KR102437889B1 - Air circulation type high temperature combustion firewood stove - Google Patents

Abstract

The present invention relates to an air circulation type high-temperature combustion firewood stove. The present invention is to provide the air circulation type high-temperature combustion firewood stove. According to the present invention, up to three combustion chambers with different diameters are installed inside a case of a stove main body. Therefore, heat and smoke generated as a firewood is burned in a primary combustion chamber are not immediately discharged or emitted, but are burned through secondary and tertiary combustion chambers and then circulated through the case before discharged. As a result, the heat and the smoke stay inside the case of the stove main body for a long time and are burned, and circulate inside the case to be completely burned, thereby maximizing high-temperature combustion and thermal efficiency. The air circulation type high-temperature combustion firewood stove of the present invention comprises: a housing; the primary combustion chamber; the secondary combustion chamber; the tertiary combustion chamber; a discharge unit; first to third air supplying pipes; and a lower part bulkhead.

Description

Air circulation type high temperature combustion firewood stove

The present invention relates to a wood stove, and more particularly, by allowing the wood to burn for a long time while circulating inside the stove without immediately discharging the smoke generated after the wood is burned, high-temperature combustion and thermal efficiency It relates to an air circulation type high-temperature combustion wood stove that maximizes

A stove is often used as a device to keep the air in a certain space in a warm state. There are various types of fuel used for the stove, such as oil and coal, as well as using firewood. A space of a certain size is required so that the firewood can be burned well, and a passage through which outside air can be easily introduced and a smoke exhaust passage must be provided so that the smoke generated during combustion can be smoothly discharged. In recent years, various types of wood stoves have been released to suit different uses, such as household use, greenhouse use, and agricultural use for plastic houses and smart farms.

In general, wood stoves use logging, thinned wood, and discarded waste wood as their main fuel, which can be easily obtained in the vicinity of life. The heat exchange efficiency is very low, and there is a problem that the calorific value is too small compared to the input amount of the wood. The wood stove burns the gas from the wood to generate heat. Of course, there is a problem that the smoke generated during combustion is not smoothly discharged.

Regarding the wood stove, patent registration No. 1497830 “high efficiency wood stove”, patent registration No. 1786730 “wood stove”, and patent registration No. 2155508 “burner for wood stove” have appeared. There are many problems with wood stoves that have appeared so far. Specifically,

First, since the main body of the stove is a single hollow tube, and the communication is directly connected to one side of the main body, the heat and smoke generated while burning the firewood do not stay inside the main body of the stove for a long time. Since it is discharged directly to the outside through the heat exchanger, there is a problem that not only the thermal efficiency is low, but also the amount of heat generated is too small compared to the input amount of firewood.

Second, since the heat and smoke are emitted directly from the main body of the stove, it is fundamentally a structure that cannot be completely burned by firewood. In addition, because of the structure in which air circulation cannot be made inside the main body, the smoke generated during combustion is not smoothly discharged, so there is a problem that only soot sticks to the chimney and the inner wall of the main body.

Third, because the door leaf for putting the firewood into the stove is located at the lower side of the main body of the stove, it is inconvenient to put the firewood in a squatting position. Since the firewood is piled up inside, there is a problem that the fire is easily extinguished because of the newly put in if the previously put in is not completely lit. There is a problem in that the input firewood is ignited and burned in a short time, so that the thermal efficiency and calorific value are too low compared to the input firewood.

The present invention has been devised to solve the above problems, and an object of the present invention is to install primary to tertiary combustion chambers having different diameters inside the housing of the stove, so that firewood is removed from the primary combustion chamber. By passing through the secondary and tertiary combustion chambers without discharging the heat and smoke generated during combustion, the length of time it stays in the combustion chamber, and then circulating the inside of the housing before discharging it causes heat and smoke to remain inside the housing of the stove for a long time. This is to provide an air circulation type high-temperature combustion wood stove that not only burns completely while staying, but also circulates inside the housing to maximize high-temperature combustion and thermal efficiency.

Another object of the present invention is to insert the firewood vertically from the upper part of the stove housing so that a large amount of firewood can be put in at once, prevent the fire from going out while putting the firewood, and an air circulation type that allows complete combustion while burning for a long time. It is to provide a high-temperature combustion wood stove.

An air circulation type high-temperature combustion wood stove according to the present invention comprises: a housing having a hexahedral casing; It has a hollow cylindrical shape and is vertically installed inside the housing, and the opened upper surface is connected to the upper surface of the housing and is fixedly installed, the opened upper surface is closed with a lid, and the lower surface is provided with a receptacle, There is a primary combustion chamber that opens the lid and puts firewood; a secondary combustion chamber connected to a lower portion of the primary combustion chamber and installed horizontally; a tertiary combustion chamber having a hollow cylindrical shape and being installed vertically at the end of the secondary combustion chamber, the height of which is lower than that of the primary combustion chamber; a discharge unit protruding outward from the housing at the upper end of the tertiary combustion chamber and discharging the smoke generated while the firewood is burned; first to third air supply pipes that suck air from the outside of the housing and supply air to the first to third combustion chambers, respectively; It is installed in a plate shape at a height spaced apart from the bottom surface of the housing by a predetermined interval, and comprises a lower bulkhead in which the primary combustion chamber to the tertiary combustion chamber are installed on the plate-shaped upper part, and the firewood is burned in the primary combustion chamber. It is characterized in that the smoke generated during the combustion is further sequentially passed through the secondary combustion chamber and the tertiary combustion chamber, and then the smoke is exhausted through the exhaust unit.

Preferably, the size of the cross section of the secondary combustion chamber is smaller than the size of the cross section of the primary combustion chamber, and the size of the cross section of the tertiary combustion chamber is formed smaller than the size of the cross section of the secondary combustion chamber.

Preferably, the tertiary combustion chamber is formed of a double tube having an inner tube and an outer tube, and a combustion air hole is formed in the inner tube in a spiral shape.

Preferably, the inlets for sucking the outside air from the first to third air supply pipes are respectively located on the outside of the housing, and each air supply pipe sequentially connects the outer peripheral surface of the secondary combustion chamber and the outer peripheral surface of the lower end of the primary combustion chamber inside the housing. The first air supply pipe has air supply holes formed at equal intervals in the portion piped to be in contact with the outer circumferential surface of the primary combustion chamber, so that air is supplied to the inside of the primary combustion chamber through the air supply hole, and the second The air supply pipe is piped to supply air to the inlet of the secondary combustion chamber after passing through the outer peripheral surface of the secondary combustion chamber and the outer peripheral surface of the lower end of the primary combustion chamber, and the third air supply pipe connects the outer peripheral surface of the secondary combustion chamber and the outer peripheral surface of the lower end of the primary combustion chamber. After piping is sequentially in contact with the outer peripheral surface of the secondary combustion chamber again after the piping is piped to supply air to the tertiary combustion chamber.

Preferably, an opening/closing valve capable of adjusting the amount of air sucked into each air supply pipe is installed at the inlet of each air supply pipe located outside the housing in the first to third air supply pipes.

Preferably, in the interior of the housing, a front bulkhead installed in a plate shape on the outside of the primary combustion chamber spaced apart from the front vertical surface of the housing by a predetermined interval, and a rear vertical surface of the housing spaced apart by a predetermined interval to the outside of the tertiary combustion chamber A plate-like rear bulkhead is further installed; Each upper end of the front bulkhead and the rear bulkhead is connected to the ceiling of the housing, and the lower end is connected to the lower bulkhead and is fixedly installed. The smoke burned in the combustion chamber is discharged to the space surrounded by the front bulkhead, the rear bulkhead and the lower bulkhead, and then is discharged through the smoke circulation hole formed in the front bulkhead, so that the inner surface of the housing is spaced apart from the front bulkhead, the rear bulkhead, and the lower bulkhead. After circulating the inside of the housing along the circulation path formed as the result is, it is discharged to the outside through the discharge unit.

Preferably, a sliding door damper is further installed at the end of the secondary combustion chamber, so that at the initial stage of igniting the fire, the sliding door damper is opened to discharge smoke directly without passing through the tertiary combustion chamber.

Preferably, the discharge unit, horizontal communication installed to protrude a predetermined length from the housing; Vertical communication installed vertically at the end of horizontal communication; It is installed in the lower part of the vertical communication and is configured with a diffusion air damper that can control the temperature of the smoke that is discharged by inhaling or blocking the outside air by adjusting the opening degree.

The wood stove according to the present invention is formed in a spiral shape with the smallest diameter after second combustion in the secondary combustion chamber without immediately discharging the heat and smoke generated when the wood wood is burned in the primary combustion chamber with the largest diameter. The heat and smoke formed in a tornado shape by burning the third time in the tertiary combustion chamber where one combustion air hole is formed is circulated again inside the housing and then discharged. It stays for a long time, circulates and burns, so that it burns completely, maximizing thermal efficiency as well as high-temperature combustion.

In addition, the air supplied to each combustion chamber through each air supply pipe is heated and supplied in a heated state, and it has the same structure as the venturi tube in which the diameter of the primary combustion chamber is the largest and the diameter of the tertiary combustion chamber is the smallest. Smoke generated from burning wood in the secondary combustion chamber accumulates as it goes to the secondary and tertiary combustion chambers, and the smoke discharged at a high speed from the tertiary combustion chamber circulates along the inner wall of the stove housing and is then discharged. An environment for combustion and high-temperature combustion is created, and thermal efficiency can be maximized while enabling actual complete combustion and high-temperature combustion.

In addition, since the firewood is put in from the upper part of the stove housing, it is not only convenient to put the firewood in, but also the firewood is placed vertically so that a large amount of firewood can be put in at once. Since it is not put on top of the burning firewood, the fire does not go out while the firewood is put in, and complete combustion is possible as it burns for a long time.

1 is a perspective view of a wood stove according to the present invention.
2 is a view for explaining the configuration of the wood stove.
3 is a view for explaining a structure for supplying air to the primary combustion chamber through the first air supply pipe.
4 is a view for explaining a structure for supplying air to the secondary combustion chamber through the second air supply pipe.
5 is a view for explaining a structure for supplying air to the tertiary combustion chamber through the third air supply pipe.
6 is a view for explaining a state in which the heat and smoke that have been burned up to the tertiary combustion chamber are circulated and exhausted inside the housing.

The technical feature of the wood stove according to the present invention is that the internal structure of the hearth housing is provided with three combustion chambers connected sequentially with different cross-sectional areas, so that the smoke generated while the wood is burned stays in the stove for a long time and burns completely. Of course, high-temperature combustion and thermal efficiency are maximized, and by inserting the firewood from the upper part of the stove housing, the input posture is convenient, a large amount of firewood can be put in at once, and complete combustion over a long period of time while preventing the fire from being extinguished. to be.

The wood stove according to the present invention has different cross-sectional areas and sequentially connected primary to tertiary combustion chambers 20, 30, and 40 are installed inside the housing 10, and air is sucked from the inside of the housing 10. First to third air supply pipes 21 , 31 , 41 for supplying heated air to each combustion chamber are respectively installed, and the first to third combustion chambers 20 , 30 and 40 are provided in the housing 10 . It is installed on the upper part of the lower bulkhead 14 that is spaced apart from the floor and installed at a certain height, and the smoke generated when the firewood is burned in the primary combustion chamber 20 is sequentially added to the secondary combustion chamber 30 and the tertiary combustion chamber 40. After being burned while passing through, the smoke is circulated inside the housing 10 and then the smoke is exhausted through the discharge unit 50 (see FIGS. 1 and 2 ).

The housing 10 is configured with a hexahedral casing 11 , and a see-through window made of heat-resistant glass is installed at an appropriate location of the casing 11 so that the inside of the housing 10 can be seen. The primary combustion chamber 20 has a hollow cylindrical shape and is vertically installed inside the housing 10, an opened upper surface is connected to the upper surface of the housing 10 and is fixedly installed, and the opened upper surface is a lid It is closed by (15), and an ash tray 22 is provided on the lower surface, and the lid 15 is opened to put firewood.

Since the user opens the lid 15 at the upper part of the primary combustion chamber 20 and puts the firewood in a standing position without bending the waist, it is not only convenient to insert the firewood, but also because the firewood is placed vertically upright. It is possible to put in the firewood, and there is an advantage that the fire does not go out while putting in the firewood because it is not put in as the firewood that is newly put in does not accumulate on top of the firewood that is burning.

The lower surface of the primary combustion chamber 20 is formed in a lattice shape in which holes of a certain size are uniformly formed, so that ash generated after the firewood is burned is discharged to the ash tray 22 through the lattice shape. , A cleaning tool that can be opened and closed is installed in the portion of the housing 10 where the ash tray 22 is located so that the ash accumulated on the ash tray 22 can be taken out from the outside of the housing 10 (see FIG. 2 ). ).

The secondary combustion chamber 30 is connected to the lower portion of the primary combustion chamber 30 and installed horizontally, and the cross-sectional shape of the secondary combustion chamber 30 is preferably made in a rectangular shape. Because, after the first to third air supply pipes 21, 31, and 41 each suck in air from the outside, the first to third air supply pipes 21, 31, 41 are connected to the secondary combustion chamber 30 and the primary combustion chamber ( 20) Since it is piped so as to be in contact with the outer circumferential surface and supplies heated air to each combustion chamber after being heated by the heat of each combustion chamber, if the air supply pipe is formed in a rectangular shape, the area in which the air supply pipe comes into contact with the outer circumferential surface of the combustion chamber expands. This is because a lot of heat can be absorbed (see FIG. 4 ).

The tertiary combustion chamber 40 has a hollow cylindrical shape and is vertically installed at the end of the secondary combustion chamber 30 , and has a lower height than the primary combustion chamber 20 . That is, the upper end of the primary combustion chamber 20 is installed in contact with the ceiling of the housing 10, but the upper end of the tertiary combustion chamber 40 is installed so as not to touch the ceiling of the housing. After the smoke circulates in the housing 10 , it is discharged to the discharge unit 50 . In addition, the tertiary combustion chamber 40 is formed as a double tube in which the inner tube 43 and the outer tube 42 are installed to be spaced apart from each other at a predetermined interval in order to further increase the combustion efficiency, and the inner tube 43 has a spiral. It is desirable to form the combustion air hole 431 in a shape so that the smoke is combusted while forming a tornado shape, so that the flame stays in the combustion chamber for a sufficient time and the smoke that has not been burned is completely burned so that the combustion temperature can also rise. (See Fig. 5).

One of the characteristics of the present invention is that the cross-sectional area of each combustion chamber is manufactured differently, and the size of the cross-section of the secondary combustion chamber 30 is smaller than the size of the cross-section of the primary combustion chamber 20, and the tertiary combustion chamber ( The size of the cross section of 40) is formed smaller than the size of the cross section of the secondary combustion chamber 30 . The air supplied to each combustion chamber through each air supply pipe is heated and supplied in a hot state, and the diameter of the primary combustion chamber 20 is the largest and the diameter of the tertiary combustion chamber 40 is the smallest. Because of the structure, the heat and smoke generated while burning wood in the primary combustion chamber 20 is naturally accumulated as it goes to the secondary and tertiary combustion chambers 30 and 40, and the high speed in the tertiary combustion chamber 40 Since the heat and smoke discharged from the furnace are discharged after heat exchange while circulating along the inner wall of the stove housing 10, the thermal efficiency can be maximized during complete combustion and high-temperature combustion.

The first to third air supply pipes 21 , 31 , and 41 suck air from the outside of the housing 10 and supply air to the first to third combustion chambers 20 , 30 and 40 , respectively. The inlets for sucking the outside air from the first to third air supply pipes 21 , 31 , 41 are respectively located outside the housing 10 , and each air supply pipe has a secondary combustion chamber 30 inside the housing 10 . It is piped so as to sequentially contact the outer circumferential surface of the primary combustion chamber 20 and the outer circumferential surface of the lower end of the primary combustion chamber 20, and it is preferable to use a rectangular cross-sectional shape of each air supply pipe. As described above, since each air supply pipe is a rectangular tube, the contact area is wide while in contact with the outer peripheral surfaces of the secondary combustion chamber 30 and the primary combustion chamber 20, so that a lot of heat can be structurally absorbed from the combustion chamber.

The first air supply pipe 21 has air supply holes 212 formed at equal intervals in a portion in contact with the outer circumferential surface of the primary combustion chamber 20, so that air is provided in the primary combustion chamber 20 through the air supply hole 212. A hole for supplying air must be formed in the primary combustion chamber 20 as well at a position corresponding to the air supply hole 212, and the end of the first air supply pipe 21 is closed. it should be

The second air supply pipe 31 passes the outer peripheral surface of the secondary combustion chamber 30 and the outer peripheral surface of the lower end of the primary combustion chamber 20, and then heats the heated air through the end of the secondary air supply pipe 31. It is supplied to the inlet portion of the secondary combustion chamber (30). The third air supply pipe 41 is piped so as to sequentially contact the outer circumferential surface of the secondary combustion chamber 30 and the outer circumferential surface of the lower end of the primary combustion chamber 20, and then again after being piped to be in contact with the outer circumferential surface of the secondary combustion chamber 30 It is piped to supply air to the secondary combustion chamber 40 , and the hottest air is supplied to the tertiary combustion chamber 40 .

In the first to third air supply pipes 21, 31 and 41, at the inlet of each air supply pipe positioned outside the housing 10, first to third on-off valves capable of controlling the amount of air sucked into each air supply pipe. (211, 311, 411) are installed, respectively, the user can adjust the amount of air sucked by manually adjusting.

One of the features of the present invention is that it maximizes thermal efficiency by maximizing the use of heat by circulating the inside of the housing 10 and then discharging it without discharging the burned smoke up to the tertiary combustion chamber 40 immediately. In order to form a circulation path through which smoke can circulate inside the housing, a front bulkhead 12, a rear bulkhead 13, and a lower bulkhead 14 are installed inside the housing 10 to be spaced apart from the casing 11 by a predetermined distance. did.

The lower bulkhead 14 has a plate-like configuration installed at a height spaced apart from the bottom surface of the housing 10 by a predetermined interval, and the primary to tertiary combustion chambers 20, 30, and 40 are installed on the plate-like upper part. and the ash tray 22 is installed in the lower part of the lower partition wall 14 . The front bulkhead 12 is spaced apart from the front vertical surface of the casing 11 of the housing 10 (in this specification, 'front' refers to the side opposite to the side where the discharge part is installed, that is, the side on which the primary combustion chamber is installed) and the primary combustion chamber. It is installed in a plate shape on the outside of (20), and the rear bulkhead 13 is the rear vertical surface (in this specification, the 'rear' is the side where the discharge part is installed, that is, the tertiary combustion chamber) in the casing 11 of the housing 10. installed side) and spaced apart from each other in a plate shape on the outside of the tertiary combustion chamber 40 (see FIG. 6 ).

Each upper end of the front bulkhead 12 and the rear bulkhead 13 is connected to the ceiling of the housing 10 and the lower end is connected to the lower bulkhead 14 to be fixedly installed, and the front bulkhead installed in contact with the ceiling of the housing 10 ( 12), a smoke circulation hole 121 is formed in the upper central part, so that the heat and smoke burned in the tertiary combustion chamber 40 are directed to the front bulkhead 12, the rear bulkhead 13, and the lower bulkhead 14. After being discharged into the enclosed internal space, it is discharged through the smoke circulation hole 121 formed in the front bulkhead 12, so that the inner surface of the housing 10 is the front bulkhead 12, the rear bulkhead 13, and the lower bulkhead 14 ) and is circulated inside the housing 10 along the circulation passage formed while being spaced apart and then discharged to the outside through the discharge unit 50 . As described above, since smoke and heat circulate inside the housing 10 and stay inside the housing 10 for a sufficient time, it is possible to maximize the thermal efficiency during complete combustion and high-temperature combustion (see FIG. 6 ).

It is preferable to install the sliding door damper 16 on the outside of the end portion of the secondary combustion chamber 30 rather than the portion where the tertiary combustion chamber 40 is installed. At the initial stage of igniting the firewood, the fire is not completely lit, so there is a lot of smoke. will be expelled immediately. After the fire is lit, if the sliding door damper 16 is closed, the smoke does not go from the secondary combustion chamber 30 to the discharge unit 50 but goes to the tertiary combustion chamber 40 and is burned in the tertiary combustion chamber 40. After circulating inside the housing 10 , it is exhausted to the discharge unit 50 .

The discharge unit 50 is installed to protrude outward from the housing 10 on the upper end side of the tertiary combustion chamber 40 to discharge the smoke generated while the firewood is burned, and from the housing 10 horizontally The horizontal communication 51 protruded to a certain length, the vertical communication 52 installed vertically at the end of the horizontal communication 51, and the vertical communication 52 installed in the lower part to control the amount of external air sucked It is configured to include a diffusion air damper (53), and the diffusion air damper (53) is installed to be located at a lower position than the horizontal communication (51) in order to effectively control the temperature of the discharged heat and smoke. it is preferable The diffusion air damper 53 adjusts the opening degree of the control plate that opens and closes the passage to increase and decrease the amount of external air sucked in to control the temperature of the smoke discharged, and the diffusion air damper has a characteristic configuration of the present invention. However, since it is a configuration widely used in various fields, a detailed description thereof will be omitted.

At the initial stage of ignition of the wood stove, the diffusion air damper 53 is kept closed to prevent cold air from flowing in. When the wood stove is overheated, the stored heat is immediately discharged. By opening it, cold air is sucked in from the outside and mixed with the hot air, so that the heat is not immediately discharged, and the temperature of the emitted heat and smoke is controlled. When the stove is operating in a normal state, if the diffusion air damper 53 is left in the half-open state, an appropriate amount of cold air from the outside is sucked in and mixed with the smoke and heat that is discharged, and it is possible to control the discharge of the stored heat.

The above description is illustrative of the present invention, and the embodiments published in the specification are intended to explain, not to limit the technical idea of the present invention, so those of ordinary skill in the art to which the present invention pertains Various modifications and variations will be possible without departing from the technical idea of Therefore, the protection scope of the present invention is interpreted by the matters described in the claims, and technical matters within the scope equivalent thereto should be construed as being included in the scope of the present invention.

10: housing 11: casing
12: front bulkhead 121: smoke circulation hole
13: rear bulkhead 14: lower bulkhead
15: lid 16: sliding door damper
20: primary combustion chamber 21: first air supply pipe
211: first on/off valve 212: air supply hole
22: ash tray
30: secondary combustion chamber 31: second air supply pipe
311: second on-off valve
40: 3rd combustion chamber 41: 3rd air supply pipe
411: third on-off valve 42: external pipe
43: inner tube 431: combustion air hole
50: discharge part 51: horizontal communication
52: vertical communication 53: diffusion air damper

Claims (8)

a housing having a hexahedral casing;
It has a hollow cylindrical shape and is vertically installed inside the housing, and the opened upper surface is connected to the upper surface of the housing and is fixedly installed, the opened upper surface is closed with a lid, and the lower surface is provided with a receptacle, There is a primary combustion chamber that opens the lid and puts firewood;
a secondary combustion chamber connected to a lower portion of the primary combustion chamber and installed horizontally;
a tertiary combustion chamber having a hollow cylindrical shape and installed vertically at the end of the secondary combustion chamber, the height of which is lower than that of the primary combustion chamber;
a discharge unit protruding outward from the housing at the upper end of the tertiary combustion chamber and discharging the smoke generated while the firewood is burned;
first to third air supply pipes that suck air from the outside of the housing and supply air to the first to third combustion chambers, respectively;
a lower bulkhead installed in a plate shape at a height spaced apart from the bottom surface of the housing by a predetermined interval, the primary combustion chamber to the tertiary combustion chamber installed on the plate-like upper part;
consists of,
The inlets for sucking the outside air from the first to third air supply pipes are respectively located on the outside of the housing, and each air supply pipe is piped to sequentially contact the outer peripheral surface of the secondary combustion chamber and the outer peripheral surface of the lower end of the primary combustion chamber inside the housing. becomes,
In the first air supply pipe, air supply holes are formed at equal intervals in the portion piped to be in contact with the outer circumferential surface of the primary combustion chamber, so that air is supplied to the interior of the primary combustion chamber through the air supply hole,
The second air supply pipe is piped to supply air to the inlet of the secondary combustion chamber after passing through the outer peripheral surface of the secondary combustion chamber and the outer peripheral surface of the lower end of the primary combustion chamber,
The third air supply pipe is piped to sequentially contact the outer circumferential surface of the secondary combustion chamber and the outer circumferential surface of the lower end of the primary combustion chamber, and then piped to contact the outer circumferential surface of the secondary combustion chamber again.
An air circulation type high temperature combustion wood stove, characterized in that the smoke generated when the firewood is burned in the primary combustion chamber is further burned through the secondary combustion chamber and the tertiary combustion chamber sequentially, and then the smoke is exhausted through the exhaust.
According to claim 1,
The size of the cross section of the secondary combustion chamber is smaller than the size of the cross section of the primary combustion chamber, and the size of the cross section of the tertiary combustion chamber is formed smaller than the size of the cross section of the secondary combustion chamber. wood stove.
According to claim 1,
The tertiary combustion chamber is formed of a double tube having an inner tube and an outer tube, and the combustion air hole is formed in a spiral shape in the inner tube.
delete According to claim 1,
Air circulation type high temperature combustion, characterized in that in the first to third air supply pipes, an opening/closing valve capable of adjusting the amount of air sucked into each air supply pipe is installed at the inlet of each air supply pipe located outside the housing. wood stove.
According to claim 1,
Inside the housing, the front bulkhead is spaced apart from the front vertical surface of the housing by a predetermined distance and installed in a plate shape on the outside of the primary combustion chamber, and is spaced apart from the rear vertical surface of the housing in a plate shape on the outside of the tertiary combustion chamber The rear bulkhead is further installed,
Each upper end of the front bulkhead and the rear bulkhead is connected to the ceiling of the housing, and the lower end is connected to the lower bulkhead and fixedly installed, and a smoke circulation hole is formed in the upper central part of the front bulkhead installed in contact with the ceiling of the housing,
The smoke burned in the tertiary combustion chamber is discharged to the space surrounded by the front bulkhead, the rear bulkhead, and the lower bulkhead, and then is discharged through the smoke circulation hole formed in the front bulkhead, so that the inner surface of the housing is the front bulkhead, the rear bulkhead, and the lower part. An air circulation type high-temperature combustion wood stove, characterized in that it is discharged to the outside through a discharge unit after circulating inside the housing along a circulation passage formed while being spaced apart from the bulkhead.
According to claim 1,
An air circulation type high temperature combustion wood stove, characterized in that a sliding door damper is further installed at the end of the secondary combustion chamber, and the sliding door damper is opened to immediately discharge the smoke when the fire wood is ignited.
According to claim 1, wherein the discharge unit,
a horizontal communication installed protruding from the housing by a predetermined length;
a vertical communication installed vertically at the end of the horizontal communication;
a diffusion air damper that is installed at the lower end of the vertical communication and can control the temperature of the smoke emitted by inhaling or blocking the outside air by adjusting the opening degree;
Air circulation type high temperature combustion wood stove, characterized in that it comprises a.

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