 is formed between the bottom of the combustion cylinder 100 and the dropping network 300. Therefore, the air supplied to the air inlet hole 120 can be smoothly supplied into the solid fuel and the hot air cylinder 200 through the space.

The drop network 300 may be formed in a fixed state at the bottom of the hot air cylinder 200. In this case, when the hot air cylinder 200 is inserted into the combustion cylinder 100, the dropping net 300 is naturally installed in the combustion cylinder 100 together.

On the other hand, in the combustion apparatus according to the present invention provided with the dropping net 300 as described above, ash generated in the process of burning solid fuel falls into the space below the dropping net 300 and collects. In order to remove this, a door may be formed at the lower end of the combustion vessel 100, and otherwise, a drawer may be formed to collect ash in the drawer. Through this configuration, it is possible to remove the ash at an appropriate time.

Hereinafter, a state of burning solid fuel with the combustion apparatus according to the present invention will be described. Figure 4 is an exemplary view showing in cross section the state of use of the combustion apparatus according to the present invention.

Charcoal is selected for solid fuel. Charcoal is suitable for use in the combustion apparatus of the present invention because of its high calorific value, low smoke generation and long burning time.

To use the combustion apparatus according to the present invention, the solid fuel is filled in the space between the inner wall of the combustion cylinder 100 and the outer wall of the hot air cylinder 200. In that state, solid fuel is ignited. The top of the filled solid fuel is ignited to allow downward combustion. According to this, since a downward combustion is performed from top to bottom, it is helpful for complete combustion and it is possible to reduce the generation of harmful gases.

In the ignition process, a separate ignition material may be used to smoothly ignite.

During the process of combustion, external air is introduced into the combustion vessel 100 through the air inlet 120 to supply oxygen required for combustion. When the air inlet hole 120 is formed in the lower portion of the combustion vessel, external air flows in from the lower portion of the combustion vessel 100, so that it rises naturally and supplies oxygen to the solid fuel.

When the combustion proceeds to some extent, the air in the hot air cylinder 200 is heated. Accordingly, the hot air is discharged from the hot air cylinder 200 to the outside while the rising air flow is generated. Since the temperature inside the hot air cylinder 200 increases as time goes by, the amount and speed of the hot air discharged increases. In particular, when the hot air cylinder 200 is formed thinner as it goes upward, the discharge speed of the hot air increases further, and when the tornado 240 is formed, the hot air is swirled and discharged. You can send air. This promotes convection.

In the above process, when the through hole 220 is formed under the hot air cylinder 200, since air introduced from the outside is also supplied to the solid fuel through the through hole 220, combustion is promoted. In addition, since the flame generated while the solid fuel is burned can also be introduced into the hot air cylinder 200 through the through hole 220, the air inside the hot air cylinder 200 is heated more rapidly.

Here, as the combustion continues, the ash generated falls into a space formed under the drop network 300 and collects. By removing the ash collected by falling in this way at an appropriate time point, the combustion apparatus according to the present invention can be used continuously or repeatedly.

100: combustion vessel, 120: air inlet hole,
200: hot air cylinder, 220: through hole,
240: whirlwind taxiway, 300: drop net.

Claims (5)

Including a combustion cylinder 100 in which an air inlet hole 120 is formed, and a hot air cylinder 200 that is erected in the combustion cylinder 100 and through which air is introduced, the inner wall of the combustion cylinder 100 and By filling the space between the outer walls of the hot air cylinder 200 and burning solid fuel, a rising air flow is generated inside the hot air cylinder 200 and the hot air is discharged to the outside.
The combustion cylinder 100 further includes a dropping network 300 supporting the lower end of the hot air cylinder 200 to form a space between the floor and the solid fuel, and the air inlet hole 120 It is formed between the bottom of the combustion tank 100 and the dropping network 300,
The hot air cylinder 200 is formed to be thinner toward the top, thereby increasing the speed of discharged hot air. The method of claim 1,
The hot air cylinder 200 is cylindrical, but a tornado 240 is formed in a spiral shape along the inner circumferential surface to induce hot air to swirl and discharge.

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