KR20130053802A - Radiant heating downward combustion stove - Google Patents

Abstract

PURPOSE: A downward combusting type stove is provided to increase stay time of air with rapid combustion by supplying the air required for combustion from an upper part to a lower part. CONSTITUTION: A downward combusting type stove comprises an air supply pipe, an air outlet(40), and a thermal radiation pipe(60). The air supply pipe is connected to the outside. The air supply pipe is formed from a lower part to an upper part of a combustion chamber. The air supply pipe supplied air required to combust. The air outlet includes a trap formed to face the bottom of the combustion chamber. One or more the thermal radiation pipes are formed to be penetrated through a main body(10). The thermal radiation pipes are inclined to generate a convective process. The thermal radiation pipes are tapered to accelerate flow speed of the air.

Description

Radiant heating downward combustion stove

The present invention relates to a downward combustion radiant stove, and more particularly, to increase the combustion rate by supplying the air required for combustion from the top to the bottom, and install a radiant conduit to allow the air to pass through to the downward combustion radiant stove that maximizes the heating effect. It is about.

In general, heat transfer is divided into conduction, radiation, and convection.

Among the convection, the fluid transfers heat in the vertical motion by buoyancy. When the lower part is heated, the entire fluid is evenly heated by the convection.

Korean Patent Laid-Open Publication No. 10-2007-0096133 (published October 10, 2007) discloses a stove for heating and heating surrounding air.

Referring to FIG. 9, a conventional stove body 2, a discharge passage 4 installed at an upper portion of the body 2 and a combustion gas is discharged, and air at one side of the upper portion (lower portion) of the body 2. A fuel inlet 5 connected to the supply inlet pipe 11 to supply fuel, a blower 1 installed at one side of the lower part to supply air into the body 2, and the body 2 has a lower portion An air chamber (7) fixed by the air chamber fixing stand (21), a rostol (back plate) (6) installed at a lower portion of the air chamber (7) and fixed by a back receiving stand (31), It can be seen that it comprises a reclaimer (3) provided in the lower portion of the rostol (ash) (6).

In addition, the air chamber 7 has a bowl-shaped circular shape, and is provided with a plurality of injection nozzles (diameter 1 to 3 mm) 7-1, and the lower part is opened in a pipe shape on both sides and the upper part is sealed. Is installed in a vertical state extending to the top, it can be seen that the injection nozzle (diameter 1 ~ 3mm) comprises an air discharge pipe (8) provided with the injection nozzle (8-1) in one direction.

According to the above configuration, since the heat of combustion is transmitted to the atmosphere through the stove body, the heating effect cannot be expected until the stove body is sufficiently heated, and the contact area with the atmosphere is limited to the stove body, so that the heat exchange rate is lowered. There was a problem.

In addition, the conventional stove has a problem that the fuel is burned from one side by the supply of the air required for combustion from the air inlet pipe installed on one side, the combustion is not uniform, and the air residence time in the combustion chamber is short, which leads to a low thermal efficiency.

In addition, the conventional stove is made of a bowl-like air chamber to fuel the injection nozzle is perforated so that the air required for combustion flows into the air chamber, the injection nozzle is blocked by the remaining ash such as coal, charcoal, firewood, etc. There is a problem that the supply of the necessary air is not smooth, not only the combustion rate is lowered, but also the cleaning is not easy due to the clogging of the injection nozzle.

The present invention has been made in order to solve the above-mentioned problems, to provide a downward combustion heat-dissipating stove that increases the combustion rate by increasing the residence time of the air along with even combustion by supplying the air required for combustion from the top to the bottom.

In addition, the present invention is to provide an environment-friendly down-burning heat dissipation stove that can be easily cleaned by installing a heat radiation conduit to maximize the heating effect while maximizing the heating effect while minimizing the generation of ash at a high combustion rate.

The present invention, in order to solve the above problems, the main body forming the appearance of the stove, the combustion chamber provided inside the main body, the combustion discharge pipe for discharging the combustion gas generated in the combustion chamber to the outside and the opening and closing for the fuel injection In the stove is provided with an inlet, the air supply pipe communicating with the outside is formed extending from the lower side of the combustion chamber to supply the air required for combustion from the top to the bottom, characterized in that the trap is formed so that the air outlet toward the bottom of the combustion chamber .

The main body is characterized in that at least one heat dissipation conduit penetrating the main body is formed so that the heat passes through the air.

The heat dissipation conduit is characterized in that it is installed to be inclined to cause convection action.

The heat dissipation conduit is characterized in that the tapered to accelerate the flow rate of air.

The heat dissipation conduit is characterized in that the drawer is further provided to insert and pull out so that food can be heated to contain.

The heat dissipation conduit is characterized in that the duct portion for receiving the air fed from the blower is provided on one side so as to force air blowing.

The heat dissipation conduit is characterized in that the louver is installed up and down to adjust the direction of the wind on the other side.

The main body of the main body is characterized in that the heat dissipation conduit is installed to a predetermined depth so that the heat exchange is made through the air therein, and the heating tube is provided in communication with the main body protrudes from the end of the heat dissipation conduit.

The heating tube is characterized in that the elbow tube is installed to be rotated to adjust the direction of the wind at the top.

And the main body is characterized in that the reopening opening is provided at the bottom of the combustion chamber, the back plate is installed in the lower outlet of the main body to be inserted and removed.

According to the present invention, as the air required for combustion is supplied from the top to the bottom, the fuel is burned from the top to the bottom, the combustion is made evenly from the center to the outside, and the air residence time in the combustion chamber is long, thereby enabling high efficiency combustion. The effect of complete combustion is to significantly reduce the generation of ash.

In addition, according to the present invention there is an effect that can be quickly heated by the installation of a heat dissipation conduit, it is possible to increase the contact area with the atmosphere to maximize the heating efficiency.

1 is a perspective view of a downward combustion heat dissipation stove according to the present invention,
Figure 2 is a cross-sectional view showing the internal structure of the bottom combustion type heat dissipation stove according to the present invention,
3 and 4 is a cross-sectional view showing the structure of the heat dissipation conduit of the downward combustion heat dissipation stove according to the present invention,
5 is a perspective view showing a drawer structure of a downward combustion heat dissipation stove according to the present invention;
Figure 6 is a perspective view showing the structure of the duct portion of the downward combustion heat dissipation stove according to the present invention,
Figure 7 is a perspective view showing a louver structure of the downward combustion heat dissipation stove according to the present invention,
Figure 8 is a cross-sectional view showing a back structure of the bottom combustion type heat dissipation stove according to the present invention,
9 is a cross-sectional view showing the internal structure of a conventional stove.

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

Downward combustion heat dissipation stove according to the present invention uses a solid fuel such as wood, pellets, lignite.

First, as shown in FIGS. 1 and 2, the downward combustion heat dissipation type stove according to the present invention has a main body 10 that greatly forms the appearance of a stove, a combustion chamber 20 provided inside the body 10, and a combustion chamber 20. A combustion discharge pipe 30 for discharging the combustion gas generated in the outside) and the opening and closing opening 40 for injecting fuel into the combustion chamber 20 are provided.

In addition, the air supply pipe 50 communicating with the outside is formed to extend from the lower side of the combustion chamber 20 so as to supply the air required for combustion from the top to the bottom, and the trap 51 is formed so that the air outlet points toward the bottom of the combustion chamber. do.

Here, the trap 51 is a portion bent in a U-shape so that the air outlet of the air supply pipe 50 formed to extend upwards toward the bottom of the combustion chamber 20, and convection action causes external cold air to flow into the combustion chamber 20. Although introduced, the discharge of hot combustion gas in the combustion chamber 20 is blocked.

According to the above technical configuration, the air required for combustion is supplied from the outside through the air supply pipe 50, the air outlet of the air supply pipe 50 toward the lower portion of the combustion chamber 20, but a predetermined distance from the lower portion of the combustion chamber 20 As they are spaced apart, the air required for combustion is supplied from top to bottom. Of course, the air inlet side of the air supply pipe 50 is provided with a switch 52 for adjusting the air inflow amount.

Therefore, during combustion, the fuel burns from the top to the bottom, burns from the center to the outside, so that combustion is made evenly, and the residence time of the air is increased, thereby increasing the combustion rate.

On the other hand, in the case of a large stove is applied a forced blowing method for supplying air from the side of the main body to supply a large amount of air, in this case, the flow rate in the combustion chamber is faster, the heat of combustion is easily escaped through the exhaust passage to reduce the thermal efficiency.

According to the present invention, when a plurality of air supply pipes are installed in consideration of the combustion chamber area, a plurality of air supply pipes can be provided to supply appropriate air for combustion, and by supplying air for combustion from the top to the bottom, the air residence time is increased to maximize thermal efficiency. You can do it.

Next, the main body 10 has at least one heat dissipation conduit 60 penetrating the main body 10 so that air passes through the main body 10 to form heat exchange.

According to the above technical configuration, the area of contact with the atmosphere is increased by the area of the heat dissipation conduit 60 to increase the heat exchange rate, and even if the main body 10 is not sufficiently heated, the heat dissipation conduit 60 is first heated to provide rapid heating. This becomes possible.

Next, the heat dissipation conduit 60 is installed inclined in the main body 10 to cause convection, as shown in FIG.

According to the above technical configuration, as the heat dissipation conduit 60 is installed inclined in the main body 10, the heated air in the heat dissipation conduit 60 rises along the inclined surface and is discharged to the room (heating space), and through the lower side of the inclined surface. Cold air is introduced into the heat dissipation conduit 60.

Therefore, the heating air in the heat dissipation conduit 60 is quickly discharged to the outside by the convection action to increase the heating efficiency.

Next, the heat dissipation conduit 60 is tapered to accelerate the flow rate of air as shown in FIG.

Specifically, the heat dissipation conduit 60 is installed inclined in the main body 10 so that the discharge port 61 is located on the upper side and the inlet 62 is located on the lower side, and the discharge port 61 is inlet 62 as it is tapered to one side. It is formed smaller than).

Accordingly, the flow rate of the air heated in the heat dissipation conduit 60 passes through the narrow discharge port 61 in close contact with the cold air introduced through the inlet 62.

As a result, the heating air can be sent away through the discharge port 61, thereby expanding the heating space.

Next, the heat dissipation conduit 60 is further provided with a drawer 70 is inserted and pulled out so that food can be heated to heat as shown in FIG.

According to the above technical configuration, the inside of the heat dissipation conduit 60 can be baked evenly put the sweet potato or potato in the drawer 70 as the heat is released from the top, bottom, left and right. Therefore, it is easy to cook a simple snack when heating.

Next, the heat dissipation conduit 60 is provided with a duct part 70 for receiving the air fed from the blower 73 on one side thereof to force the air blown as shown in FIG.

In detail, the blower 73 is installed below the main body 10, and the duct part 70 is provided at one side of the heat dissipation conduit 60 (not shown). The air blown by the blower 73 is pumped into the duct 71 through the duct pipe 72 to pass through the heat dissipation conduit 60 to perform heat exchange to be discharged into the room through the other side of the heat dissipation conduit 60.

Therefore, it is possible to maximize the heating effect by forced air.

Next, the heat dissipation conduit 60 (not shown) as shown in Figure 7 is provided with a louver 80 that can be rotated up and down to adjust the direction of the wind on the other side.

Accordingly, the outside air pressurized by the blower 71 is heated while passing through the heat dissipation conduit 60, and the direction is changed by the louver 80 to be discharged into the room.

Next, referring to FIG. 5, the main body 10 is provided with a heat dissipation conduit 60 at a predetermined depth to allow heat to pass through the air to be formed therein, and the main body 10 at the end of the heat dissipation conduit 60. The heating tube 63 is provided in communication with the upper part to protrude.

According to the above configuration, the heat dissipation conduit 60 is inserted into the main body 10 at a predetermined depth rather than penetrating the main body 10 as described above, and the air heated in the heat dissipation conduit 60 is main body. (10) The heating tube 63 is installed to be discharged into the room through the upper portion.

In addition, the heating tube 63 is provided with an elbow tube 64 that can be rotated to adjust the direction of the wind at its upper end. Reference numeral 65 is a handle for rotating the elbow (64).

Accordingly, it is possible to adjust the discharge direction of the heated air heated in the heat dissipation conduit 60 by rotating the elbow 64 to the left and right.

Next, as shown in FIG. 8, the main body 10 is provided with a reopening outlet 90 which can be opened and closed at the bottom of the combustion chamber, and a backrest 95 is installed at the lower part of the redistribution outlet 90 to be inserted from the outside of the main body. do.

According to the above technical configuration, after the combustion is completed, the combustion chamber 20 can be easily cleaned by opening the lid 91 of the redistribution outlet 90 and pushing the ash into the redistribution outlet 90 to recover the ashes through the ash tray 95. Will be.

The above description is an embodiment for aiding the understanding of the present invention, and various modifications and changes can be made within the scope of the technical idea of the present invention, which will be apparent to those skilled in the art.

10: Body
20: combustion chamber
30: combustion discharge pipe
40: inlet
50: air supply line
60: heat dissipation conduit
70: duct section
80: louver
90 Cultivation Exit

Claims (10)

In a stove provided with a main body forming the appearance of the stove, a combustion chamber provided inside the main body, a combustion discharge pipe for discharging the combustion gas generated in the combustion chamber to the outside, and an opening and closing opening for injecting fuel into the combustion chamber,
A downward combustion heat-dissipating stove, characterized in that an air supply pipe communicating with the outside extends upward from the lower side of the combustion chamber so that the air for combustion can be supplied from the top to the lower side, and a trap is formed so that the air outlet faces the bottom of the combustion chamber. . The method of claim 1,
The main body has at least one heat dissipation conduit penetrating through the main body so that air passes through the heat exchange is formed, characterized in that the downward combustion heat dissipation stove. The method of claim 2,
The heat dissipation conduit is a downward combustion heat dissipation stove, characterized in that installed inclined to cause convection action. The method of claim 3, wherein
The heat dissipation conduit is a downward combustion heat dissipation stove characterized in that the tapered to accelerate the flow rate of air. The method of claim 2,
The heat dissipation conduit is a downward combustion heat dissipation stove characterized in that the drawer is further provided to insert and pull out to heat the food. The method of claim 2,
The heat dissipation conduit is a downward combustion heat dissipation stove characterized in that the duct portion for receiving the air supplied from the blower is provided on one side so as to force the forced air blowing. The method according to claim 6,
The heat dissipation conduit is a downstream combustion type heat dissipation stove characterized in that the louver is installed up and down to adjust the direction of the wind on the other side. The method of claim 1,
The main body has a heat dissipation conduit is installed in a predetermined depth so that the heat exchange is carried out through the air therein, and the heating tube is installed in communication with the end of the heat dissipation conduit protruding from the upper end of the heat dissipation stove . The method of claim 8,
The heating pipe is a downward combustion heat dissipation stove characterized in that the rotatable elbow is installed to adjust the direction of the wind at its end. The method of claim 1,
The main body is provided with a reopening outlet that can be opened and closed at the bottom of the combustion chamber, the lower back combustion type heat dissipation stove characterized in that the lower back is installed in the lower outlet of the main body inserted and removed.

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