KR101431134B1 - Non-powered pellet stove - Google Patents

Abstract

The present invention relates to a non-powered pellet stove, comprising: a fuel chamber provided with a hopper for receiving a plurality of fuels; a fuel chamber coupled to the hopper for discharging the plurality of fuels from the hopper in one direction; A fuel inlet for introducing the fuel is formed at one side, a combustion chamber outlet is formed at the other side, and an air inlet A combustion chamber in which an inlet port is formed, and a partition plate which is formed in a plate shape and which is provided along the longitudinal direction inside the fuel chamber and the combustion chamber to divide the fuel chamber and the inside of the combustion chamber.

Description

Non-powered pellet furnace {NON-POWERED PELLET STOVE}

The present invention relates to a non-powered pellet stove, and more particularly, to a non-powered pellet stove capable of burning pellets using natural convection, without requiring a separate blowing device, Pellet stove.

In general, wood chips or pellets are made by using wood byproducts. In recent years, energy crises due to the depletion of fossil fuels such as light oil, kerosene and gasoline, and global warming due to increased carbon emissions have been solved As an eco-friendly energy source that can be used, heating devices such as boilers and stoves are being developed.

An example of prior art documents is disclosed in the Published Patent Application No. 2011-0066258. In this patent, a conical container in which a cylindrical pipe and a pellet are burnt is integrally formed to form an air intake space, and a vent hole is formed in an upper portion, an intermediate portion, and a bottom of the conical container, And an ignition heater storage tube is formed in the ignition heater storage tube, and an ignition heater is formed in the ignition heater storage tube, and an air blower for supplying external air to the air inlet.

However, this prior art has a drawback that a separate power such as electricity is required to drive the blower to supply the outside air.

Further, there is a problem that not only the supply amount of the pellets supplied to the conical container in which the pellets are burned can be controlled, but also the thermal power required for burning the pellets can not be controlled.

Published Patent No. 2011-0066258

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and an object of the present invention is to provide a pellet- A non-powered pellet stove is provided.

BRIEF DESCRIPTION OF THE DRAWINGS Other objects and advantages of the invention will become more apparent from the following detailed description of preferred embodiments with reference to the attached drawings, in which:

A non-powered pellet hearth furnace according to the present invention is a non-powered pellet furnace comprising a fuel chamber which is provided with a hopper for receiving a plurality of fuels and which is connected to the hopper and which discharges the plurality of fuels from the hopper in one direction, A fuel inlet port through which the fuel flows into the fuel inlet port, a combustion chamber outlet port formed in the other end of the fuel inlet port, and an air inlet port communicating with the outside of the fuel inlet port, And a partition plate disposed in the fuel chamber and the combustion chamber in the longitudinal direction to partition the inside of the fuel chamber and the combustion chamber.

In the non-powered pellet stove according to the present invention, it is preferable that a vent hole is formed on a side surface of the fuel chamber so that air is introduced into the fuel chamber, and further, It is further preferable to further include a closure plate covering the pores.

In the non-powered pellet hearth according to the present invention, it is preferable that the partition plate comprises two or more pieces.

According to the present invention, since natural convection can be used to burn pellets, it is not necessary to use a separate blowing device and the power such as electricity to be driven thereby is not required.

Further, in the present invention, the fuel chamber of the hearth and the inside of the combustion chamber are partitioned by the partition plate, so that the supply amount of fuel and the thermal power can be controlled.

1 is a perspective view of an embodiment of a non-powered pellet stove according to the present invention,
FIG. 2 is a partially cutaway perspective view of the fuel chamber and the combustion chamber of the embodiment of FIG. 1;
3 is a flow diagram of a non-powered pellet stove of the embodiment of FIG. 1,
Fig. 4 is a perspective view showing a modification of the embodiment of Fig. 1; Fig.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of a non-powered pellet heater according to the present invention will be described in detail with reference to the accompanying drawings.

Prior to the description of the present invention, the term "fuel" in this specification refers to wood chips, pellets and the like, and pellets are exemplarily described in this specification, but it is obvious that other fuels mentioned above are applicable to the present invention .

FIG. 1 is a perspective view of one embodiment of a non-powered pellet furnace according to the present invention, and FIG. 2 is a partially cutaway perspective view of a fuel chamber and a combustion chamber of the embodiment of FIG.

The non-powered pellet heater 100 according to the present invention includes a fuel chamber 110, a combustion chamber 120, and a partition plate 130, as shown in FIGS.

The fuel chamber 110 is connected to the hopper H and receives a plurality of fuels 10 from the hopper H and discharges the fuel in one direction. A plurality of fuels (10) are injected into the hopper (H) through the upper part of the hopper (H). The hopper H is capable of selectively coupling the fuel to the fuel chamber 110 according to the amount of the plurality of fuels 10 accommodated therein. The hopper H is coupled to the open upper portion of the fuel chamber 110 using a coupling means such as a bolt. The fuel chamber 110 is obliquely inclined in a tubular shape and receives a plurality of fuels 10 from the hopper H. The reason why the fuel chamber 110 is tilted obliquely is to prevent the plurality of fuels 10 supplied from the hopper H from being loaded in the fuel chamber 110 and to be beautiful in appearance. The fuel chamber 110 may be divided into a preheated space and a non-preheated space. The preheated space refers to a space near the combustion chamber 120, and the unheated space is a space away from the combustion chamber 120. A plurality of ventilation holes 111 are formed in the side surface of the fuel chamber 110 so as to allow air to flow into the fuel chamber 110. The air introduced into the fuel chamber 110 through the vent hole 111 flows along a plurality of particles of the fuel 10 accommodated in the fuel chamber 110 to promote combustion of the fuel 10 . The shielding plate 112 is bonded to the outer wall of the fuel chamber 110 where the vent holes 111 are formed to cover the vent holes 111, respectively. The shielding plate 112 is a plate that is bent so that its cross section is square, and has a size such that a plurality of ventilation holes 111 are not visible from the outside, and is coupled through welding means such as welding or bolt. The shielding plate 112 is designed to provide a beautiful appearance of the fuel chamber 110 in which a plurality of ventilation holes 111 are formed. The present invention is exemplified in that the shielding plate 112 is a plate member bent in a rectangular shape in cross section so as to give a beautiful appearance to the fuel chamber 110 in which the vent hole 111 is formed, A plate material bent in a circular shape in cross section, a plate material bent in a triangular shape in cross section, and the like, as well as a curved plate material of another shape.

The combustion chamber 120 is formed with two inlets 121 and 122 and one outflow port 123. One inlet 121 is fixed to communicate with the fuel chamber 110 and is discharged from the fuel chamber 110 Fuel 10 is burned. The fuel 10 discharged from the fuel chamber 110 is ignited by using an ignition device such as a gas torch in a state of being stacked on the combustion chamber 120. One inlet 121 of the two inlet ports 121 and 122 formed in the combustion chamber 120 is a fuel inlet port 121 through which a plurality of fuels 10 flows in communication with the fuel chamber 110, (122) is an air inlet (122) communicating with the outside to introduce outside air. One outlet 123 formed in the combustion chamber 120 communicates with the heat dissipation chamber 140 described below. One opening and closing door 124 is formed in the combustion chamber 120. The opening and closing door 124 of the combustion chamber 120 is openable and closable to the air inlet 122. The opening and closing door 124 of the combustion chamber 120 is formed with an inlet hole 124a. The inflow hole 124a introduces outside air into the combustion chamber 120 to help burn the fuel 10. [ The air is introduced into the combustion chamber 120 through one inflow hole 124a formed in the opening and closing door 124 of the combustion chamber 120. However, The inlet hole 124a may be formed in the opening / closing door 124 of the combustion chamber 120 as long as it is possible. The opening and closing door 124 of the combustion chamber 120 ignites a plurality of fuels 10 laminated in the combustion chamber 120 while partially opening from the air inlet 122 and then closes the air inlet 122 again . The combustion chamber 120 can be divided into a preheating space on the basis of the combustion plate 125 and a combustion space below the combustion chamber. The combustion plate 125 is a U-shaped plate member and is fixed to a lower portion of the fuel inlet 121 which is elongated and communicates with the interior of the fuel chamber 110. The combustion plate 125 smoothes the combustion of the fuel 10 because the combustion space is ensured by the combustion plate 125 and the air supply is smooth. One end of the combustion plate 125 in the width direction and one end in the longitudinal direction are fixed to the combustion chamber 120 so that a plurality of fuels 10 discharged from the fuel chamber 110 are stacked at both ends in the width direction and at one end in the longitudinal direction, Some of the plurality of fuels 10 pass through the combustion plate 125 and fall to the bottom of the combustion chamber 120. The fuel 10 that has fallen on the bottom of the combustion chamber 120 is converted into fine particles 10a due to combustion. Although the combustion plate 125 is made of a U-shaped plate to facilitate combustion, the present invention is not limited to the E-shaped plate, the T-shaped plate, the H-shaped plate, the mesh net, As shown in FIG.

The partition plate 130 is formed in a plate shape to partition the inside of the fuel chamber 110 and the inside of the combustion chamber 120. The other end of the partition plate 130 is vertically bent and passes through a combustion plate 124 fixed to the combustion chamber 120 to be introduced into the combustion chamber 120, . The fuel chamber 110 partitioned by the partition plate 130 is capable of regulating the supply amount by dividing a plurality of supplied fuels 10 and the combustion chamber 120 partitioned by the partition plate 130 is divided into a combustion chamber 120, It is possible to control the thermal power by adjusting the inflow amount of the air. The partition plate 130a can be deformed as shown in Fig. The partition plate 130a divides the inside of the fuel chamber 110 and the inside of the combustion chamber 120 by two or more. This is because more space is formed than the space defined by the one partition plate 130 described above, so that the supply amount of the fuel 10 and the thermal power control are more efficient.

The heat dissipation chamber 140 communicates with the exhaust port 123 of the combustion chamber 120 and exhausts the ash 10a and the exhaust gas through the exhaust port 123 of the combustion chamber 120. The ash material 10a flows into the heat dissipation chamber 140 ), And the exhaust gas is discharged to the outside. The heat dissipation chamber 140 is formed with one discharge port 141 and one opening / closing door 142. One discharge port 141 formed in the heat dissipation chamber 140 is an exhaust gas discharge port 141 formed in the upper portion of the heat dissipation chamber 140 to discharge the exhaust gas discharged from the combustion chamber 120. The exhaust gas outlet 141 is separately connected to the pipe-shaped communication pipe 143 to discharge the exhaust gas to the outside. One opening and closing door 142 formed in the heat dissipation chamber 140 can be opened and closed in a lower portion of the heat dissipation chamber 140 and a circular glass plate 142a is formed. The glass plate 142a is transparent so that the internal condition of the heat dissipation chamber 140 can be visually confirmed. The glass plate 142a has a circular shape and the internal condition of the heat dissipation unit 140 is visually checked. However, if the internal condition of the heat dissipation unit 140 can be visually confirmed, a glass plate 142a A triangular shape, a rectangular shape, and the like, as well as other shapes. The opening and closing door 142 of the heat dissipation chamber 140 is kept closed during the burning process and is opened when the material 10a stacked in the heat dissipation chamber 140 is removed. The material 10a stacked on the heat dissipation chamber 140 is removed by repeatedly entering and exiting the opening and closing door 142 of the heat dissipation chamber 140 in an opened state. When the removal of the ash 10a is completed, the opening and closing door 142 of the heat dissipating chamber 140 is closed and the operation of burning the fuel 10 again is performed.

The cooking chamber 150 is formed on the top of the combustion chamber 120 and is formed between the fuel chamber 110 and the heat dissipation chamber 140. The cooking platform 150 can directly place the object to be cooked in a space heated by the heat generated by the combustion of the fuel 10, or cook the food by placing the cooking utensil.

One embodiment of the present invention described above and shown in the drawings should not be construed as limiting the technical idea of the present invention. The scope of protection of the present invention is limited only by the matters described in the claims, and those skilled in the art will be able to modify the technical idea of the present invention in various forms. Accordingly, such improvements and modifications will fall within the scope of the present invention as long as they are obvious to those skilled in the art.

10: fuel 10a: ash
100: Non-powered pellet stove 110: Fuel chamber
111: Vents 112: Cover plate
120: combustion chamber 121: fuel inlet
122: air inlet 123: outlet
124: opening / closing door 124a: inflow hole
125: combustion plate 130: partition plate
140: Heat dissipation chamber 141: Exhaust gas outlet
142: opening and closing door 142a: glass plate
143: communication pipe 150:
H: Hopper

Claims (4)

A fuel chamber which is provided with a hopper for containing a plurality of fuels and which is connected to the hopper and discharges the plurality of fuels from the hopper in one direction,
A fuel inlet connected to a lower portion of the fuel chamber to burn the fuel discharged from the fuel chamber, a fuel inlet through which the fuel flows into one side, a combustion chamber outlet formed in the other side, A combustion chamber in which an air inlet for introducing outside air is formed,
And a partition plate disposed in the fuel chamber and the combustion chamber in the longitudinal direction to partition the interior of the fuel chamber and the combustion chamber.
The method according to claim 1,
Wherein a vent hole is formed in a side surface of the fuel chamber so that air flows into the fuel chamber.
3. The method of claim 2,
And a closure plate coupled to an outer wall of the fuel chamber in which the vent hole is formed to cover the vent hole.
The method according to claim 1,
Wherein the partition plate comprises two or more partition plates.

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