KR200468604Y1 - Firewood stove - Google Patents

Abstract

By implementing a three-stage multiple combustion system in three combustion chambers, a firewood stove is disclosed that is capable of completely burning unburned gas that has not been burned yet to realize complete combustion. The firewood stove disclosed body; A first combustion chamber configured inside the main body; A second combustion chamber configured at one side of the first combustion chamber; A third combustion chamber configured at one side of the second combustion chamber and configured to have an inner cylinder and an outer cylinder communicating with each other at a lower side thereof; A fuel supply pipe penetrating through an upper surface of the main body to be inserted into a lower end portion of the first combustion chamber to inject fuel into the first combustion chamber, and forming a heat transfer path between an outer surface and an inner surface of the first combustion chamber; A first heat induction pipe extending from the upper end of the first combustion chamber to the center of the upper end of the second combustion chamber and extending to the lower end of the second combustion chamber; A second hot air induction pipe connecting an upper end of the second combustion chamber and an upper end of an outer cylinder of the third combustion chamber to communicate with each other; And an exhaust pipe protruding from the upper end of the inner cylinder of the third combustion chamber to an upper surface of the main body and communicating with the inner cylinder.

Description

Firewood stove {FIREWOOD STOVE}

The present invention relates to a firewood stove, and more specifically, to a firewood stove configured to realize the complete combustion by completely burning unburned gas that is not burned by implementing three-stage multiple combustion in three combustion chambers. will be.

Not only the energy crisis due to oil depletion but also global warming due to carbon emissions increase, interest in eco-friendly energy is increasing under the banner of low carbon green growth.

In particular, wood and pellet fuels have been in the spotlight as natural-friendly fuels, and firewood stoves and pellet combustion systems using them as fuels have been widely used.

On the other hand, registered utility model 193809 discloses an example of a conventional firewood stove. As shown in Fig. 1, the conventional firewood stove is installed in a wood-fired boiler by separating the ignition door and the fuel replenishment door into two, and installing the flue position at the lower side of the incinerator (lower type flue). The size of the flue can be adjusted using the flue size regulator, and the incineration temperature is sensed to adjust the incineration with the air volume automatic controller.

Therefore, the conventional firewood stove is configured to solve the heating by using waste such as wood, paper, etc., which can be easily obtained around living.

However, in the conventional technology, since heat and smoke generated during combustion of firewood are discharged to the outside quickly through the communication, the heat exchange efficiency is not so much improved, and there is a problem that the amount of heat generated is small compared to the input amount of fuel. In addition, there is a problem that a large amount of smoke is generated as well as the complete combustion of the firewood is not made, and a smooth discharge of the smoke generated during combustion is not achieved.

The present invention has been devised to solve the above problems, the purpose is to implement a three-stage multiple combustion method in three combustion chambers, by being configured to completely burn the unburned gas not yet burned, thereby realizing complete combustion, It is to provide a firewood stove that thermal efficiency is greatly improved and fuel consumption is saved.

In addition, the purpose is to provide a firewood stove configured to smoothly discharge the smoke generated during combustion inside the firewood stove.

It is also an object to provide a firewood stove that is compatible to use pellet fuel.

The object of the present invention is a main body; A first combustion chamber configured inside the main body; A second combustion chamber configured at one side of the first combustion chamber; A third combustion chamber configured at one side of the second combustion chamber and configured to have an inner cylinder and an outer cylinder communicating with each other at a lower side thereof; A fuel supply pipe penetrating through an upper surface of the main body to be inserted into a lower end of the first combustion chamber so that fuel is injected into the first combustion chamber, and forming a heat transfer path between an outer surface and an inner surface of the first combustion chamber; A first heat induction pipe extending from the upper end of the first combustion chamber to the center of the upper end of the second combustion chamber and extending to the lower end of the second combustion chamber; A second hot air induction pipe connecting an upper end of the second combustion chamber and an upper end of an outer cylinder of the third combustion chamber to communicate with each other; It can be achieved by providing a firewood stove characterized in that it comprises an exhaust pipe which is formed to protrude from the upper end of the inner cylinder of the third combustion chamber to the upper surface of the main body and communicate with the inner cylinder.

Here, an initial fuel inlet is formed at a lower end of the first combustion chamber so as to communicate with the inside of the first combustion chamber, and the initial fuel inlet is a lower stopper configured to control the amount of air introduced into the first fuel chamber by adjusting the number of ventilation holes. It is configured to be selectively opened and closed through, the fuel supply pipe is configured to be selectively opened and closed through the upper stopper, the upper stopper is formed with a fuel injection hole in the upper surface and the fuel injection hole is configured to be eccentrically rotated in the center of the upper surface of the upper stopper It is preferably configured to be opened and closed through the cover, the safety net is installed around the main body is preferably configured to prevent a safety accident of the user.

And, a preheater is installed on the outside of the exhaust pipe to preheat the exhaust pipe, the preheater is a preheating main body is formed to surround the exhaust pipe and a plurality of through-holes are formed to allow the air to enter the outer surface, the preheater The outer surface of the main body preferably communicates with the inside of the preheating main body and is configured to include a gas torch insertion opening for supplying heat into the preheating main body.

In addition, the fuel supply pipe is equipped with a pellet burner is configured to be heated through the pellet fuel, the pellet burner is inserted into the fuel supply pipe and is provided with an inlet at the upper end of the pellet burner body is configured to be selectively opened and closed through the lid; The feed duct is formed integrally with the pellet burner body and is configured to be in the upper and lower narrow shapes, and a supply duct is formed at the bottom thereof to supply pellets sequentially fed into the inlet. It is preferable that the pellet comprises a pellet combustion chamber configured to be injected into the first combustion chamber through the communication hole, the primary combustion pellet through the input plate formed.

In addition, an air inflow passage is formed between the fuel supply pipe and the pellet burner body, and a through hole through which the pellet burner body penetrates is formed at the top of the fuel supply pipe and adjusts the amount of air introduced along the upper edge. An air inlet control plug having an adjustment unit is fitted and coupled thereto, and an air inlet hole communicating with the pellet combustion chamber is formed along the outer circumferential surface of the bottom of the pellet burner body, so that the air introduced through the air control unit opens the air inflow passage. It is preferably configured to be guided along and supplied to the pellet combustion chamber through the air inlet.

The firewood stove according to the present invention implements three-stage multi-combustion in three combustion chambers, so that it is possible to realize the complete combustion by completely burning the unburned gas that has not been burned. Since the high calorific value can be realized with the fuel, the fuel consumption is configured to be saved.

In addition, since the fuel is completely burned in the firewood stove according to the present invention, a large amount of smoke generated during incomplete combustion is prevented from being discharged to the outside, and the exhaust gas that is completely burned can be smoothly discharged through the exhaust pipe. It is effective.

1 is a view of a conventional firewood stove,
2 is a perspective view of a firewood stove according to the present invention,
3 is a cross-sectional view taken along the line AA of FIG.
4 is a cross-sectional view taken along the line BB of FIG.
5 is a view showing another preferred embodiment of the firewood stove according to the present invention,
6 and 7 is a view showing another preferred embodiment of the firewood stove according to the present invention.

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

2 is a perspective view of a firewood stove according to the present invention, FIG. 3 is a sectional view taken along line AA of FIG. 2, and FIG. 4 is a sectional view taken along line BB of FIG. 2.

Referring to Figures 2 to 4, the present invention implements a three-stage multiple combustion method in the three combustion chambers connected, the firewood stove is configured to realize the complete combustion by burning completely unburned gas The first combustion chamber 210, the second combustion chamber 220, and the third combustion chamber 230 may include a main body 100 installed therein. Here, the main body 100 is composed of the upper plate 110 and the lower plate 120 as shown, the first combustion chamber 210, the second combustion chamber 220, between the upper plate 110 and the lower plate 120, Although the third combustion chamber 230 may be installed, although not shown, the third combustion chamber 230 may be provided in a housing shape and configured to accommodate the first combustion chamber, the second combustion chamber, and the third combustion chamber. In addition, the bottom surface of the lower plate 120 is preferably provided with a wheel (R) is configured to facilitate the movement of the body.

In addition, a first combustion chamber 210 is configured in the main body 100, a second combustion chamber 220 is configured at one side of the first combustion chamber 210, and a third combustion chamber is configured at one side of the second combustion chamber 220. 230 is configured. In addition, the third combustion chamber 230 includes an inner cylinder 231 and an outer cylinder 232 in which lower sides thereof communicate with each other. Here, the first combustion chamber 210, the second combustion chamber 220, the third combustion chamber 230 may be installed adjacent to each other in the main body 100, the first combustion chamber 210, the second combustion chamber 220 Of course, the third combustion chamber 230 may be installed side by side. In addition, the first combustion chamber 210, the second combustion chamber 220, and the third combustion chamber 230 may be provided in various shapes as long as they have a combustion space therein. desirable.

Then, the fuel is injected into the first combustion chamber 210 through the upper surface of the main body 100 to be inserted into the lower end of the first combustion chamber 210, and the outer surface and the first combustion chamber 210. The fuel supply pipe 300 is formed to form a heat transfer path 310 between the inner surface of the. That is, the fuel is injected into the upper side of the fuel supply pipe 300 is supplied to the first combustion chamber 210, the heat generated in the first combustion chamber 210 is the first combustion chamber 210 through the heat transfer path (310) It is configured to be transferred to the upper side of the).

In addition, a first heat induction pipe 400 extends from the upper end of the first combustion chamber 210 to the center of the upper end of the second combustion chamber 220 and extends to the lower end of the second combustion chamber 220. . That is, the first hot air induction pipe 400 is generated in the first combustion chamber 210 to induce heat transferred to the upper side of the first combustion chamber 210 through the heat transfer path 310 to the second combustion chamber ( 220 is guided to the inner lower side. Here, the heat guided to the lower side of the second combustion chamber 220 through the first hot air induction pipe 400 is transferred to the upper side of the second combustion chamber 220 to perform the reburn process.

In addition, a second hot air induction pipe 500 is configured to connect the upper end of the second combustion chamber 220 and the upper end of the outer cylinder of the third combustion chamber 230 to communicate with each other. That is, the second hot induction pipe 500 is introduced into the lower side of the second combustion chamber 220 through the first hot induction pipe 400, and then heat is transferred to the upper side of the second combustion chamber 220. It is configured to guide to guide the upper end of the outer cylinder 232 of the third combustion chamber (230). Here, the heat guided to the upper end of the outer cylinder 232 through the second heat induction pipe 500 is transferred to the lower side of the outer cylinder 232 and flowed into the lower side of the inner cylinder 231 and then to the upper side of the inner cylinder 231. During the transfer, a second reburn process is performed.

The exhaust pipe 600 is formed to protrude from the upper end of the inner cylinder 231 of the third combustion chamber 230 to the upper surface of the main body 100 to communicate with the inner cylinder 231. That is, the exhaust pipe 600 is discharged to the outside by performing a second reburn process while being transferred to the upper side of the inner cylinder 231. In this case, it is preferable that the communication pipe 610 is coupled to the exhaust pipe 600 so that the exhaust gas can be easily discharged to the outside.

On the other hand, it is preferable that the initial fuel inlet 700 is formed at the lower end of the first combustion chamber 210 to communicate with the inside of the first combustion chamber 210. That is, the initial fuel inlet 700 is a portion for performing initial combustion by injecting fuel into the first combustion chamber 210 before the fuel is injected through the fuel supply pipe 300. Here, the initial fuel inlet 700 may be configured to be selectively opened and closed through a lower plug 710 configured to control the amount of air flowing into the first fuel chamber 210 by adjusting the number of vents 711. It is desirable to be configured.

Further, the fuel supply pipe 300 is preferably configured to be selectively opened and closed through the upper cap 720. Here, the upper plug 720 is a fuel injection hole 721 is formed on the upper surface and the fuel injection hole 721 is configured to be selectively opened and closed through the cover 722 configured to be eccentrically rotated in the center of the upper surface of the upper plug do. Of course, the fuel injection hole 721 is configured to allow not only fuel but also air to flow into the first combustion chamber 210 so that fuel combustion can be efficiently performed.

Furthermore, it is preferable that a safety net 730 is installed around the main body 100 to prevent a safety accident of a user.

Now look at the combustion process and action / effect of the firewood stove according to the present invention configured as described above.

The firewood stove according to the present invention is supplied with fuel to the upper side of the fuel supply pipe 300 is supplied to the first combustion chamber 210, the fuel supplied to the first combustion chamber 210 is the primary combustion. Then, the heat generated by combustion in the first combustion chamber is led to the upper side of the first combustion chamber 210 through the heat transfer path 310. That is, the primary combustion is made while the heat is guided to the upper side of the first combustion chamber 210 through the heat transfer path 310.

In addition, the heat induced to the upper side of the first combustion chamber 210 through the heat transfer path 310 is guided to the lower side of the second combustion chamber 220 through the first heat induction pipe 400. Here, the heat guided to the lower side of the second combustion chamber 220 through the first heat induction pipe 400 is transferred to the upper side of the second combustion chamber 220 to perform the reburn process. That is, the secondary combustion is made while the heat is transferred to the upper side of the second combustion chamber 220 as described above.

Then, the heat transferred to the upper side of the second combustion chamber 220 is guided to the upper end of the outer cylinder 232 through the second heat induction pipe 500, and then transferred to the lower side of the outer cylinder 232, the inner cylinder 231 After being introduced to the lower side of the inner cylinder 231 is transferred to the upper side to perform the second reburn process. That is, the third combustion is made while the heat is transferred to the upper side of the inner cylinder 231 as described above.

In addition, the exhaust pipe 600 communicated with the inner cylinder is transferred to an upper side of the inner cylinder 231 to perform a second reburn process, and exhausted exhaust gas is completely burned out.

As such, the present invention implements three-stage multi-combustion in three combustion chambers, and thus, burns unburned gas completely and realizes complete combustion. Since high calorific value can be realized, fuel consumption is saved.

In addition, the present invention is because the complete combustion of the fuel in the firewood stove is realized so that a large amount of smoke generated during incomplete combustion is prevented from being discharged to the outside and the exhaust gas that is completely burned can be smoothly discharged through the exhaust pipe. There is an advantage.

On the other hand, the firewood stove according to the present invention it is preferable that the preheater 800 is installed outside the exhaust pipe 600 to preheat the exhaust pipe. Specifically, as shown in FIG. 5, the preheater 800 is installed to surround the exhaust pipe 600, and a preheating base 810 in which a plurality of through holes 811 are formed to allow air to flow into the outer surface. And a gas torch insertion hole 820 configured to communicate with an inside of the preheating base 810 and to insert a torch T into an outer surface of the preheating base 810 to supply heat to the preheating base 810. It is configured by. That is, during the initial combustion of the first combustion chamber 210, when the exhaust pipe 600 is heated through the preheater 800, the exhaust pipe 600 has a higher temperature than the first combustion chamber 210. Therefore, the air of the first combustion chamber 210 is moved to the exhaust pipe 600 by the temperature difference with the exhaust pipe 600, and the smoke generated during the initial combustion of the first combustion chamber 210 is easily discharged to the exhaust pipe. Here, the preheating base 800 is configured to be coupled to each other through a fastening member (C) such as the exhaust pipe 600 and the connecting ring.

And, as shown in Figure 6 and 7, the subject innovation is preferably a pellet burner 900 is mounted on the fuel supply pipe 300 is configured to be able to heat through the pellet fuel (P). Specifically, the pellet burner 900 is inserted into the fuel supply pipe 300 and is provided with an inlet 911 at the upper end of the pellet burner body 910 and configured to be selectively opened and closed through the lid 911a, and the pellet burner A supply duct 920 formed integrally with the body 910 and configured to have a light-lower narrowing shape, and a supply hole 921 for sequentially supplying pellets P introduced into the inlet 911 at a lower end thereof; In addition, the first combustion chamber 210 is formed through the communication hole 931a by the pellet P, which is primarily burned through the input plate 931 formed at the lower side of the supply duct 920 and having a plurality of communication holes 931a formed therein. It is configured to include a pellet combustion chamber 930 is configured to be injected into). That is, the pellet combustor 900 is supplied with the pellet fuel P introduced into the inlet 911 to the pellet combustion chamber 930 through the supply hole 921 of the supply duct, and then the first combustion in the pellet combustion chamber. The pellet fuel is injected into the first combustion chamber 210 through the communication hole 931a and configured to be combusted. As such, the present invention has the advantage of being compatible with the use of various fuels because it can be used by mounting the pellet burner 900 that can use the pellet fuel in the fuel supply pipe (300).

Here, an air inflow passage 940 is formed between the fuel supply pipe 300 and the pellet burner body 910, and the pellet burner body 910 penetrates through the center of the fuel supply pipe 300. A ball 951 is formed and an air inlet control plug 950 to which an air control unit 952 is formed to control the amount of air flowing along the upper edge thereof is fitted and coupled to the bottom of the pellet burner body 910. The air inlet hole 960 communicating with the pellet combustion chamber 930 is preferably formed along an outer circumferential surface thereof. That is, the air introduced through the air conditioner 952 is guided along the air inlet passage 940 and is supplied to the pellet combustion chamber 930 through the air inlet hole 960. Therefore, the air is continuously supplied to the pellet combustion chamber 930 so that the combustion efficiency of the pellet fuel P is significantly increased, and the complete combustion of the pellet fuel is achieved.

As described above, the present invention has been shown and described in connection with specific embodiments, but those skilled in the art that various modifications and changes can be made without departing from the spirit and scope of the invention as indicated by the claims. Anyone can easily know.

100: main body 210: first combustion chamber
220: second combustion chamber 230: third combustion chamber
300: fuel supply pipe 400: first hot air induction pipe
500: second heat induction pipe 600: exhaust pipe
700: initial fuel input 710: lower stopper
720: upper stopper 730: safety net
800: preheater 900: pellet burner

Claims (5)

main body;
A first combustion chamber configured inside the main body;
A second combustion chamber configured at one side of the first combustion chamber;
A third combustion chamber configured at one side of the second combustion chamber and configured to have an inner cylinder and an outer cylinder communicating with each other at a lower side thereof;
A fuel supply pipe penetrating through an upper surface of the main body to be inserted into a lower end of the first combustion chamber so that fuel is injected into the first combustion chamber, and forming a heat transfer path between an outer surface and an inner surface of the first combustion chamber;
A first heat induction pipe extending from the upper end of the first combustion chamber to the center of the upper end of the second combustion chamber and extending to the lower end of the second combustion chamber;
A second hot air induction pipe connecting an upper end of the second combustion chamber and an upper end of an outer cylinder of the third combustion chamber to communicate with each other;
Firewood stove characterized in that it comprises an exhaust pipe protruding from the upper end of the inner cylinder of the third combustion chamber to the upper surface of the main body in communication with the inner cylinder.
The method of claim 1,
An initial fuel inlet is formed at a lower end of the first combustion chamber so as to communicate with the inside of the first combustion chamber, and the initial fuel inlet is provided through a lower stopper configured to control the amount of air flowing into the first fuel chamber by adjusting the number of ventilation holes. Is configured to be opened and closed selectively,
The fuel supply pipe is configured to be selectively opened and closed through the upper stopper, the upper stopper is a fuel injection hole is formed on the upper surface and the fuel injection hole is configured to be selectively opened and closed through a cover configured to be eccentrically rotated in the center of the upper surface of the upper stopper ,
Firewood stove characterized in that the safety net is installed around the main body is configured to prevent a safety accident of the user.
The method of claim 1,
The preheater is installed outside the exhaust pipe to preheat the exhaust pipe,
The preheater is installed to wrap the outside of the exhaust pipe and the preheating main body is formed with a plurality of through-holes to allow air to flow into the outer surface, the preheater is configured to communicate with the inside of the preheating main body and the torch is inserted into the outer surface of the preheating main body A firewood stove comprising a gas torch insertion opening for supplying heat into the body.
The method of claim 1,
The fuel supply pipe is equipped with a pellet burner is configured to be heated through the pellet fuel,
The pellet burner is inserted into the fuel supply pipe and is provided with an inlet at the top is configured to open and close selectively through the lid, the pellet burner body is integrally formed in the shape of the upper and lower strait, the inlet at the bottom The first combustion pellets are introduced into the first combustion chamber through the supply holes through which the feed ducts are formed, and the feed ducts are sequentially supplied with the feed ducts, and the input plate formed under the supply ducts and formed with a plurality of communication holes. Firewood stove, characterized in that configured to include a pellet combustion chamber configured to be.
5. The method of claim 4,
An air inlet passage is formed between the fuel supply pipe and the pellet burner body, and a through hole through which the pellet burner body penetrates is formed at the top of the fuel supply pipe, and an air control unit for adjusting the amount of air introduced along the upper edge thereof. The air inlet control plug is formed is coupled to the lower end of the pellet burner body is formed with an air inlet hole communicating with the pellet combustion chamber along its outer peripheral surface,
Firewood stove, characterized in that the air flowing through the air control unit is guided along the air inlet passage is supplied to the pellet combustion chamber through the air inlet hole.

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