KR100638395B1 - A fireplace - Google Patents

Abstract

The present invention relates to a fireplace. The present invention provides a casing forming an appearance; A fuel storage container provided at an upper portion of the casing and storing fuel burned; A combustion chamber provided at a front end portion of the casing and configured to receive fuel stored in the fuel storage container and combust the fuel; A fuel transfer means provided in the casing and transferring fuel stored in the fuel reservoir to the combustion chamber; An ignition device provided in the combustion chamber and igniting fuel supplied to the combustion chamber; A combustion material receiver installed in the casing corresponding to the lower side of the combustion chamber and configured to collect combustion materials generated in a process of burning fuel in the combustion chamber; Indoor air flow means for flowing indoor air into and out of the casing to transfer the heat generated in the combustion chamber in the combustion chamber to the indoor air; And outdoor air flow means for supplying air consumed in the process of burning fuel in the combustion chamber to the inside of the combustion chamber from outside, and exhausting combustion gas generated in the process of burning fuel in the combustion chamber from the inside of the combustion chamber to the outside; It is configured to include, the combustion chamber is contained in the combustion chamber is supplied with the fuel supplied from the fuel container is provided with a combustion cylinder is formed of a metal material having a predetermined thermal conductivity, the corresponding to the lower side of the combustion cylinder A communication hole selectively communicates with a lower portion of the casing by a shielding plate at a bottom surface of the combustion chamber, and the combustion cylinder is seated in a seating space formed by a seating rib protruding upward from an edge of the communication hole. do. According to this invention, more comfortable and safe heating is attained, and continuous heating for a long time becomes easy.

Fireplace, Fuel Reservoir, Fuel Transfer, Indoor Air Flow, Outdoor Air Flow

Description

Fireplace {A fireplace}

1 is a side cross-sectional view showing a fireplace according to the prior art.

Figure 2 is a perspective view showing the appearance of a preferred embodiment of the fireplace according to the present invention.

3 is a right sectional view of the embodiment shown in FIG.

4 is a left sectional view of the embodiment shown in FIG.

5 is a cross-sectional view illustrating main parts of a combustion chamber having a humidifier in the embodiment illustrated in FIG. 2.

FIG. 6 is a cross-sectional view illustrating main parts of a combustion chamber having a filtration filter in the embodiment shown in FIG. 2.

7a to 7d is an operational state diagram showing a process of heating the room according to the embodiment shown in FIG.

Explanation of symbols on the main parts of the drawings

11: casing 13: support

21: fuel reservoir 23: fuel inlet

25: fuel outlet 27: top cover

31: First transfer path 33: Second transfer path

35: transfer screw 41: combustion chamber

42: front cover 43: through hole

44: seating rib 44a: seating space

45: combustion cylinder 45a: aeration vent

45b: combustion ash discharge hole 47: first combustion ash receiver

48: second combustion material receiving 49: shielding plate

51: ignition device 61: suction grill

63: heating pipe 65: discharge grill

67: blower fan assembly 69: soot removing member

69a: handle 71: outdoor air supply duct

73a, 73b: combustion gas exhaust duct 74: exhaust hole

75: exhaust fan assembly 81: water tank

83: steam supply pipe 85: shielding cap

86: water vapor outlet 91: filtration filter

93: support rib M: feed motor

F: fuel F: combustion material

The present invention relates to a fireplace, and more particularly to a wall stove is divided into a space in which the combustion of fuel and a space in which heat is exchanged between the combustion fuel and the indoor air.

Fireplace is a kind of heating device, generally provided on one side of the living room, such as to heat the wood or coal combustion to the living room to heat the room. 1 shows the configuration of a typical fireplace.

As shown in the drawing, the combustion chamber 1 of the conventional fireplace is provided on one side of the inner wall Wi of a room such as a living room. The combustion chamber 1 has a predetermined hexahedral shape in which a front surface is opened to communicate with a room, thereby forming a predetermined space for combustion of fuel. As fuel burned in the combustion chamber 1, wood or coal cut into a predetermined size is generally used.

One end of the exhaust passage 3 communicates with one side of the combustion chamber 1. The exhaust passage 3 is for exhausting the combustion gas generated while burning fuel in the combustion chamber 1 to the outside, and may be formed by the inner wall Wi and the outer wall Woo or by a separate duct. have. Although not shown, an exhaust port is provided at the other end of the exhaust passage 3.

On the other hand, the bottom surface of the combustion chamber 1 is provided with a combustion ash receiver 7 for collecting ashes of fuel burned in the combustion chamber 1. The combustion ash receiver 7 is detachably installed in an installation groove 8 formed by recessing a portion of the bottom surface of the combustion chamber 1 downward. In addition, the bottom surface of the combustion chamber 1 corresponding to the upper side of the combustion ash receiver 7 is provided with a combustion filter plate 9 for selectively transmitting only the combustion ash to the combustion ash receiver 7.

Look at the heating process by the conventional fireplace is configured as described above.

First, fuel is supplied to the inside of the combustion chamber 1 by a predetermined amount, and the fuel is ignited. At this time, the user ignites the fuel using a separate ember. The ignited fuel is burned using indoor air, and most of the heat generated in the process of burning the fuel is supplied to the room by radiation, and a part of the heat is supplied to the room by convection to be heated.

On the other hand, the combustion gas generated in the process of burning fuel is exhausted to the outside through the exhaust passage (3). The combustion material generated while the fuel is burned is collected in the combustion ash receiver 7, and when a predetermined amount or more of the combustion ash is collected in the combustion ash receiver 7, the combustion ash receiver 7 is moved outside the combustion chamber 1. It can be withdrawn to empty the combustion material collected therein.

However, the fireplace according to the prior art configured as described above has the following problems.

As described above, since the combustion chamber 1 communicates with the room, fuel is burned by the room air. Therefore, when the fuel is burned in the combustion chamber 1, there is a fear that the indoor oxygen is insufficient and the indoor environment is not good.

In addition, a portion of the combustion gas generated during the combustion of fuel in the combustion chamber 1 may be partially transmitted through the front surface of the combustion chamber 1 opened. Therefore, indoor air may be contaminated by combustion gas.

The heat of the fuel burnt in the combustion chamber 1 is directly supplied to the room by radiation. Therefore, when the user burns fuel while the fuel is burned in the combustion chamber 1, the flame of the fuel that is burned on it is transferred to other items in the room, thereby increasing the risk of fire.

On the other hand, the heating of the room is performed only while the fuel supplied to the combustion chamber 1 is combusted. However, since the amount of fuel supplied to the inside of the combustion chamber 1 is limited, it becomes difficult to continuously heat the room.

In addition, in order to additionally supply fuel to the combustion chamber 1, the user must directly supply fuel through the open front surface of the combustion chamber 1 while the fuel is combusted. Therefore, the process of additionally supplying fuel to the combustion chamber 1 is not easy.

The present invention is to solve such a conventional problem, it is an object of the present invention to provide a fireplace configured to maintain a comfortable indoor environment.

Another object of the present invention is to provide a fireplace configured to be heated more safely.

Another object of the present invention is to provide a fireplace which is configured to enable continuous indoor heating.

Another object of the present invention is to provide a fireplace which is configured to facilitate the further supply of fuel.

According to a feature of the present invention for achieving the above object, the present invention, the casing to form an appearance; A fuel storage container provided at an upper portion of the casing and storing fuel burned; A combustion chamber provided at a front end portion of the casing and configured to receive fuel stored in the fuel storage container and combust the fuel; A fuel transfer means provided in the casing and transferring fuel stored in the fuel reservoir to the combustion chamber; An ignition device provided in the combustion chamber and igniting fuel supplied to the combustion chamber; A combustion material receiver installed in the casing corresponding to the lower side of the combustion chamber and configured to collect combustion materials generated in a process of burning fuel in the combustion chamber; Indoor air flow means for flowing indoor air into and out of the casing to transfer the heat generated in the combustion chamber in the combustion chamber to the indoor air; And outdoor air flow means for supplying air consumed in the process of burning fuel in the combustion chamber to the inside of the combustion chamber from outside, and exhausting combustion gas generated in the process of burning fuel in the combustion chamber from the inside of the combustion chamber to the outside; It is configured to include, the combustion chamber is contained in the combustion chamber is supplied with the fuel supplied from the fuel container is provided with a combustion cylinder is formed of a metal material having a predetermined thermal conductivity, the corresponding to the lower side of the combustion cylinder A communication hole selectively communicates with a lower portion of the casing by a shielding plate at a bottom surface of the combustion chamber, and the combustion cylinder is seated in a seating space formed by a seating rib protruding upward from an edge of the communication hole. do.

The fuel reservoir is formed in a hopper shape having a fuel inlet and a fuel outlet formed by opening at least a portion of the upper and lower surfaces thereof, and the fuel inlet is selectively opened and closed by an upper cover provided at one side of the upper surface of the casing. It features.

The front surface of the casing is characterized in that the front cover for selectively opening and closing the combustion chamber.

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The front and rear surfaces and the bottom surface of the combustion cylinder, through the air through the outdoor air flowing into the combustion chamber by the outdoor air flow means and the combustion material discharged from the combustion of the fuel in the process of burning the fuel inside the combustion cylinder The material discharge hole is characterized in that each formed.

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The fuel transfer means may include a fuel transfer passage connecting the fuel outlet port of the fuel storage passage and the combustion chamber, a transfer screw provided in the fuel transfer passage to transfer fuel stored in the fuel storage passage to the combustion cylinder; It characterized in that it comprises a transfer motor for providing a driving force for the rotation of the transfer screw.

The fuel transfer passage may include a first transfer passage having the other end inclined upward toward the combustion chamber while one end is connected to the fuel discharge port of the fuel reservoir and a downward slope in the state where the one end is connected to the other end of the first transfer passage. It is characterized in that the other end is composed of a second transfer passage penetrating one side of the combustion chamber and protrudes therein.

The ignition device is characterized in that the heating element is generated when the external power is applied to transfer heat to the combustion cylinder.

The combustion ash receiver is installed in a lower portion of the casing corresponding to the lower portion of the combustion chamber, and the first combustion ash receiver is collected and transferred to the combustion cylinder through the combustion ash discharge hole and the communication hole, and the combustion cylinder is connected to the combustion cylinder. And a second combustion material receiver removably installed on the bottom surface of the combustion chamber except for a corresponding part and collecting the combustion material moving outside of the combustion cylinder by the outdoor air supplied into the combustion chamber. It is done.

The indoor air flow means is provided on both sides of the front of the casing, the suction grill, the indoor air is sucked indoor air into the interior of the casing, and the indoor air sucked into the interior of the casing to the room and at least part of the combustion chamber A heating pipe exposed to the inside of the exhaust pipe, and an exhaust port provided at one end of the heating pipe and passing through the heating pipe and exhausting indoor air, which receives heat generated in the process of burning fuel in the combustion cylinder, to the room; And a blower fan assembly which sucks indoor air through the suction grill and exhausts indoor air, which is guided by the heating pipe and received heat through the exhaust port, to the room.

The outdoor air flow means is provided to penetrate the rear surface of the casing, the outdoor air supply duct and the combustion gas exhaust duct for communicating the combustion chamber and the outside, and supply the outdoor air into the combustion chamber through the outdoor air supply duct. At the same time, it characterized in that it comprises an exhaust fan assembly for exhausting the combustion gas generated in the process of burning fuel through the combustion gas exhaust duct to the outside.

One end of the outdoor air supply duct is located at a lower portion relative to the interior of the combustion chamber, and one end of the combustion gas exhaust duct is located at a relatively upper position inside the combustion chamber.

The fuel used for heating is characterized in that the compressed wood having a predetermined size.

The inside of the casing is characterized in that the humidifier for humidifying the indoor air supplied with heat generated in the process of burning fuel.

The humidifier includes a water tank provided inside the combustion chamber and storing water for humidification, a fuel connected to one side of the upper surface of the casing and one side of the water tank, and the water stored in the water tank combusted in the combustion chamber. And a shielding cap provided at one end of the steam supply pipe connected to one side of the casing and provided with a plurality of steam outlets for supplying steam to the room. It features.

On the flow path of the indoor air guided by the heating pipe is characterized in that the air cleaner for purifying the indoor air supplied with the heat generated in the process of burning fuel.

The air purifier includes a filtration filter for removing various foreign substances contained in the indoor air flowing by the heating pipe, a deodorant for deodorizing the indoor air flowing through the heating pipe, and an indoor air flowing through the heating pipe. At least one or more of the antimicrobial agent for removing the various bacteria characterized in that it is provided.

According to the present invention, a comfortable indoor environment is maintained during heating, safe heating is achieved, and continuous heating is easily performed for a long time.

Hereinafter, with reference to the accompanying drawings a preferred embodiment of the fireplace according to the present invention.

Figure 2 shows the appearance of a preferred embodiment of the fireplace according to the present invention, Figure 3 and Figure 4 shows the left and right side cross-sectional views of the embodiment shown in Figure 2, respectively, Figures 5 and 6 shown in Figure 2 In the embodiment the main part of the combustion chamber with a humidifier and a filtration filter is shown.

As shown here, the casing 11 forming part of the exterior of the fireplace is formed in a substantially hexahedral shape in which both front edges are inclined, and the front surface thereof is opened. Inside the casing 11 is formed a predetermined space is provided with various components constituting the fireplace.

The casing 11 may be positioned at a predetermined height on the bottom surface by the support 13. In addition, depending on the type of fireplace according to the installation place, the casing 11 forms all or part of the appearance of the fireplace. That is, as shown in Figure 2, when the rear end of the fireplace is installed to be embedded in the wall of the building the casing 11 will form only the front end of the fireplace. In addition, when the fireplace is installed to expose all the interior space of the building, the casing 11 forms the entire appearance of the fireplace.

As shown in FIG. 3, a fuel reservoir 21 is provided inside the casing 11. The fuel reservoir 21 is a place where the fuel for heating is stored therein, is formed in a substantially hopper shape. The fuel reservoir 21 is provided in the upper portion of the inner space of the casing 11 so that the fuel stored therein moves downward by its own weight.

As fuel stored in the fuel reservoir 21, that is, fuel used for heating, for example, compressed wood having a predetermined size is used. Since such compressed wood contains a relatively small amount of water compared to ordinary wood, high thermal efficiency can be expected as compared with ordinary wood of the same volume, and the benefits of minimizing the generation of smoke during combustion can be expected. have.

The upper surface of the fuel reservoir 21 corresponding to the front end of the casing 11 is provided with a fuel inlet 23 for entering the fuel injection zone. The fuel inlet 23 is selectively opened and closed by an upper cover 27 which is installed at the front end of the casing 11 so as to be rotatable up and down about its one end. In addition, the bottom of the fuel reservoir 21 is provided with a fuel outlet 25 that serves as an outlet for discharging the fuel.

Fuel transfer passages 31 and 33 are provided to supply fuel stored in the fuel reservoir 21 to the combustion chamber 41 to be described below. The fuel transfer passages 31 and 33 may have a first transfer passage 31 having the other end inclined upwardly toward the combustion chamber 41 when one end is connected to the fuel outlet 25 of the fuel storage passage 21. And, the other end of the first transfer passage 31 is provided with a second inclined downward in the state connected to one end thereof so that the other end passes through one side of the combustion chamber 41 and protrudes therein. The fuel transfer passages 31 and 33 are configured in this way to prevent the fuel stored in the fuel storage passage 21 from being arbitrarily supplied to the combustion chamber 42.

A conveying screw 35 is provided inside the first conveying path 31. The transfer screw 35 is rotated by a transfer motor M to transfer the fuel delivered to one end of the second transfer passage 33 through the fuel outlet 25 to the first transfer passage 31. Play a role.

By adjusting the rotational speed of the transfer screw 35 to adjust the amount of fuel supplied for heating, it is possible to control the heating temperature of the room. In other words, when the rotational speed of the transfer screw 35 is increased, the amount of fuel supplied is increased to increase the heating temperature of the room. On the contrary, when the rotational speed of the transfer screw 35 is reduced, the amount of fuel supplied is relatively reduced, thereby lowering the heating temperature of the room.

In addition, a combustion chamber 41 is provided at the front end of the casing 11. The combustion chamber 41 is a place where the combustion of fuel occurs, the front surface of which is opened and closed by the front cover 41 and selectively communicates with the room. The front cover 41 is formed of at least a portion of a transparent material so that the user can visually check the state in which the fuel is burned in the combustion chamber 41, the shape corresponding to the front shape of the casing 11 Is formed.

A communication hole 43 is formed in the bottom surface of the combustion chamber 41 and communicates with the upper and lower sides, and a seating space 44a is formed by a mounting rib 44 protruding upward from the edge of the communication hole 43. . The seating space 44a is located directly below one end of the second transfer passage 33 positioned inside the combustion chamber 41 through the combustion chamber 41.

In the seating space 44a, a combustion cylinder 45 through which combustion of fuel is substantially mounted is seated. The combustion cylinder 45 has a substantially hexahedron shape corresponding to the seating space 44a, and an upper surface thereof is opened. The flue delivered to the second transfer passage 33 is dropped into the combustion cylinder 45 by its own weight and is contained in the combustion cylinder 45. The combustion cylinder 45 is formed of a metal material having a predetermined thermal conductivity.

The front and rear surfaces of the combustion cylinder 45 are formed with a plurality of ventilation holes 45a through which outdoor air supplied to the combustion chamber 41 passes outdoors. In addition, the bottom surface of the combustion cylinder 45 is provided with a plurality of combustion material discharge hole (45b) for delivering the combustion material generated in the process of burning fuel to the first combustion material receiving 47.

In addition, a first combustion material receiver 47 is installed at the lower portion of the casing 11 corresponding to the lower side of the combustion chamber 41 so as to be accessible. In the first combustion material receiving body 47, a combustion material generated in the process of burning fuel in the combustion cylinder 45 is delivered through the combustion material discharge hole 45b and the communication hole 43 and collected.

In addition, a second combustion material receiver 48 is detachably installed on the bottom surface of the combustion chamber 41 except for a portion corresponding to the combustion cylinder 45. When the second combustion material receiver 48 is moved to the outside of the combustion cylinder 45 by the combustion air generated in the process of burning fuel in the combustion cylinder 45 by the outdoor air supplied to the combustion chamber 41. To collect the combustion material. The height of the second combustion material receiving 48 is preferably determined corresponding to that of the seating rib 44.

The bottom surface of the combustion chamber 41 in which the communication hole 43 is formed and the lower portion of the casing 11 in which the first combustion material receiver 47 is installed are selectively communicated by the shielding plate 49. This is to prevent the combustion material from being transferred to the room through the first combustion material receiver 47 during the combustion of fuel in the combustion cylinder 45.

Meanwhile, an ignition device 51 is provided to ignite the fuel collected in the combustion cylinder 45. As the ignition device 51, a heating element installed through one side of the seating rib 44 corresponding to the rear surface of the seating space 44a is used. In the illustrated embodiment, the ignition device 51 is located inside one end of the outdoor air supply duct 71 to be described below. The ignition device 51 generates heat by an external power source applied to transfer heat to the combustion cylinder 45.

As shown in FIG. 2, suction grills 61 are provided at both sides of the front surface of the casing 11 corresponding to both sides of the combustion chamber 41. The suction grill 61 has an entrance area in which indoor air is sucked into the casing 11 by driving the blower fan assembly 67 to be described below.

A plurality of heating pipes 63 are provided to guide the air sucked into the casing 11 into the room through the suction grill 61. A predetermined flow path through which indoor air flows is formed in the heating pipe 63, and one end of the heating pipe 63 is positioned inside the casing 11, and the other end of the heating pipe 63 is disposed in the casing 11. It communicates indoors and outdoors through the top of the front. A portion of the heating pipe 63 is exposed to the interior of the combustion chamber 41 so that the indoor air passing through the interior of the heating pipe 63 receives heat generated during the combustion of fuel inside the combustion cylinder 45. .

A discharge grill 65 is provided at an upper end of the front surface of the casing 11 adjacent to one end of the heating pipe 63. The discharge grill 65 prevents a user from directly exposing the hot air exhausted into the room through the heating pipe 63. Although not shown, it is possible to adjust the direction of the air exhausted into the room through the heating pipe 63 by forming the discharge grill 65 so that the angle can be adjusted to a predetermined width.

The blowing fan assembly 67 is provided inside the casing 11. The blowing fan assembly 67 sucks indoor air into the casing 11 through the suction grill 61 and exhausts the sucked indoor air into the room through the heating pipe 63. To provide.

The soot removing member 69 may be provided to remove soot generated on the outer circumferential surface of the heating pipe 63 in the process of burning fuel in the combustion cylinder 45. The soot removing member 69 moves in the longitudinal direction of the heating pipe 63 in close contact with the outer circumferential surface of the heating pipe 63 to remove soot. One side of the soot removing member 69 is provided with a handle 69a for the user to operate the soot removing member 69 indoors.

As shown in FIG. 3 and FIG. 4, an outdoor air supply duct 71 is provided to supply outdoor air to the inside of the combustion chamber 41. One end of the outdoor air supply duct 71 penetrates one side of the seating ribs 44 forming a rear surface of the seating space 44a to be adjacent to the combustion cylinder 45 to form an interior of the combustion chamber 41. Is located in. The other end of the outdoor air supply duct 71 penetrates the rear surface of the casing 11 and is located outdoors.

In addition, combustion gas exhaust ducts 73a and 73b are provided to exhaust the combustion gas generated in the process of burning fuel in the combustion cylinder 45 to the outside. The combustion gas exhaust ducts 73a and 73b may include a first exhaust duct 73a for guiding combustion gas to the exhaust fan assembly 75 and a combustion gas guided to the exhaust fan assembly 75. It consists of the 2nd exhaust duct 73b which guides outdoors.

The first exhaust duct (73a) and the exhaust hole 74 is provided in the upper portion of the rear of the combustion chamber 41 relative to one end of the outdoor air supply duct 71 located in the combustion chamber 41 and the Communicating. The second exhaust duct 73b penetrates through the rear surface of the casing 11 at one side of the exhaust fan assembly 75 and is at least partially positioned outdoors.

The exhaust fan assembly 75 is configured to supply outdoor air to the combustion chamber 41 through the outdoor air supply duct 71 and to exhaust combustion gas to the outside through the combustion gas exhaust ducts 73a and 73b. ) Is provided. The exhaust fan assembly 75 is provided at one side of the combustion gas exhaust ducts 73a and 73b to forcibly exhaust the exhaust gas generated in the process of burning fuel to the outside to circulate the outdoor air and the exhaust gas.

And although not shown, a control unit for controlling the operation of the fireplace, that is, the transfer screw 35, the ignition device 51, the blowing fan assembly 67 and the exhaust fan assembly 75 and the like is provided. The controller may be provided at one side of the casing 11 or at one side of the room.

Meanwhile, as shown in FIG. 5, a water tank 81 may be provided inside the combustion chamber 41. In the water tank 81, water for humidifying the room is stored. One end of the water vapor supply pipe 83 is connected to one side of the water tank 81. The steam supply pipe 83 serves to supply water, which is formed by evaporation of water stored in the water tank 81 by heat generated in the process of burning fuel in the combustion cylinder 45, to the room. do.

The other end of the steam supply pipe 83 is connected to one side of the upper surface of the casing 11 adjacent to one end of the heating pipe 63. And the other end of the steam supply pipe 83 is provided with a shielding cap (85). The shielding cap 85 is provided with a plurality of steam outlets 86 through which the steam delivered through the steam supply pipe 83 is discharged to the room.

In addition, as illustrated in FIG. 6, a filtration filter 91 may be provided on the upper surface of the casing 11 adjacent to one end of the heating pipe 63. The filtration filter 91 serves as an air cleaner for filtering various foreign substances contained in the indoor air that receives heat generated in the process of burning fuel in the combustion cylinder 45.

The filtration filter 91 is provided orthogonal to the flow direction of the indoor air discharged into the room through the heating pipe 63. To this end, a plurality of support ribs 93 may be provided to support the front lower end and the rear upper end of the filtration filter 91, respectively.

In FIG. 6, a case in which the filtration filter 91 is used among the various components of the air cleaner is described, but a deodorant for removing odor in the indoor air may be provided. In addition, the inner circumferential surface of the heating pipe 63 may be coated with silver nanoparticles that perform an antibacterial function to remove various bacteria contained in the indoor air.

Hereinafter will be described with reference to the accompanying drawings the operation of a preferred embodiment of the fireplace according to the present invention.

7A to 7D illustrate a process of heating a room according to a preferred embodiment of the fireplace according to the present invention.

First, as shown in FIG. 7A, the fuel cover is injected into the fuel reservoir 21 while the upper cover 27 is rotated to open the fuel inlet 23 of the fuel reservoir 21. In this way, the fuel F injected into the fuel reservoir 21 is transferred to the first transfer path 31 through the fuel outlet 25 provided in the lower portion of the fuel reservoir 21 by its own weight.

At this time, the combustion chamber 41 is shielded by the front cover 41, the first and second combustion material receiving 48 is provided on the lower surface of the casing 11 and the bottom of the combustion chamber 41, respectively. In addition, the through hole 43 provided in the bottom surface of the combustion chamber 41 is shielded by the shielding plate 49.

When the fuel F is stored in the fuel reservoir 21 by a predetermined amount, as illustrated in FIG. 7B, the upper cover 27 is rotated to shield the fuel inlet 23. When the fireplace is operated by manipulating the control unit, the transfer screw 35 rotates and the fuel F transferred to the first transfer passage 31 moves along the first transfer passage 31 so that the second transfer passage ( 33).

Fuel F stored in the fuel reservoir 21 is continuously transferred toward the first transfer passage 31 by its own weight. When the control unit sets a relatively high heating temperature in the room, the transfer screw 35 rotates at a high speed, thereby increasing the amount of fuel F, and explaining a relatively low heating temperature in the room. The feed screw 35 rotates at a low speed so that the amount of fuel F supplied is reduced. On the other hand, the fuel F delivered to the second conveying passage 33 moves downward along the second conveying passage 33 by its own weight and falls therein, thereby causing the combustion cylinder 45 to be provided inside the combustion chamber 41. ) Will be included.

Next, as shown in FIG. 7C, when the fuel F is contained in the combustion cylinder 45 by a predetermined amount, the ignition device 51 is heated by an external power source to which the ignition device 51 is applied. The heat of the ignition device 51 is transferred to the combustion cylinder 45, and the fuel F contained therein is ignited and combusted.

Meanwhile, as the fuel contained in the combustion cylinder 45 is ignited, the exhaust fan assembly 75 is driven to supply the outdoor air to the combustion chamber 41 through the outdoor air supply duct 71. In addition, the combustion gas generated in the process of burning fuel in the combustion cylinder 45 is exhausted to the outside through the combustion gas exhaust ducts 73a and 73b by the continuous driving of the exhaust fan assembly 75. . At this time, it is possible to further increase the contact area between the outdoor air and the fuel by the vent hole (45a) formed in the front and rear surfaces of the combustion cylinder (45).

When the fuel is burned in the combustion cylinder 45, the blower fan assembly 67 is driven to suck the indoor air into the casing 11 through the suction grill 61. In this way, the indoor air sucked into the casing 11 is discharged into the room through the heating pipe 63 by the blower fan assembly 67. At this time, the indoor air flowing through the heating pipe 63 is discharged to the room under the condition that the heat generated in the process of burning the fuel (F) in the combustion cylinder 45 is received.

At this time, as shown in Figure 5, the water stored in the interior of the water tank 81 provided in the combustion chamber 41 in the heat generated during the combustion of the fuel (F) in the interior of the combustion cylinder 45 It is evaporated and supplied into the room through the steam supply pipe 83 and the steam outlet 86. In addition, as shown in Figure 6, foreign matter contained in the indoor air discharged into the room through the heating pipe 63 is filtered by the filter 91.

On the other hand, when the heating of the room is completed, by operating the control unit to stop the fireplace. Then, the shielding plate 49 is pulled to the front of the casing 11 and separated, and as shown in FIG. 7D, the first combustion material receiver 47 is pulled out to the front of the casing 11. And the combustion material (W) collected in the first combustion material receiving 47 is emptied.

In addition, the front cover 41 is rotated to open the combustion chamber 41, and then the second combustion material receiver 48 is removed to empty the combustion material W collected in the second combustion material receiver 48. . In addition, the combustion cylinder 45 is separated to empty the combustion material (W) remaining therein.

In the state in which the top cover 27 is rotated, the handle 69a of the soot removing member 69 is grasped to reciprocate in the longitudinal direction of the heating pipe 63. At this time, the soot removing member 69 removes the soot formed on the outer circumferential surface of the heating pipe 63 while moving along the heating pipe 63.

Within the scope of the basic technical idea of the present invention, many modifications are possible to those skilled in the art, and the scope of the present invention should be interpreted based on the appended claims. will be.

In the illustrated embodiment, the fuel is transferred inside the first transfer passage by the transfer screw, but it is also possible to transfer the fuel using a transfer spring.

In addition, although not shown in the drawings, the cooking vessel for heating the food of the combustion chamber can be installed in and out. For example, it may be possible to form a predetermined space recessed therein on one side of the combustion chamber and to install a cooking vessel conforming to such a space from outside.

According to the fireplace according to the present invention as described above can be expected the following effects.

The circulation of air for supplying heat generated during the combustion of fuel in the combustion chamber to the room and the circulation of air for combustion of the fuel are partitioned from each other. Therefore, pollution of indoor air, that is, various harmful substances or odors generated during the combustion of fuel can be prevented from being transmitted to the room.

In addition, since combustion of fuel is performed while the front surface of the combustion chamber is shielded, a phenomenon in which a user is burned by a flame or a fire is blown to an item in a room during heating is prevented.

And since the fuel stored in the fuel reservoir is continuously supplied to the combustion chamber, the heating of the room can be made continuously.

In addition, during the combustion of fuel in the combustion chamber, the fuel inlet of the fuel reservoir can be simply opened to supply additional fuel.

Claims (18)

A casing forming an appearance; A fuel storage container provided at an upper portion of the casing and storing fuel burned; A combustion chamber provided at a front end portion of the casing and configured to receive fuel stored in the fuel storage container and combust the fuel; A fuel transfer means provided in the casing and transferring fuel stored in the fuel reservoir to the combustion chamber; An ignition device provided in the combustion chamber and igniting fuel supplied to the combustion chamber; A combustion material receiver installed in the casing corresponding to the lower side of the combustion chamber and configured to collect combustion materials generated in a process of burning fuel in the combustion chamber; Indoor air flow means for flowing indoor air into and out of the casing to transfer the heat generated in the combustion chamber in the combustion chamber to the indoor air; And Outdoor air flow means for supplying air consumed in the process of burning fuel in the combustion chamber outdoors to the interior of the combustion chamber and exhausting combustion gas generated in the process of burning fuel in the combustion chamber from the interior of the combustion chamber to the outside; It is configured to include, The combustion chamber is provided in the combustion chamber is filled with the fuel supplied from the fuel reservoir is combusted and formed of a metallic material having a predetermined thermal conductivity, On the bottom surface of the combustion chamber corresponding to the lower side of the combustion cylinder is formed a communication hole selectively communicating with the lower portion of the casing by a shielding plate, The combustion cylinder is a fireplace, characterized in that seated in the seating space formed by a seating rib protruding upward from the edge of the communication hole. The method of claim 1, The fuel reservoir is formed in a hopper shape having a fuel inlet and a fuel outlet formed by opening at least a portion of the upper and lower surfaces thereof. And the fuel inlet is selectively opened and closed by an upper cover provided at one side of the upper surface of the casing. The method of claim 2, The front of the casing is a fireplace, characterized in that provided with a front cover for selectively opening and closing the combustion chamber. delete The method of claim 3, wherein The front and rear surfaces and the bottom surface of the combustion cylinder, through the air through the outdoor air flowing into the combustion chamber by the outdoor air flow means and the combustion material discharged from the combustion of the fuel in the process of burning the fuel inside the combustion cylinder Fireplace, characterized in that each material discharge hole is formed. delete The method of claim 5, The fuel transfer means, A fuel transfer passage connecting the fuel outlet of the fuel reservoir and the combustion chamber; A transfer screw provided in the fuel transfer passage to transfer fuel stored in the fuel storage passage to the combustion cylinder; Fireplace characterized in that it comprises a transfer motor for providing a driving force for the rotation of the transfer screw. The method of claim 7, wherein The fuel transfer passage, A first transfer passage having the other end inclined upwardly toward the combustion chamber in a state where one end is connected to a fuel outlet of the fuel reservoir; Fireplace, characterized in that the second end of the first transfer passage is provided inclined downward in the state that one end is connected to the other end passes through one side of the combustion chamber and protrudes therein. The method of claim 8, The ignition device is a fireplace, characterized in that the heating element is generated when the external power is applied to transfer heat to the combustion cylinder. The method of claim 9, The combustion ash receiver, A first combustion material receiver installed at a lower portion of the casing corresponding to the lower side of the combustion chamber, the first combustion material receiving and collecting combustion material through the combustion material discharge hole and the communication hole; And a second combustion material receiver detachably installed on a bottom surface of the combustion chamber except for a portion corresponding to the combustion cylinder, and collecting the combustion material moving outside of the combustion cylinder by outdoor air supplied into the combustion chamber. Fireplace, characterized in that configured by. The method of claim 10, The indoor air flow means, A suction grill provided at both sides of the front of the casing and having indoor air sucked into the casing; A heating pipe for guiding indoor air sucked into the casing to an interior and at least a portion of the indoor air exposed to the interior of the combustion chamber; An exhaust port provided at one end of the heating pipe and exhausting indoor air, which receives heat generated in a process of burning fuel in the combustion cylinder while passing through the heating pipe, to the room; And a blower fan assembly which sucks indoor air through the suction grill and exhausts indoor air, which is guided by the heating pipe and receives heat through the exhaust port. The method of claim 11, The outdoor air flow means, An outdoor air supply duct and a combustion gas exhaust duct provided to penetrate the rear surface of the casing to communicate the combustion chamber with the outside; And an exhaust fan assembly for supplying outdoor air to the inside of the combustion chamber through the outdoor air supply duct and simultaneously exhausting combustion gas generated in the process of burning fuel through the combustion gas exhaust duct to the outside. Fireplace. The method of claim 12, One end of the outdoor air supply duct is located in the lower portion relative to the interior of the combustion chamber, One end of the combustion gas exhaust duct is located in the upper portion relative to the interior of the combustion chamber. The method according to any one of claims 1 to 13, The fuel used for heating the fireplace, characterized in that the compressed wood having a predetermined size. The method of claim 14, The inside of the casing is a fireplace, characterized in that the humidifier for humidifying the indoor air supplied with heat generated in the process of burning fuel. The method of claim 15, The humidifier, A water tank provided inside the combustion chamber and storing water for humidification; A steam supply pipe connected to one side of the upper surface of the casing and one side of the water tank and supplying water vapor stored in the water tank to the room by vaporization of heat of fuel combusted in the combustion chamber; And a shielding cap provided at one end of the steam supply pipe connected to one side of the casing and formed with a plurality of steam outlets for supplying steam to the room. The method of claim 14, The fireplace characterized in that the air purifier is provided on the flow path of the indoor air guided by the heating pipe to purify the indoor air supplied with the heat generated during the combustion of the fuel. The method of claim 17, The air cleaner, A filtration filter for removing various foreign substances contained in the indoor air flowing by the heating pipe; Deodorant for deodorizing the indoor air flowing through the heating pipe, Fireplace, characterized in that at least one of the antibacterial agent for removing various bacteria contained in the indoor air flowing through the heating pipe.

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