KR20190111404A - Combustion apparatus and combustion facilities having the same - Google Patents

Abstract

The present invention provides a combustion apparatus and combustion facilities having the same. According to the present invention, the combustion apparatus comprises: an apparatus body; a discharge unit connected to the apparatus body to discharge combustion gas to the outside of the apparatus body; and a cyclone unit connected to the discharge unit. The discharge unit comprises: a first discharge duct extending in a height direction of the apparatus body; and a second discharge duct vertically connected in a gravity direction in the first discharge duct, and connected to a lower portion at a predetermined distance from the uppermost portion of the first discharge duct to form a dead zone in the first discharge duct.

Description

Combustion apparatus and combustion apparatus including the same {COMBUSTION APPARATUS AND COMBUSTION FACILITIES HAVING THE SAME}

The present invention relates to a combustion apparatus and a combustion installation comprising the same.

In general, thermal energy can be obtained by igniting and burning fuel, and various combustion apparatuses are used to obtain thermal energy in this way. Solid fuel fueled from domestic waste such as waste plastic may be used as a fuel of the combustion apparatus, and such solid fuel may be advantageous in terms of economics and resource recycling.

1 schematically shows a combustion apparatus 10 of a conventional solid fuel. The combustion device 10 burns the solid fuel supplied from the fuel hopper 13 for handling the fuel in the combustion chamber 12 of the combustion furnace body 11, and discharges the combustion gas generated at this time to the combustion furnace body 11. Discharge through 14.

Since the exhaust gas is very hot, it is supplied to a boiler and subjected to heat recovery. By the way, the device that is in constant and repeated contact with the high temperature combustion gas, especially the discharge pipe, etc. should be replaced periodically because of the cracks or thermal damage to the inner wall over time due to the high temperature combustion gas.

In addition, since the combustion gas contains granulated particles, measures for such particles are also required.

KR 20-0445277 Y1 (2009.07.07)

It is an object of the present invention to improve the flow of combustion gases and to improve the efficiency, performance and durability of equipment and equipment.

The present invention provides a combustion apparatus and a combustion installation comprising the same.

Combustion apparatus according to the present invention, the apparatus body; and a discharge unit connected to the apparatus body for discharging the combustion gas to the outside of the apparatus body; And a cyclone unit connected to the discharge unit, wherein the discharge unit comprises: a first discharge duct extending in a height direction of the device body; And a second discharge duct connected to the first discharge duct in a direction perpendicular to the direction of gravity and connected to a lower portion from a top of the first discharge duct to form a dead zone in the first discharge duct. It can be provided.

In addition, the second discharge duct may be provided such that the outer periphery is located at a height lower than the top of the first discharge duct so that the combustion gas existing at the top of the first discharge duct descends.

In addition, the second discharge duct is connected between the first discharge duct and the cyclone unit, the inner diameter may be provided to decrease toward the cyclone unit.

In addition, the second discharge duct may be provided such that the inner diameter and the outer diameter decrease linearly.

The second discharge duct may further include a straight cross-section that connects the first discharge duct and the cyclone unit in a cross section on a plane perpendicular to the gravity direction; And a non-linear cross-sectional portion connecting the first discharge duct and the cyclone unit to be offset from the straight cross-sectional portion.

In addition, the first and second discharge ducts may be provided such that their centers are on the same line in a plane perpendicular to the direction of gravity.

The second discharge duct may be connected to a tangential part of the cyclone unit.

On the other hand, the combustion equipment according to the present invention is a boiler device provided to receive the combustion gas; And the combustion device connected to the boiler device to supply combustion gas to the boiler device, wherein the combustion device includes a plurality of second discharge ducts directly connected to one cyclone unit. Can be.

In addition, the combustion equipment according to the present invention is a boiler device provided to receive the combustion gas; And the combustion device connected to the boiler device to supply combustion gas to the boiler device, wherein the combustion device includes a plurality of cyclone units, the same number as the cyclone units being provided And a plurality of second discharge ducts connected to the cyclone unit in a one-to-one correspondence.

In addition, the combustion equipment according to the present invention is a boiler device provided to receive the combustion gas; And the combustion device connected to the boiler device to supply combustion gas to the boiler device, wherein the combustion device comprises: a plurality of second discharge ducts; And a main duct connected to the second discharge duct, integrating the second discharge duct, and connected to the cyclone unit.

According to the present invention, it is possible to improve the efficiency, performance and durability of the device and the equipment, and to construct the equipment of a scale suitable for the use environment.

1 schematically shows a combustion apparatus of a conventional solid fuel.
2 schematically shows a combustion device according to the invention.
Figure 3 shows the flow field of the combustion gas of the combustion apparatus according to the present invention.
Figure 4 shows the velocity field of the combustion gas of the combustion apparatus according to the present invention.
5 shows a flow field of combustion gas of a conventional combustion apparatus.
6 shows the velocity field of the combustion gas of a conventional combustion apparatus.
7 is a plan view of a combustion apparatus according to the present invention.
8 is a plan view of a combustion apparatus according to another embodiment of the present invention.
Figure 9 schematically shows a combustion plant according to the invention.
10 schematically shows a combustion plant according to an embodiment of the present invention.
11 schematically illustrates a combustion plant according to another embodiment of the present invention.
Figure 12 schematically shows a combustion plant according to another embodiment of the present invention.

In order to help the understanding of the description of the embodiments of the present invention, the elements described with the same reference numerals in the accompanying drawings are the same elements, and the related elements among the components that will act the same in each embodiment may be represented by the same or extended numbers. Notation.

Further, in order to clarify the gist of the present invention, a description of elements and techniques well known by the prior art will be omitted, and hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

However, the spirit of the present invention is not limited to the embodiments presented, but may be proposed in other forms in which specific elements have been added, changed, or deleted by those skilled in the art, but are also included within the scope of the same spirit as the present invention. Leave it on.

Swivel combustion technology can be applied to combustion equipment and combustion equipment that burn solid fuels such as municipal waste and waste plastics. Swirl combustion technology refers to a technology that discharges high-temperature combustion gas obtained by burning solid fuel in a rotary combustion furnace through the exit of the rotary combustion furnace, and supplies it to the boiler to recover heat from the combustion gas.

At this time, the duct (duct) such as the evaporation tube applied to the rotary combustion furnace is directly affected by the flame or high temperature combustion gas, so local heating, breakage, heat breakage, heat damage, and the like frequently occur.

In addition, when supplied to the boiler in the state that the particles contained in the combustion gas is fed to cause a decrease in the efficiency of the boiler, it is also necessary to filter the particles and the like assembled from the combustion gas.

Thus, the present invention provides a combustion device as described below, the combustion device 100 according to the present invention, as shown in Figure 2, the device body 110, the combustion is generated combustion gas connected to the device body 110, the device body It may include a discharge unit 120 for discharging to the outside of the 110 and a cyclone unit 130 connected to the discharge unit to collect the particles contained in the combustion gas.

At this time, the discharge unit 120 is connected in a direction perpendicular to the first discharge duct 121 and the first discharge duct 121 extending in the height direction of the device body 110, that is, perpendicular to the direction of gravity. The second discharge duct 122 connected to a lower portion from the uppermost portion 121a of the first discharge duct 121 to form a dead zone 123 on the upper portion of the first discharge duct 121. It may be provided.

The first discharge duct 121 may have a height such that flame does not flow from the apparatus body 110.

In addition, the second discharge duct 122 is connected to the cyclone unit 130, and the combustion gas supplied through the fine particles is filtered out at the tangential portion 131 of the cyclone unit 130.

In FIG. 2, when the first discharge duct 121 is positioned downward from the top 121a of the first discharge duct 121, the outer circumference 122a of the second discharge duct 122 exists.

That is, due to a difference in height between the top 121a of the first discharge duct 121 and the outer periphery 122a of the second discharge duct 122, a predetermined distance downward from the top 121a of the first discharge duct 121. Dead zone 123 is present.

The dead zone 123 is present inside the first discharge duct 121, and the dead zone 123 is in the pipe in a section from the uppermost part 121a of the first discharge duct 121 to just before the outer circumference 122a of the second discharge duct 122. It means the area where flow can occur.

Preferably, the length of the dead zone 123 may be 30% or more and 60% or less of the diameter of the first discharge duct 121, and when the dead zone 123 is in this range flows to the center of the second discharge duct 122 The flow rate can be increased most effectively.

3 shows an analysis result according to an exemplary embodiment of the present invention, in which the length of the dead zone 123 is a value corresponding to 33% of the diameter of the first discharge duct 121. It can be seen that the pressure is increased in the dead zone 123, the flow of the combustion gas (G) congestion occurs and affects the flow of the combustion gas (G) to the second discharge duct 122.

In addition, the velocity field of the combustion gas shown in FIG. 4 increases the flow rate of the combustion gas from the connection portion of the first discharge duct 121 and the second discharge duct 122 and the center of the second discharge duct 122. It can be seen that the flow rate of the second discharge duct 122 is increased from the red part being pushed toward the side.

This causes the pressure rise and the flow stagnation occurring in the dead zone 123 to cause the combustion gas (G in FIG. 3) to fall at the uppermost portion 121a of the first discharge duct 121, and thus, the first discharge duct 121. Combustion gas falling from the uppermost portion (121a) of the will act to push down the combustion gas flowing into the second discharge duct 122.

Therefore, the flow and flow velocity in the second discharge duct 122 is increased at the center of the second discharge duct 122.

In contrast with the flow field shown in FIG. 5 and the velocity field shown in FIG. 6, when there is no dead zone in the first discharge duct 121, there is no flow falling to the wall surface of the second discharge duct 122. It can be seen that the flow rate increases.

As such, when there is no dead zone and the combustion gas is concentrated toward the wall, the inner wall damage of the emission duct is rapidly accelerated because a large amount of the combustion gas continuously contacts the wall of the emission duct.

In contrast, in the discharge unit 120 according to the present invention, the flow of the combustion gas is concentrated to the center of the second discharge duct 122 and the influence on the wall surface of the second discharge duct 122 is minimized, so that the discharge unit 120 ) Durability can be improved, and the life can be extended.

On the other hand, as shown in Figure 7, the first and second discharge ducts (121, 122) is a center (C ₁ ) of the first discharge duct 121 and the second discharge duct 122 in a plane perpendicular to the direction of gravity The center C ₂ may lie on the same line.

Accordingly, the flow efficiency can be improved by concentrating the flow to the center of the second discharge duct 122, and the durability of the first and second discharge ducts 121 and 122 can be further improved by preventing the flow rate from being lowered.

On the other hand, as shown in FIG. 8, the second discharge duct 122 may be provided such that its inner diameter decreases toward the cyclone unit 130.

Also preferably, the inner diameter of the second exhaust duct 122 may be provided to decrease linearly. As a result, the flow velocity increases toward the cyclone unit 130, thereby improving durability of the first and second discharge ducts 121 and 122 and extending the service life.

In addition, in a preferred embodiment of the present invention, the second discharge duct 122 has a cross-section 124 connecting the first discharge duct 121 and the cyclone unit 130 in a cross section perpendicular to the direction of gravity. And a non-linear cross-section 125 which connects the first discharge duct 121 and the cyclone unit 130 to be offset from the straight cross-section 124.

According to this, the flow rate of the combustion gas flowing into the cyclone unit 130 can be made faster to improve the efficiency of the combustion device.

On the other hand, the present invention as another aspect provides a combustion facility 200 including the combustion device 100, as shown in Figure 9, the combustion facility 200 according to the present invention is the combustion device 100 and the It may include a boiler device 210 is connected to the cyclone unit 130 of the combustion device 100 by a connection pipe 211 to receive the combustion gas.

As shown in Figure 10, the combustion facility 200 according to an embodiment of the present invention is provided with a plurality of second exhaust duct 122 may be connected to one cyclone unit 130, the cyclone unit 130 is a connection pipe It is connected to the boiler apparatus 210 by 211 can supply the combustion gas.

In another embodiment of the present invention, as shown in FIG. 11, the plurality of second discharge ducts 122 and the plurality of cyclone units 130 are connected in a one-to-one correspondence, and each cyclone unit 130 is connected to the connection pipe 211. It can be connected to the boiler device 210 by).

In addition, in another embodiment, as shown in FIG. 12, a plurality of second discharge ducts 122 may be integrated into one main duct 212 and connected to one cyclone unit 130, and the cyclone unit 130 may be used. ) May be connected to the boiler apparatus 210 by a connecting pipe 211.

As such, the combustion facility according to the present invention can be built not only on a scale suitable for the use environment, but also on a large scale of the facility, and thus can be applied to various industrial environments.

The matters described above have been described with respect to an embodiment of the present invention, and the scope of the present invention is not limited thereto, and various modifications and variations are possible without departing from the technical spirit of the present invention described in the claims. It will be apparent to one of ordinary skill in the art.

10: combustion apparatus of solid fuel 11: combustion furnace body
12 combustion chamber 13 fuel hopper
14: discharge pipe 100: combustion device
110: device body 120: discharge unit
121: first discharge duct 122: second discharge duct
123: dead zone 130: cyclone unit
131: tangential part 200: combustion equipment
211 connector 212 main duct

Claims (10)

Device body;
A discharge unit connected to the device body to discharge combustion gas to the outside of the device body; And
Includes; cyclone unit connected to the discharge unit,
The discharge unit,
A first discharge duct extending in the height direction of the apparatus body; And
A second discharge duct connected to the first discharge duct in a direction perpendicular to a direction of gravity, and connected to a lower portion from a top of the first discharge duct to form a dead zone in the first discharge duct; Combustion apparatus having a.
The method of claim 1,
The second discharge duct,
And an outer periphery is provided at a height lower than a top of the first discharge duct so that the combustion gas existing at the top of the first discharge duct is provided to descend.
The method of claim 1,
The second discharge duct,
The combustion device is connected between the first exhaust duct and the cyclone unit, the inner diameter is provided to decrease toward the cyclone unit direction.
The method of claim 3,
The second discharge duct,
A combustion device characterized in that the inner and outer diameters are provided to decrease linearly.
The method of claim 3,
The second discharge duct,
A straight cross-section having a cross section connecting the first discharge duct and the cyclone unit on a plane perpendicular to the direction of gravity; And
A non-linear cross-sectional portion connecting the first discharge duct and the cyclone unit to be offset from the straight cross-section;
Combustion apparatus comprising a.
The method of claim 1,
The first and second discharge ducts,
And the center is provided in the same line on a plane perpendicular to the direction of gravity.
The method of claim 1,
The second discharge duct,
Combustion apparatus characterized in that connected to the tangential portion of the cyclone unit.
Boiler apparatus provided to receive the combustion gas; And
Includes; the combustion device of any one of claims 1 to 7, which is connected to the boiler device to supply combustion gas to the boiler device.
The combustion device,
And a plurality of said second discharge ducts directly connected to one said cyclone unit.
Boiler apparatus provided to receive the combustion gas; And
Includes; the combustion device of any one of claims 1 to 7, which is connected to the boiler device to supply combustion gas to the boiler device.
The combustion device,
A plurality of said cyclone units;
And a plurality of second discharge ducts having the same number as the cyclone units and connected one-to-one to the cyclone unit.
Boiler apparatus provided to receive the combustion gas; And
Includes; the combustion device of any one of claims 1 to 7, which is connected to the boiler device to supply combustion gas to the boiler device.
The combustion device,
A plurality of second discharge ducts; And
And a main duct connected to the second discharge duct, integrating the second discharge duct, and connected to the cyclone unit.

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