KR20180010457A - Pellet boiler having mobile fire grate - Google Patents

Abstract

The present invention relates to a pellet boiler provided with a movable fire grate for moving down and burning supplied pellet fuel, and more particularly, to a pellet boiler provided with a movable fire grate, where a moving fire grate that moves in a forward/backward direction is installed on an upper portion of a fixed fire grate, such that pellet fuel being burned is moved downward while material completely burned is continuously discharged from a combustion portion, thereby maintaining durability of the combustion portion and a combustion performance as well in a best condition.

Description

Technical Field [0001] The present invention relates to a pellet boiler having a mobile grate,

The present invention relates to a pellet boiler provided with a movable grate to which the supplied pellet fuel moves downward and burns.

Generally, the solid fuel used in the wood pellet boiler has a disadvantage that the thermal efficiency is relatively low as compared with the fossil fuel, because the solid fuel used as the pellet type solid fuel is used as the bio-SRF wood material , It has a simple structure, low fuel cost, and is environmentally friendly. In recent years, it has been using herbaceous fuel which can be completely burned due to environmental pollution.

The pellet boilers using such herbaceous fuels are largely composed of a gun type burner, which is a registered trademark 10-1346914 (public announcement date: 2014.01.02), and a crucible type burner, which is a registered trademark 10-1394254 (public announcement date 2014.05.13) consist of.

However, such conventional dry type or crucible type burners are difficult to discharge ashes continuously at the time of burning, so that frequent failures and durability are deteriorated.

That is, according to the kind of the herbaceous fuels to be burned, the incidence of flour-like material and sludge (clinking) after burning shows a difference of several tens of times, so that the conventional burner types are inconvenient to use the characteristic herbaceous fuel .

In addition, since the conventional burner type can not easily discharge the ash, the combustion performance is also deteriorated.

Disclosure of the Invention The present invention has been proposed in order to solve the above-mentioned problems, and it is an object of the present invention to provide a pelletizing device capable of continuously discharging ashes during burning regardless of kinds of herbal pellet fuels to maintain the performance of the burner, It is intended to provide a boiler.

According to an aspect of the present invention, there is provided a pellet boiler provided with a movable grate, comprising: a housing part formed with a water chamber to be heat-exchanged; A supply part for supplying the pellet fuel stored in the combustion part by a predetermined amount, and a supply part for supplying the pellet fuel to the housing part, the combustion part and the supply part And a control unit for controlling at least one of the plurality of combustion chambers, wherein the combustion unit has a guide bracket formed with an installation space portion therein, a plate having a plate shape at the rear of the guide bracket and formed with an exposure hole through which the pellet fuel is discharged, A plurality of vertically adjacent mounting spaces, A moving grate having a plate shape, a plurality of moving gates movably installed between the fixed grate and moving the pellet fuel in a downward direction, a plurality of actuators reciprocating the moving grate, And an ignition means formed to ignite the pellet fuel supplied through the exposure hole.

Further, the supply unit may initially supply the pellet fuel to the upper surface of the moving grate, which is located at the top of the plurality of moving grate, so that the supply unit can be ignited by the ignition means, and the ignition means is a heater.

Further, it is preferable that a plurality of air holes are formed in at least one of the fixed grate, the moving grate, and the guide bracket to supply air required for complete combustion of the pellet fuel.

The actuator may include a connecting bracket for simultaneously moving the plurality of moving grate members and simultaneously moving the connecting grate. A plurality of connecting rods are provided on the connecting bracket to be detachably engaged with the engaging grooves formed in the lower portion of the moving grate Do.

The housing unit includes a heat exchanger body having a water chamber therein, an upper chamber provided at an upper portion of the heat exchanger body, a lower chamber provided at a lower portion of the body of the heat exchanger, And a second heat exchanger is installed to expose the combustion chamber to guide the combustion gas generated by the combustion unit to the upper chamber and guide the combustion gas to the upper chamber and to be connected to the upper chamber and the lower chamber, And a plurality of heat exchange links each of which is connected to the lower chamber and the upper chamber, wherein the pass pipe is installed to be downwardly inclined so as to guide the combustion gas downward, and a third heat exchanger installed to be exposed to the water chamber, The combustion gas rises along the firebox and performs primary heat exchange, and is directed downward by the path tube It is preferable that the secondary heat exchange is carried out while performing the conversion and the exhaust heat is generated after the tertiary heat exchange is performed along the heat exchange association.

And a combustion promoting ring for completely burning the pellet fuel, wherein the combustion promoting ring is a tubular collecting body which is open at an upper side and a lower side and has a hollow portion having a predetermined diameter, The air suction groove formed on the outer surface of the collecting body so as to have a diameter smaller than the diameter of the hollow portion formed on the inner wall of the collecting body, And an air inflow hole formed at one end of the inflow pipe so as to communicate with the air intake groove and at the other end of the air inflow hole formed to perforate the jaw so that the air supplied through the inflow pipe can be introduced into the collecting body .

The supply unit may include a hopper for storing the pellet fuel, a crushing screw for rotating the pellet fuel supplied from the hopper, and the pellet fuel supplied through the crushing screw by a predetermined amount And the pellet fuel supplied from the hopper may be crushed and supplied to the feed screw. The pellet feeder may further include a feed screw that feeds the pellet fuel to the feed screw.

According to the present invention, a moving grate that moves in the forward / backward direction is provided on the upper portion of the fixed grate differently from the prior art to move the pellet fuel in the downward direction, and the completely burned material is continuously discharged from the combustion portion, The durability of the combustion section as well as the effect of maintaining the combustion performance in the best condition.

1 shows a pellet boiler equipped with a mobile grate according to the invention.
2 is a cross-sectional view illustrating the inside of a firebox of a pellet boiler provided with a movable grate according to the present invention.
3 is a combustion section of a pellet boiler with a movable grate according to the present invention.
4 is a sectional view of Fig. 3; Fig.
5 shows an actuator of a pellet boiler with a movable grate according to the present invention.
6 is a view showing a state in which pellet fuel in the combustion section of Fig. 3 is burned. Fig.
FIGS. 7A to 7D are views showing a combustion operation relationship of a pellet boiler provided with a movable grate according to the present invention. FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a pellet boiler having a movable grate (hereinafter briefly referred to as a pellet boiler) according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1, the pellet boiler 1 according to the present invention includes a housing part 100, a combustion part 200, and a supply part 300. The housing part 100, the combustion part 200, (Not shown) installed in the housing part 100 and a controller (not shown) using a controller (not shown) for controlling the control panel by wire / wireless communication are provided in the housing part 100, the combustion part 200 and the supplying part 300. [ The control unit 400 can be burned according to the user's setting, and a detailed description of the control unit 400 will be omitted so as not to obscure the gist of the present invention.

More specifically, the housing unit 100 is provided with a combustion unit 200 and a supply unit 300, which will be described later, to prevent the generation of condensed water at the time of combustion and to heat exchange a plurality of times to improve the heat exchange efficiency And includes a heat exchanger body 110, an upper chamber 120, a lower chamber 130, a firebox 140, a path tube 150, a heat exchange association 160, and a supply chamber 170 in the configuration.

In this case, the heat exchanger body 110 is provided with a water chamber WT therein. When the pellet fuel P of herbal system such as wood is supplied from the supply unit 300 and burned through the combustion unit 200, The low-temperature water passing through the heat exchanger (WT) exchanges heat with the heat source generated during combustion.

The upper chamber 120 and the lower chamber 130 are respectively installed on the upper and lower sides of the water chamber WT provided in the heat exchanger body 110. The upper chamber 120 and the lower chamber 130 are respectively provided with combustion gases generated in the combustion unit 200, 110 to change the direction of flow.

The upper chamber 120 and the lower chamber 130 include first and second upper chambers 121 and 123 and first and second lower chambers 131 and 133, respectively.

The lower part of the first upper chamber 121 is connected to the upper part of the artillery chamber 140 and the upper part of the passageway 150 so that the combustion gas generated in the first lower chamber 131 is collected through the artillery chamber 140, (150).

The second upper chamber 123 is installed so that the lower portion communicates with the upper portion of the heat exchange association 160 and the combustion gas flowing into the path pipe 150 can be moved to the heat exchange association 160 through the second lower chamber 133 An air blower for sucking the combustion gas is installed.

The first lower chamber 131 has a space in which the combustion unit 200 can be burned and an upper part of the first lower chamber 131 is provided to communicate with the lower part of the fire room 140. The combustion gas is blown by the suction force of the fan through the fire room 140 To the first upper chamber 121 and provides a space through which the ash of the pellet fuel, which has been completely burned through the combustion section 200, can be primarily collected.

Although not shown, a door (not shown) may be formed in the first lower chamber 131 to discharge the collected material to the outside of the heat exchange body 110. The second lower chamber 131 The same configuration can be applied.

The second lower chamber 133 is installed so that its upper portion communicates with the lower portion of the pass pipe 150 and the lower portion of the heat exchange association 160 and is included in the combustion gas moving in the pass pipe 150 or the heat exchange association 160. (S) to be collected secondarily.

Accordingly, the water WT existing in the heat exchanger body 110 flows through the firebox 140 between the first lower chamber 131 and the first upper chamber 121 at a temperature of about 1000 ° C or higher And is moved through the path tube 150 between the first upper chamber 121 and the second lower chamber 133 to be heated by the combustion gas at 700 ° C. to 800 ° C. Tertiary heat exchange is performed sequentially with the combustion gas maintaining the temperature of about 300 to 600 ° C. moving through the heat exchange association 160 between the second lower chamber 133 and the second upper chamber 123 .

The firebox 140, the pass pipe 150, and the heat exchange association 160 provide a transfer path through which the combustion gas flows, causing heat exchange between the combustion gas and the low temperature water of the water column WT, A first to third heat exchange is sequentially performed.

Particularly, the present invention suppresses an excessive decrease in the temperature of the combustion gas by using the pass pipe 150 provided between the firebox 140 and the heat exchange association 160. Therefore, it is possible to prevent the condensed water from being generated and increase the thermal efficiency while preventing the facility size from becoming large.

In addition, the lower part of the downwardly inclined path tube 150 is connected to the second lower chamber 133 according to the present invention. Accordingly, since the flow of the combustion gas in the first upper chamber 121 is changed and the ashes are separated and collected in the second lower chamber 133, the ash generated during the combustion of the pellet fuel is more reliably separated and collected, So that it is possible to prevent environmental pollution.

The heat exchanger body 110 is provided with a water tank (WT) therein. The water chamber WT is formed by using the space inside the heat exchanger body 110 and the fire room 140, the path tube 150 and the heat exchange association 160 described later are exposed to the water chamber WT, respectively.

Although not shown, the heat exchanger body 110 is generally formed with an inlet through which low-temperature water (direct water or heating water return) for heat exchange is supplied and an outlet through which heat-exchanged hot water is discharged.

The combustion chamber 140 is installed to be exposed to the water chamber WT provided in the heat exchanger body 110 and performs primary heat exchange between the combustion gas and the low temperature water. At this time, the combustion gas generated in the combustion unit 200 is supplied to the upper side And guided to the first upper chamber 121.

For this purpose, the artificial chamber 140 has a columnar shape having a predetermined height, and a shape such as a circular column or a square column is used depending on the shape of the heat exchanger body 110. In addition, high heat conductivity material is used to increase the heat exchange rate.

2, when the pellet fuel P is burned through the combustion unit 200 at the lower end opening (that is, the heat source inflow side) of the artillery chamber 140, The air intake hole 183, and the air inlet hole 185, as shown in FIG.

The collecting body 181 has a hollow cylindrical shape with a predetermined diameter so that the flame of the combustion unit 200 can be collected therein, and the upper and lower openings are opened.

At this time, it is preferable that a jaw portion 181a having a smaller diameter than the open / lower diameter is formed on the inner surface of the collecting body 181 so that the flame can be collected easily.

The air inlet groove 183 is formed in a furrow shape on the outer surface of the collecting body 181 and communicates with an inlet pipe 187 provided in the heat exchanger body 110 to form an air inlet groove 183, So that air can be totally introduced into the apparatus.

A plurality of air inflow holes 185 are radially formed in the collector 181 so that one end extends from the inner wall of the air inflow groove 183 to the jaw portion 181a and air flows through the inlet tube 187 to the collector 181 So that the air necessary for complete combustion can be supplied.

At this time, the air inflow hole 185 is inclined in one direction so that the air introduced into the collecting body 181 flows in the form of a tornado, and the collected flames extend in the longitudinal direction of the firebox 140, It is preferable to increase the height.

The pass pipe 150 is installed between the fire room 140 and the heat exchange association 160 to guide the flow of the combustion gas so that the combustion gas discharged from the fire room 140 is supplied to the heat exchange association 160.

Referring again to FIG. 1, the pass pipe 150 is installed to be exposed to the water chamber WT to perform secondary heat exchange, and is connected between the first upper chamber 121 and the second lower chamber 133, Downwardly inclined so as to guide the gas downward.

That is, the upper opening of the pass pipe 150 is connected to the first upper chamber 121, and the lower opening is connected to the second lower chamber 133, thereby lowering the combustion gas rising along the fire chamber 140 again, 2 lower chamber 133 as shown in FIG.

As a preferred embodiment, at least one tube having a square or circular cross section is used in the path tube 150 without a heat exchange fin (or baffle plate) different from the heat exchange tube 160 to be described later. However, a pipe made of a metal having high thermal conductivity is used for heat exchange.

The pass pipe 150 is used as an aid to the heat exchange association 160 and is used to prevent the combustion gas from falling below the dew point temperature by lowering the heat exchange rate relative to the heat exchange association 160 do.

That is, it is possible to prevent the thermal efficiency from being lowered through heat exchange in the path tube 150, and to increase the temperature of the low temperature water filled in the water WT of the heat exchanger body 110 to some extent, Prevents excessive temperature drop of gas.

Accordingly, the present invention prevents the generation of condensed water in the heat exchange association 160 and prevents the ash of the pellet fuel from adhering to the inside of the heat exchange association 160 due to the generation of condensed water, thereby lowering the heat exchange rate.

Further, the present invention facilitates switching of the combustion gas from the lower chamber 130 to the heat exchange association 160 by providing the path tube 150 downwardly inclined with respect to the flow path of the combustion gas. Therefore, the combustion gas and the ashes are well separated.

However, the diameter, inclination angle, and cross-sectional shape of the above-described path pipe 150 are adjusted so that the combustion gas passing through the path pipe 150 is maintained at 700 ° C. or higher and 800 ° C. or lower desirable.

If the temperature is less than 700 ° C, condensation water is apt to be generated in the heat exchange association 160. On the contrary, if the temperature is higher than 800 ° C, sufficient heat recovery is not performed even if the heat exchange association 160 performs tertiary heat exchange.

The heat exchange association 160 is installed to be exposed to the water WT of the heat exchanger body 110 to perform tertiary heat exchange and the plurality of heat exchange associations 160 are connected to the second lower chamber 133 and the second upper chamber 123, so that the combustion gas can rise independently of each other, thereby achieving tertiary heat exchange with water and then allowing the exhaust gas to be exhausted by the fan.

As shown in the figure, a plurality of heat exchange joints 160 are provided with a heat exchange fin 161 (or a baffle plate having a similar function) inside the heat exchanger body 160, In a lattice pattern to maximize the heat transfer area.

Accordingly, the present invention can prevent the generation of condensed water by increasing the temperature difference between the low-temperature water and the combustion gas by the path tube 150, while the portion of the path tube 150 alone, which does not provide a sufficient heat exchange effect, And is compensated by association 160.

Each of the heat exchange fins 161 is installed in the heat exchange association 160 integrally with the cleaning rod 163 provided outside the heat exchanger body 110 so that the heat exchange fins 161 can be lifted and lowered, It is desirable to be able to remove the sludge adhered to the sludge.

The supply chamber 170 is formed on the side of the heat exchanger body 110 so that the lower part communicates with the first lower chamber 131 and the upper part is provided with the supply part 300 so as to communicate with the outside so that the pellet fuel P can be supplied. And the combustion unit 200 is installed in the lower part so as to communicate with the first lower chamber 131.

3 to 5, the combustion unit 200 combusts the pellet fuel P supplied by a predetermined amount through the supply unit 300, and when the combustion is performed, the pellet fuel P is lowered A fixed grate 220, a moving grate 230, an actuator 240, and an ignition means 250. The guide bracket 210, the fixed grate 220, the moving grate 230, the actuator 240,

The guide bracket 210 is fixedly installed so as to be exposed in the first lower chamber 131 so that the installation space 211 can be formed therein.

At this time, a plate-shaped plate 213 is fixed to the inner wall of the first lower chamber 131 at the rear of the guide bracket 210, and a pellet fuel And a plurality of moving grate members 230 are provided in the lower portion by the actuator 240 in the forward and backward directions by the actuator 240 A reciprocating through hole is formed.

A plurality of fixed grate 220 is fixedly installed in the installation space 211 and the moving grate 230 is moved back and forth through the actuator 240 along the side wall of the guide bracket 210 .

The guide bracket 210 and the plate 213 are formed with a refractory material such as a castable refractory or the like to prevent the refractory wall from being damaged by heat generated during combustion.

The fixed grate 220 has a plate shape as a whole and a plurality of grate gates 230 are vertically disposed adjacent to each other in the installation space 211 so that the movable grate 230 can move with the movable grate 230, Respectively.

The fixed grate 220 is installed in the fixed grate 220 so that each end of the movable grate 230 can be vertically laid so that the pellet fuel P burned at the time of movement can be moved downward in stages and finally collected at the bottom of the first lower chamber 131. [ (See Fig. 4).

The fixed grate 220 in the present invention may include a plurality of fixed grate 220 disposed at the bottom of the installation space 211 so that the ends thereof do not coincide with each other in a vertical line, The guide brackets 210 are not spaced apart from the bottom surface of the guide bracket 210. However, the guide brackets 210 may be installed in a larger number depending on the amount of the pellet fuel P to be burned or the capacity of the pellet boiler 1 .

The moving grate 230 may have the same shape as the fixed grate 220 described above and between the fixed grate 220 and the bottom surface of the guide bracket 210 between the fixed grate 220 and the actuator 260, (240).

At this time, an engaging groove 231 for detachably engaging with the engaging rod 243 is formed under the moving grate 230 to facilitate maintenance.

It is also preferable that a plurality of air holes are formed in the fixed grate 220 or the guide bracket 210 as well as the moving grate 230 so that the air required for combustion of the pellet fuel P can be introduced.

The moving distance of the moving grate 230 is such that the pellet fuel P that is burning at the top can be moved to the front of the plate 213 or the fixed grate 220 to move downward.

The pellet fuel P exhausted through the supply unit 300 is seated on the upper part of the moving grate 230 located at the uppermost one of the plurality of the moving grate 230 installed in the guide bracket 210, Make it possible to ignite.

The actuator 240 is installed to be positioned behind the plate 213. The tension shaft is coupled with a connection bracket 241 that is integrally coupled to the rear of the plurality of moving grate members 230 to move the movable grate 230 in the forward / (230).

In addition, a plurality of coupling rods 243 are formed at the upper portion of the connection bracket 241 to engage with the coupling grooves 231 formed at the lower portion of the moving grate 230.

At this time, it is preferable that the coupling grooves 231 are formed adjacent to each other in the longitudinal direction below the moving grate 230 so as to control the moving distance of the moving grate 230 which can move to the actuator 240.

The ignition means 250 is configured to ignite and burn the pellet fuel P supplied to the upper portion of the moving grate 230 through the supply portion 300.

The ignition means 250 may be a heater, for example, and may be exposed outside the plate 213 to ignite the pellet fuel P supplied to the moving grate 230.

In order to facilitate understanding of the combustion unit 200, the operation will be described in detail with reference to the drawings.

7A to 7D, when the actuator 240 is advanced to move the plurality of moving grate 230 to a position above the fixed grate 220, when the transport screw 323 rotates, So that the pellet fuel P can be supplied to the upper portion of the moving grate 230 through the holes 215.

At this time, it is preferable that the pellet fuel P be supplied to the upper surface of the moving grate 230 located at the top of the plurality of moving grate 230 installed in the guide bracket 210.

Next, the pellet fuel P supplied to the ignition means 250 is ignited and waits for a predetermined period of time to be burned. The actuator 240 is then moved back so that the pellet fuel P, which is being burned at the top of the moving grate 230, And is mounted on the upper surface of the fixed grate 220 positioned below the moving grate 230 to be burnt for a predetermined time.

Thereafter, the actuator 240 advances again so that the moving grate 230 is moved forward to be positioned above the fixed grate 220. In the exposure hole 215, the pellet fuel P is supplied again, and at the same time, The combustion gas ignited by the pellet fuel is ignited and the combustion gas necessary for heat exchange can be continuously supplied.

At this time, the pellet fuel P being burned on the upper surface of the fixed grate 220 is moved to the front surface of the moving grate 230 through the movement of the moving grate 230 so that the pellet fuel P can be seated on the upper surface of the fixed grate 220 and burned .

By repeatedly executing the above-described procedure, the combustion unit 200 can supply the high-temperature combustion gas to the combustion chamber 140 together with the continuous combustion of the pellet fuel P in the heat exchanger body 110, The ash pellet fuel is collected at the bottom surface of the first lower chamber 131 and discharged to the outside of the heat exchanger body 110 by the operator.

In the combustion unit 200 according to the present invention, the supplied pellet fuel P is supplied to the stationary grate 220 or the moving grate 230 by a predetermined amount. However, in actual use, It should be noted that, as shown, the pellet fuel P may be burned while being covered on top of all the grate.

1, the supply unit 300 is configured to continuously supply a predetermined amount of the pellet fuel P to the combustion unit 200 under the control of the control unit 400. The hopper 310 and the screw 320).

The hopper 310 has a shape of an open top / bottom and is fixedly installed inside the supply chamber 170.

The hopper 310 may be opened or closed through a door rotatably installed on the opened upper portion of the heat exchanger body 110 so as to supply pellets fuel P to the hopper 310.

The crushing screw 321 is installed to communicate with the lower part of the hopper 310 and is supplied with the pellet fuel P and the transfer screw 323 Is installed so as to communicate with the inside of the crushing screw 321 and can supply the pellet fuel P to the combustion unit 200 through the exposing hole 215.

Of course, the screws 320 in the present invention are shown as being able to supply the pellet fuel P to the combustion unit 200 in a pair, but this is an example and it is possible to use one screw It is also possible to supply the pellet fuel P to the combustion section 200.

At this time, as shown in the figure, the pair of screws 320 are installed so as to be able to rotate simultaneously by a chain 325 connected to a motor (not shown) Is formed to be narrower than the interval between the blades formed in the screw 323 and is broken by the crushing screw 321 without being affected by the thickness of the supplied herbal pellet fuel and is conveyed to the combustion unit 200 by the conveying screw 323 .

The pellet boiler 1 according to the present invention constructed as above has a moving grate 230 moving in the forward / backward direction above the fixed grate 220 to separate the pellet fuel P in the combustion The material that has been completely burned and moved downward is continuously discharged by the combustion unit 200, thereby maintaining the durability of the combustion unit 200 as well as maintaining the combustion performance in the best condition.

The specific embodiments of the present invention have been described above. It is to be understood, however, that the spirit and scope of the invention are not limited to these specific embodiments, but that various changes and modifications may be made without departing from the spirit of the invention, If you are a person, you will understand.

Therefore, it should be understood that the above-described embodiments are provided so that those skilled in the art can fully understand the scope of the present invention. Therefore, it should be understood that the embodiments are to be considered in all respects as illustrative and not restrictive, The invention is only defined by the scope of the claims.

1: Pellet boiler with mobile grate according to the invention
100: housing part 110: heat exchanger body
120: upper chamber 121: first upper chamber
123: second upper chamber 130: lower chamber
131: first lower chamber 133: second lower chamber
140: Japanese style room 150:
160: heat exchange association 161: heat exchange pin
163: cleaning rod 170: supply chamber
180: combustion promoting ring 181: collector
183: air inflow groove 185: air inflow hole
187: Inflow pipe 200: Combustion part
210: guide bracket 211: installation space part
213: plate 215: exposed ball
220: fixed grate 230: moving grate
231: coupling groove 240: actuator
241: connecting bracket 243: connecting rod
250: Ignition means 300:
310: hopper 320: screw
321: Crushing screw 323: Feed screw
325: chain 400: control unit
P: pellet fuel WT: water chamber

Claims (7)

A housing part 100 formed with a water chamber WT for achieving heat exchange;
A combustion unit 200 installed in the housing unit 100 so as to move and fix the fuel pellets in a stacked structure and move downward the pellet fuel P in a stepwise manner;
A supply unit 300 installed in the housing unit 100 to store the pellet fuel P and supplying the pellet fuel P stored in the combustion unit 200 by a predetermined amount; And
And a control unit 400 for controlling at least one of the housing unit 100, the combustion unit 200 and the supply unit 300. The combustion unit 200 includes:
A guide bracket 210 having a mounting space 211 formed therein and a plate 213 fixed to the rear of the guide bracket 210 to have a plate shape and having an exposure hole 215 through which the pellet fuel P is discharged A plurality of stationary grate 220 having a plate shape and fixedly installed adjacent to each other in a direction perpendicular to the installation space 211, a plurality of movable gates 220 disposed between the stationary grate 220, A moving grate 230 for moving the pellet fuel P in a downward direction, an actuator 240 for reciprocally moving a plurality of the moving grate 230, And an ignition means (250) for igniting the pellet fuel (P) supplied through the ignition means (250). The method according to claim 1,
The supplying unit 300 may initially supply the pellet fuel P to the upper surface of the moving grate 230 located at the top of the plurality of moving grate 230 to be ignited by the igniting means 250 , And the ignition means (250) is a heater. The method according to claim 1,
Wherein at least one of the fixed grate (220), the moving grate (230), and the guide bracket (210) is formed with a plurality of air holes to supply air required for complete combustion of the pellet fuel (P) Pellet boiler with grate. The method according to claim 1,
The actuator 240 includes a connecting bracket 241 for moving the moving grate 230 in parallel with the plurality of moving grate 230, And a plurality of engaging rods (243) are detachably coupled to the grooves (231) so as to be detachably attached to the grooves (231). The method according to claim 1,
The housing unit 100 includes a heat exchanger body 110 having a water chamber WT therein;
An upper chamber 120 provided at an upper portion of the heat exchanger body 110;
A lower chamber 130 provided below the heat exchanger body 110;
A firebox 140 installed to be exposed to the water chamber WT so as to perform primary heat exchange and guide the combustion gas generated in the combustion unit 200 upward to the upper chamber 120;
A pass pipe 150 connected to the upper chamber 120 and the lower chamber 130 so as to be exposed to the water chamber WT and subjected to secondary heat exchange and installed to be downwardly inclined to guide the combustion gas downward, ; And
And a plurality of heat exchange joints (160) installed to be exposed to the water chamber (WT) to perform tertiary heat exchange and connected between the lower chamber (130) and the upper chamber (130)
The combustion gas rises along the fire room 140 and performs primary heat exchange and performs secondary heat exchange while changing direction to the lower side by the path pipe 150. The combustion gas rises along the heat exchange association 160, And the pellet boiler is equipped with a movable grate. 6. The method of claim 5,
A combustion promoting ring 180 for completely burning the pellet fuel P is disposed in an open lower portion of the artillery chamber 140. The combustion promoting ring 180 is opened upward or downward and has a predetermined diameter A jaw portion 181a formed on the inner wall of the collector 181 and having a diameter smaller than the diameter of the hollow portion 181a formed on the outer surface of the collector 181, An inlet pipe 187 communicating with the air inlet groove 183 and supplying air necessary for complete combustion, one end communicating with the air inlet groove 183, and the other end communicating with the air inlet groove 183, And an air inflow hole (185) formed to be pierced to the jaw portion (181a) so that the air supplied through the inflow pipe (187) can be introduced into the collector (181) The pellet boiler comprising: The method according to claim 1,
The supply unit 300 includes a hopper 310 in which the pellet fuel is stored;
A crushing screw 321 for rotating the pellet fuel supplied from the hopper; And
And a feed screw 323 for feeding the pellet fuel supplied through the crushing screw 321 to the burning unit 200 by a predetermined amount while rotating,
The blade spacing of the crushing screw 321 is narrower than the blade spacing of the feed screw 323 so that the pellet fuel supplied from the hopper 310 is crushed and supplied to the feed screw 323 Wherein the pellet boiler is provided with a movable grate.

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