KR102488344B1 - Oxide Dust Collector of Waste Heat Recovery Boiler - Google Patents

Abstract

The present invention relates to an oxide dust collector for an exhaust heat recovery boiler. The oxide dust collector for an exhaust heat recovery boiler is installed in an exhaust gas outlet (2) installed on a circular arc-shaped surface on one side of a lower part in a gas duct (1) discharging exhaust gas, which comes into contact with a pin and a heat pipe of an exhaust heat recovery boiler, to the outside after the exhaust gas comes into contact with the pin and the heat pipe of the exhaust heat recovery boiler recovering the heat by heat exchange with gas of a high temperature discharged as a gas turbine operates. The oxide dust collector for an exhaust heat recovery boiler collects oxide contained in the exhaust gas and discharges the exhaust gas from which the oxide is removed to the gas duct (1). The exhaust gas outlet (2) installed on the circular arc-shaped surface on one side of the lower part of the gas duct (1) has multiple windows separated in lines. The oxide dust collector for an exhaust heat recovery boiler comprises: a fixing bar (10) connected and fixed to the exhaust gas outlet (2) of each gas duct (1); a fixing frame (20) having a funnel port (21) corresponding to the size of the exhaust gas outlet (2) and fixed to each fixing bar (10); a dust collecting unit (30) closing the funnel port (21) by being fixed and connected to the funnel port (21) of each fixing frame (20) and filtering the oxide contained in the exhaust gas passing through the funnel port (21); and a dust collecting unit fixing unit (40) separably fixing each dust collecting unit (30) to the fixing frame (20). The oxide dust collector for an exhaust heat recovery boiler can be simply maintained through partial replacement in case of a repair and also reduce maintenance costs.

Description

Oxide Dust Collector of Waste Heat Recovery Boiler}

The present invention relates to an oxide dust collector for a waste heat recovery boiler that is low cost, simple to install, easy to maintain, and to reduce the generation of waste.

In order to maximize the plant output and efficiency of gas turbine power generation, the combined power plant introduces the high-temperature exhaust gas discharged from the gas turbine into a heat recovery steam generator (HRSG) to generate high-temperature and high-pressure steam as a heat source.

At this time, the generated high-temperature and high-pressure steam drives a steam turbine and a generator to generate power.

The combined power plant includes a gas turbine, a heat recovery boiler in which a high-pressure evaporator, an intermediate-pressure evaporator, and a low-pressure medium-pressure generator are formed, and a steam turbine.

In the power generation method, the primary power generation is performed by operating a gas turbine, and then the high-temperature exhaust gas discharged at about 620 ° C is recovered from the heat recovery boiler, and the recovered heat is used to produce steam suitable for steam turbine power generation. way to raise it.

The heat recovery boiler is a type of boiler that generates high-temperature, high-pressure steam using high-temperature combustion gas discharged from a gas turbine, and is used as steam for driving a steam turbine or for industrial processes.

Carbon steel is used as the main material for the fin tube, which is the main equipment for cooling the waste heat recovery boiler. However, since such carbon steel has a property of being easily oxidized at high temperatures, the surface is corroded and oxides (rust, etc.) tend to be easily generated.

Since these oxides deteriorate the heat exchange effect, they must be periodically removed. To remove this oxide, air blowing or CO2 blasting is performed.

However, at the time of initial start-up after removing the oxide, the excess corrosive material dropped from the fin tube is discharged into the atmosphere through the chimney, and in some workplaces, red-based iron oxide particles are actually discharged, causing environmental pollution and civil complaints. there was.

In some workplaces, red iron oxide particles are actually emitted, causing civil complaints from residents in nearby areas.

In LNG cogeneration, there is almost no emission of fine dust and particulate matter during normal facility operation, but when restarting after stopping, compensation for damage to the surroundings due to emission of iron oxide particles should be considered.

Therefore, there is a need for a technique for suppressing the discharge of iron oxides temporarily rather than constantly.

As an example for improving the problem of discharging iron oxide particles during initial operation after oxide removal, Korean Patent Publication No. 10-2012-0134613 (title of invention: iron oxide dust collector for heat recovery boiler) has been proposed. .

In the iron oxide collector of the heat recovery boiler, in the iron oxide collector of the heat recovery boiler used in the gas turbine of the combined power plant, the heat recovery boiler converts the introduced low-temperature boiler water into high-temperature and high-pressure steam It includes a pressure part including a heat pipe, a drum, and a header as a path, and a non-pressure part including a duct, a casing, and a chimney as a path through which the introduced high-temperature gas turbine combustion gas passes. The opening of the chimney of the non-pressure part is A non-woven fabric filter that collects corrosive materials dropped from the heat transfer pipe when restarting after performing preventive maintenance work (Overhaul); A first screen network installed at the lower end of the non-woven fabric filter to prevent sagging when the non-woven fabric filter is attached; And it is characterized in that a second screen net is installed on the upper end of the non-woven fabric filter to prevent corrosive substances from blowing in the air flow direction from the non-woven fabric filter.

However, since the iron oxide dust collector of the heat recovery boiler is installed in the opening of the chimney, the vertical type HRSG has a high installation position, so it is not easy to repair it. In addition, the diameter of the chimney is about 6 m, and since a dust collector having a larger area must be provided, there is a problem that the installation cost is high, and the dust collector is large, so it is not easy to install. .

Another example for improving the problem of discharging iron oxide particles during initial operation after oxide removal is to install a screen installed vertically to block a passage leading to a chimney in a horizontal type HRSG to remove oxides.

Since the area of the passage leading to the chimney is considerably large, the above-described methods have problems in that the installation cost of the non-woven fabric or the screen of the dust collector is high, and the air for their installation is long.

In addition, since the nonwoven fabric or the entire screen must be replaced during repair, maintenance is not easy, maintenance costs are high, and a lot of waste is generated during disposal, which causes secondary environmental pollution.

The present invention has been made to solve the above problems, and an object of the present invention is to enable simple maintenance through partial replacement during repair and to reduce maintenance costs by collecting oxides of heat recovery boilers. to provide the device.

In order to achieve the above object, the oxide dust collector of the heat recovery boiler of the present invention recovers heat by heat exchange with the high-temperature gas discharged by operating the gas turbine, and then contacts the exhaust heat exchanger and fins of the exhaust heat recovery boiler. It is installed in the exhaust gas discharge port 2 provided on the curved surface of one side of the lower part of the flue 1 that discharges gas to the outside, collects oxides contained in the exhaust gas, and discharges the oxide-free exhaust gas to the flue 1. As an oxide dust collector of a waste heat recovery boiler to be discharged, the exhaust gas discharge port 2 provided on the circular arc surface of one side of the lower part of the flue 1 has a plurality of windows spaced apart in a row, and the flue 1 A fixing bar 10 coupled and fixed to each of the exhaust gas outlets 2; A fixed frame 20 fixed to each of the fixing bars 10 and having a communication hole 21 corresponding to the size of the exhaust gas outlet 2; A dust collection unit 30 coupled and fixed to the communication ports 21 of each of the fixed frames 20 to close the communication ports 21 and filter oxides contained in the exhaust gas passing through the communication ports 21; It is characterized in that it comprises a; dust collecting part fixing part 40 for fixing each of the dust collecting part 30 to the fixing frame 20 detachably.

In addition, each of the dust collecting parts 30 is composed of a unit dust collecting part 31 divided into a plurality of upper and lower parts, and the dust collecting part fixing part 40 separates each unit dust collecting part 31 from the fixing frame 20 It is characterized in that it consists of a unit dust collecting unit fixing part 41 fixed to.

In addition, the unit dust collecting part fixing part 41 has an upper end protruding part 41a formed by protruding outwardly of the flue 1 at the upper end of the unit dust collecting part 31, and lower sides of both sides of the upper end protruding part 41a. It is characterized in that the protrusions 41b on both sides of the flue 1 protrude outward in an inverted triangle shape, and each of the unit dust collecting parts 31 is installed inclined at a predetermined angle with the flue 1. .

In addition, the unit dust collecting unit 31 includes a square frame 31a forming a rectangular outline so as to form a hollow portion, and an outline fixed to the square frame 31a to close the hollow portion. A non-woven fabric filter unit 31b that filters out oxides and purifies the passing exhaust gas, and is located in contact with the rear of the non-woven fabric filter unit 31b and has an outer frame fixed to the square frame 31a, and the non-woven fabric filter unit 31b It is characterized in that it consists of a mesh reinforcing portion (31c) made of a metal material to reinforce the strength.

In addition, the non-woven fabric filter part 31b and the mesh reinforcing part 31c are characterized in that they have a repetitive ridge shape in the width direction.

The oxide dust collector of the heat recovery boiler of the present invention according to the configuration described above removes iron oxide generated from polluted exhaust gas discharged from industrial facilities such as thermal power plants from the time it is discharged to the atmosphere to prevent diffusion at an early stage. As a result, it has the effect of keeping the air cleaner, and it is possible to replace some of the dust collecting parts without replacing the entire nonwoven fabric or screen during repair, so maintenance is easy, maintenance costs are low, and waste is reduced. It has the advantage of being able to reduce secondary environmental pollutants due to its low occurrence.

1 is a view showing a schematic structure of a heat recovery boiler.
2 is a view showing the flue of the heat recovery boiler.
3 is an exploded view showing the oxide dust collector of the heat recovery boiler according to the present invention.
4 is a view showing a fixing structure of a fixing bar of an oxide dust collector of an exhaust heat recovery boiler according to the present invention.
5 is a view showing the structure of fixing the dust collector of the oxide dust collector of the heat recovery boiler according to the present invention.
6 is a view showing the structure of a unit dust collector of the oxide dust collector of the heat recovery boiler according to the present invention.

Hereinafter, the oxide dust collector of the heat recovery boiler according to the present invention will be described in detail with reference to the drawings.

1 is a view showing the schematic structure of an exhaust heat recovery boiler, FIG. 2 is a view showing the flue of the heat recovery boiler, FIG. 3 is an exploded view showing an oxide dust collector of the heat recovery boiler according to the present invention, and FIG. 4 is It is a view showing the fixing structure of the fixing bar of the oxide dust collector of the heat recovery boiler according to the present invention. FIG. 5 is a view showing the structure of fixing the dust collector of the oxide dust collector of the heat recovery boiler according to the present invention. FIG. It is a drawing showing the structure of the unit dust collector of the oxide dust collector of the heat recovery boiler by

The oxide dust collector of the heat recovery boiler according to the present invention is in contact with the heat exchanger tube and fin of the heat recovery boiler (HRSG) (see FIG. 1) that recovers heat by heat exchange with the high-temperature gas discharged by operating the gas turbine and then contacts it. It is installed in the exhaust gas discharge port 2 (see FIG. 2) provided on the circular arc surface of one side of the lower part of the flue 1 that discharges the exhaust gas to the outside, and the oxide contained in the exhaust gas is collected and the oxide is removed. It is a device that allows the gas to be discharged into the flue (1).

At this time, the exhaust gas outlet 2 provided on the arc surface of one side of the lower portion of the flue 1 is provided with a plurality of windows spaced apart in a matrix (see FIG. 2).

The oxide dust collector of the heat recovery boiler according to the present invention, as shown in FIG. 3, includes a fixing bar 10; fixed frame 20; dust collection unit 30; It consists of; a dust collecting part fixing part 40.

The fixing bar 10 is coupled and fixed to each of the exhaust gas outlets 2 of the flue 1 . The fixing bars 10 are provided in plurality and may be formed in a straight line vertically or horizontally and spaced apart from each other. In addition, the fixing bar 10 is provided in plurality and is formed in a straight line vertically and horizontally, so that the entire shape may be spaced apart from each other to form a # shape. In addition, the fixing bar 10 may form an X shape formed to cross each other in a diagonal direction of the exhaust gas outlet 2 .

In the drawing, it is shown that it is formed in a straight line up and down and provided with spaced apart from each other.

The fixing bar 10 is an exhaust gas outlet coupling part 11 having both ends formed in a "c" shape so that it can be coupled to the exhaust gas outlet 2 without changing the structure of the exhaust gas outlet 2 ( 4) is preferably provided so that it is inserted into and coupled to the inner periphery of the exhaust gas outlet (2).

The fixing frame 20 is fixed to each of the fixing bars 10 and a communication port 21 corresponding to the size of the exhaust gas outlet 2 is formed.

The fixing of the fixing bar 10 and the fixing frame 20 may be fixed by welding, or may be fixed by screwing.

The dust collecting part 30 is coupled and fixed to the communication hole 21 of each of the fixed frames 20 to close the communication hole 21 and removes oxides contained in the exhaust gas passing through the communication hole 21. It acts as a filter.

The dust collecting part fixing part 40 serves to fix each of the dust collecting part 30 to the fixing frame 20 detachably.

In this way, unlike the conventional screen that simultaneously closes and filters the entire exhaust gas outlet, the present invention collects oxides by the dust collecting unit that closes and filters each exhaust gas outlet, so it is not necessary to replace the entire exhaust gas outlet during maintenance. Since part of the dust collection unit can be replaced without the need, not only is maintenance easy, maintenance costs are low, and there is an advantage in that secondary environmental pollution factors can be reduced due to low generation of waste.

In the case of a large-scale power plant, since each of the exhaust gas outlets 2 is considerably large, the dust collection unit 30 is also inevitably large. Therefore, the dust collecting part 30 of the oxide dust collector of the heat recovery boiler of the present invention is made of a unit dust collecting part 31, and the dust collecting part fixing part 40 is the unit dust collecting part ( 31) to be fixed to the fixing frame 20.

The unit dust collecting unit 31 is divided into a plurality of upper and lower dust collecting units 30 .

The dust collecting part fixing part 40 is composed of a unit dust collecting part fixing part 41 for fixing each unit dust collecting part 31 to the fixing frame 20 .

In addition, in the present invention, it is preferable that each of the unit dust collectors 31 be installed inclined at a predetermined angle with the flue 1.

To this end, the unit dust collecting part fixing part 41 includes an upper end protruding part 41a formed by protruding outwardly of the flue 1 and an upper end of the unit dust collecting part 31 being fixed, and both sides of the upper protruding part 41a. The protruding parts 41b on both sides protruding outwardly of the flue 1 in an inverted triangle shape are provided at the bottom so that the unit dust collection part 31 is installed inclined at a predetermined angle with the flue 1 (FIG. 5 Reference).

At this time, in order to fix the unit dust collecting part 31 to the fixing frame 20, the unit dust collecting part 31 is installed inside the top protrusion 41a and both side protrusions 41b of the unit dust collecting part fixing part 41. is inserted, and then fastened with screws so that the unit dust collecting part 31 is fixed to the fixing frame 20.

In this way, when each of the unit dust collectors 31 is installed inclined at a predetermined angle with the flue 1, when the exhaust gas is discharged to the flue 1 through the exhaust gas outlet 2, the exhaust gas is discharged. In addition to being able to smoothly, the exhaust gas is not concentrated in the exhaust gas outlet 2 located at the top, and can be discharged evenly through the exhaust gas outlet 2 as a whole, thereby increasing the dust collection efficiency.

In addition, it is preferable that each of the unit dust collectors 31 installed on the fixed frame 20 has a larger inclination angle with the flue 1 as it goes upward.

In this way, when the angle of inclination of each of the unit dust collectors 31 installed on the fixed frame 20 with the flue 1 increases toward the top, the exhaust gas is discharged through each exhaust gas outlet 2. When discharged to (1), the exhaust gas is not rushed to the upper exhaust gas outlet (2), and it is possible to discharge the exhaust gas evenly through each of the unit dust collectors 31, thereby further reducing the exhaust gas discharge. be able to do it smoothly.

In addition, as shown in FIG. 6, the unit dust collecting unit 31 passes through a rectangular frame 31a forming a rectangular outline so as to form a hollow portion and an outline fixed to the square frame 31a so as to close the hollow portion. A non-woven fabric filter unit 31b that filters oxides contained in the exhaust gas and purifies the passing exhaust gas, and is located in contact with the rear of the non-woven fabric filter unit 31b and has an outer frame fixed to the square frame 31a, and the non-woven fabric filter unit 31b It is preferable to consist of a mesh reinforcing part 31c made of metal to reinforce the strength of the filter part 31b.

In this way, when the mesh reinforcing part 31c is provided in the unit dust collection part 31, the strength of the nonwoven fabric filter part 31b is reinforced, thereby reducing the tearing or damage of the nonwoven fabric filter part 31b.

In addition, it is preferable that the non-woven fabric filter part 31b and the mesh reinforcing part 31c have a repetitive ridge shape in the width direction.

In this way, when the non-woven fabric filter part 31b and the mesh reinforcement part 31c form a repetitive ridge shape in the width direction, the strength of the non-woven filter part 31b and the mesh reinforcement part 31c increases, so that the non-woven fabric It is possible to further reduce the tearing or damage of the filter part 31b, and the contact area of the non-woven fabric filter part 31b increases, so that the dust collection efficiency can be increased.

In addition, a mesh reinforcing part support part 31d located at the rear of the mesh reinforcing part 31c and fixed to the square frame 31a to support the mesh reinforcing part 31c may be further provided.

The mesh reinforcing part support part 31d may be formed in a straight line in the left and right directions, spaced apart from each other in a plurality vertically, and may be provided in an X shape in a diagonal direction of the square frame 31a.

In addition, a square frame insertion guide accommodating the square frame 31a is further provided on the both side protrusions 41b, so that the square frame 31a can be inserted and coupled.

Technical ideas should not be interpreted as being limited to the above-described embodiments of the present invention. Not only the scope of application is diverse, but also various modifications and implementations are possible at the level of those skilled in the art without departing from the gist of the present invention claimed in the claims. Therefore, such improvements and changes fall within the protection scope of the present invention as long as they are obvious to those skilled in the art.

1: flue 2: exhaust gas outlet
10: fixed bar 11: exhaust gas outlet coupling
20: fixed frame 21: communication hole
30: dust collection unit 31: unit dust collection unit
31a: square frame 31b: non-woven fabric filter unit
31c: mesh reinforcement part 31d: mesh reinforcement part support
40: dust collecting part fixing part 41: unit dust collecting part fixing part
41a: top protrusion 41b: both side protrusions

Claims (5)

Equipped on the circular arc surface of one side of the lower part of the flue 1 that discharges the contacted exhaust gas to the outside after contact with the heat transfer tube and fin of the heat recovery boiler that recovers heat by heat exchange with the high-temperature gas discharged by operating the gas turbine An oxide dust collector of a waste heat recovery boiler installed at an exhaust gas outlet (2) to collect oxides contained in exhaust gas and discharge exhaust gas from which oxides are removed to a flue (1),
The exhaust gas outlet 2 provided on the arc surface of one side of the lower part of the flue 1 is provided with a plurality of windows spaced apart in a matrix,
A fixing bar 10 coupled and fixed to each of the exhaust gas outlets 2 of the flue 1;
A fixing frame 20 fixed to each of the fixing bars 10 by welding or screwing and having a communication port 21 corresponding to the size of the exhaust gas outlet 2;
A dust collection unit 30 coupled and fixed to the communication ports 21 of each of the fixed frames 20 to close the communication ports 21 and filter oxides contained in the exhaust gas passing through the communication ports 21;
A dust collecting part fixing part 40 for fixing each of the dust collecting parts 30 to the fixing frame 20 detachably;
Each of the dust collecting parts 30 is composed of a unit dust collecting part 31 divided into a plurality of upper and lower parts,
The dust collecting part fixing part 40 is composed of each unit dust collecting part fixing part 41 fixing each unit dust collecting part 31 to the fixing frame 20,
The unit dust collecting part fixing part 41 has an upper end of the unit dust collecting part 31 fixed and formed by protruding outwardly from the flue 1, and the lower part of both sides of the upper protruding part 41a. Protrusions 41b on both sides of the flue 1 protrude outward in a triangular shape, and each unit dust collecting part 31 is installed inclined at a predetermined angle with the flue 1,
When the unit dust collecting part 31 is fixed to the fixing frame 20, the unit dust collecting part 31 is inserted into the upper end protrusion 41a and the both side protrusions 41b of the unit dust collecting part fixing part 41. Then, the unit dust collecting unit 31 is fixed to the fixing frame 20 by fastening with screws,
The unit dust collection unit 31,
A square frame 31a forming a rectangular outline so that a hollow part is formed;
A non-woven fabric filter unit 31b having an outer frame fixed to the square frame 31a to close the hollow portion and filtering oxides contained in the passing exhaust gas and purifying the passing exhaust gas;
It is located in contact with the rear part of the non-woven fabric filter part 31b and has an outer frame fixed to the square frame 31a, and is made of a metal mesh reinforcing part 31c for reinforcing the strength of the non-woven filter part 31b,
The non-woven fabric filter part 31b and the mesh reinforcement part 31c have a repetitive valley shape in the width direction,
The fixing bar 10 is provided in plurality and is formed in a straight line vertically and horizontally, and is spaced apart from each other so that the overall shape forms a # shape, and the exhaust gas outlet (2) without changing the structure of the exhaust gas outlet (2). 2) is provided with an exhaust gas outlet coupling part 11 having both ends formed in a "c" shape so that it can be coupled to the exhaust gas outlet 2 and inserted into the inner circumference of the exhaust gas outlet 2,
It is located at the rear of the mesh reinforcement part 31c and is fixed to the square frame 31a to support the mesh reinforcement part 31c. (31d) is further provided,
A square frame insertion guide for accommodating the square frame 31a and inserting and coupling the square frame 31a is further provided on the both side protrusions 41b,
When the exhaust gas is discharged to the flue (1) through the exhaust gas outlet (2), the exhaust gas is discharged smoothly, the exhaust gas is not driven into the exhaust gas outlet (2) located at the top, and the exhaust gas outlet ( 2), each of the unit dust collecting parts 31 installed on the fixed frame 20 has an inclination angle with the flue 1 increasing toward the top so that the dust can be discharged evenly and the dust collection efficiency can be increased. Oxide dust collector of heat recovery boiler. delete delete delete delete

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