KR101263770B1 - ash discharge apparatus for solid fuel boiler - Google Patents

Abstract

The present invention relates to a ash discharging apparatus for a solid fuel boiler, the ash discharging apparatus for discharging ash into a combustion apparatus of a boiler in which solid fuel is used, which is disposed inside the combustion apparatus, and one side of the ash discharging apparatus is closed. It is formed in the hollow shaft shape so that the other side has an open cooling space, the screw portion is installed so that ash is discharged to the outside of the combustion apparatus by rotation, the screw portion is inserted into the cooling space from the other open side of the screw portion, It is formed in a hollow shaft shape so that one side is open and the other side has a closed supply space, the cooling supply portion formed with a through hole to communicate with the supply space on the other side, the other end of the screw portion so that one end is rotated together with the screw portion The cooling water supply is inserted into the cooling supply part and rotated together to supply and A cooling rotary part installed to cover the outer side of the cooling rotary part and having a supporting space to be rotatably supported in the state in which the cooling rotary part is inserted, and a cooling supporting part installed to supply and discharge the cooling water, and the It is fastened to the other side of the cooling rotation portion, and includes a drive unit for providing power for rotating the cooling rotation portion.

Description

Ash discharge apparatus for solid fuel boiler

The present invention relates to a combustion apparatus for a solid fuel boiler.

A boiler is a device that generates steam by burning fuel and transferring the heat of combustion to water. BACKGROUND ART It is widely used to supply steam at high temperature and high pressure to steam turbines used as power devices for thermal power generation and ships, for work in various factories, or to supply steam for general heating. The main part of the boiler consists of a steel vessel (boiler body) containing water and steam, a combustion device and a furnace.

As the fuel burned in the above-described boiler, coal, which is fossil fuel, petroleum, which is liquid, and city gas, which is a gas, are used. However, coal and petroleum reserves are limited, so the price is expected to increase due to continuous use, and the end resource is exhausted and cannot be used. In addition, in the case of city gas, it is difficult to transport and store it as a gas, and in order to supply facilities such as piping in order to supply each home or place of use, a lot of cost is required, and there is always a risk of explosion.

Thus, low cost boilers such as rice husks, whole rice, lumber, and wood chips are being developed. The amount of solid fuel is lower than that of coal, petroleum, and the like, and it is difficult to burn, resulting in a problem in that much energy is consumed by combustion. Recently, wood pellets (wood pellets) having high heat generation by compressing wood have been developed and used. Wood pellets are used by compression processing after crushing the waste wood in the form of sawdust, and generates a higher calorific value than the ordinary wood and burns up to 95%, leaving little debris. Carbon emissions are only one-twelfth the level of diesel, making them an environmentally friendly fuel.

As such, the solid fuel can reduce the generation of ash (sludge) while increasing the calorific value, the boiler for this is continuously developed. However, the solid fuel can reduce the generation of ash during combustion, but inevitably, as ash is generated, a device for discharging ash should be installed inside the boiler.

Such a re-discharge device of the prior art is installed in the form of a screw into the combustion device in which the solid fuel is supplied to the boiler and burned. The screw described above is installed inside the space to be burned to discharge the ash generated by the combustion of the solid fuel to the outside, and is installed to be discharged to the outside by rotation.

However, the re-discharge apparatus of the prior art is installed at a position where heat is generated by combustion of solid fuel inside the combustion apparatus, and is exposed so that the high heat of combustion is transmitted to the screw as it is. Therefore, as the screw is rotated by the high heat to be burned easily heat deformation occurs, the discharge efficiency of the ash is lowered, and accordingly the replacement speed is faster, there is a problem that the cost used for maintenance increases.

In addition, the ash discharge device of the prior art has a heat flow generated by the combustion of the solid fuel in the combustion device continuously transmitted to the screw, if the failure occurs as the combustion proceeds in the state where the discharge of ash is stopped, backflow and incomplete combustion After the combustion device is stopped for replacement, the operator waits for the time for the temperature to drop to a temperature at which replacement is possible, and then removes the broken screw, and as the reinstallation proceeds, it takes a lot of time. There was a problem that caused the loss.

The problem to be solved by the present invention is a water-cooled structure is installed inside the screw to remove the ash generated in the combustion device of the boiler using a solid fuel, minimizing the thermal deformation of the screw to prevent breakage, re-emission An object of the present invention is to provide a ash discharging device for improving solid efficiency.

The problem to be solved by the present invention is not limited to those mentioned above, the problem to be solved of another content not mentioned will be clearly understood by those skilled in the art from the following description.

A ash discharging apparatus for a solid fuel boiler according to an embodiment of the present invention is a ash discharging apparatus for discharging ash into a combustion apparatus of a boiler in which solid fuel is used, the ash discharging apparatus being disposed inside the combustion apparatus, and one side of the ash discharging apparatus. Is formed in a hollow shaft shape so as to have a closed cooling space and the other side is open, the screw portion is installed so that ash is discharged to the outside of the combustion apparatus by rotation, the screw portion is inserted into the cooling space from the other open side of the screw portion It is formed in a hollow shaft shape so that one side is open and the other side has a closed supply space, the cooling supply portion formed with a through hole to communicate with the supply space on the other side, the screw so that one end is rotated with the screw portion Fastened to the other side of the part, and the cooling water supply part is inserted into the inside and rotated together to supply the cooling water A cooling rotary part installed to be discharged, a cooling support part surrounding an outer side of the cooling rotary part, having a supporting space to be rotatably supported with the cooling rotary part inserted therein, and installed to supply and discharge the cooling water, and It is fastened to the other side of the cooling rotating part, and includes a driving unit for providing power to rotate the cooling rotating part, the cooling water is supplied to the cooling rotating part from the cooling support to the open side of the supply space through the supply hole It is supplied to the cooling space that is inside the screw portion, and after cooling the screw portion while moving to the other side to the cooling space may be discharged through the cooling rotating portion and the cooling support portion to cool the screw portion.

In addition, the screw portion is disposed inside the combustion device, the screw blade protruding around the outer periphery in the form of a spiral so that ash is discharged by the rotation, and is disposed in the center of the screw blade, the other end of the cooling rotating portion It has a screw fastening portion is fastened to, and is formed in the hollow shaft shape to form the cooling space therein, and may include a screw shaft for rotating the screw blade by the operation of the drive unit, the screw shaft is the drive unit By rotating the screw blade while being rotated by the operation of the ash is discharged to the outside along the spiral, while rotating with the cooling rotary part is supplied to the cooling space through the cooling rotary part and the cooling supply to the cooling space, and cooled and cooled, After cooling, the cooling supply unit and the cooling rotating unit May be discharged.

The cooling rotation unit may include a rotation coupling unit formed to be coupled to the screw coupling unit at one end thereof, and an operation coupling unit configured to be coupled to the driving unit at the other end thereof. The cooling rotation unit may include the screw unit and the It may be fastened by a rotation fastening part, and may be fastened by the driving part and the operation fastening part to rotate the screw part by the operation of the driving part.

In addition, the drive unit is disposed on the other side of the cooling rotation unit, the drive motor for providing power to rotate the cooling rotation unit coupled with the screw portion, and is disposed on one side of the drive motor, the one end is the cooling It may include a drive shaft which is coupled to the operating fastening portion of the rotation unit, the drive shaft is installed to rotate by the operation of the drive motor, the drive shaft is rotated by the operation of the drive motor is fastened to the drive fastening portion The cooling rotating part and the screw part can be rotated.

In addition, a supply fastening part may be formed at one side of the air supply hole to the other side of the cooling supply part to be fastened with the cooling rotation part inserted therein, and the cooling supply part may be inserted into one side of the cooling rotation part while the cooling supply part is inserted. An insertion discharge space having a larger size than the cooling supply part may be formed in communication with the cooling space so that a flow path through which the cooling water supplied from the supply part is discharged may be formed, and the other side of the inner surface of the insertion discharge space may be formed inside the cooling rotation part. An insertion discharge hole penetrated to be in communication with the support space toward the side may be formed, and on the other side of the inside of the cooling rotation part, one side may be in communication with the insertion discharge space and the other side may be closed so that the other end of the cooling rotation part is inserted into the inside. Insert fastening portion is formed to one side to be fastened to the supply fastening portion on the surface As the insertion supply space can be formed, the inner side of the cooling rotation part can be formed through the insertion supply hole to be communicated with the support space at a position in communication with the supply hole in the inner surface of the insertion supply space, The cooling water is supplied into the supply hole through the insertion supply space through the cooling rotating part and the support space, and is supplied to the screw part through the supply space, and the insert discharge is communicated with the cooling space after cooling in the screw part. The space may be discharged to the support space of the cooling rotating part through the insertion discharge hole.

In addition, the cooling support portion is disposed on the other side of the screw portion, the support space in which the cooling rotation is inserted is formed therein, the support discharge is penetrated at a position in communication with the insertion discharge hole to one side of the support space A support body having a ball and having a support supply hole penetrating at a position in communication with the insertion supply hole to the other side of the support space, respectively disposed on both sides of the support body, and inserted into the cooling rotation part to rotate; The cooling rotating part is disposed to be supported on the bearing, one side of the support body, the discharge pipe is inserted into the support discharge hole is installed to discharge the cooling water to the outside, and is disposed on the other side of the support body Is inserted into the support supply hole so that the cooling water is supplied It may include a supply pipe that is installed, the support body can support the rotation by inserting the cooling rotary parts inserted into the inside of the support body to the bearings respectively installed on both sides, the cooling water is the support supply It may be supplied to the cooling rotating part through the insertion supply hole through the supply pipe inserted into the ball, and may be discharged to the outside through the discharge pipe inserted into the support discharge hole through the insertion discharge hole at the time of discharge.

And a discharge blocking ring disposed inside the support body, the discharge blocking ring being disposed to contact the outer surface of the cooling rotation part inserted and positioned at both sides of the support discharge hole, respectively, on the inner surface of the support space. It is disposed on the inner side of the body, and both sides of the support supply hole may be further provided with a supply blocking ring which is installed to contact the outer surface of the cooling rotating portion inserted into each of the inner surface of the support space, The discharge blocking ring may be sealed to be discharged to the discharge pipe while preventing the coolant discharged to the insertion discharge hole from leaking between the cooling rotating part to be inserted and the support space, and the supply blocking ring may be inserted into the cooling rotating part to be inserted. Supply to the insertion supply hole through the supply pipe between the support space It may be closed to block the cooling water from being leaked.

Specific details of other embodiments are included in the detailed description and the drawings.

According to an embodiment of the present invention, a device in which cooling water is supplied and cooled in a screw-type ash discharging device installed inside the combustion apparatus for supplying and burning solid fuel to discharge ash generated during combustion of the solid fuel to the outside. By discharging the ash to the outside while cooling, thereby preventing the ash discharging device from being deformed by the heat generated by the combustion, and suppressing the reduction of the ash discharge efficiency due to the heat deformation, and the replacement cycle by the heat deformation. The longer the cost, the lower the cost of maintenance.

In addition, it has a structure in which cooling water is supplied to the inside of the screw for discharging ash, so that the heat of combustion can be continuously transmitted to the screw and prevented from being broken, so that it can withstand high temperature of heat of combustion, thereby being used in a combustion device that generates high heat. This increases the versatility and minimizes the loss of work due to replacement, thus improving the combustion efficiency.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the description of the claims.

1 is an installation state diagram showing a state in which the ash discharge device for a solid fuel boiler according to an embodiment of the present invention is installed in a combustion device.
FIG. 2 is an exploded perspective view showing the ash discharging device for the solid fuel boiler of FIG. 1. FIG.
3 is an exploded partial front view of the ash discharging apparatus for the solid fuel boiler of FIG. 1;
4 is a partial cross-sectional front view showing the ash discharging device for the solid fuel boiler of FIG.
FIG. 5 is a partial cutaway cross-sectional view showing a major part of the ash discharging device for the solid fuel boiler of FIG. 1. FIG.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Like parts are designated with like reference numerals throughout the specification.

Then, the configuration of the ash discharge apparatus for a solid fuel boiler according to an embodiment of the present invention will be described with reference to FIGS. 1 to 5.

1 is an installation state diagram showing a state in which the ash discharging device for a solid fuel boiler according to an embodiment of the present invention is installed in a combustion device, Figure 2 is an exploded perspective view showing the ash discharging device for a solid fuel boiler of FIG. 3 is a partial cross-sectional exploded front view of the ash discharging device for the solid fuel boiler of FIG. 1, FIG. 4 is a partial cross-sectional front view showing the ash discharging device for the solid fuel boiler of FIG. 1, and FIG. 5 is a solid fuel boiler of FIG. 1. A partial cutaway cross-sectional view showing the main part of the solvent discharge device.

1 to 5, the ash discharging device 100 for a solid fuel boiler according to an embodiment of the present invention is installed in one side of the combustion device 10 in which the solid fuel is supplied and combusted in operation By means of discharging ash generated during combustion.

Such, the ash discharging device 100 includes a screw unit 110, the cooling supply unit 120, the cooling rotation unit 130, and the drive unit 150 for discharging the ash by rotation. The screw unit 110 includes a screw blade 111 for discharging ash by rotation inside the combustion device 10, and a screw shaft 112.

The screw blade 111 is disposed inside the combustion device 10 and protrudes around the outer portion of the screw shaft 112 in a spiral form so that ash is discharged by rotation.

The screw shaft 112 is disposed in the center of the screw blade 111, and is provided in the form of a hollow shaft so as to have a cooling space 113 with one side closed inside and the other open. The screw shaft 112 has a screw fastening portion 114 fastened to the cooling rotation part 130 at the other end so as to be rotated by the operation of the driving part 150, and in the form of a hollow shaft to form a cooling space therein. It is provided so that the screw blade 111 may rotate.

Here, the screw shaft 112 is rotated by the operation of the driving unit 150 to rotate the screw blade 111, the ash is discharged to the outside along the spiral, and rotates together with the cooling rotary unit 130 and the cooling rotary unit 130 and Cooling water is supplied to the cooling space 113 through the cooling supply unit 120 to be cooled, and after cooling, the cooling water is again discharged to the cooling supply unit 120 and the cooling rotating unit 130.

The cooling supply unit 120 is inserted inward from the other side of the screw shaft 112, has a supply space 121 is inserted into the cooling space inward, one side is opened inward, the other side is closed, the other side supply space It is provided in the form of a shaft having a feed hole 122 penetrated so as to communicate with (121). The other end of the cooling supply unit 120 is provided with a supply fastening unit 123 which is fastened in a state where the cooling rotating unit 130 is inserted into one side of the air supply hole 122. The cooling supply unit 120 is inserted into the screw shaft 112 in the state in which the cooling supply unit 123 is fastened to the cooling rotation unit 130, and the cooling water supplied to the supply hole 122 passes through the supply space 121. It is installed to be supplied to the cooling space 113 communicated to the open one side.

Cooling rotation part 130 is disposed on the other side of the screw shaft 112, one end is fastened so as to rotate with the screw shaft 112, and the cooling water supply 120 is inserted into the inner rotation and the cooling water is rotated together It is installed to supply and discharge.

In addition, the cooling supply unit 120 is inserted into one side of the cooling rotation unit 130 and communicates with the cooling space 113 to form a flow path through which the cooling water supplied from the cooling supply unit 120 is discharged. A large insertion discharge space 131 is formed. An insertion discharge hole 132 penetrated to the other side of the inner surface of the insertion discharge space 131 is formed to communicate with the cooling support 140.

Then, the other side of the inside of the cooling rotary unit 130 is connected to the insertion discharge space 131 and the other side is closed to the supply fastening portion 123 to the inner side in the state where the other end of the cooling rotary unit 130 is inserted An insertion supply space 121 in which an insert fastening portion 135 is formed at one side is formed to be fastened. An insertion supply hole 122 penetrated to communicate with the cooling support 140 is formed at a position in communication with the supply hole 122 at an inner surface of the insertion supply space 121.

That is, the coolant is supplied to the supply hole 122 through the cooling rotation part 130 and the cooling support part 140 through the insertion supply space 121, and is supplied to the screw part 110 through the supply space 121. After cooling in the unit 110, it may be discharged to the cooling support 140 of the cooling rotating part 130 through the insertion discharge hole 132 through the insertion discharge space 131 communicated with the cooling space 113.

In addition, one end of the cooling rotation unit 130 is formed with a rotational fastening unit 136 to be coupled to the screw fastening unit 114 of the screw unit 110, the other end of the cooling rotation unit 130 is fastened with the driving unit 150 As the actuation fastening part 137 is formed to be, the cooling rotating part 130 is fastened by the screw part 110 and the rotation fastening part 136, and is fastened by the driving part 150 and the actuation fastening part 137. The screw unit 110 may be rotated by the operation of the driving unit 150.

The cooling support 140 includes a support body 141 on which the cooling rotation part 130 is rotatably supported, a bearing 143, a discharge pipe 145, a discharge blocking ring 146, a supply pipe 148, and a supply blocking ring. (149). The support body 141 is disposed on the other side of the screw unit 110, and a support space 142 into which the cooling rotation part 130 is inserted is formed therein, and an insertion discharge hole 132 is inserted into one side of the support space 142. ) Has a support discharge hole 144 penetrating at a position communicating with the support supply hole, and a support supply hole 122 penetrating at a position communicating with the insertion supply hole to the other side of the support space 142.

The bearings 143 are disposed on both sides of the support body 141, respectively, and are inserted inwardly so that the cooling rotation part 130 is rotated so that the cooling rotation part 130 is rotated. That is, the support body 141 may support the rotating rotation by inserting the cooling rotary part 130 inserted into the support body 141 into the bearings 143 disposed on both sides.

Discharge pipe 145 is disposed on one side of the support body 141, is inserted into the support discharge hole 144 is installed to discharge the coolant to the outside.

Discharge blocking ring 146 is disposed on the inner side of the support body 141, the outer surface of the cooling rotating part 130 is inserted into the inner side of the support space 142 on both sides of the support discharge hole 144, respectively Installed in contact with That is, the discharge blocking ring 146 may be sealed to be discharged to the discharge pipe 145 while blocking the cooling water discharged into the insertion discharge hole 132 between the cooling rotary part 130 and the support space 142 is inserted. have.

The supply pipe 148 is disposed on the other side of the support body 141 and is inserted into the support supply hole 122 so as to supply the cooling water. That is, the cooling water is supplied to the cooling rotating part 130 through the insertion supply hole 122 through the supply pipe 148 inserted into the support supply hole 122, and discharges the support through the insertion discharge hole 132 at the time of discharge. It may be discharged to the outside via the discharge pipe 145 is inserted into the ball (144).

The supply shutoff ring 149 is disposed inside the support body 141 and is positioned at both sides of the support supply hole 122 on the inner side of the support space 142, respectively. Installed in contact with That is, the supply blocking ring 149 may seal the cooling water supplied to the insertion supply hole 122 through the supply pipe 148 between the cooling rotation unit 130 and the support space 142 to be inserted to block the leakage of the cooling water. .

The driving unit 150 includes a driving motor 151 and a driving shaft 152 that are coupled to the cooling rotation unit 130 to provide power to be rotated. The driving motor 151 is disposed on the other side of the cooling rotation unit 130 and provides power for rotating the cooling rotation unit 130 coupled to the screw unit 110.

The drive shaft 152 is disposed on one side of the drive motor 151, and has a drive coupling part 153 that is engaged with the operation coupling part 137 of the cooling rotation part 130 at one end thereof, and operates the driving motor 151. It is installed to rotate. That is, the driving shaft 152 may rotate by the operation of the driving motor 151 to rotate the cooling rotating part 130 and the screw unit 110 fastened by the driving fastening part 153.

As described above, the coolant is supplied from the cooling support part 140 to the cooling rotating part 130 and is cooled to the inside of the screw part 110 toward the open side of the supply space 121 through the supply hole 122. ) And cooled to the cooling space 113 while moving to the other side to cool the screw unit 110 and then discharged through the cooling rotating unit 130 and the cooling support unit 140 to cool the screw unit 110.

Although the preferred embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

100: ash discharge device 110: screw portion
111: screw blade 112: screw shaft
113: cooling space 114: screw fastening portion
120: cooling supply 121: supply space
122: supply hole 123: supply fastening portion
130: cooling rotation part 131: insertion discharge space
132: insertion outlet hole 133: insertion supply space
134: insertion hole 135: insertion fastening portion
136: rotation fastening portion 137: operation fastening portion
140: cooling support 141: support body
142: support space 143: bearing
144: support discharge hole 145: discharge pipe
146: discharge blocking ring 147: support supply hole
148: supply pipe 149: supply blocking ring
150: driving unit 151: driving motor
152: drive shaft 153: drive fastening portion

Claims (7)

In the ash discharging device for discharging ash into the combustion device of the boiler in which solid fuel is used,
Is disposed inside the combustion device, is formed in the hollow shaft shape so as to have a cooling space in which one side is closed and the other side in the inside, the screw unit is installed so that ash is discharged to the outside of the combustion device by rotation,
Cooling is formed in the hollow shaft shape is inserted into the cooling space from the other open side of the screw portion, the one side is open and the other side has a closed supply space, the feed hole penetrated to communicate with the supply space on the other side Supply Line,
One end is fastened to the other side of the screw portion to be rotated together with the screw portion, the cooling rotating portion is installed so that the cooling water is supplied and discharged while the cooling supply is inserted and fastened inward rotation,
A cooling support part surrounding an outer side of the cooling rotating part, having a supporting space to be rotatably supported in an inserted state of the cooling rotating part, and installed to supply and discharge the cooling water, and
A driving part coupled to the other side of the cooling rotation part and providing power to rotate the cooling rotation part;
Including;
The cooling water is supplied from the cooling support part to the cooling rotating part and supplied to the cooling space inside the screw part through the supply hole to the open side of the supply space, and cools the screw part while moving to the other side in the cooling space. After being discharged through the cooling rotating part and the cooling support part to cool the screw part.
Ash drainage for solid fuel boilers. The method of claim 1,
The screw unit,
A screw blade disposed inside the combustion device and protruding around the outside in a spiral form so that ash is discharged by rotation;
It is disposed in the center of the screw blade, has a screw fastening portion which is fastened to the cooling rotary part at the other end, is formed in a hollow shaft form to form the cooling space therein, the screw blade is rotated by the operation of the drive unit Screw shaft
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The screw shaft is rotated by the operation of the drive unit to rotate the screw blade is discharged to the outside along the spiral, and rotates together with the cooling rotary unit while supplying the cooling water to the cooling space through the cooling rotary unit and the cooling supply unit. Cooled and cooled, and after cooling can be discharged to the cooling supply and the cooling rotating unit
Ash drainage for solid fuel boilers. The method of claim 2,
The cooling rotating unit,
Rotating fastening portion formed to be coupled to the screw fastening portion of the screw portion at one end, And
Operation fastening portion formed to be engaged with the drive portion at the other end
Including;
The cooling rotating part is fastened by the screw part and the rotational fastening part, and fastened by the driving part and the operating fastening part to rotate the screw part by the operation of the driving part.
Ash drainage for solid fuel boilers. The method of claim 3,
The driving unit includes:
A drive motor disposed on the other side of the cooling rotation part and providing power to rotate the cooling rotation part fastened to the screw part;
A drive shaft disposed on one side of the drive motor, the drive shaft having one end coupled to the actuation fastening portion of the cooling rotation part, the drive shaft being installed to rotate by operation of the drive motor;
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The drive shaft is rotated by the operation of the drive motor can rotate the cooling rotary part and the screw portion fastened to the drive fastening portion
Ash drainage for solid fuel boilers. The method of claim 1,
On one side of the supply hole to the other side of the cooling supply portion is formed a supply fastening portion for fastening in the state in which the cooling rotation is inserted,
An insertion discharge space having a larger size than the cooling supply part is formed at one side of the cooling rotation part so as to communicate with the cooling space so that a flow path through which the cooling water supplied from the cooling supply part is discharged is formed while the cooling supply part is inserted.
An insertion discharge hole is formed inside the cooling rotating part so as to communicate with the support space toward the other side of the inner surface of the insertion discharge space.
The other side of the inside of the cooling rotating part is connected to the insertion discharge space and the other side is closed is inserted into the insertion fastening portion formed on one side to be fastened by the supply fastening part on the inner side with the other end is inserted Supply space is formed,
As the inside of the cooling rotating part is formed through the insertion supply hole penetrated so as to communicate with the support space at a position in communication with the supply hole on the inner surface of the insertion supply space,
The cooling water is supplied into the supply hole through the insertion supply space through the cooling rotating part and the support space, and is supplied to the screw part through the supply space, and the insert discharge is communicated with the cooling space after cooling in the screw part. It may be discharged to the support space of the cooling rotary part through the insertion discharge hole through the space
Ash drainage for solid fuel boilers. The method of claim 5,
The cooling support,
The support space is disposed on the other side of the screw portion, and the support space into which the cooling rotation part is inserted is formed, and has a support discharge hole penetrating at a position communicating with the insertion discharge hole to one side of the support space, A support body having a support supply hole penetrated at a position in communication with the insertion supply hole to the other side of the
Bearings disposed on both sides of the support body and inserted into the cooling rotor to be rotated to support the cooling rotor to rotate;
Is disposed on one side of the support body, the discharge pipe is inserted into the support discharge hole is installed to discharge the cooling water to the outside, and
A supply pipe disposed on the other side of the support body and inserted into the support supply hole and installed to supply the cooling water;
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The support body may support the rotation by inserting and installing the cooling rotary parts inserted into the support body in the bearings respectively installed on both sides,
The cooling water is supplied to the cooling rotating part through the insertion supply hole through the supply pipe inserted into the support supply hole, and externally through the discharge pipe inserted into the support discharge hole through the insertion discharge hole at the time of discharge. Can be discharged into
Ash drainage for solid fuel boilers. The method according to claim 6,
Discharge blocking rings are disposed in the support body, the discharge blocking ring is installed to contact the outer surface of the cooling rotating portion inserted into each side of the support space on both sides of the support discharge hole, and inserted;
The supply blocking ring is disposed inside the support body and is installed to contact the outer surface of the cooling rotation part which is positioned on both sides of the support supply hole and respectively positioned on the inner surface of the support space.
Respectively,
The discharge blocking ring may be sealed to be discharged to the discharge pipe while blocking the leakage of the cooling water discharged to the insertion discharge hole between the cooling rotary part is inserted and the support space,
The supply blocking ring may seal the cooling water supplied to the insertion supply hole through the supply pipe between the cooling rotation part to be inserted and the support space to prevent leakage of the cooling water.
Ash drainage for solid fuel boilers.

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