KR100646629B1 - Gas air heater for power plant - Google Patents

Abstract

An air preheater for a power plant is provided to eliminate soot, ashes or tar from a heating surface, and to increase heat exchange efficiency by injecting steam from an injection nozzle to a large surface of an element with a soot blower. An air preheater(40) includes a housing(42), an element(45) dividing the housing into an upper part and a lower part and exchanging heat by moving up and down fluid, a duct(44) extended up and down to open upper and lower parts, turned and installed in the upper and lower parts of the element to cover part of the element and separate and move high temperature fluid and low temperature fluid in the housing, and plural injection nozzle heads(41) connected to the duct to remove foreign matters from the element by injecting steam. Plural injection nozzle heads are spaced from each other and arranged circumferentially in the housing.

Description

Air preheater for power plant {GAS AIR HEATER FOR POWER PLANT}

1 is a schematic representation of a typical cogeneration power flow.

2 is a schematic plan view of an air preheater according to the prior art.

3 is a plan view of the elements of the air preheater.

4 is a plan view of an air preheater with multiple spray nozzle heads in accordance with the present invention.

5A and 5B are cross-sectional views taken along the lines A-A and B-B of FIG. 4.

6 shows a nozzle of a multi-jet nozzle head according to the present invention.

FIG. 7 is a view illustrating a state in which the duct of FIG. 4 is rotated 90 degrees counterclockwise. FIG.

※ Description of symbols for main members in drawings *

40: air preheater 41: multi-jet nozzle head

42 housing 44 duct

The present invention relates generally to an air preheater (GA / H) connected to a boiler of a cogeneration plant, and more particularly to an air preheater for a power plant having a soot blower having a blow nozzle head composed of multiple stages.

The energy plant includes an air preheater with element elements for recovering the waste heat of the waste gas from the boiler. The air flowing through the pressurized blower, which is an air suction device in the air preheater, passes through the air preheater before entering the combustor, and the air introduced through the pressurized blower exchanges heat with the element element heated by the waste gas discharged from the boiler. By reducing the waste heat of the waste gas by this heat exchange, it is possible to lower the temperature of the exhaust gas and consequently reduce the heat released to the atmosphere, thereby increasing the boiler efficiency. In addition, the combustion efficiency of the fuel is increased and the combustion speed is increased to increase the combustion chamber heat generation rate (Kcal / m 3 hr), reduce the combustion chamber volume, and completely burn the fuel at a low air ratio.

Referring to FIG. 1, which is a general cogeneration flow chart, the fuel gas supplied to the boiler 10 is combusted to generate waste gas. The waste gas discharged from the boiler 10 is supplied to the air preheater 12 through the discharge line 11 and heats the element element in the air preheater 12. The air supplied to the air preheater 12 exchanges heat with the heated element element. On the other hand, the high pressure steam discharged from the boiler 10 operates the steam turbine 13 and is discharged as low pressure steam.

Next, an air preheater according to the prior art will be described with reference to the accompanying drawings.

2 is a schematic plan view of an air preheater according to the prior art.

An element 25 that is heat-exchanged while passing hot waste gas and low temperature outside air is fixedly positioned to partition the housing 24 up and down in a cylindrical housing 24 of an air preheater, and an element (up and down) is disposed above and below the element 25. A duct 23 having an open face toward 25 is rotatably installed above and below the element 25 so as to cover a part of the element 25. The cold outside air flows from the bottom up the space in the duct 23 and passes through a portion of the corresponding element 25. The hot waste gas flows from top to bottom in the space between the duct 23 and the housing 24 and passes through the remaining part of the corresponding element 25. At this time, since the duct 23 arranged above and below the element 25 rotates at a low speed, the low temperature outside air passes through the position where the hot waste gas near the radial edge of the duct 23 has passed. That is, low temperature outside air passes through the element 25 of the portion heated by the high temperature waste gas by the movement of the duct 23, and thus the low temperature outside air is heated by the element 25. On the other hand, the waste gas of high temperature passes again by the rotation of the duct 23 to the element 25 of the said part heat-exchanged by low temperature external air, and the said part 25 of the element 25 is heated again by it.

When the air preheater is continuously operated for a long time, soot, ash, tar, etc. are accumulated on the heat exchanger plate, which is the heat transfer surface of the air preheater, by waste gas, thereby inhibiting heat transfer and ventilation. In order to prevent this problem, soot blowers 21 and 22 which periodically clean the deposits on the heat transfer surface are attached to the duct 23. As shown in FIG. 2, the soot blowers 21, 22 having the conventional single injection nozzle heads are attached to the outside of the upper and lower ducts 23. As shown in FIG. The soot blowers 21 and 22 are configured to be steam-typed and easy to operate. The soot blowers 21 and 22 attached to the duct 23 rotate together with the duct 23 inside the air preheater and inject steam to the element 25 through a single injection nozzle head formed therein to the element 25. Remove soot, ash, etc. attached.

However, when injecting steam to the element 25 with such a single jet nozzle head, the total area of the element 25 is 8000 mm, the heat transfer area is 11700 m 2, and the rotation of the duct 23 is 1 rpm, so that the total area is Compared with the spray amount of steam is small compared to the soot removal effect by the steam is insufficient. In the internal inspection of the air preheater, a large amount of soot, ash, tar, etc. is accumulated in the element 25, so that the single injection nozzle head does not achieve the soot removal effect as desired. This causes a huge energy loss and there is a problem that leads to a facility accident due to a fire when accumulating soot, ash, tar and the like.

SUMMARY OF THE INVENTION An object of the present invention is to provide an air preheater with a soot blower in which multiple injection nozzle heads are formed so that the steam generated from the injection nozzles reaches the element surface as a whole to solve the problems of the prior art.

In order to achieve the above object, a heat exchanger for a power plant according to the present invention is disposed so as to partition the inside of the housing up and down, and the fluid exchanges heat while the fluid flows up and down, and the upper and lower surfaces are extended and extended up and down. A duct which covers a part and is rotatably installed on the upper and lower parts of the element to separate and flow the high and low temperature fluid flowing in the housing, and vapor for removing the foreign matter attached to the element and attached to the element. It characterized in that it comprises a plurality of injection nozzle head for spraying.

In this case, the plurality of injection nozzle heads may be arranged side by side in the circumferential direction of the housing.

In addition, the plurality of spray nozzle heads may be attached to the outside of the duct.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings. Like reference numerals in the accompanying drawings denote like elements.

3 is a plan view of an element 45 used in an air preheater, FIG. 4 is a plan view of an air preheater with multiple injection nozzle heads according to the invention, and FIGS. 5A and 5B are lines AA and BB of FIG. 6 is a cross-sectional view of the nozzle of the multi-jet nozzle head according to the present invention, and FIG. 7 is a view illustrating a state in which the duct of FIG. 4 is rotated 90 degrees counterclockwise.

The element 45 used in the air preheater according to the present invention is a portion in which hot waste gas and low temperature external air are exchanged while passing, and an annular outer frame 31 having a predetermined height and the outer frame 31. Is provided with inner frames 32 and 33 for partitioning in radial and circumferential directions, and a plurality of heat exchange plates 34 for heat exchange in the region partitioned by these frames. The heat exchange plate 34 has a grid-like or corrugated metal plate arranged vertically in the partitioned area, allowing waste gas and outside air to pass vertically through the element 45. Thus, heat exchange occurs between the hot waste gas and the cold outside air via the heat exchange plate 34.

4, 5a and 5b, such an element 45 is fixedly positioned to partition the housing 42 up and down within the cylindrical housing 42 of the air preheater and above and below the element 45. As shown in the figure, the duct 44 is rotatably installed up and down. The illustrated duct 44 has a cross sectional shape of a dumbbell, and the upper and lower ends thereof are open and extend upward and downward. However, this duct 44 may be of any shape as long as the surface facing the element is open and covers only a part of the element.

On the other hand, as shown in Figure 4 the duct 44 is connected to the multiple injection nozzle head 41 according to the present invention. That is, the multiple injection nozzle head 41 is connected to each of the ducts 44 disposed on the high temperature side and the low temperature side to face the upper and lower surfaces of the element 45. The multiple spray nozzle head 41 is connected to the duct 44 such that the multiple spray nozzle head 41 also rotates with the duct 44 as the duct 44 rotates. The multi-jet nozzle head 41 consists of a plurality of jet nozzle heads each extending in a substantially radial direction so as to pass all parts of the element 45 when rotating. These spray nozzle heads are connected to each other in various manners such as adhesion and welding while being spaced apart from each other in the circumferential direction to form a single multiple spray nozzle head. The number of injection nozzle heads and the separation distance there between may vary depending on the design of the air preheater. At this time, a plurality of injection nozzles are arranged in the longitudinal direction in each injection nozzle head as shown in FIG.

In addition, although the multi-jet nozzle head 41 according to the present invention is attached to the outside of the duct 44 in FIG. 4, it may be installed inside the duct 44 or may be installed both inside and outside.

As such, the air preheater equipped with the multi-jet nozzle head according to the present invention compared to the conventional single jet nozzle head constitutes multiple jet nozzle heads so that steam generated from the jet nozzle reaches the wider element surface in a short time and is sooted. Foreign substances such as can be removed more effectively.

Next will be described the operation of the air preheater according to the present invention with reference to the drawings. As shown in FIGS. 4A and 4B, low temperature outside air is supplied from the bottom through the inside of the duct 44 to the top, and the hot waste gas is passed through the space between the housing 42 and the outside of the duct 44. Supplied from the top. The hot waste gas supplied from the top heats the element 45 in the portion corresponding to the space between the housing 42 and the outside of the duct 44. Then, when the duct 44 rotates, the low temperature external air supplied from the lower portion through the duct 44 exchanges heat with the portion of the element 45 heated by the waste gas before the rotation of the duct 44.

That is, referring to FIGS. 4 and 7 showing the state before and after the duct 44 with the multi-jet nozzle head 41 is rotated 90 degrees counterclockwise, the rotational speed of the duct 44 is Considering 1 rpm, the duct 44 rotates about 90 degrees after 15 seconds. When the duct 44 rotates for 15 seconds, that is, about 90 degrees, the C region inside the duct 44 is outside the duct 44 and the D portion outside the duct 44 is It will be inside 44. That is, in FIG. 4, the element heats low-temperature air in region C, and the hot waste gas heats the element in region D. In FIG. Then, when the duct 44 rotates 90 degrees, the waste gas of high temperature heats an element in area | region C, and an element heats low-temperature air in area | region D. In FIG. Through this, the low temperature outside air exchanges heat through the hot waste gas and the element.

On the other hand, when the air preheater is continuously operated for a long time, foreign substances such as soot and ash adhere to the heat transfer surface of the element 45, and the heat transfer and ventilation effects of the element are reduced. Multiple spray nozzle heads 41 according to the invention are attached to the duct 44 in a circumferentially spaced arrangement of the housing 42 to remove foreign matter. Due to the multiple injection nozzle heads, steam generated at the injection nozzles is supplied to a wider area of the element. As a result, the amount of the foreign matter removed by effectively blowing the foreign matter such as soot, ash, tar can be increased to maximize the effect of removing the foreign matter.

While the invention has been shown and described with reference to specific embodiments, those skilled in the art will readily recognize that various modifications and variations of the invention may be made without departing from the spirit and scope of the claims herein.

Therefore, according to the present invention, by providing a soot blower having multiple spray nozzle heads, steam generated from the spray nozzle is sprayed on a wider element surface to remove soot, ash, tar, etc. adhering to the heat transfer surface, thereby increasing heat exchange efficiency. You can.

Claims (3)

housing, An element arranged to partition the inside of the housing up and down and for heat exchange while the fluid flows up and down, A duct which opens and extends upward and downward and covers a part of the element and is rotatably installed above and below the element to separate and flow the high and low temperature fluid flowing in the housing; And a plurality of injection nozzle heads connected to the duct for injecting steam for removing foreign substances attached to the element. Air preheater. The method according to claim 1, The plurality of injection nozzle head is characterized in that arranged side by side in the circumferential direction of the housing, Air preheater. The method according to claim 1 or 2, The plurality of spray nozzle head is characterized in that attached to the outside of the duct, Air preheater.

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