JPH0861006A - Steam turbine - Google Patents

Abstract

PURPOSE: To capture and discharge drain so as to prevent errosion of a blade by providing a gap for capturing the drain in a corner part formed by a nozzle blade and an outer wall. CONSTITUTION: A gap 8 is provided in an outer wall 5 by a nozzle blade 4 and a space 7. An annular space 10 linked with the gap 8 and an ejecting hole 11 for ejecting the drain therefrom are also provided. Thus, watery films stuck to the outer wall or the surface of the nozzle blade are effectively eliminated, errosion of the blade is prevented, eddy flow in a corner part between the nozzle blade and the outer wall is reduced and any loss in secondary flow can be reduced. Therefore, reliability is improved by preventing errosion of the blade. Also, reduction in efficiency can be prevented since the secondary flow loss can be reduced.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a steam turbine having a structure for collecting water droplets adhering to a nozzle blade and an outer wall, and more particularly to a steam turbine having a space for collecting water droplets in the outer wall. .

[0002]

2. Description of the Related Art Conventionally, various structures have been proposed for capturing water droplets adhering to nozzle blades and outer walls of steam turbines. As one of them, for example, the one described in JP-A-60-190602 is known. This known device has a V-shaped drain trapping groove at the root of the nozzle vane and the outer ring, where the upstream side of the steam flow is shallow on the convex side and the concave side of the nozzle vane, and becomes gradually deeper toward the downstream side of the steam flow. It is provided so that the drain can be captured by the capture groove.

[0003]

Although various inventions and inventions have been made as described above for the purpose of preventing erosion of turbine blades (moving blades) by water droplets in steam, the drain is most concentrated in the prior art. Since no consideration was given to capturing from the position, the drain was not captured sufficiently, and the erosion of the turbine blade (moving blade) could not be completely prevented. In addition, since the steam was also captured when the drain was captured, turbine efficiency declined.

Further, at the same time as the drain is trapped, the steam is also trapped as associated steam and discharged outside the system as non-working vapor, leading to a decrease in turbine efficiency.

An object of the present invention is to provide a steam turbine capable of efficiently catching water droplets by compensating for a decrease in efficiency due to associated steam and providing a void for catching drainage at a position where the drain is concentrated. is there.

[0006]

The features of a steam turbine according to the present invention for achieving the above object include a nozzle blade, and an outer wall and an inner wall for fixing respective radial end portions of the nozzle blade. In the steam turbine configured to form a steam flow path by the outer wall and the inner wall, in the vicinity of the nozzle blade fixing portion of the outer wall, a gap formed along the contour shape of the nozzle blade in the nozzle blade fixing portion. It is provided.

Further, a discharge hole may be further provided which is in communication with the gap and discharges the water droplet to the outside of the steam flow path.

[0008]

[Function] The water droplets in the steam flow toward the downstream side together with the steam while concentrating on the outer wall side by the centrifugal force. Water droplets concentrated on the outer wall side adhere to the outer wall of the diaphragm, and the adhered water droplets combine and grow toward the downstream side. Also,
The water droplets concentrated on the outer wall side also adhere to the nozzle blades, and the water droplets combine and grow toward the downstream side and the outer wall side. Therefore,
The water droplets attached to the outer wall and the nozzle blade are most concentrated on the nozzle blade fixing portion of the outer wall, that is, the corner portion where the outer wall and the nozzle blade intersect.

The water droplets that have come out of the diaphragm collide with the blade in the subsequent stage and erode the blade. The degree of erosion is
The larger the water droplets that collide, the more erosion occurs, so if you capture the water droplets (drain) that have adhered to the outer wall and nozzle blades and have grown,
This will prevent blade erosion.

Therefore, by providing a trapping gap formed along the contour shape of the nozzle blade in the nozzle blade fixing portion at the corner portion where the outer wall and the nozzle blade intersect with each other,
It is possible to capture the drain directly from the drain concentration part, and it is possible to effectively capture it, and it is possible to prevent the blade on the wake side from being eroded.

Further, a vortex flow is generated in the corner portion between the nozzle blade and the outer wall to cause a secondary flow loss. However, the secondary flow loss can be reduced by capturing the vortex flow together with the accompanying steam at the time of capturing the drain from the void. It is possible to compensate for the decrease in efficiency due to the capture of the associated vapor.

Further, since the voids provided at the corners of the nozzle blade and the outer wall can be formed in the usual diaphragm manufacturing process, the structure is simple and the manufacturing cost is low.

[0013]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 shows the structure of a steam turbine according to an embodiment of the present invention. The steam turbine is composed of a nozzle blade 4, an outer wall 5 and an inner wall 20 for fixing respective ends of the nozzle blade 4 in the radial direction, and a blade 6 flowing out from the nozzle blade 4 and rotated by the above. The outer wall 5 and the inner wall 20 form a vapor flow path.

Since the water droplets 2 existing in the steam 1 have a heavier mass than the steam 1, they are collected on the outer peripheral side under the influence (centrifugal force) of the blade 6 rotating at a high speed (usually 3000, 3600 or 1500, 1800 rpm). Attach to the outer wall 5. The attached water droplets flow through the outer wall toward the downstream while the water droplets combine with each other and grow.

The water droplets 2 adhering to the nozzle blades 4 become water films 3 like the above-mentioned outer wall and grow downstream while flowing toward the outer wall 5 side as they grow. Then, this water film is captured by the voids 8 and passes through the space 10 to the discharge hole 1
1 is configured to be discharged to the outside of the steam flow path.
This detailed description will be given later, but before that, the growth of the water film 3 will be described in more detail with reference to FIGS. 2 and 3.

FIG. 2 shows the nozzle blade 4 described in FIG.
It is an enlarged view of the outer wall 5 of the tip part and its vicinity.

The water droplets 2 adhering to the surface of the nozzle blade 4 grow while the water droplets combine with each other while flowing downstream. The grown water film 3 travels along the nozzle blade surface toward the outer wall 5 side under the influence of the centrifugal force of the steam. The water film 3 is captured by the void 8 provided near the nozzle blade fixing portion on the outer wall and collected in the space 10.

FIG. 3 is a cross-sectional view taken along the line AA of FIG. 1. The water droplets 2 attached to the outer wall 5 travel through the outer wall 5 toward the downstream while growing while the water droplets combine with each other and grow. The flow direction of the water film 3 with respect to the flow 1 is not following the flow of the steam because of its large mass, and flows in the axial direction of the turbine due to the inertial force. Therefore, most of the water film 3 flows and gathers on the concave side surface of the nozzle blade 4.

As described above, the water droplets 2 attached to the nozzle blade 4 and the outer wall 5 both gather at the corners where the outer wall 5 and the nozzle blade 4 intersect.

When this water film exits the nozzle blades 4 and the outer wall 5, it collides with the blades 6 and causes erosion, impairing the reliability of the turbine. Especially, it becomes a water film
When colliding with, the collision energy becomes large and the amount of erosion also increases because the mass is large. The water droplets that do not adhere to the nozzle blades 4 and the outer wall 5 and collide with the blades 6 while existing in the vapor have a small mass and a small collision energy, so that there is no problem with respect to the erosion of the blades 6.

As described above, in order to reduce the erosion of the blade 6, the water film 3 attached to the nozzle blade 4 and the outer wall 5 and grown.
It is an effective method to capture the gas before it leaves the nozzle blade 4 and the outer wall 5 and separate it from the steam.

In this embodiment, at the nozzle blade fixing portion of the outer wall where the water film 3 is most concentrated, that is, at the corner portion between the nozzle blade 4 and the outer wall 5, the contour of the nozzle blade in the nozzle blade fixing portion as shown in FIG. A void 8 formed along the shape is provided, and the water film 3 is captured there, introduced into the space 10 formed by the spacer 7 and the outer ring 9, and a discharge hole communicating from this space 10 to a low pressure region. The structure is such that it passes through 11 and is discharged to the outside of the system of the main steam flow. With this configuration, most of the water film 3 attached to the nozzle blades 4 and the outer wall 5 can be captured, and water droplets that collide with the blade 6 can be minimized.

Next, how to make the voids 8 will be described with reference to FIG.

FIG. 4 is a flow chart for explaining the method of manufacturing the diaphragm applied to the present invention.

The nozzle blade 4 and the spacer 7 are assembled by fitting the nozzle blade 4 into the nozzle blade insertion hole 71 in which the spacer 7 is processed. The nozzle blade insertion hole 71 is made larger than the contour shape of the nozzle blade 4 by the gap 8. Next, the spacer 7 and the nozzle blade 4 are fixed by welding 40 or the like. At this time, the welding range is only the steam inlet side of the nozzle blade 4, the inlet side and the outlet side, the convex side of the nozzle blade 4, the central portion of the nozzle blade 4, or the like. In this example, only the steam inlet side is welded. The nozzle ring, in which the nozzle blade 4 and the spacer 7 are assembled and integrally fixed, is assembled and welded 41 to the outer ring 9 and the inner ring 91, which are prepared in advance, and fixed. A groove 10a for forming a space 10 is processed in the outer ring 9. As described above, the void 8 for capturing the drain and the space 10 communicating with the void 8 are formed. The manufacturing flow up to this point is not for making a special drain trapping structure, and is no different from normal diaphragm manufacturing. One of the features of the present invention is to focus on the conventional diaphragm manufacturing method, and to make the nozzle blade insertion hole 71 larger than the contour shape of the nozzle blade 4 by a gap of 8 minutes, and to provide a drain capturing gap here. It is also possible to easily and inexpensively provide a drain trapping structure that has conventionally required complicated processing. Further, a swirl of steam is generated at the corner between the nozzle blade 4 and the outer wall 5, which is known as a secondary flow loss. According to the present invention, since the vortex flow is captured and discharged as the associated steam together with the drain from the position where the vortex flow is generated, the secondary flow loss can be reduced.

FIG. 5 shows another embodiment which focuses on the secondary flow loss reduction which is one of the effects of the present invention. The void 8 and the space 10 are the same as in FIG. The discharge hole 11a for discharging the drain and the associated steam captured from the space 10 has a pipe 21.
By connecting to a high-vacuum region such as a condenser (not shown) through the space and strongly sucking in from the space 10, more vortex flow can be captured and secondary flow loss can be reduced. Of course, the trapped amount of drain will increase.

FIG. 6 shows another embodiment of the present invention, in which the trapped drain is discharged through a discharge hole 11 directly connected to the void 8. Even with this structure, the effect of the present invention can be expected similarly.

[0029]

Since the present invention is constructed as described above, it has the following effects.

By providing the drain trapping gap at the corner between the nozzle blade and the outer wall, the drain can be trapped from the position where the drain is most concentrated, the blade erosion due to the collision of the drain can be prevented, and the steam turbine The reliability of can be improved. Further, it is expected that the turbine efficiency will be improved by capturing the vortex flow that causes the secondary flow loss. Furthermore, since the manufacturing method is no different from that of a normal diaphragm, it is possible to provide a drain trap structure which is easy to process and inexpensive.

[Brief description of drawings]

FIG. 1 is a partial cross-sectional view of a steam turbine according to an embodiment of the present invention.

FIG. 2 is an enlarged view of a tip portion of the nozzle blade 4 described in FIG. 1 and an outer wall 5 in the vicinity thereof.

FIG. 3 is a cross-sectional view taken along the line AA in FIG. 1, showing water film growth on the outer wall.

FIG. 4 is a flowchart of a diaphragm manufacturing method applied to the present invention.

FIG. 5 is a cross-sectional view of a wet stage of a steam turbine according to another embodiment of the present invention.

FIG. 6 is a cross-sectional view of a wet stage of a steam turbine according to another embodiment of the present invention.

[Explanation of symbols]

4 ... Nozzle blade, 5 ... Outer wall, 7 ... Spacer, 8 ... Void, 1
0 ... space, 11 ... discharge hole.

Claims (2)

[Claims] 1. A steam turbine, comprising: a nozzle blade; and an outer wall and an inner wall for fixing radial ends of the nozzle blade, respectively, wherein the outer wall and the inner wall form a steam flow path. A steam turbine characterized in that a gap formed along the contour shape of the nozzle blade in the nozzle blade fixing portion is provided near the nozzle blade fixing portion of the outer wall. 2. A steam turbine, comprising: a nozzle blade; and an outer wall and an inner wall for fixing radial end portions of the nozzle blade, wherein the outer wall and the inner wall form a steam flow path. In the vicinity of the nozzle blade fixing portion of the outer wall, a gap is formed along the contour shape of the nozzle blade in the nozzle blade fixing portion, and a gap for collecting water droplets adhering to the nozzle blade and the outer wall is provided,
Further, a steam turbine is provided, which is provided with a discharge hole communicating with the gap to discharge water droplets to the outside of the steam flow path.