KR20200143553A - Pellet feeding apparatus and pellet stove having the same - Google Patents

Abstract

Disclosed are a pellet supply device and a pellet stove including the same. The pellet supply device includes: a pellet supply hopper; a pellet supply duct that supplies pellet fuel supplied from the pellet supply hopper to a combustion chamber; a transfer belt that transfers pellets falling from the pellet supply hopper to the pellet supply duct; and a belt drive unit driving the transfer belt wherein a plurality of through holes are formed to pass and filter pellet powder supplied together with the pellets.

Description

Pellet supply device and pellet stove including the same {PELLET FEEDING APPARATUS AND PELLET STOVE HAVING THE SAME}

The present invention relates to a pellet supply apparatus, and more particularly, to a pellet supply apparatus capable of heating while automatically supplying pellets, and a pellet stove including the same.

Due to the recent increase in the price of energy sources such as crude oil, wood-pellets processed by crushing forestry wastes or felling trees into sawdust and then compressing them into cylinders with a length of 3.8 cm and thickness of 0.6 to 0.8 cm. It is in the spotlight as an alternative energy, and such wood pellets can exhibit high thermal efficiency at a relatively low cost of about 50-60% compared to kerosene or diesel, and since they are completely burned at high temperatures, there is a characteristic that almost no incineration ash remains after incineration. , It does not pollute the environment because no harmful gas is generated by combustion.

In particular, the above-mentioned wood pellet is a fuel that is not subject to carbon dioxide regulation by the IPCC (Intergovernmental Panel on Climate Change) because the carbon emission, which is the main cause of global warming, is also weak at 1/12 of that of ordinary diesel. As it is widely known as an advanced eco-friendly energy source that can supply energy, it is possible to accurately control the amount of energy, has a large energy density and storage capacity, and helps to reduce energy costs, studies to utilize these wood pellets in various fields have been conducted. It is actively progressing.

Due to the demand for such a pellet stove, various types of pellet stoves are currently being developed and sold.

In a general pellet stove, when pellets of a pellet hopper are supplied to the combustion unit through a pellet supply pipe, the heat generated by combustion of the pellets supplied to the combustion unit is supplied through a heat dissipation pipe (duct) to allow indoor heating.

However, when the pellets are supplied and burned as described above, the pellet powder generated during the storage and transport of the pellets is also supplied, thereby reducing the combustion efficiency in the combustion chamber.

Korean Patent Registration No. 10-1271748

The present invention has been invented in view of the above points, and an object of the present invention is to provide a pellet supply device having an improved structure to filter out the pellet powder and supply only solid pellets of a certain size or more, and a pellet stove including the same.

The pellet supply apparatus of the present invention for achieving the above object comprises: a pellet supply hopper; A pellet supply duct for supplying the pellet fuel supplied from the pellet supply hopper to the combustion chamber; A transfer belt for transferring the pellets falling from the pellet supply hopper to the pellet supply duct; And a belt driving unit for driving the transfer belt, wherein a plurality of through holes are formed in the transfer belt to pass and filter the pellet powder supplied together with the pellet.

As a result, when the pellets are supplied, it is possible to filter out the pellets and prevent them from being introduced into the combustion chamber, thereby increasing combustion efficiency.

Here, it is preferable to further include a vibration generating unit for generating vibration when the transfer belt is traveling.

Thereby, the pellet powder on the conveyance belt can be easily separated and removed using vibration.

In addition, the driving unit may include a belt driving roller supporting and running the transfer belt; A belt support roller supporting the running of the transfer belt; And a driving motor for driving the belt drive roller, wherein the vibration generating unit includes a main vibrator connected to the shaft of the belt support roller.

Thereby, by generating vibration in the roller for running the conveying belt, it is possible to effectively transmit the vibration to the conveying belt.

In addition, at least one of the belt drive roller and the belt support roller may have an eccentric shaft.

As a result, vibration can be generated in the conveying belt through eccentric rotation of the roller.

In addition, the vibration generating unit may include a pair of belt contact rollers installed to correspond to each other with a lower running portion of the transfer belt therebetween; And a sub-vibrator connected to at least one of the pair of belt contact rollers.

As a result, it is possible to effectively shake off and remove the pellet powder stuck to the belt or stuck in the through hole.

In addition, it is preferable to further include a brush member that is rotatably in contact with the lower surface of the transfer belt, and shakes off the pellet powder accumulated in the surface of the transfer belt and the through hole.

Accordingly, it is possible to effectively remove the pellet powder on the transfer belt by using the brush member.

The pellet stove of another aspect of the present invention for achieving the above object, a pellet supply hopper; A pellet supply duct for supplying the pellet fuel supplied from the pellet supply hopper to the combustion chamber; A transfer belt for transferring the pellets falling from the pellet supply hopper to the pellet supply duct; A belt drive unit for driving the transfer belt to travel, wherein a plurality of through holes for filtering through and filtering the pellet powder supplied with the pellets are formed in the transfer belt;

A combustion chamber installed in the apparatus main body in which the pellet supply device is installed, and in which pellets supplied through the pellet supply duct are burned; And

And a heat dissipating duct installed in the device body to generate heat while passing heat generated by combustion in the combustion chamber.

Accordingly, the pellet powder containing the supplied pellets is removed, and the pellet powder is introduced into the combustion chamber, thereby preventing the reduction of combustion efficiency.

According to the pellet supply device and the pellet stove according to the present invention, when the pellets are supplied to the combustion chamber, the pellet powder supplied together with the solid pellets can be separated and removed.

Therefore, when the pellet powder is supplied to the combustion chamber, it is possible to prevent the combustion efficiency from deteriorating.

Particularly, in the process of supplying the pellets, the pellet powder may be firstly removed through the through hole formed in the transfer belt, and the pellet powder may be separated and removed secondarily using vibration.

1 is a perspective view showing a pellet stove according to an embodiment of the present invention.
2 is a schematic left side view of the pellet blade shown in FIG. 1.
3 is a schematic front view of the pellet stove shown in FIG. 1.
Figure 4 is a schematic right side view of the pellet stove shown in Figure 1;
5 is a schematic plan view of the pellet stove shown in FIG. 1.
6 is a cross-sectional view taken along line I-I of FIG. 5.
7 is an enlarged view of portion A of FIG. 6.
8 is a schematic plan configuration diagram for explaining the transfer belt and the belt drive shown in FIG. 7.
9 is a schematic view for explaining another example of the belt driving unit shown in FIG. 7.
10 is a schematic diagram for explaining another example of the belt drive shown in FIG. 7.

Hereinafter, a pellet supply apparatus and a pellet stove including the same according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 to 8, a pellet stove according to an embodiment of the present invention, a device body 100, a combustion chamber 200 installed in the device body 100, and heat dissipation installed in the device body 100 A duct 300 and a pellet supply device 400 are provided.

The device body 100 may be divided into a base portion 110 and a housing portion 120 installed above the base portion 110. The combustion chamber 200 is installed at the bottom of the housing portion 120 of the apparatus body 100. The pellets are burned in the combustion chamber 200, and the burned heat is moved and discharged through the heat dissipation duct 300. In the combustion chamber 200, an ash receiving member (not shown) and an ignition unit (not shown) for recovering the ash remaining after the pellets are burned are installed. Various examples of the combustion chamber 200 are possible, and a detailed description thereof will be omitted since it can be easily understood by those skilled in the art from known techniques.

The heat dissipation duct 300 may be divided into a main heat dissipation duct 310 connected to the combustion chamber 200 and a sub heat dissipation duct 320 branched from the main heat dissipation duct 310 in the vertical direction. The main heat dissipation duct 310 is arranged in a zigzag manner from the bottom to the top, and is installed inside the housing 120 to dissipate heat forward. The sub heat dissipation duct 320 is vertically arranged vertically, and is connected to the main heat dissipation duct 310 from the top. The upper portion of the sub heat dissipation duct 320 extends to the outside of the upper portion of the housing portion 120, and the lower portion is connected to the recovery portion 330 installed on the inner bottom of the housing portion 120. The re-recovery unit 330 may have a bucket structure, and may have a bucket structure filled with water. Therefore, when a foreign material or ash falling through the sub heat dissipation duct 320 falls, it can be effectively recovered by contacting water.

The pellet supply device 400 includes a pellet supply hopper 410, a pellet supply duct 420 supplying the pellet fuel supplied from the pellet supply hopper 410 to the combustion chamber, and pellets falling from the pellet supply hopper 410. A transfer belt 430 for transferring to the pellet supply duct 420 and a belt driving unit 440 and a vibration generating unit 450 for driving the transfer belt 430 are provided.

The pellet supply hopper 410 is installed on one side of the device body 110, that is, adjacent to the housing 120, and an opening/closing cover may be installed at the top so that pellets can be injected through the top. A discharge port through which pellets are discharged is formed in the lower part of the pellet supply hopper 410, so that the pellets can be discharged by a certain amount. As an example, a supply auger is installed at the outlet at the lower end of the pellet supply hopper 410, so that pellets may be supplied by dropping a predetermined amount into the lower transfer belt 430. A pellet supply housing 401 is installed below the pellet supply hopper 410.

The pellet supply duct 420 is installed to connect the pellet supply housing 401 and the combustion chamber 200 and is formed to be inclined downward toward the combustion chamber 200. The upper end of the inlet side of the pellet supply duct 420 is located inside the pellet supply housing 401 and the pellets supplied through the transfer belt 430 are injected.

The transfer belt 430 is installed to travel horizontally on a caterpillar under the pellet supply hopper 410. The transfer belt 430 transfers the supplied pellets by falling from the pellet supply hopper 410 to the pellet supply duct 420 while traveling on a caterpillar track. At this time, a plurality of through holes 431 are formed in the transfer belt 430 to prevent the falling pellet powder from being introduced into the pellet supply duct 420, which is included in the pellets falling on the upper traveling part of the transfer belt 430. . It is preferable that the through hole 431 is formed in a size such that only the solid pellets cannot pass through, and only the pellets in a state of being fragmented or pulverized to a size less than a standard size can pass. Through this through hole 431, the primary path passes through the upper driving part 430a of the transfer belt 430 and falls to the lower driving part 430b. The pellet powder falling into the lower driving part 430b falls to the lower part of the lower driving part 430b through the through hole 431 of the lower driving part 430b.

Here, it is preferable that a pellet powder recovery container 450 for recovering the separated pellet powder by falling through the transfer belt 430 is installed. On the side of the pellet supply housing 401, an entrance through which the pellet powder collection container 450 can enter may be formed.

The belt driving unit 440 is for driving the conveyance belt 430 on a caterpillar track, a belt driving roller 441 supporting the conveying belt and running, and a belt supporting the running of the conveying belt 430 A drive motor 445 for driving the support roller 443 and the belt drive roller 441 is provided.

The belt drive roller 441 and the belt support roller 443 are disposed to be spaced apart from each other by a predetermined distance, and are installed side by side. The belt drive roller 441 drives the transfer belt 430 to travel while being rotated by receiving power from the drive motor 445. The belt support roller 443 guides and supports the transfer belt 430 to travel while being driven and rotated when the transfer belt 430 is driven. Of course, it may be driven by transmitting power to the belt support roller 443 as well.

The drive motor 445 may be installed in the apparatus body 100 and provides power to the belt drive roller 441 through a power transmission means including a drive gear 446 and a driven gear 447.

In addition, it is preferable that the belt drive roller 441 and the belt support roller 443 have a non-circular cross-sectional shape. That is, as shown in FIG. 7, each of the belt drive roller 441 and the belt support roller 443 has a cam structure, so that the transfer belt 430 shakes vertically and horizontally when rotating. . Accordingly, the pellet powder on the transfer belt 430 may fall downward through the through hole 431 to be separated from the solid pellet.

In addition, it is preferable to further include a lower brush member 459 for rotating in contact with the lower running portion 430a of the transfer belt 430 to remove the pellet powder deposited on the surface and the pellet powder remaining in the through hole 432. The lower brush member 459 is preferably installed between the contact roller 453 and the belt support roller 443. It is preferable that the lower brush member 459 includes a brush roller that cleans the surface of the lower traveling part 430b while rotating in the opposite direction to the traveling direction of the transfer belt 430.

In addition, an upper brush member 458 may be further provided to remove the pellet powder while rotating in contact with the upper surface of the lower running part 430a to correspond to the lower brush member 459. Here, the upper brush member 458

In addition, as shown in FIG. 9, a belt drive roller 441 ′ and a belt support roller 443 ′ may be provided having a circular cross-sectional shape, but having a configuration in which a rotation shaft is eccentrically installed. Even in this case, a vibration phenomenon occurs while the conveying belt 430 is driven by the eccentrically disposed rotating shaft, so that the pellet powder can be effectively separated and removed.

The vibration generating unit 450 is for generating vibration in the conveying belt 430, and as shown in FIG. 8, a main vibrator 451 connected to the rotating shaft of the belt support roller 443, and the conveying belt 430 ) And a sub-vibrator 455 connected to at least one of a pair of belt contact rollers 453 and a pair of belt contact rollers 453 installed to rotate in contact with the upper and lower portions of the lower traveling part 430b of Equipped.

The main vibrator 451 is installed to be supported by a bearing on a support shaft of the belt support roller 443. The main vibrator 451 is controlled to receive power in connection with the driving signal of the transfer belt 430, thereby controlling to generate vibration. Then, when the transfer belt 430 is running, vibration generated in the belt support roller 443 is transmitted to the transfer belt 430 so that the transfer belt 430 may shake.

The pair of belt contact rollers 453 contact each of the upper and lower portions of the lower running portion 430b of the transfer belt 430 and are installed to correspond to each other. The belt contact roller 453 may be installed to be rotated by being in contact with the conveying belt 430. A sub-vibrator 455 is provided in any one of the pair of belt contact rollers 453, so that vibration is generated in the belt contact roller 353. Then, the vibration is transmitted to the lower traveling part 430b through the belt contact roller 453 so that the pellet powder can be effectively removed through the through hole 431 of the lower traveling part 430b. Of course, it is possible to prevent clogging of the through hole 431 by effectively removing the pellet powder lump or pellet fragments embedded in the through hole 431.

According to the above configuration, when the pellets supplied from the pellet supply hopper 410 through the transfer belt 430 are supplied to the pellet supply duct 420, small pieces below the standard or pellet powder can be effectively separated and removed. . Therefore, by supplying only pellets of a standard size or more into the combustion chamber, combustion is effectively performed, and combustion efficiency can be prevented from deteriorating due to the pellet powder.

In addition, according to another embodiment of the present invention, as shown in FIG. 10, a contact roller 353' and an eccentric contact roller 456 are installed on the lower traveling portion 430b of the transfer belt 430 You can also have

Above, the present invention has been shown and described in connection with a preferred embodiment for illustrating the principle of the present invention, but the present invention is not limited to the configuration and operation as shown and described as such. Rather, it will be well understood by those skilled in the art that a number of changes and modifications to the present invention can be made without departing from the spirit and scope of the appended claims.

100..device body 200..combustion chamber
300..heat radiating duct 310..main radiating duct
320..sub heat dissipation duct 330..recovery part
400..Pellet supply device 410..Pellet supply hopper
420..Pellet supply duct 430..Transfer belt
440..belt driving part 450..vibration generating part
441,441'..belt drive roller 443,443'..belt support roller
445..Drive motor 451..Main vibrator
453,453'..contact roller 455..sub vibrator
456..Eccentric contact roller 459..Brush member

Claims (7)

Pellet feed hopper;
A pellet supply duct for supplying the pellet fuel supplied from the pellet supply hopper to the combustion chamber;
A transfer belt for transferring the pellets falling from the pellet supply hopper to the pellet supply duct;
Includes; a belt driving unit for driving and driving the transfer belt,
A pellet supply device, characterized in that a plurality of through holes are formed in the transfer belt for filtering by passing the pellet powder supplied together with the pellet. The method of claim 1,
Pellet supply device, characterized in that it further comprises a vibration generating unit for generating vibration when the transport belt is traveling. The method of claim 2, wherein the driving unit,
A belt drive roller supporting and running the transfer belt;
A belt support roller supporting the running of the transfer belt; And
Including; a drive motor for driving the belt drive roller,
The vibration generating unit comprises a main vibrator connected to the shaft of the belt support roller. The method of claim 3,
At least one of the belt drive roller and the belt support roller has an eccentric shaft. The method of claim 3, wherein the vibration generating unit,
A pair of belt contact rollers installed to correspond to each other with a lower traveling part of the transfer belt therebetween; And
And a sub-vibrator connected to at least one of the pair of belt contact rollers. The method of claim 5,
A pellet supply device, further comprising a brush member that is rotatably in contact with a lower surface of the lower traveling portion of the transfer belt, and shakes off the pellet powder accumulated in the surface of the transfer belt and the through hole. The pellet supply device according to any one of claims 1 to 6.
A combustion chamber installed in the apparatus main body in which the pellet supply device is installed, and in which pellets supplied through the pellet supply duct are burned;
And a heat dissipation duct installed in the device body to generate heat while passing heat generated by combustion in the combustion chamber.

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