JPH11343811A - Steam turbine plant, main steam stop valve and reheat steam stop valve - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce costs by removing a drain pipe, a drain valve and a drain pit for discharging a drain in the vicinity of the valve seat of a main steam stop valve or a reheat steam stop valve. SOLUTION: A main steam stop valve 13 provided in the inlet side of a high pressure steam turbine and a reheat steam stop valve 18 provided in the inlet side of a middle pressure steam turbine respectively have a valve body 31 having an inlet 46, an outlet 47 and a valve seat 36, and a valve element 35 disposed to be freely moved up and down in the upper side of the valve seat 36. The upper surface 36a of the valve seat 36 of the valve body 31 is positioned above or on the same horizontal plane as the lower end surface 46a of the inlet 46. Thus, a drain in the vicinity of the valve seat 36 is caused to flow to the inlet 46 side without remaining in the vicinity of the valve seat 36.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a steam turbine plant and a main steam stop valve and a reheat steam stop valve disposed in the steam turbine plant.

[0002]

2. Description of the Related Art Conventionally, as a steam turbine plant,
A high-pressure steam turbine, a main steam stop valve and a steam control valve provided on the inlet side of the high-pressure steam turbine, a medium-pressure steam turbine, and a reheat steam stop valve and an intercept valve provided on the inlet side of the medium-pressure steam turbine There is known a reheat-type steam turbine plant having the following. In such a steam turbine plant, drain accumulates in the steam piping system, and when the drain flows into the high-pressure steam turbine or the medium-pressure steam turbine, the drain hits the impeller of the high-pressure steam turbine or the medium-pressure steam turbine, causing damage such as erosion. Wake up. Therefore, sufficient care is taken to prevent the drain from flowing into the high-pressure steam turbine or the medium-pressure steam turbine.

For example, a drain mechanism is provided in a steam pipe, a main steam stop valve, and a reheat steam stop valve, and the drain accumulated in the drain mechanism is discharged to a drain pit or the like via the drain valve.

[0004] The operation of recent steam turbine plants has been largely automated, and these drain valves have also been automated using electric motors or other media. When the steam turbine plant is stopped, the steam piping, the main steam stop valve, and the reheat steam stop valve are in a cold state. When the steam starts to flow, the steam pipe, the main steam stop valve and the reheat steam stop valve are gradually warmed up, and at the same time, the steam is cooled to drain. The drain is discharged via a drain valve from a drain discharge mechanism appropriately arranged in the main steam stop valve and the reheat steam stop valve. The steam pipe, the main steam stop valve and the reheat steam stop valve are warmed up, and the drain valve is closed with no drain generated.

FIG. 3 shows a steam turbine plant according to the prior art.

As shown in FIG. 3, steam generated from the boiler 11 flows into a high-pressure steam turbine 15 through a steam pipe 12, a main steam stop valve 13, and a steam control valve 14. The steam worked in the high-pressure steam turbine 15 returns to the boiler 11 through the pipe 16. The steam reheated by the boiler 11 flows into the medium-pressure steam turbine 20 through a reheat steam pipe 17, a reheat steam stop valve 18, and an intercept valve 19. The steam worked in the medium-pressure steam turbine 20 flows into the low-pressure steam turbine 22 through the crossover pipe 21.
Next, the steam worked in the low-pressure steam turbine 22 is supplied to the condenser 2
The steam flows into 3 and becomes water. This water is supplied to the water supply pump 24 again.
And is supplied to the boiler 11.

During this time, the drain in the steam pipe 12 flows into the pit 25c through the drain pipe 25a and the drain valve 25b. The drain before the valve seat of the main steam stop valve 13 passes through the drain pipe 26a and the drain valve 26b, and the pit 2
6c. Further, the drain after the valve seat of the main steam stop valve 13 flows to the pit 27c through the drain pipe 27a and the drain valve 27b. The drain before the valve seat of the steam control valve 14 is connected to the drain pipe 2 of the drain after the valve seat of the main steam stop valve 13.
It is common to reject through 7a and drain valve 27b. Similarly, the drain in the reheat steam pipe 17 flows to the pit 28c through the drain pipe 28a and the drain valve 28b. The drain before the valve seat of the reheat steam stop valve 18 flows to the pit 29c through the drain pipe 29a and the drain valve 29b. The drain after the valve seat of the reheat steam stop valve 18 flows to the pit 30c through the drain pipe 30a and the drain valve 30b. The drain before the valve seat of the intercept valve 19 is generally removed through the drain pipe 30a and the drain valve 30b of the drain after the valve seat of the reheat steam stop valve 13.

[0008]

FIG. 4 shows the structure of the main steam stop valve 13 and the reheat steam stop valve 18 according to the prior art. As shown in FIG. 4, both the main steam stop valve 13 and the reheat steam stop valve 18 are cast products, and the valve seat 36
And a valve body 35 disposed above the valve seat 36.

The valve main body 31 is covered with an upper lid 32, and the upper lid 32 is fixed to the valve main body 31 by a nut 33. A strainer 44 is disposed in the valve body 31. Further, the valve body 35 is supported by a valve rod 37 penetrating through a valve rod guide piece 38, and the valve rod 37 is disposed below the oil cylinder via a coupling 41. 40. The oil cylinder 40 is connected to the valve body 31 via an oil cylinder connecting piece 39.

In FIG. 4, a valve seat 36 generally provided on a valve body 31 is also a place where casting defects easily occur, and its internal shape is machined or formed by a grinder or the like. As a result, the upper surface of the valve seat 36 is lower than the lower end surface of the inlet 46 of the valve body 31, and the drain 45 is accumulated on the valve seat 36. If the steam turbine plant is started without removing the drain 45, the drain 45
, The steam flows into the high-pressure steam turbine 15 or the medium-pressure steam turbine 20 at an ultra-high speed together with the steam, hits an impeller (not shown), and the impeller blades are eroded and damaged.

In order to prevent such erosion, the valve body 3
1 is provided with a drain discharge mechanism, and before the high-pressure steam turbine 15 or the medium-pressure steam turbine 20 is started, the drain valve 26
b, 29b to open the drain 45 on the valve seat 36 and the valve body 31
Is discharged to the outside. It is necessary to reliably perform such drainage before starting the high-pressure steam turbine 15 or the medium-pressure steam turbine 20, and the drain valves 26b and 29b are electrically operated to automatically open and close. The valve seat 36
Is drained outward by opening the drain valves 27b and 30b from the drain discharge mechanism 43.

However, the main steam stop valve 13 and the reheat steam stop valve 18 used in the steam turbine plant depend on the size of the steam turbine.
In this case, two and two drain valves are installed, and correspondingly, the same number of drain valves are installed. If the drain valve does not open due to malfunction, etc., the drain
5 or medium pressure steam turbine 20. Therefore, it is important to eliminate or reduce these drain valves as much as possible in terms of cost and reliability of the steam turbine plant.

[0013] The present invention has been made in view of the above points, and a steam turbine plant, a main steam stop valve, and a reheat steam stop valve capable of reducing costs and improving reliability. The purpose is to provide.

[0014]

The present invention comprises a high-pressure steam turbine, a main steam stop valve and a steam control valve provided on the inlet side of the high-pressure steam turbine, and the main steam stop valve has an inlet and an outlet. A valve body having a valve seat, and a valve body that is disposed above the valve seat and moves vertically, wherein the upper surface of the valve seat is located above the lower end surface of the inlet or on the same horizontal plane. A steam turbine plant, a high-pressure steam turbine, a main steam stop valve and a steam control valve provided on the inlet side of the high-pressure steam turbine, a medium-pressure steam turbine, and a reheat provided on the inlet side of the medium-pressure steam turbine. A steam stop valve and an intercept valve, wherein at least one of the main steam stop valve and the reheat steam stop valve has a valve body having an inlet, an outlet, and a valve seat, and is disposed above the valve seat and moves vertically. And the valve The upper surface of the valve seat is located above the lower end surface of the inlet or on the same horizontal plane, a main body having an inlet, an outlet, and a valve seat, and a main body having an inlet, an outlet, and a valve seat. A main steam stop valve, comprising: a valve body that moves in the direction, wherein the upper surface of the valve seat is located above the lower end surface of the inlet or on the same horizontal plane.
A main body having an inlet, an outlet, and a valve seat, and a valve body that is disposed above the valve seat and moves in a vertical direction, and the upper surface of the valve seat is located above the lower end surface of the inlet or on the same horizontal plane. A reheat steam stop valve.

According to the present invention, the main steam stop valve or the reheat steam stop valve has the upper surface of the valve seat of the valve body located above the lower end surface of the inlet or on the same horizontal plane. Or, the drain does not accumulate near the valve seat of the valve body of the reheat steam stop valve.

[0016]

Embodiments of the present invention will be described below with reference to the drawings. 1 and 2 are views showing one embodiment of the present invention.

As shown in FIG. 2, the steam turbine comprises a boiler 11, a high-pressure steam turbine 15 connected to the boiler 11 via a steam pipe 12 having a main steam stop valve 13 and a steam control valve 14, and a boiler. 11 is provided with a medium-pressure steam turbine 20 connected via a reheat steam pipe 17 to which a reheat steam stop valve 18 and an intercept valve 19 are attached. A low-pressure steam turbine 22 is connected to the medium-pressure steam turbine 20 via a crossover pipe 21, and a condenser 23 is connected to the low-pressure steam turbine 22. The condenser 23 is connected to the boiler 11 via a water supply pump 24.

The steam pipe 12 is connected to a drain pipe 25a having a drain valve 25b.
Is connected to the pit 25c.

The main steam stop valve 13 has a drain valve 27b.
Is connected to the drain pipe 27a,
The end of a is connected to the pit 27c. Further, a drain pipe 28a having a drain valve 28b is connected to the reheat steam pipe 17, and an end of the drain pipe 28a is
8c.

Next, the main steam stop valve 13 and the reheat steam stop valve 18 will be described with reference to FIG. As shown in FIG. 1, the main steam stop valve 13 and the reheat steam stop valve 18 have substantially the same structure, and both are made of cast products.
That is, the main steam stop valve 13 and the reheat steam stop valve 18
Includes a valve body 31 having a valve seat 36 and a valve body 35 disposed above the valve seat 36.

The valve body 31 is covered by an upper cover 32, and the upper cover 32 is fixed to the valve body 31 by a nut 33. A strainer 44 is disposed in the valve main body 31. Further, the valve body 35 is supported by a valve rod 37 penetrating through a valve guide piece 38, and the valve rod 37 is disposed below the oil cylinder 40 via a coupling 41. It is connected to. The oil cylinder 40 is connected to the valve body 31 via an oil cylinder connecting piece 39.

As shown in FIG. 1, the valve body 31 has an inlet 46 and an outlet 47.
6 is located above or on the same horizontal plane as the lower end surface 46a of the inlet 46.

As described above, the upper surface 36a of the valve seat 36 is
6 is located above the lower end surface 46a or on the same horizontal plane, the drain on the upper surface 36a of the valve seat 36 is
It flows to 6 side. Therefore, drain does not accumulate near the valve seat 36.

A drain discharge mechanism 43 is provided below the valve seat 36, and the drain discharge mechanism 43 is connected to the drain pipes 27a and 30a shown in FIG.

Next, the operation of the present embodiment having the above configuration will be described. The steam generated from the boiler 11 is supplied to a steam pipe 12, a main steam stop valve 13, a steam control valve 14,
Through the high-pressure steam turbine 15. The steam worked in the high-pressure steam turbine 15 returns to the boiler 11 through the pipe 16. The steam reheated by the boiler 11 is supplied to a reheat steam pipe 17, a reheat steam stop valve 18, an intercept valve 1
9 and flows into the intermediate-pressure steam turbine 20. The steam worked in the medium-pressure steam turbine 20 flows into the low-pressure steam turbine 22 through the crossover pipe 21. Next, the steam worked in the low-pressure steam turbine 22 flows to the condenser 23, and the steam becomes water. This water is pressurized again by the water supply pump 24 and supplied to the boiler 11.

During this time, the drain in the steam pipe 12 flows into the pit 25c through the drain pipe 25a and the drain valve 25b. Drain after the valve seat of the main steam stop valve 13 flows from the drain discharge mechanism 43 of the valve body 31 to the pit 27c through the drain pipe 27a and the drain valve 27b. The drain before the valve seat of the steam control valve 14 is also the drain pipe 27a and the drain valve 27b for the drain after the valve seat of the main steam stop valve 13.
Eliminate through.

Similarly, the drain in the reheat steam pipe 17 flows to the pit 28c through the drain pipe 28a and the drain valve 28b. The drain after the valve seat of the reheat steam stop valve 18 flows from the drain discharge mechanism 43 of the valve body 31 to the pit 30c through the drain pipe 30a and the drain valve 30b. The drain before the valve seat of the intercept valve 19 is also connected to the drain pipe 30a of the drain after the valve seat of the reheat steam stop valve 13 and the drain valve 30b.
Eliminate through.

As described above, according to the present embodiment, the upper surface 36a of the one seat 36 of the main steam stop valve 13 and the reheat steam stop valve 18 is disposed above the lower end surface 46a of the inlet 46 or on the same horizontal plane. The upper surface 36a of the valve seat 36
There is no drain on top. The drain near the valve seat 36 of the main steam stop valve 13 and the reheat steam stop valve 18 is supplied from the main steam pipe 12 and the reheat steam pipe 17 to the drain valve 2 respectively.
Drain pipes 25a and 28 having 5b and 28b
The liquid is discharged to drain pits 25c and 28c via a. For this reason, the conventionally provided drain valve 26b, 2
The drain pipes 26a and 29a having 9b can be eliminated.

In the above embodiment, in both the main steam stop valve 13 and the reheat steam stop valve 18, the upper surface 36a of the valve seat 36 is located above the lower end surface 46a of the inlet 46 or on the same horizontal plane. However, in any one of the main steam stop valve 13 and the reheat steam stop valve 18, the upper surface 36 a of the valve seat 36 is connected to the lower end surface 4 of the inlet 46.
6a may be located above or on the same horizontal plane.

[0030]

As described above, according to the present invention, drain does not accumulate near the valve seat of the main steam stop valve or the valve body of the reheat steam stop valve. For this reason, a drain pipe, a drain valve, and a drain pit for discharging drain near the valve seat of the main steam stop valve or the reheat steam stop valve can be removed,
The cost can be reduced and the reliability of plant operation can be improved.

[Brief description of the drawings]

FIG. 1 shows a steam stop valve and a reheat steam stop valve according to the present invention.

FIG. 2 is a diagram showing a steam turbine plant according to the present invention.

FIG. 3 is a diagram showing a conventional steam turbine plant.

FIG. 4 is a view showing a conventional steam stop valve and a reheat steam stop valve.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 11 Boiler 13 Main steam stop valve 14 Steam control valve 15 High pressure steam turbine 18 Reheat steam stop valve 19 Intercept valve 20 Medium pressure steam turbine 31 Valve body 36 Valve seat 36a Valve seat upper surface 46 Inlet 46a Inlet lower end surface 47 Exit

Continued on the front page (51) Int.Cl. ⁶ Identification code FI F16T 1/00 F16T 1/00 F

Claims (4)

[Claims] 1. A high-pressure steam turbine, comprising: a main steam stop valve and a steam control valve provided on an inlet side of the high-pressure steam turbine, wherein the main steam stop valve has a valve body having an inlet, an outlet, and a valve seat. A valve body disposed above the valve seat and moving in a vertical direction, wherein the upper surface of the valve seat is located above the lower end surface of the inlet or on the same horizontal plane. 2. A high-pressure steam turbine, a main steam stop valve and a steam control valve provided on an inlet side of the high-pressure steam turbine, a medium-pressure steam turbine, and a reheat steam provided on an inlet side of the medium-pressure steam turbine. A valve body including a stop valve and an intercept valve, at least one of a main steam stop valve and a reheat steam stop valve having an inlet, an outlet, and a valve seat; and a valve body disposed above the valve seat and moving in a vertical direction. Wherein the upper surface of the valve seat is located above the lower end surface of the inlet or on the same horizontal plane. 3. A main body having an inlet, an outlet, and a valve seat, and a valve body disposed above the valve seat and moving in a vertical direction, wherein the upper surface of the valve seat is located above the lower end surface of the inlet or on the same horizontal plane. The main steam stop valve, which is located. 4. A main body having an inlet, an outlet, and a valve seat, and a valve body disposed above the valve seat and moving in a vertical direction, wherein the upper surface of the valve seat is above the lower end surface of the inlet or on the same horizontal plane. A reheat steam stop valve characterized by being located.