KR101306785B1 - Pellet Heater - Google Patents

Abstract

A pellet heater, comprising a primary fuel container, a burner, a ash tray, and an air supply member. The primary fuel container stores the pellets. The burner is coupled in communication with the lower portion of the primary fuel container, has an air inlet on one side, and burns pellets supplied from the primary fuel container. The ash tray is coupled in communication with the bottom of the burner and receives the burned pellets in the burner. The air supply member is coupled to an upper portion of the ash tray, is inserted into the air inlet of the burner, and has a pipe shape that becomes narrower toward the rear.

Description

Pellet Heater

The present invention relates to a heater, and more particularly to a pellet heater using the pellets.

Heaters are classified into oil heaters, gas heaters, and electric heaters according to the fuel used. Oil or gas heaters cost a lot of fuel and generate carbon dioxide, which reduces their use. In addition, electric heaters also consume a lot of power has been pointed out in the energy efficiency.

In particular, in the case of heating a large space such as a plastic house, factory, oil, gas, electric heater has a significant maintenance cost. In recent years, the oil price has risen and the burden is increasing.

Therefore, farms, factories, public institutions, and the like are increasing heating apparatuses using solid fuels such as inexpensive briquettes, coal, lignite, and wood pellets to reduce heating costs.

Among these solid fuels, wood pellets are known as environmentally friendly fuels because they do not generate pollutants during combustion. Wood pellets are compacted with sawdust or wood and processed into pellets, which are as high as anthracite and have low calorific value and are easy to use. The pellet heater is a heating device using such a pellet, and generally has a structure in which the pellet descending from the upper pellet fuel container is burned by a burner, and the heat of combustion is radiated to the room through a heat radiation pipe to warm the indoor air.

Due to the environmental friendliness and low cost of wood pellets, heaters or boilers using wood pellets have been actively developed.

Korean Patent No. 1039119 discloses a pellet combustion device for burning wood pellets close to complete combustion. In view of the structure, a blow port and a blower are provided in the first combustion chamber that burns the pellets supplied from the pellet fuel cylinder, thereby achieving complete combustion. In addition, in the second combustion chamber communicating with the lower part of the primary combustion chamber, a blower and a blower are further provided for further combustion.

Another prior art, Korean Patent Laid-Open Publication No. 10-2010-0106645, discloses a wood pellet heater capable of efficiently handling complete combustion and temperature control. According to the structure, the fuel is supplied to the inside of the blower in which the electric heater is installed so that the fuel can be directly ignited by the electric heater, and the flame sensor, the temperature sensor, the blower, etc. are provided for the smooth supply of air and the continuous combustion. have.

Looking at the above prior art, it is equipped with a blower, a temperature sensor, etc. for complete combustion or temperature control, this additional device is inevitable to use electricity because it is difficult to avoid the point of energy efficiency.

In addition, the prior art adds additional devices such as a blower, a temperature sensor, etc., which complicates the structure of the pellet heater and increases the manufacturing cost.

The present invention is to solve this problem of the prior art,

First, to provide a non-powered pellet heater that does not use external power, such as electricity,

Second, the amount of heat generated can be controlled by adjusting the amount of fuel supplied to the combustion chamber,

Thirdly, to prevent backfire occurring between the plurality of fuel tanks, to prevent the backfire blocking means from becoming inoperable by the pellets,

Fourth, increase the pellet capacity, and

Fifth, it aims to block smoke from rising up into the fuel tank.

The pellet heater of the present invention for achieving this object includes a primary fuel container, a burner, a ash tray, an air supply member.

The primary fuel container stores the pellets supplied to the burners.

The burner is coupled in communication with the lower portion of the primary fuel canister and burns the pellets supplied from the primary fuel canister. One side of the burner is formed with an air inlet through which air is introduced from the outside.

The ash tray is coupled in communication with the bottom of the burner to receive the pellets burned in the burner. The ash tray secondaryly burns pellets that have not been completely burned in the burner.

The air supply member is provided in the form of a pipe and is coupled to the upper one side of the ash tray. The air supply member is inserted into the air inlet of the burner, the shape of which is tapered in width narrowing toward the rear.

The pellet heater of the present invention may further include a fuel throttle plate, and the fuel throttle plate is slidably inserted into the communication coupling portion of the primary fuel container and the burner.

The pellet heater of the present invention may further include a secondary fuel cylinder coupled to communicate with the upper portion of the primary fuel cylinder, in this case may further include a fuel blocking plate. The fuel block plate is slidably inserted into the communication coupling portion of the secondary fuel container and the primary fuel container. The fuel blocker blocks the feed of pellets from the secondary fuel cell to the primary fuel cell and also prevents backfire from the primary fuel cell to the secondary fuel cell. Here, it is preferable that the fuel cut-off plate is configured to protrude from the center portion of the insertion side end portion so that spaces are formed at both edges. The protruding shape may be composed of triangles, circles, and the like.

The pellet heater of the present invention may further include a tertiary fuel cylinder coupled to communicate with the upper portion of the secondary fuel cylinder. The tertiary fuel canister is configured to slide up and down along the outer surface of the secondary fuel canister. In this case, it further comprises a fixing means for fixing the tertiary fuel canister to the secondary fuel canister. The fixing means may use bolts and nuts, rivets and the like.

The pellet heater of the present invention may further include a fuel cell cover coupled to the upper portion of the tertiary fuel cell. An inner side of the fuel cell cover is provided with a sealing member for sealing the tertiary fuel cell. The sealing member prevents the smoke from leaking out of the tertiary fuel container when smoke rises into the tertiary fuel container.

The burner of the pellet heater of the present invention includes a fuel pedestal, wherein the fuel pedestal is formed with a plurality of through holes and is inclinedly coupled in the burner. The fuel pedestal supports and burns the pellets supplied from the primary fuel container, and then drops the burned pellets through the through hole to the ash tray. A vent in the fuel cradle delivers air entering the pellets through the air inlet of the burner. It is preferable that the inclination of the fuel cradle descends while going backward.

The pellet heater of this invention which has such a structure is a non-powered pellet heater which does not use external power, such as electricity, at all. As a result, the structure is simple and easy to manufacture, and the manufacturing cost can be reduced by 20% or more.

The pellet heater of the present invention can control the amount of heat generated by adjusting the amount of fuel supplied to the combustion chamber through the fuel throttle plate, and does not use any energy such as electricity in this process.

The pellet heater of the present invention can be blocked through the fuel blocking plate when backfire occurs between a plurality of fuel tanks. In addition, by making the end of the fuel cutoff plate protrude, it is possible to solve the problem that the falling pellet is caught between the fuel cutoff plate and the fuel container so that the fuel cutoff plate is not completely closed.

The pellet heater of the present invention can slidably connect a plurality of fuel tanks up and down, thereby increasing the capacity of the pellet and can be easily adjusted.

In addition, the pellet heater of the present invention, even if the smoke flows back through the fuel container, the back flow of smoke due to the sealing member of the fuel cell cover does not leak out of the fuel container.

1A and 1B are an overall perspective view of a pellet heater according to the present invention.
2A and 2B show a first embodiment of a pellet heater section according to the present invention.
3A and 3B show a second embodiment of the pellet heater unit according to the present invention.
4A and 4B show a third embodiment of the pellet heater unit according to the present invention.
5A and 5B show a fourth embodiment of the pellet heater unit according to the present invention.

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

1A and 1B are an overall perspective view of a pellet heater according to the present invention.

As shown in FIGS. 1A and 1B, the pellet heater includes a case 100, a protective film (not shown), a heat dissipation pipe 200, an external communication 300, a heater cover 400, a pellet heater 500, and the like. It includes.

The case 100 has a heat dissipation pipe 200 and a pellet heater unit 500 therein.

The protective film (not shown) is provided in the form of a net on the front of the case 100, and a plurality of rods are usually arranged horizontally or crosswise. The protective film (not shown) blocks the contact with the heat dissipation pipe 200.

The heat dissipation pipe 200 is composed of a plurality of pipes, a plurality of pipes are arranged up and down, one side of each pipe is connected in zigzag up and down or left and right communication. The heat dissipation pipe 200 receives combustion heat from the pellet heater unit 500 and warms the indoor air while slowly passing a plurality of pipes, and then is discharged to the outside through the external communication 300 on the upper side.

The heater cover 400 incorporates a pellet heater 500. The heater cover 400 has a plurality of through holes 410 are formed at least on the lower side, the plurality of through holes is a passage for supplying external air to the pellet heater 500.

The pellet heater unit 500 generates the combustion heat by burning the pellet supplied from the upper portion, and transmits the combustion heat to the lowermost pipe of the heat dissipation pipe 200.

2A and 2B show a first embodiment of a pellet heater section according to the present invention.

As shown in FIGS. 2A and 2B, the first embodiment of the pellet heater unit includes a primary fuel container 510, a burner 520, a backrest 530, an air supply member 540, and a fuel container cover 550. do.

The primary fuel container 510 stores the pellets, and naturally lowers the pellets to the burner 520 located below. The outer shape of the primary fuel container 510 may be configured in various ways, such as square, polygon, circular, etc., it is preferable to have a tapered shape that decreases in width as it goes downward. The tapered shape is suitable for supplying a certain amount of pellets to the burner 520 located below.

Burner 520 burns the pellets. One side, usually the rear of the burner 520 is provided with a pipe connector 522 connected to the lowermost pipe of the heat dissipation pipe 200, the combustion heat generated by the burner 520 through the pipe connector 522 is a heat dissipation pipe Is passed to 200.

 The upper part of the burner 520 communicates with the primary fuel container 510 and receives pellets from the primary fuel container 510 corresponding to an area corresponding to the lower width of the primary fuel container 510.

An air inlet communicating with the outside is formed at one side, and usually the front of the burner 520, and external air for injecting pellets is introduced through the air inlet.

The burner 520 has a fuel pedestal therein. The fuel pedestal is coupled in the burner 520 in a descending manner from front to back. The fuel pedestal is formed with a plurality of through holes penetrating up and down. The fuel pedestal may have one or more steps along the slope.

The fuel pedestal receives and supports the pellets supplied from the primary fuel container 510, and when the received pellets are burned, the fuel pellets are dropped into the lower ash tray 530 through a plurality of through holes.

A plurality of through holes formed in the fuel pedestal delivers air introduced through the air inlet of the burner 520 to a pellet located on the upper surface of the fuel pedestal.

Fuel pedestals have an angle of inclination of 30 to 70 °. If the angle of inclination of the fuel base is not 30 °, it is not easy for the pellets to fall along the fuel base, and if the angle of inclination exceeds 70 °, the pellets have a small moving distance, which increases the possibility of backfire and also speeds up the dropping of the pellets.

The ash tray 530 has a rectangular cylindrical shape with an empty inside. The upper part of the ash tray 530 is open and communicates with the lower part of the burner 520 through the upper opening. The ash tray 530 receives burnt pellets falling from the burner 520.

If the pellets dropped from burner 520 are not completely burned, ash tray 530 completely burns the pellets in combustion secondarily. In this case, the ash tray 530 may further include a cutout portion that communicates with the pipe connector 522 of the burner 520 at the upper rear side. The combustion heat generated by the secondary combustion in the ash tray 530 is transmitted to the pipe connector 522 of the burner 520 through the cutout, and is transmitted to the lowermost pipe of the heat dissipation pipe 200.

The backrest 530 may be configured by separating the upper case 532 and the lower plate 534, as shown in FIG. 2B.

The air supply member 540 is coupled to one side upper portion, usually the front upper portion of the ash tray 530, and is provided in the form of a pipe passing from the front to the rear. The air supply member 540 is inserted into an air inlet located in front of the burner 520 to direct external air into the burner 520, usually toward the bottom of the inclined surface of the fuel pedestal. The introduced air passes through the through holes of the fuel cradle to burn pellets located on the inclined surface.

The air supply member 540 is configured in a tapered shape, the width of which narrows toward the rear. When the air supply member 540 is formed in a tapered shape, the outside air introduced from the wide front becomes faster while moving in the rear pellet direction. This can accelerate the flow of air to the pellets. In this manner, the tapered air supply member 540 can function as a blower.

In addition, the air accelerated at the rear of the air supply member 540 passes quickly through the through hole of the fuel cradle, and as a result, a phenomenon in which smoke flows back from the burner 520 to the primary fuel container 510 can be reduced.

The fuel cell cover 550 closes the upper opening of the primary fuel cell 510. An inner side of the fuel container cover 550 may be attached with a sealing member 552 to block the primary fuel container 510 from the outside. The sealing member 522 blocks the smoke from leaking out of the primary fuel container 510 when the smoke rises into the primary fuel container 510.

The fuel container cover 550 may be detachably coupled to the primary fuel container 510.

3A and 3B show a second embodiment of the pellet heater unit according to the present invention.

As shown in Figs. 3A and 3B, the second embodiment further includes a fuel throttle plate 560 in the first embodiment.

The fuel throttle plate 560 is composed of a plate 562 and a handle 564. The upper part of the burner 520 is formed with a slit penetrating from the front to the rear. The slit is formed to include at least a portion of the communication coupling portion of the primary fuel container 510 and the burner 520.

 The fuel throttle plate 560 is inserted into the slit of the burner 520, and the plate 562 of the fuel throttle plate 560 slides back and forth in the slit of the burner 520.

The plate 562 of the fuel throttle plate 560 has a length that blocks one third or one half of the communication area between the primary fuel tank 510 and the burner 520. This is because the fuel throttle plate 560 controls the amount of pellets descending from the primary fuel container 510 to the burner 520, and it is not necessary to completely block the descending pellets.

4A and 4B show a third embodiment of the pellet heater unit according to the present invention.

4A and 4B add a secondary fuel cell 570 in communication with the primary fuel cell 510 on top of the primary fuel cell 510 in the first or second embodiment, and 1 A fuel blocking plate 582 is further provided to block the primary fuel cylinder 510 and the secondary fuel cylinder 570.

The secondary fuel container 570 stores the pellets, and additionally supplies the pellets to the primary fuel container 510 located below.

The shape of the secondary fuel container 570, like the primary fuel container 510, can be configured in various ways, such as square, polygon, circle, etc., and has a tapered shape that decreases in width as it goes downward. The tapered shape is suitable for supplying a certain amount of pellets to the primary fuel tank 510 located below.

The primary fuel cell 510 and the secondary fuel cell 570 have the same shape, in which case the upper opening of the primary fuel cell 510 is larger than the lower opening of the secondary fuel cell 570, and thus the primary fuel cell 510 ) And the secondary fuel container 570 is difficult to directly combine. Thus, the supporting plate 580 is further provided as shown in Figs. 4A and 4B. The support plate 580 has a structure for closing the upper opening of the primary fuel tank 510 except the center, and the central opening is in communication with the lower opening of the secondary fuel tank 570.

A partially recessed space is formed in the upper opening of the primary fuel container 510, and when the support plate 580 is coupled to the upper portion of the primary fuel container 510, the recessed space constitutes a slit. The slit is formed to include a communication coupling portion of at least the primary fuel cylinder 510 and the secondary fuel cylinder 570.

The fuel blocking plate 582 is composed of a plate 581 and a handle 583. The plate 581 of the fuel blocking plate 582 is slid into the slit. The plate 581 of the fuel blocking plate 582 is such that its length completely blocks the communication coupling portion of the primary fuel cylinder 510 and the secondary fuel cylinder 570. This is because the fuel blocking plate 582 is used to lower the pellets from the secondary fuel container 570 to the primary fuel container 510 so as to further supply pellets to the primary fuel container 510, and further, into the primary fuel container 510. If embers remain in the pellets, the fire may spread to the secondary fuel container 570 because it also performs a function of blocking the fire.

The fuel cutoff plate 582 is preferably configured to protrude from the center of the insertion end. The pellet may have a length of 3 cm or more. In this case, if the insertion end of the fuel blocking plate 582 is in a straight line, the insertion end may be caught in the pellet so as not to completely close the communication coupling portion of the secondary fuel cell 570 and the primary fuel cell 510. This is because it does not happen. The protruding shape of the insertion end of the fuel blocking plate 582 can be configured in various ways, such as a triangle, a circle.

5A and 5B show a fourth embodiment of the pellet heater unit according to the present invention.

5A and 5B further include a tertiary fuel cylinder communicating with the secondary fuel cylinder 570 on the upper portion of the secondary fuel cylinder 570 in the third embodiment.

The tertiary fuel cylinder 590 is preferably configured to slide up and down along the outer surface of the secondary fuel cylinder 570. Because, when the smoke flows back to the secondary fuel tank 570, if the tertiary fuel cylinder 590 is in the secondary fuel cylinder 570, the smoke in the sliding surface of the secondary fuel cylinder 570 and the tertiary fuel cylinder 590. Because it may leak.

In addition, the tertiary fuel cylinder 590 may be fixed to the secondary fuel cylinder 570 by using a fixing means. By installing a plurality of fixing portions up and down, the overall height of the tertiary fuel cylinder 590 and the secondary fuel cylinder 570 can be adjusted. Bolts, nuts, rivets and the like can be used as the fixing means.

Pellet heater 500 of the present invention described above can be applied to a home boiler, it can be applied to a house heater for growing crops.

While the invention has been described in terms of several embodiments, it is to be understood that the invention is not limited thereto. Those skilled in the art will be able to variously modify or modify the spirit of the present invention based on this embodiment. Accordingly, the scope of the present invention is defined by the following claims, and such variations and modifications made by a person skilled in the art can be construed as being included in the scope of the present invention.

100: case 200: heat dissipation piping
300: external communication 400: heater section cover
500: pellet heater 510: primary fuel container
520: burner 530: ash tray
540: air supply member 550: fuel container cover
552: sealing member 560: fuel control plate
570: secondary fuel container 580: support plate
582 fuel block 590 tertiary fuel container

Claims (6)

In a pellet heater,
A primary fuel container for storing pellets;
A burner communicating with a lower portion of the primary fuel container, having an air inlet on one side, and combusting pellets supplied from the primary fuel container;
A ash tray coupled to the lower portion of the burner to receive pellets burned in the burner; And
It is coupled to the upper portion of the ash tray, inserted into the air inlet of the burner, and configured in a pipe shape that becomes narrower toward the rear, and includes an air supply member for accelerating the front inlet air to supply to the rear pellets Pellet heater, characterized in that. The method of claim 1,
And a fuel control plate detachably coupled to the communication coupling portion of the primary fuel container and the burner and selectively opening and closing the communication coupling portion of the primary fuel container and the burner. The method of claim 1,
A secondary fuel cylinder coupled to and communicated with an upper portion of the primary fuel cylinder; And
And a fuel blocking plate detachably coupled to the communication coupling portion of the secondary fuel cylinder and the primary fuel cylinder, and selectively opening and closing the communication coupling portion of the secondary fuel cylinder and the primary fuel cylinder. heater. The fuel blocking plate of claim 3, wherein the fuel blocking plate is
A pellet heater characterized in that the center portion of the insertion side end portion is configured to protrude. The method according to claim 3 or 4,
A tertiary fuel cylinder coupled to an upper portion of the secondary fuel cylinder and sliding up and down along an outer surface of the secondary fuel cylinder; And
And a fixing means for fixing the tertiary fuel canister to the secondary fuel canister. The method of claim 5,
And a fuel cell cover coupled to an upper portion of the tertiary fuel container and having a sealing member attached to an inner side to seal an upper opening of the tertiary fuel container.

Images