KR20190046434A - Ash emission device generated in a fluid bed combustion device and method of ash emission using the same - Google Patents

Abstract

The present invention relates to an apparatus for emitting ash generated by a fluidized bed combustion apparatus and a method for emitting ash using the same. According to the present invention, the apparatus for emitting ash generated by the fluidized bed combustion apparatus comprises: a screw case which serves as a passage through which ash is transferred; one or more ash inlets installed on an upper end of the screw case, into which ash is introduced; a transfer screw installed inside the screw case to transfer the introduced ash towards one side; an ash outlet which emits the ash transferred by the transfer screw; and one or more reverse slip prevention pads installed on an upper end inside the screw case to prevent the ash transferred towards the one side from reversely slipping. The screw case includes: a lower surface formed in an arc shape, and an upper surface formed horizontally to have a ′U′-shaped cross-section. In the screw case, the ash outlet side is more highly inclined that the ash inlet side. According to the present invention, the apparatus for emitting ash is able to block a flow of gas emitted together with solid (ash) essential accompanied, to prevent a reverse slip of the solid (ash) by using the reverse slip prevention pads, to prevent the solid (ash) from reversely flowing into the fluidized bed, and to allow a user to check if the ash is being smoothly transferred or not in real time through a transparent checking hole installed on the apparatus. In addition, the transfer screw of the apparatus for emitting ash includes: a shaft; and a plurality of blades detachably installed on an external surface of the shaft, so when the blades are damaged by abrasion or the like, the transfer screw can be partially replaced, thereby increasing work efficiency.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a flue gas discharge apparatus and a flue gas discharge method using the flue gas flue gas combustion apparatus,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a rotary discharge device generated in a fluidized bed combustion device and a rotary discharge method using the rotary discharge device.

A boiler is a device that burns fuel and transfers its heat to water to generate steam. It is widely used for supplying steam of high temperature and high pressure to a steam turbine which is used as a power device for thermal power generation, ships and the like, for working of various factories, and for supplying steam to general heating. The main part of the boiler consists of a steel container (boiler body) containing water and steam, a combustion device and a furnace for the fuel.

As the fuel burned in the above-mentioned boiler, coal such as a fossil fuel, petroleum as a liquid, and city gas as a gas are used. However, since coal and oil have limited reserves, they are expected to rise in price due to continuous use, and the resource is exhausted and can not be used. In addition, in the case of city gas, it is difficult to transport and store gas because it is a gas, and in order to supply it to each home or use place, facilities such as piping are required, so that a lot of cost is required and there is always a risk of explosion.

Accordingly, boilers using an inexpensive and combustible solid fuel such as rice hull, rice flour, scrap wood, and wood chips are being developed. The solid fuel has a problem in that the amount of heat is lower than that of coal and oil, and it is difficult to burn the solid fuel, so that a lot of energy is required for combustion. In recent years, a wood pellet having a high calorific value by compressing wood has been developed and used. Wood pellets are used by pulverizing waste wood, etc., in sawdust form, and then compressing the wood, which has a higher calorific value than normal wood and a burning rate of 95%, leaving little residue. Carbon emissions are only one-twelfth of the level of general diesel, which is becoming an eco-friendly fuel.

In this way, solid fuels are continuously being developed to reduce the occurrence of condensation while increasing the calorific value. However, solid fuels can reduce the occurrence of condensation at the time of combustion, but inevitably, as the reaction occurs, the boiler must have a device for discharging the flue.

The rotary discharge device is usually installed in the form of a screw in a lower part of a fluidized bed combustion device in which a solid fuel is supplied to a boiler and burned. The screw is installed at a lower portion of a space to be burned for discharging the sludge generated by the combustion of the solid fuel to the outside, and is installed to be discharged to the outside by rotation. In order to reduce the friction between the case and the foreign matter (metal, inorganic material, etc.) contained in the rotary shaft and the rotary shaft to reduce the power, the rotary shaft discharging device is made of a U- Or more) in order to cool down the cooling water. In addition, since the flow gas is mixed and discharged during the pouring process, it is installed to have a bottom surface and a slope (10 to 45 degrees) in order to prevent the fire and to transfer the discharged pour to the next process .

Therefore, in the conventional fluidized bed pumping device, the gas, which is essentially involved in the flow material and the pumping process, may be supplied to the pumping device together with the punch and then may be discharged to the outside. However, if an inclined screw is installed to seal the flow of the gas using the transferring solid (ash or transferring material), a reverse flow occurs in a direction opposite to the direction in which the screw pushes the solid, There was a backflow problem.

Accordingly, the inventors of the present invention discovered that the backward slip prevention can be prevented by installing the back slip prevention pad in the slip discharge device while studying to overcome the above-mentioned problem, thus completing the present invention.

In this connection, Korean Utility Model Registration No. 20-0153459 discloses a cooling device for a screw conveyor for re-transfer.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a rotary discharge device which is generated in a fluidized bed combustion device and a rotary discharge method using the rotary discharge device.

In order to achieve the above object,

A screw case 120 serving as a passage through which the rotor is transferred;

At least one rotary inlet (110) installed at an upper end of the screw case (120) and introducing the rotary inlet;

A transfer screw 130 installed in the screw case 120 to transfer the incoming sludge to one side;

A return port 140 for discharging the wafer transferred by the transfer screw 130; And

At least one reverse slip prevention pad (160) installed at an upper end of the screw case (120) to prevent reverse slip of the slide conveyed to the one side;

Lt; / RTI >

The screw case 120 has a lower surface formed in an arcuate shape, an upper surface formed in a horizontal shape and having a " U "

The screw case 120 is installed such that the side of the rotation output port 140 is inclined higher than the side of the rotation inlet 110

Thereby providing a rotary discharge device generated in the fluidized bed combustion device.

In addition,

The present invention also provides a method of discharging a fluid using a fluid discharge device generated in the fluidized bed combustion device.

The use of the pouring device according to the present invention can prevent the flow of the gas discharged together with the solid (sludge) which is essentially involved and prevent the reverse flow of the solid (sludge) by using the reverse slip prevention pad, Can be prevented from flowing back to the fluidized bed again, and it is possible to confirm in real time whether or not the fluid is smoothly transferred through the transparent check port provided in the device. In addition, since the conveying screw of the rotary ejecting apparatus includes a shaft and a plurality of blades detachably attachable to the outer surface of the shaft, it is possible to partially replace the blade when the blade is damaged due to abrasion or the like, .

1 is a schematic view showing a side surface of a rotary ejecting apparatus according to the present invention;
2 is a schematic view showing a top surface of a rotary ejecting apparatus according to the present invention;
3A is a schematic view showing a side surface of an anti-backward slip prevention pad according to the present invention;
FIG. 3B is a schematic view showing a front face of the reverse slip prevention pad according to the present invention; FIG.
FIG. 3c is a schematic view showing that the reverse slip prevention pad according to the present invention is connected to the screw case; FIG.
FIG. 4 is an enlarged view of a feed screw and an anti-reverse slip pad according to the present invention.

The present invention

A screw case 120 serving as a passage through which the rotor is transferred;

At least one rotary inlet (110) installed at an upper end of the screw case (120) and introducing the rotary inlet;

A transfer screw 130 installed in the screw case 120 to transfer the incoming sludge to one side;

A return port 140 for discharging the wafer transferred by the transfer screw 130; And

At least one reverse slip prevention pad (160) installed at an upper end of the screw case (120) to prevent reverse slip of the slide conveyed to the one side;

Lt; / RTI >

The screw case 120 has a lower surface formed in an arcuate shape, an upper surface formed in a horizontal shape and having a " U "

The screw case 120 is installed such that the side of the rotation output port 140 is inclined higher than the side of the rotation inlet 110

(101) generated in the fluidized bed combustion apparatus.

Hereinafter, a rotary discharge device 101 generated in a fluidized bed combustion apparatus according to the present invention will be described in detail with reference to FIGS. 1 and 2. FIG.

First, the above-mentioned fluidized bed combustion is the most preferable method of using coal combustion among the combustion technologies developed so far, and blowing air at a proper rate to a mixed powder layer of a fluidized medium such as coal particles and limestone, (Suspended Fluidzed Bed). Because of the unique combustion principle, the fluidized bed combustion can overcome the problems of various types of coal as compared with the conventional coal combustion technique. For example, it can maintain relatively stable combustion and can be combusted at low temperature. It also has the advantage of allowing the burning of raw coal waste to be burned, preventing the clay of limestone from clinging, and simultaneously eliminating various side effects that occur.

Meanwhile, the coals injected into the fluidized bed are mixed with the inactive layer material and burned, and coarse ash flows out to the lower portion of the lower layer or the lower portion of the discharge plate. In the present invention, Which is a device for discharging the ash.

First, the spinneret 101 includes a screw case 120 serving as a passage through which the spinneret is fed. The screw case 120 may have an arcuate shape on its lower surface and a horizontal U-shaped cross section on its upper surface, but is not limited thereto.

One or more rotary inlet ports 110 may be installed at the upper end of the screw case 120 and a rotary outlet 140 may be installed at one side thereof. The rotary inlet 110 may be provided in plural, or may be installed at a distance from each other when a plurality of rotary inlet ports 110 are installed.

At this time, the rotary inlet 110 is not shown in the figure, but may be connected to a fluidized bed combustion device and connected to a lower rotary outlet formed in a lower portion of the fluidized bed combustion device, but the present invention is not limited thereto.

In addition, the screw case 120 may be provided with a feed screw 130 for feeding the feed stream from the feed inlet 110 to one side. The feed screw 130 may be a generally used screw and may include a shaft 190 and a blade 200 formed on an outer surface of the shaft. The feed screw 130 may be driven by receiving the power of the motor, It is not.

Meanwhile, the interval between the blades 200 of the conveying screw 130 may be gradually widened toward the circulation outlet 140, but is not limited thereto.

When the rotary ejecting apparatus 101 has a plurality of rotary input / output openings 110, the distance between the blades 200 is gradually widened because the amount of the rotary movement of the rotary outputting apparatus 101 toward the rotary outputting opening 140 increases.

In addition, the screw case 120 may be inclined and the side of the rotor 140 may be formed higher than the rotor inlet 110, but the present invention is not limited thereto.

The screw case 120 may be inclined so as to prevent the backward slip of the gas that is necessarily accompanied with the rotation of the screw case 120. In particular, when the gas reversely slips and flows back through the rotary inlet 110, a problem may occur in the fluidized bed combustion device. However, due to the inclination of the rotary shaft, the fluid flows into the connection portion of the screw case 120 and the inlet 110 The gas may not flow back to the inlet 110 part naturally as it accumulates.

In addition, one or more reverse slip prevention pads 160 may be provided to prevent slip of the slip conveyed to one side of the upper inside of the screw case 120.

3B is a front view, FIG. 3C is a side view of the reverse slip prevention pad 160, FIG. 3B is a side view of the reverse slip prevention pad 160, FIG. Indicates that they are in contact with each other.

Referring to FIG. 3A, the reverse slip prevention pad 160 has an upper portion fixed and a side surface in a vertical direction. Referring to FIG. 3B, the front face of the reverse slip prevention pad 160 may be formed such that the upper portion thereof is horizontal, the lower portion thereof has an arc-like shape, and the upper portion and the lower portion thereof are connected as a face. Referring to FIG. 3C, the lower portion of the reverse slip prevention pad 160 may be in contact with the blade 200 of the feed screw.

The reverse slip prevention pad 160 has a structure that can be opened or closed in the direction of rotation but can not be opened or closed in the reverse direction, so that foreign matter having a large volume can be transferred to one side and reverse flow of the foreign matter or gas can be prevented It is possible to have the function to be able to.

The rotary ejection apparatus 101 may have one or more transparent check ports 150 installed at one side of the screw case 120 to check the inside of the screw case 120.

The inspection hole 150 is not limited to any material as long as it can be seen through the inside, but it should be made of a material capable of withstanding the operating temperature and pressure of the rotary discharge device 101. For example, the inspection port 150 may be made of tempered glass, but is not limited thereto.

The shape of the screw 120 is not limited, and the operator can sufficiently confirm the state of the screw 120 (i.e., the state of the screw 130). However, as the number of the inspection ports 150 is increased, it is more preferable that the state of damage to the local wear of the conveyance screw 130 can be confirmed at various positions in real time.

The rotary ejection apparatus 101 may further include a cooling device for lowering the temperature inside the screw case 120.

The cooling device is not limited in any form, but may be one that preferably uses cooling water. 1 and 2 show a cooling water inlet port 170 and an outlet port 180. The cooling water inlet 170 and the outlet port 180 are provided to cool the heat of the conveyance screw 130 generated when the cooling water flows into the screw case 120, . At this time, the inside of the screw case 120 is formed as a double jacket, the inside of the double jacket is formed with a rotation transfer line by the transfer screw 130, and a cooling water line is formed outside the screw jacket 120. However, It is not.

In the absence of the cooling device, the heat generated by the combustion of the solid fuel in the combustion device may be continuously transferred to the transfer screw 130, and breakage may occur. Also, backward flow and incomplete combustion may occur as the combustion progresses in the state where the discharge of the meeting is stopped. In addition, in order to replace the feed screw 130, it is necessary to replace the broken feed screw 130 after waiting for a time for the temperature to drop to a temperature at which the operator can perform the replacement operation while the burner is stopped. And a loss due to a temperature drop may occur. However, the above problem can be solved by providing the cooling device.

Meanwhile, the plow conveyed through the conveying screw 130 may be discharged to the outside of the plow discharger 101 through the plow outlet 140.

In addition,

The present invention also provides a method of discharging a fluid using a fluid discharge device generated in the fluidized bed combustion device.

Hereinafter, the ash discharge method according to the present invention will be described in detail.

First, the coal charged in the fluidized bed combustion apparatus is mixed with the inactive layer material and burned. The coarse ash flows out to the lower portion of the bed or the lower portion of the discharge plate. The outflow is installed in the upper end of the screw case 120 And is introduced into the screw case 120 of the rotary ejection apparatus 101 according to the present invention through the rotary inlet 110. [

The screw case 120 may have an arcuate shape on its lower surface and a horizontal U-shaped cross section on its upper surface, but is not limited thereto.

In addition, a plurality of the rotation inlet ports 110 may be provided, and when the plurality of rotation inlet ports 110 are provided, the rotation inlet ports 110 may be installed at intervals.

Next, the shaft introduced into the screw case 120 is conveyed to one side of the rotary ejecting apparatus 101 through the conveying screw 130. The feed screw 130 may be installed inside the screw case 120 to feed the feed stream from the feed inlet 110 to one side.

The feed screw 130 may be a generally used screw and may include a shaft 190 and a blade 200 formed on an outer surface of the shaft. The feed screw 130 may be driven by receiving the power of the motor, It is not.

Meanwhile, the interval between the blades 200 of the conveying screw 130 may be gradually widened toward the circulation outlet 140, but is not limited thereto.

When the rotary ejecting apparatus 101 has a plurality of rotary input / output openings 110, the distance between the blades 200 is gradually widened because the amount of the rotary movement of the rotary outputting apparatus 101 toward the rotary outputting opening 140 increases.

In addition, the screw case 120 may be inclined and the side of the rotor 140 may be formed higher than the rotor inlet 110, but the present invention is not limited thereto.

The screw case 120 may be inclined so as to prevent the backward slip of the gas that is necessarily accompanied with the rotation of the screw case 120. In particular, when the gas reversely slips and flows back through the rotary inlet 110, a problem may occur in the fluidized bed combustion device. However, due to the inclination of the rotary shaft, the fluid flows into the connection portion of the screw case 120 and the inlet 110 The gas may not flow back to the inlet 110 part naturally as it accumulates.

In addition, one or more reverse slip prevention pads 160 may be provided to prevent slip of the slip conveyed to one side of the upper inside of the screw case 120.

3B is a front view, FIG. 3C is a side view of the reverse slip prevention pad 160, FIG. 3B is a side view of the reverse slip prevention pad 160, FIG. Indicates that they are in contact with each other.

Referring to FIG. 3A, the reverse slip prevention pad 160 has an upper portion fixed and a side surface in a vertical direction. Referring to FIG. 3B, the front face of the reverse slip prevention pad 160 may be formed such that the upper portion thereof is horizontal, the lower portion thereof has an arc-like shape, and the upper portion and the lower portion thereof are connected as a face. Referring to FIG. 3C, the lower portion of the reverse slip prevention pad 160 may be in contact with the blade 200 of the feed screw.

The reverse slip prevention pad 160 has a structure that can be opened or closed in the direction of rotation but can not be opened or closed in the reverse direction, so that foreign matter having a large volume can be transferred to one side and reverse flow of the foreign matter or gas can be prevented It is possible to have the function to be able to.

The rotary ejection apparatus 101 may have one or more transparent check ports 150 installed at one side of the screw case 120 to check the inside of the screw case 120.

The inspection hole 150 is not limited to any material as long as it can be seen through the inside, but it should be made of a material capable of withstanding the operating temperature and pressure of the rotary discharge device 101. For example, the inspection port 150 may be made of tempered glass, but is not limited thereto.

The shape of the screw 120 is not limited, and the operator can sufficiently confirm the state of the screw 120 (i.e., the state of the screw 130). However, as the number of the inspection ports 150 is increased, it is more preferable that the state of damage to the local wear of the conveyance screw 130 can be confirmed at various positions in real time.

The rotary ejection apparatus 101 may further include a cooling device for lowering the temperature inside the screw case 120.

The cooling device is not limited in any form, but may be one that preferably uses cooling water. 1 and 2 show a cooling water inlet port 170 and an outlet port 180. The cooling water inlet 170 and the outlet port 180 are provided to cool the heat of the conveyance screw 130 generated when the cooling water flows into the screw case 120, . At this time, the inside of the screw case 120 is formed as a double jacket, the inside of the double jacket is formed with a rotation transfer line by the transfer screw 130, and a cooling water line is formed outside the screw jacket 120. However, It is not.

In the absence of the cooling device, the heat generated by the combustion of the solid fuel in the combustion device may be continuously transferred to the transfer screw 130, and breakage may occur. Also, backward flow and incomplete combustion may occur as the combustion progresses in the state where the discharge of the meeting is stopped. In addition, in order to replace the feed screw 130, it is necessary to replace the broken feed screw 130 after waiting for a time for the temperature to drop to a temperature at which the operator can perform the replacement operation while the burner is stopped. And a loss due to a temperature drop may occur. However, the above problem can be solved by providing the cooling device.

Finally, the plow conveyed through the conveyance screw 130 may be discharged to the outside of the plow discharger 101 through the plow outlet 140.

101: Aspirator
110: Inlet inlet
120: Screw case
130: Feed screw
140:
150: Checkpoint
160: reverse slip prevention pad
170: Cooling water inlet
180: Cooling water outlet
190: shaft
200: blade

Claims (8)

A screw case 120 serving as a passage through which the rotor is transferred;
At least one rotary inlet (110) installed at an upper end of the screw case (120) and introducing the rotary inlet;
A transfer screw 130 installed in the screw case 120 to transfer the incoming sludge to one side;
A return port 140 for discharging the wafer transferred by the transfer screw 130; And
At least one reverse slip prevention pad (160) installed at an upper end of the screw case (120) to prevent reverse slip of the slide conveyed to the one side;
Lt; / RTI >
The screw case 120 has a lower surface formed in an arcuate shape, an upper surface formed in a horizontal shape and having a " U "
The screw case 120 is installed such that the side of the rotation output port 140 is inclined higher than the side of the rotation inlet 110
A device for removing ash generated in a fluidized bed combustion device.
The method according to claim 1,
Wherein the reverse slip prevention pad (160) is formed in a horizontal shape at an upper portion and an arc shape at a lower portion thereof.
The method according to claim 1,
Wherein the conveying screw (130) comprises a shaft (190) and a plurality of detachable blades (200) formed on the outer surface of the shaft.
The method of claim 3,
Wherein the lower portion of the reverse slip prevention pad (160) is in contact with the blade (200) of the transfer screw forming a gap.
The method of claim 3,
Wherein a gap between the blades (200) of the conveying screw (130) is widened toward the circulation outlet (140).
The method according to claim 1,
Wherein the rotary ejection apparatus further comprises one or more transparent check ports (150) installed at one side of the screw case (120) to confirm the inside of the screw case (120) Device.
The method according to claim 1,
Wherein the rotary discharge device further comprises a cooling device for lowering the temperature inside the screw case (120).
The method of claim 1, wherein the ash is discharged from the fluidized bed combustion apparatus.

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