KR20100050352A - A bypass valve plug of steam turbine - Google Patents

Abstract

PURPOSE: A bypass valve plug for a high pressure vapor turbine is provided to prevent the damage of a plug sheet by blocking shock occurrence and causing a vortex phenomenon by overheated vapor smoothly moved along a rounded slope. CONSTITUTION: A bypass valve plug for a high pressure vapor turbine(70) comprises a stepped protrusion(73), a vapor passage part(75) and a sloped part(80). The stepped protrusion comprises a supporting shaft(71) longitudinally extended and a seat(72). The vapor passage part is formed between the wing portions(74) of the plug. The sloped part is formed at the upper part of the inner surface of the vapor passage part with the same height as the seat. The vapor passage part comprises short and long passage parts which are alternately formed. Each passage part is formed to slope at a certain angle in order that the upper width becomes narrower.

Description

A Bypass Valve Plug of Steam Turbine

The present invention relates to a plug which is installed in a bypass valve for bypassing and regulating high temperature and high pressure superheated steam of a high pressure steam turbine, such as a steam turbine of a power plant. The rounded inclined portion having the same height as the seat portion is formed above the inner surface of the vapor passage portion formed therebetween so that the superheated steam moves smoothly along the rounded inclined portion to prevent the occurrence of shock, thereby forming the vortex phenomenon. It is possible to prevent the sheet portion of the breakage, as well as the angle formed so as to be inclined at an angle so as to narrow the upper side of each of the steam passage formed between the wings, fine control of the superheated steam passing through the steam passage of the plug Plug of bypass valve for high pressure steam turbine for further smooth operation It relates.

In general, the bypass valve for bypassing or uniformly controlling the high-temperature, high-pressure superheated steam of the high-pressure steam turbine, such as a steam turbine of the power plant, as shown in Figure 1, the bypass valve 10 The superheated steam inlet 30 is formed under the valve body 20 of the superheated steam outlet, and the superheated steam outlet is formed at a right angle to discharge the superheated steam introduced through the circular space 40 in the valve body 20. 50 is provided, and a perforated cylindrical plate 60 is installed at the periphery of the circular space portion, and inside the valve body portion 20 via a support shaft 71 extending longitudinally in the vertical direction. The step portion 73 in which the seat portion 72 is provided, and the plug 70 in which the steam passage portions 75 are formed between the plurality of wing portions 74 below, are configured to be opened and closed upward and downward. .

Therefore, in the case of overheating of the high-pressure steam turbine or in order to control the flow rate of the superheated steam, the high temperature and high pressure superheated steam flowing into the superheated steam inlet 30 of the bypass valve 10 is the valve body portion ( 20) flows into the circular space portion 40 of the valve body portion 20 along the vapor passage portion 75 formed between the wing portions 74 of the plug 70 installed therein, and in a direction perpendicular thereto. It is to be discharged through the superheated steam outlet (50) communicated.

However, as shown in FIG. 2, the plug provided in the conventional bypass valve has a width (a) of the vapor passage portion 75 formed between the lower blade portion 74 of the seat portion 72 of the plug 70. Since T) has the same width as the upper side in contact with the seat portion 72, the high temperature and high pressure superheated steam introduced through the respective steam passages 75 as shown in the superheated steam operation state diagram of FIG. Is gathered with each other in contact with the seat portion 72 so that the density of the superheated steam rapidly increases, and the plug 70 is caused by the impact force generated at the portion where the superheated steam is rapidly increased in density. ) Is a big disadvantage that the sheet portion 72 of the breakage occurs.

4 is a photograph showing a state of fluidity change due to high temperature and high pressure of a plug installed in a conventional bypass valve. As shown in FIG. 4, the lower seat portion 72 and the wing of the plug 70 are shown. In the upper contact portion of the steam passage portion 75 between the portions 74, the density of the superheated steam rapidly increases, thereby shortening the life of the plug, and in particular, the steam passage portion 75 of the plug 70. There were many problems, such as not being able to properly perform the fine flow control operation of the superheated steam passing through.

The present invention has been made in order to improve the above-mentioned conventional problems, the object of which is a rounding of the same height as the seat portion above the inner surface of the steam passage formed between the blades of the plug installed in the bypass valve of the high-pressure steam turbine The inclined portion is formed so that the superheated steam is smoothly moved along the rounded inclined portion to prevent the occurrence of shock, so that the vortex phenomenon is made, thereby preventing breakage of the seat portion of the plug, as well as of the bypass valve. To further extend the plug life, the length of each of the steam passage formed between the wing portions of the plug is shortened on one side, one side is formed long to contact the seat portion of the plug, so that the upper width of each passage portion is narrowed Formed to be inclined at an angle, superheat passing through the steam passage portion of the plug High pressure steam that can be performed smoothly gailcheung a fine flow rate control operation is on to provide a plug of the turbine bypass valve.

As a technical means for achieving the above object, the present invention, the superheated steam inlet is formed under the valve body portion of the bypass valve installed in the high-pressure steam turbine, the inlet through the circular space portion inside the valve body portion The superheated steam outlet is provided at a right angle so that the superheated steam is discharged, and a perforated cylindrical plate is installed at the periphery of the circular space, and a seat portion is provided through a support shaft extending vertically in the valve body. In the plug of the bypass valve for a high-pressure steam turbine, a plug having a steam passage portion respectively formed between the stepped portion and a plurality of wing portions below it can be opened and closed.

A rounded inclined portion having the same height as the seat portion is formed above the inner surface of the steam passage portion formed between the wing portions of the plug, and the length of each of the steam passage portions formed between the wing portions of the plug is cut and one side of the plug is formed. By forming a long so as to contact the seat portion, it is provided by the plug of the bypass valve for the high-pressure steam turbine, characterized in that the configuration is formed to be inclined at a predetermined angle so that the upper width of each passage portion is narrowed.

In addition, the present invention is characterized in that the inclination angle of the upper side of the passage formed between each of the wings of the plug made of 50 ~ 70 °.

According to the plug of the bypass valve for the high pressure steam turbine of the present invention, a rounded inclined portion having the same height as the seat portion is formed on the inner surface of the steam passage portion formed between the wing portions of the plug installed in the bypass valve of the high pressure steam turbine. Superheated steam is smoothly moved along the rounded inclination to prevent eddy currents while preventing shock, thereby preventing damage to the seat of the plug, and extending plug life of the bypass valve even further. And, the length of each of the steam passage formed between the blades of the plug is squeezed one side, one side is formed to be in contact with the seat portion of the plug, while being formed to be inclined at a predetermined angle to narrow the upper width of each passage portion, Fine flow rate control of superheated steam passing through the steam passage of the plug There are excellent effects that can smoothly perform the ground floor.

While the invention has been shown and described with respect to specific embodiments thereof, it will be appreciated that various changes and modifications can be made in the art without departing from the spirit or scope of the invention as set forth in the following claims. Those of ordinary skill will want to know easily.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

5 is a schematic perspective view of a plug of a bypass valve for a high pressure steam turbine according to the present invention, Figure 6 is a bottom structural view of the plug of the bypass valve of the present invention, Figure 7 is a bypass valve for a high pressure steam turbine according to the present invention The cross-sectional structural view showing the operation of the plug of the superheated steam, the same parts as in Figures 1 to 4 with the same reference numerals will be described in detail the present invention.

That is, the superheated steam inlet 30 is formed under the valve body 20 of the bypass valve 10 installed in the high pressure steam turbine, and the circular space 40 is formed inside the valve body 20. The superheated steam outlet 50 is provided at a right angle to discharge the superheated steam interposed therebetween, and a perforated cylindrical plate 60 is installed at the periphery of the circular space.

In addition, inside the valve body 20, a stepped portion 73 provided with a seat portion 72 via a support shaft 71 extending longitudinally in a vertical direction, and a plurality of wings 74 below. Plugs 70 each having a steam passage portion 75 formed therebetween are provided to be opened and closed vertically.

At this time, a rounded inclined portion 80 having the same height as the seat portion 72 is formed above the inner surface of the vapor passage portion 75 formed between the blade portions 74 of the plug 70, and the plug 70 is formed. The length of the vapor passage portion 75 formed between the wings 74 of the () is one long passage portion 75a and one side passage portion formed to be in contact with the seat portion 72 of the plug 70 75b are alternately formed, respectively.

Further, each of the passage portions 75a and 75b is configured to be inclined at 50 to 70 ° so that the upper width thereof is narrowed.

Referring to the operation and effect of the present invention made of such a configuration as follows.

5 to 7, when the bypass valve 10 is operated to overheat the high-pressure steam turbine of the power plant or to regulate the flow rate of the superheated steam, the bypass valve 10 of the The superheated steam at a high temperature and high pressure flowing into the superheated steam inlet 30 may include a steam passage 75 formed between the blades 74 of the plug 70 installed inside the valve body 20. Accordingly, after flowing into the circular space portion 40 of the valve body portion 20, it is to be discharged through the superheated steam outlet 50 communicated in a direction perpendicular to this, thereby preventing overheating of the high-pressure steam turbine.

At this time, the steam passage portion 75 formed between the blade portion 74 of the plug 70, as shown in Figure 5, the upper portion of the inner surface of the steam passage portion 75, such as the seat portion 72 The rounded slope 80 of height is integrally formed.

Accordingly, when the high temperature, high pressure superheated steam moves through the steam passage 75, the superheated steam smoothly moves along the rounded inclined portion 80, as shown in FIG. The superheated steam discharged from the contact surface between the inclined portion 80 of the 75 and the seat portion 72 of the plug 70 causes a fire flow phenomenon, thereby preventing the impact of the seat portion 72, It is possible to prevent damage to the seat portion 72 of the plug 70.

In addition, one side of the steam passage portion 75 formed between the blade portions 74 of the plug 70 is one short steam passage portion 75a, and one side seat portion 72 of the plug 70 By alternately forming the vapor passage portion (75b) formed to be in contact with each other, it is possible to smoothly control the fine flow rate of the high-temperature, high-pressure superheated steam passing through the steam passage portion (75a), (75b) of the plug 70 Make it work.

In particular, each of the steam passages 75a and 75b is formed to be inclined at 50 to 70 ° such that its upper width is narrowed, thereby overheating discharged through the elongated passage portion 75b of the plug 70. It is possible to more smoothly control the operation of the fine flow of steam.

In this case, when the upper width of each of the vapor passage portions 75a and 75b is narrowed to 50 ° or less, the width of the steam passage portion is formed so narrow that the superheated steam passing through the steam passage portion becomes too narrow. Due to the principle of the orifice, the risk of damaging the seat portion 72 of the plug 70 occurs, and when the upper width of the vapor passage portions 75a and 75b is 70 ° or more, the The superheated steam passing through the steam passage portion is ejected without causing the vortex phenomenon, and the density of the superheated steam rapidly increases at the contact portion of the upper sheet portion 72 of the steam passage portion as in the prior art, so that an impact occurs. It is preferable that the passage portions 75a and 75b be inclined at 50 to 70 degrees.

On the other hand, Figure 8 is a photograph showing the state of the fluidity change by the high temperature, high pressure of the plug installed in the bypass valve of the present invention, as shown in Figure 8, the lower seat portion of the plug 70 ( At the upper contact portion of the steam passage portion 75b between the 72 and the wing portion 74, the high temperature and high pressure superheated steam is ejected by causing an external phenomenon, so that the superheated steam is discharged relatively stably, and thus the plug 70 is discharged. While extending the lifespan, in particular, it is possible to perform a fine flow rate adjustment operation of the superheated steam passing through the steam passage portion 75 of the plug 70 properly.

1 is a front sectional structural view of a bypass valve for a general high pressure steam turbine.

Figure 2 is a schematic perspective view of a plug of the bypass valve for a conventional high pressure steam turbine.

Figure 3 is a main cross-sectional structural view showing the operation of the superheated steam of the plug of the bypass valve for a high-pressure steam turbine according to the prior art.

Figure 4 is a photograph showing the state of fluidity change by the high temperature, high pressure of the plug installed in the conventional bypass valve.

5 is a schematic perspective view of a plug of a bypass valve for a high pressure steam turbine according to the present invention;

Figure 6 is a bottom structure of the plug of the bypass valve of the present invention.

7 is a cross-sectional structural view showing the main portion of the superheated steam operation of the plug of the bypass valve for the high-pressure steam turbine according to the present invention.

Figure 8 is a photograph showing the state of fluidity change by the high temperature, high pressure of the plug installed in the bypass valve of the present invention.

Explanation of symbols on the main parts of the drawings

10 ... bypass valve 20 ... valve body

30 ... Superheated steam inlet 40 ... Round space

50.Superheated steam outlet 60 ... plate

70 ... Plug 71 ... Support Shaft

72 Seat area 73

74 ... wings 75,71a, 75b ... steam passages

80.Slope

Claims (2)

The superheated steam inlet 30 is formed under the valve body 20 of the bypass valve 10 installed in the high pressure steam turbine, and the circular body 40 is formed inside the valve body 20. The superheated steam outlet 50 is provided at a right angle to discharge the superheated steam introduced therein, and a perforated cylindrical plate 60 is installed at the periphery of the circular space, and vertically inside the valve body 20. Plugs in which steam passage portions 75 are formed between the stepped portions 73 provided with the seat portions 72 and the plurality of wing portions 74 below the support shafts 71 that are elongated in the air, In the plug of the bypass valve for high-pressure steam turbine is installed so that 70) can be opened and closed up and down, Inside the valve body 20, a stepped portion 73 provided with a seat portion 72 via a support shaft 71 extending vertically in a vertical direction, and a plurality of wing portions 74 below. Plugs 70 having steam passages 75 formed thereon are installed to be opened and closed upward and downward, and seat portions 72 are disposed above the inner surface of the steam passage 75 formed between the wing portions 74 of the plugs 70. Rounded inclined portion 80 of the same height as is formed, the length of each of the steam passage portion 75 formed between the blade portion 74 of the plug 70 is short passage portion 75a and One side is alternately formed with passage portions 75b each formed to be in contact with the seat portion 72 of the plug 70, and each passage portion 75a and 75b is inclined at a predetermined angle so that its upper width is narrowed. Plug of the bypass valve for high pressure steam turbine, characterized in that the configuration is made to form. According to claim 1, wherein the upper inclination angle of the passage portion 75 formed between the blade portion 74 of the plug 70 of the bypass valve for high-pressure steam turbine, characterized in that consisting of 50 ~ 70 ° plug.

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