KR101564844B1 - Pellet stove with high efficiency - Google Patents

Abstract

The present invention relates to a pellet stove with high efficiency, which has a combustion gas primarily exchanging heat with an air heating pipe on the upper part of a fire box, and secondarily exchanging heat with warm air supplied through the air heating pipe during a discharge process. And, the present invention relates to a pellet stove with high efficiency preventing a surrounding facility over heated by high temperature inside the fiber box, while enabling complete combustion of a pellet fuel by providing high temperature combustion environment inside the fire box.

Description

High efficiency pellet stove {Pellet stove with high efficiency}

The present invention relates to a high-efficiency pellet stove, and more particularly, to a high-efficiency pellet stove capable of supplying warm air into a room by burning pellets as fuel and radiating radiant heat to the front surface.

Recently, the use of pellet fuel including various biomass such as coal and wood has been increasing, and pellet fuel has also been used in a stove for heating the room.

1 shows a pellet stove. The pellet stove 10 is provided with a furnace 12 in a flame chamber 11 in a body (not shown) and supplies pellets fuel to the furnace 12 from a feeder 13, And ignites the pellet fuel while supplying combustion air.

Thus, the high temperature combustion gas generated in the firebox 11 is discharged to the exhaust port 11a. At this time, the air supplied through the air blowing fan 15 and the air box 16 passes through the air heating pipe 17 Lt; / RTI > The heated hot air is supplied to the room.

However, in the conventional art as described above, the high temperature combustion gas generated by burning the pellet fuel only exchanges heat once only in the process of passing through the air heating pipe 17 in the upper portion of the firebox 11. Therefore, the thermal efficiency is low.

The outdoor air of low temperature is sucked by the blowing fan 15 for the warm air and supplied to the air heating pipe 17. At this time the air heating pipe 17 is in contact with the fire room 11 to cool the fire room 11 . Therefore, it does not provide a high temperature combustion environment and causes incomplete combustion.

Further, deformation or breakage may occur in the peripheral equipment due to the high-temperature fire room 11, and there is a risk of fire or safety accidents, in particular.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a method of controlling the temperature of an air heating apparatus, in which the combustion gas performs primary heat exchange with an air heating tube above a firebox, High-efficiency pellet stove.

It is another object of the present invention to provide a high-efficiency pellet stove which can prevent the surrounding facilities from being overheated by the high temperature inside the firebox while providing a high-temperature combustion environment inside the firebox, thereby enabling complete combustion of the pellet fuel.

To this end, the high-efficiency pellet stove according to the present invention comprises: a stove body having a facility space therein; A door provided on the stove body so as to be openable and closable; A first wall installed in the inside of the hearth body to partition the inside of the hearth body and form a firebox on one side; A pellet burner module installed in the artillery chamber and having a furnace in which pellet fuel is supplied for combustion; A pellet feeder installed on the outside of the firebox to supply the pellet fuel to the furnace; An air heating pipe installed on the upper side of the firebox and having a hot air outlet at one open end exposed to the outside of the stove body and an air inlet at the other open end connected to the air supply passage; A second wall spaced apart from the first wall without the artificial chamber to form the air supply passage with the first wall; A blower for warm air for supplying air toward the air supply passage; A third wall spaced apart from the inside of the first wall having the artillery chamber to form a combustion gas discharge passage for discharging high temperature combustion gas generated in the artillery chamber with the first wall; And a combustion gas ventilator for exhausting the combustion gas introduced into the combustion gas exhaust passage to the outside.

At this time, the door includes a door plate; A transparent window provided at the center of the door plate; An air inflow hole formed through the door plate; And an air flow chamber provided on a rear surface of the door plate in which the air chamber is formed, the air flow chamber covering the air inlet hole and having an air outlet hole in a direction in which the transparent window is installed.

In addition, a heat reflecting plate may be provided between the first wall and the furnace, and the heat reflecting plate may have a shape including a rear plate, a side plate, and an upper slope plate.

The pellet burner module includes a combustion air supply block installed to surround side surfaces and bottom surfaces of the furnace to supply combustion air, the side surface of the furnace being composed of a double wall for flowing the combustion air, A spray hole for spraying combustion air is formed in the upper portion of the inner wall of the double wall, and a grating plate into which the combustion air flows is preferably installed on a bottom surface of the furnace.

In addition, it is preferable that a plurality of the air heating pipes are arranged, and the plurality of air heating pipes are spaced apart from each other, and each air heating pipe is connected to the air supply passage through the first wall.

The first wall may be formed as a hollow shape with the front side opened and the third side wall provided with side walls on both sides of the firebox, And the combustion gas discharge passage is formed between the folding plate and the first wall, wherein the folding plate is a folding plate folded at a predetermined angle in the inward direction away from the side of the first wall.

In the present invention as described above, the combustion gas performs the primary heat exchange with the air heating tube, and then performs the secondary heat exchange with the air for warm air flowing toward the air heating tube in the discharging process. Thus, the energy efficiency of the pellet fuel is significantly improved through the secondary heat exchange.

In addition, the present invention separates the supply line of the cold outside air from the firebox while preventing the overheating of peripheral equipment by using a heat reflecting plate and an air curtain type door or the like. Therefore, by providing a high-temperature combustion environment, it is possible to completely burn the pellet fuel, while preventing fire and safety accidents due to the high temperature inside the firebox.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a partial structural view of a conventional pellet stove. FIG.
2 is a perspective view of a high efficiency pellet furnace according to the present invention.
3 is a side cross-sectional view of a high efficiency pellet furnace according to the present invention.
4 is a view showing an air curtain type door of a high efficiency pellet stove according to the present invention.
5 is a view showing a pellet burner module of a high efficiency pellet stove according to the present invention.
6 is a view illustrating a heat reflecting plate of a high efficiency pellet stove according to the present invention.
7 is a cutaway perspective view of a high efficiency pellet furnace according to the present invention.
8 is a conceptual view showing a secondary heat exchange structure of a high efficiency pellet stove according to the present invention.
9 is a perspective view showing a first wall and a third wall of the high-efficiency pellet stove according to the present invention.

Hereinafter, a high-efficiency pellet burner according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Referring to FIG. 2, a high-efficiency pellet stove according to the present invention will be described with reference to FIG. 2. FIG. 2 is a perspective view of a high efficiency pellet stove according to an embodiment of the present invention. A pellet burner module 140 is installed.

The pellet fuel is supplied to the pellet burner module 140 through the fuel drop port 153 and is supplied to the air heating pipe 160 through a heat source generated by igniting the pellet fuel The hot air for discharge is heated to supply hot air.

The heat generated by the firebox Fire_B is emitted to the room through the door 120 installed at the front part of the room. At this time, heat is radiated forward by the heat reflecting plate 131 installed on the rear side of the pellet burner module 140 To be released.

Accordingly, the present invention can provide a high-efficiency pellet furnace in which warm air is supplied to the room by burning using pellets as fuel, and at the same time, radiant heat is emitted to the front surface.

Particularly, the high-efficiency pellet stove of the present invention as described above is characterized in that the high-temperature combustion gas is subjected to the primary heat exchange with the air heating pipe 160, and then the hot air for low temperature, which is flowing toward the air heating pipe 160, Perform secondary heat exchange.

Accordingly, heat exchange is performed in the entire path where the high temperature combustion gas is discharged, thereby improving the energy efficiency.

In addition, the present invention separates the supply line (Air_S) of the cool outside air from the fire room (Fire_B) and simultaneously prevents the overheating of the peripheral equipment through the heat reflecting plate (131) and the air curtain type door (120).

Therefore, by providing a high-temperature combustion environment, it is possible to completely burn the pellet fuel, while preventing fire and safety accidents due to the temperature inside the fire room (Fire_B).

3, the present invention includes a stove body 110, a door 120, a first wall 130, a pellet burner module 140, a pellet feeder 150, an air heating pipe 160, A second wall 170, a warm air blower 171, a third wall 180, and a combustion gas fan 181.

A firebox B is formed in one side of the stove body 110 with respect to the first wall 130 and a pellet burner module 140 is installed in the firebox B Fire_B. Further, peripheral equipment such as a pellet feeder 150 and the like is installed outside the firebox (Fire_B).

Also, the space between the first wall 130 and the second wall 170 is used as an 'air supply passage (Air_S)' in which low-temperature outside air is supplied as air for hot air, and the first wall 130 and the third wall And a space between the first and second combustion chambers 180 is used as a combustion gas discharge passage (Gas_E) through which the combustion gas is discharged.

More specifically, the hearth body 110 is provided with a facility space therein, and a high strength material having excellent heat resistance is used to prevent the deformation due to heat at high temperatures and the risk of fire.

As shown in FIG. 2, the hearth body 110 has a housing shape, and an inlet 111a for replenishing pellet fuel is formed through the upper plate, and a control panel CP is installed at the rear end of the upper plate. do.

In addition, a warm air discharge hole through which hot air is discharged is formed in the upper part of the front surface, and a warm air diffusion grill 112 and the like, for example, are installed in the hot air discharge hole. The air heating pipe 160, which will be described later, blows warm air into the room as it is exposed to the room through the warm air diffusion grill 112.

Further, a door 120 is provided at the front center portion so as to be openable and closable by a hinge or the like. The door 120 is provided with a transparent window 122 at a central portion of the door plate 121 so that the inside of the hearth body 110 is checked and radiant heat is radiated into the room.

A support plate S is provided on the inner front side of the hearth body 110 and a furnace 141 of the pellet burner module 140 is provided on the support plate S. The hearth 141 is provided at its lower portion with a receptacle A_T detachably assembled.

The door 120 is installed in the stove body 110 so as to be openable and closable so as to clean or maintain the interior of the firebox B and to check the combustion state of the pellets fuel while looking into the firebox B do.

In particular, the door 120 of the present invention uses an 'air curtain type door 120' to prevent the interior of the door 120 from being overheated due to a high-temperature fire room B .

4, the air curtain type door 120 includes a door plate 121, a transparent window 122 provided at the center of the door plate 121, and an air inflow hole 122 formed through the door plate 121. [ And an air flow chamber 123 provided on a rear surface of the door plate 121 on which the fire chamber 121a and the fire chamber Fire_B are formed.

At this time, the air flow chamber 123 is configured to cover and close the air inflow hole 121a formed in the door plate 121, and an air flow space is formed therein, and in the direction in which the transparent window 122 is installed A plurality of air discharge holes 123a are formed.

Therefore, the air introduced through the air inlet hole 121a of the door plate 121 from the indoor side is discharged through the air outlet hole 123a of the air flow chamber 123, To form a curtain.

The first wall 130 is installed in the inside of the hearth body 110 and divides an internal space of the hearth body 110 to form a fire room Fire_B on one side with respect to the first wall body 130. Accordingly, the first wall 130 is separated into the firebox B and the remaining space with reference to the first wall 130.

In FIG. 3, a fire room Fire_B is formed on the front side of the first wall body 130, and a peripheral device such as a pellet feeder 150 is installed on the rear side in the opposite direction.

As shown in FIG. 7, the first wall 130 includes a plurality of assembly holes 130a corresponding to the number and arrangement of the air heating pipes 160, The rear end of the heating pipe 160 is fitted.

The pellet burner module 140 includes a furnace 141, a combustion air supply block 142, a blowing pipe 143, and an igniter Ig. The pellet burner module 140 is combusted by being supplied with pellet fuel and ignited.

The furnace 141 is installed in a support plate S fixed to the lower part of the fire room Fire_B and has a space for accommodating the pellet fuel therein. The hearth 141 is provided at its lower portion with a receptacle A_T detachably assembled.

The combustion air supply block 142 is connected to the furnace 141 and supplies the combustion air Fuel_Air to the furnace 141. The combustion air supply block 142 is installed to surround the side and the bottom of the furnace 141 to supply the combustion air Fuel_Air in various directions do.

A blowing pipe 143 is connected to one end of the combustion air supply block 142 to receive combustion air Fuel_Air from the outside and a blowing air supply fan (not shown) is installed in the blowing pipe 143.

An igniter may be used as the igniter Ig. For example, the igniter Ig may be installed through the combustion air supply block 142, and the end of the ignition flame may be exposed to the inside of the furnace 141 do.

5, the side surface of the furnace 141 is composed of a double wall 141a to flow the combustion air, and an upper side of the inner wall of the double wall 141a is provided with an ejection hole H Is formed.

On the bottom surface of the opened furnace 141 is provided a grating plate 141b in which the frames are arranged in a lattice pattern so that the pellet fuel is placed on the grating plate 141b and the combustion air rising from the bottom is allowed to pass.

According to this construction, the combustion air (Fuel_Air) supplied through the combustion air supply block 142 is supplied to the bottom surface side of the furnace 141 through the grid plate 141b. Therefore, the primary combustion air A1 is supplied to the pellet fuel accumulated in the furnace 141.

The air introduced into the double wall 141a of the furnace 141 is supplied to the upper portion of the furnace 141 through the spray hole H. [ Therefore, the secondary combustion air (A2) is supplied to the flame generated by burning the pellet fuel.

Therefore, while the primary and secondary combustion air (A1, A2) is supplied through one combustion air supply block 142 to complete combustion of the pellet fuel, the air supplied from the combustion air supply block 142 The surface of the furnace 141 is cooled to prevent the furnace 141 from being overheated.

The ash generated after the pellet fuel is completely burnt in the furnace 141 falls down through the grid plate 141b, and the dropped material is accommodated in the ash base A_T. When the ash tray A_T is filled with ash, the door 120 is opened and the ash tray A_T is taken out to enable cleaning.

The swash plate 141c provided at the upper end of the rear portion of the furnace 141 guides the pellet fuel dropped through the fuel drop port 153 of the pellet feeder 150 into the furnace 141, And the vertical plate 141d provided at the upper end of the flame guides the flame upward.

In the meantime, the present invention is characterized in that a heat reflecting plate 131 is provided between the first wall 130 and the furnace 141, and the heat reflecting plate 131 is damaged by the high temperature inside the fire room B ≪ / RTI >

In addition, the low temperature outside air flowing along the air supply passage Air_S is prevented from being transmitted to the fire room Fire_B, thereby providing a high-temperature combustion environment to the fire room Fire_B.

In other words, conventionally, as shown in FIG. 1, since the air chamber 16 is in contact with the fire chamber 11 to cool the fire chamber 11, a high temperature combustion environment can not be provided and the incomplete combustion is caused. .

2, the heat reflecting plate 131 is installed to surround the furnace 141, and a fuel drop port 153 is provided through the heat reflecting plate 131 to supply the pellet fuel to the furnace 141 Let's do it.

6 (a) and 6 (b), which are a front view and a side view, the heat reflecting plate 131 is provided on the rear plate , A side plate, and an upper swash plate.

However, the upper swash plate is adjusted so as to extend forward only by a predetermined length so that the end portion thereof does not completely block the upper portion of the fire chamber Fire_B, thereby forming the flow passage VH in which the combustion gas rises.

3, the pellet feeder 150 is installed at a rear portion of the first wall 130 isolated from the fire room Fire_B by supplying pellet fuel, and includes, for example, a hopper 151 and a feed screw device 152 And a fuel drop port 153. As shown in Fig.

The hopper 151 receives the pellet fuel and temporarily stores the pellet fuel. The pellet fuel is replenished through the inlet 111a formed at the upper end of the stove body 110.

The feed screw device 152 is connected to the lower portion of the hopper 151 and feeds the pellet fuel to the fuel drop port 153 when the screw is rotated by the electric motor installed at one end. The pellet feed rate is controlled by the rotation speed of the electric motor or the rotation time.

The fuel dropper 153 drops the pellet fuel delivered from the feed screw device 152 into the furnace 141 of the pellet burner module 140. The fuel dropper 153 is installed to be inclined downward to the furnace 141 and extends to the furnace 141 through the first wall 130 and the second wall 170.

The air heating pipe 160 serves as a heat exchange pipe for heat exchange (that is, primary heat exchange) between the low temperature outside air and the high temperature combustion gas generated in the fire room Fire_B. To this end, the air heating pipe 160 is installed in the combustion gas discharge path above the fire room Fire_B.

In addition, the air heating pipe 160 serves to supply hot air heated by the heat exchange to the room. To this end, the hot air outlet of the one open end is exposed to the outside of the stove body 110, Is connected to the air supply passage Air_S.

The plurality of air heating pipes 160 are spaced apart from each other and each air heating pipe 160 penetrates the first wall 130 and is connected to the air supply passages Air_S As shown in FIG.

The second wall 170 is spaced apart from the first wall 130 without the Fire_B to form an air supply passage Air_S between the first wall 130 and the first wall 130. The air supply passage Air_S is connected to the rear end of the air heating pipe 160 (that is, the outside air inflow side) to supply the outside air of low temperature to the air heating pipe 160.

7, as an example, the second wall 170 includes a box-shaped body having an open front, so that the first wall 130 and the second wall 130 are separated from the first wall 130, ).

The second wall 170 further includes a front cover 170a to completely seal the gap between the front end of the first wall 130 and the front end of the second wall 170. [ An assembly hole 170b is formed in the upper portion of the front cover 170a to receive the front end of the air heating pipe 160 and an opening 170c is formed in the center.

The hot air blower 171 supplies hot air to the air supply passage Air_S formed between the first wall body 130 and the second wall body 170. The air for hot air supplied through the hot air blower 171 normally becomes low-temperature outside air.

The warm air blower 171 is connected to the supply chamber 172 so that the outside air is supplied to the supply chamber 172 and then the air is supplied to the entire air supply passage Air_S connected to the supply chamber 172 .

The third wall 180 is spaced from the inside of the first wall 130 having the fire chamber Fire_B and is disposed between the first wall body 130 and the combustion chamber Fire_B, Gas discharge passage Gas_E '.

That is, the high-temperature combustion gas generated in the firebox (Fire_B) rises to the upper portion of the fire room (Fire_B), and the combustion gas raised in this way is introduced into the combustion gas discharge passage (Gas_E) and then discharged to the outside.

Accordingly, the present invention performs primary heat exchange with the low temperature outside air being supplied through the air heating tube 160 while the high temperature combustion gas rises.

Further, in the process of descending along the combustion gas discharge passage Gas_E, secondary heat exchange is performed with the low temperature outside air flowing along the air supply passage Air_S to preheat the low temperature outside air.

More precisely, in the course of descending along the air supply passage Air_S, the first wall 130 is used as a heat transfer medium to preheat the low temperature outside air rising along the air supply passage Air_S.

As described above, since the present invention performs the primary heat exchange and the secondary heat exchange, the heat exchange is performed in the entire path where the high temperature combustion gas is discharged. Therefore, the efficiency of the fuel is significantly doubled as compared with the prior art.

As shown in FIG. 7, the third wall 180 forming the combustion gas discharge passage Gas_E may be of various shapes. However, as illustrated in FIG. 7, the third wall 180 may be formed of the engaging plate 180a, the folding plate 180b, And a sphere 180c.

The coupling plate 180a and the folding plate 180b constitute the side separation plates 180a and 180b. Accordingly, side partition plates 180a and 180b are respectively installed on both sides of the first wall 130 having a box shape in which a fire chamber Fire_B is provided inside and a front portion is opened.

At this time, a part of the coupling plate 180a of the side separation plates 180a and 180b is in close contact with the side surface of the first wall 130. The other folding plate 180b is folded at a predetermined angle in the inward direction away from the side surface of the first wall body 130. [ Therefore, a space used as a combustion gas discharge passage (Gas_E) is provided between the folding plate 180b and the first wall body 130. [

The collecting port 180c is installed at a lower part between the side separating plates 180a and 180b spaced from both sides and includes a vertical plate and a horizontal plate connected to the upper end of the vertical plate, .

Therefore, the combustion gas is introduced through the opened both sides of the collection port 180c, and the introduced combustion gas is discharged through the exhaust hole formed at the bottom of the rear surface of the first wall 130. [ The exhaust hole of the first wall 130 is connected to the exhaust duct 182 and the exhaust duct 182 is connected to the combustion gas ventilator 181 to exhaust the combustion gas harmful to the human body to the outside.

Fig. 8 is a perspective view of the third wall 180 as described above. The side plates 180a and 180b of the third wall 180 are divided into a coupling plate 180a and a folding plate 180b with the folding line FL as a boundary and the folding plate 180b It is folded at a certain angle to the inside.

The upper and lower ends of the folding plate 180b are cut to a predetermined height so that the combustion gas flows into the outer surface from the inner wall of the third wall 180 through the upper cutout (Gas_E1). On the contrary, the combustion gas is discharged (Gas_E2) from the outer surface of the third wall 180 to the inside through the lower cutout portion.

9 (a) and 9 (b) are views showing a state in which the combustion gas generated in the fire chamber Fire_B rises and the air heating pipe 160 And a second heat exchange with a low-temperature outside air flowing along the air supply passage Air_S during the process of discharging while performing the first heat exchange.

9 (c) is a plan view of FIG. 9 (a). An air supply passage Air_S is formed between the first wall 130 and the second wall 170, and the first wall 130 And a combustion gas discharge passage Gas_E is formed between the first wall 180 and the folding plate 180b of the third wall 180. [

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

110: stove body
120: Door
130: first wall
140: Pellet burner module
150: Pellet feeder
160: air heating tube
170: second wall
171: blower for warm air
180: Third wall
181: Combustion gas blower
Air_S: Air supply passage
Gas_E: Combustion gas discharge passage
Fuel_Air: Air for combustion

Claims (6)

A stove body 110 having a facility space therein;
A door 120 installed on the stove body 110 so as to be openable and closable;
A first wall 130 installed in the inside of the hearth body 110 to divide the inside of the hearth body 110 and form a fire room B on one side;
A pellet burner module 140 installed in the fire room Fire_B and having a furnace 141 for supplying pellets fuel and burning the pellets;
A pellet feeder 150 installed outside the fire room Fire_B to supply the pellet fuel to the furnace 141;
The hot air discharge port at one open end is exposed to the outside of the stove body 110 and the air inlet at the other open end is connected to an air heating pipe 160 connected to the air supply passage Air_S )and;
A second wall 170 spaced apart from the first wall 130 without the fire chamber Fire_B and forming the air supply passage Air_S between the first wall 130 and the first wall 130;
A blower 171 for warm air for supplying air toward the air supply passage Air_S;
A combustion gas discharge passage (not shown) which is installed on the inner side of the first wall 130 having the fire room Fire_B and discharges high temperature combustion gas generated in the fire room Fire_B between the first wall body 130 and the first wall body 130 A third wall 180 forming a gas E; And
And a combustion gas fan (181) for discharging the combustion gas introduced into the combustion gas discharge passage (Gas_E) to the outside,
The first wall 130 is formed in a box shape in which the fire room Fire_B is provided and the front part is opened,
The third walls 180 are side separation plates 180a and 180b provided on both sides of the fire room Fire_B and a part of the side separation plates 180a and 180b is formed on the side wall of the first wall 130 And the combustion gas discharge passage (Gas_E) is formed between the folding plate (180b) and the first wall (130). The method according to claim 1,
The door (120)
A door plate 121;
A transparent window 122 installed at the center of the door plate 121;
An air inflow hole 121a formed through the door plate 121; And
The airflow chamber 123 is provided on the rear surface of the door plate 121 on which the fire chamber B is formed and has an air vent hole 123a formed in the direction in which the transparent window 122 is installed, Is an 'air curtain-type door (120)' including a door (123). The method according to claim 1,
Wherein a heat reflecting plate 131 is provided between the first wall 130 and the furnace 141 and the heat reflecting plate 131 has a shape including a rear plate, a side plate, and an upper slope plate. . The method according to claim 1,
The pellet burner module 140 includes a combustion air supply block 142 installed to surround side surfaces and bottom surfaces of the furnace 141 to supply combustion air,
The side surface of the furnace 141 is formed with a double wall 141a for flowing the combustion air and an ejection hole H through which air for combustion is ejected is formed on the inner side wall of the double wall 141a, And a grid plate (141b) through which the combustion air flows is provided on the bottom surface of the furnace (141). The method according to claim 1,
The plurality of air heating pipes 160 are spaced apart from each other and each air heating pipe 160 penetrates the first wall 130 and is connected to the air supply passage Air_S) is connected to the high-efficiency pellet stove. delete

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