JP2012211525A5 - - Google Patents

Description

Low pressure steam turbine inlet structure

  The present invention relates to a steam inlet structure of a low-pressure steam turbine that supplies steam heated by a moisture separator and heater to the inside of the low-pressure steam turbine, and particularly suitable for a low-pressure steam turbine used in a nuclear power plant. The present invention relates to a steam inlet structure of a turbine.

  In a nuclear power plant, steam generated by a steam generator for taking out thermal energy generated in a nuclear reactor as steam is sent to a high-pressure turbine. Then, the steam that has worked in the high-pressure turbine is heated again by the moisture separator and is sent to the low-pressure turbine through the crossover pipe.

FIG. 4 is a perspective view of the vicinity of a low-pressure steam turbine in a nuclear power plant.
In the nuclear power plant, two moisture separation heaters 60 are provided, and the two moisture separation heaters 60 are arranged beside the low pressure steam turbine 58 so as to sandwich the low pressure steam turbine 58 therebetween. And the crossover pipe | tube 62 through which the vapor | steam heated with each moisture separation heater 60 distribute | circulates is provided. The crossover pipe 62 communicates with the low pressure steam turbine 58, and the steam flowing through the crossover pipe 62 is supplied to the low pressure steam turbine 58. That is, steam is introduced into the low-pressure steam turbine 58 from the two crossover pipes 62.

  As for the low-pressure steam turbine 58 in a nuclear power plant, it is general that two crossover pipes 62 are merged to provide a single steam supply section to the low-pressure steam turbine 58.

FIG. 5 is a schematic configuration diagram of a steam inlet structure of a low-pressure steam turbine in a conventional nuclear power plant.
The steam inlet structure 61 of the low-pressure steam turbine 58 in the nuclear power plant includes a merging portion 63b where two crossover pipes 62 merge at the upper portion of the low-pressure steam turbine 58, and a merging tube communicating between the merging portion 63b and the low-pressure steam turbine 58. A T-tube 63 formed from 63a is arranged. Thereby, the steam from the moisture separator / heater 60 flowing through each of the two crossover pipes 62 joins at the joining part 63b and is supplied to the low-pressure steam turbine 58 through the joining pipe 63a.

The crossover pipe 62 is provided with an adjusting valve 80 and a stop valve 82.
The control valve 80 is for adjusting the amount of steam flowing in the crossover pipe 62, and the stop valve 82 is for blocking the crossover pipe 62.

  Here, when the low-pressure steam turbine 58 is suddenly stopped, the low-pressure steam turbine 58 may be overspeeded due to overspeed unless the steam supply to the low-pressure steam turbine 58 is stopped immediately. In order to prevent overspeed, it is necessary to arrange the regulating valve 80 and the stop valve 82 near the low-pressure steam turbine 58 to reduce the inflow amount of the super-speed steam into the low-pressure steam turbine 58. Therefore, conventionally, the adjusting valve 80 and the stop valve 82 are installed as butterfly valves in the crossover pipe 62 as close to the low-pressure steam turbine 58 as possible.

  As another technique related to the low-pressure steam turbine inlet portion, Patent Document 1 discloses a technique for supplying steam separately from two steam introduction pipes (crossover pipes) to the low-pressure steam turbine.

JP 2010-48216 A

  By the way, in recent years, with the enlargement of nuclear power plants, the enlargement of the low-pressure steam turbine 58 has progressed. When the low-pressure steam turbine 58 becomes large, the crossover pipe 62 for supplying steam to the low-pressure steam turbine 58 also needs to be enlarged. When the crossover pipe 62 is increased in size, it is necessary to increase the size of the adjusting valve 80 and the stop valve 82 provided in the crossover pipe 62. Since the adjusting valve 80 and the stop valve 82 are provided in the crossover pipe 62 as a butterfly valve in order to be provided at a position close to the low-pressure steam turbine 58 as described above, if the valves are increased in size, the operation time is increased accordingly. Overspeed may occur. Further, when the control valve 80 and the stop valve 82 are increased in size, the position of each valve becomes far from the low-pressure steam turbine 58, which may cause overspeed.

  Further, in the steam inlet structure 61 shown in FIG. 5, four large butterfly valves are necessary and the number of parts is large. Furthermore, the stop valve 82 is located at a location where the distance from the low-pressure steam turbine 58 is farther away from the low-pressure steam turbine 58 and the position thereof is not above the low-pressure steam turbine 58 as the regulating valve 80 becomes larger. In this case, a scaffold 84 for checking the control valve 80 and the stop valve 82 must be provided separately from the steam turbine 58, which increases the cost of the entire plant.

  In the steam inlet structure 61 shown in FIG. 5, the steam supplied to the low-pressure steam turbine 58 through the crossover pipe 62 is added to the T-shaped pipe 63 in addition to the pressure loss at the stop valve 82 and the regulating valve 80. Suffers pressure loss at Therefore, the steam suffers a large pressure loss until it is supplied to the low-pressure steam turbine 58, and the pressure loss hinders performance improvement of the low-pressure steam turbine 58.

Accordingly, the present invention is related view of the prior art problems, while reducing the pressure loss of the steam supplied to the low pressure steam turbine, to provide a steam inlet structure of the low-pressure steam turbine can be prevented Overspeed Objective.

In order to solve the above problems, the first aspect of the present invention, there is provided a steam inlet structure of the low-pressure steam turbine for supplying gas steam within the low-pressure steam turbine, the two crossover tube steam flows A merging portion where two crossover pipes merge, a T-shaped tube composed of the merging portion and a merging pipe communicating with the inside of the low-pressure steam turbine, and an adjusting valve provided in the merging pipe The T-shaped tube is provided above the low-pressure steam turbine, and the adjusting valve is a plug valve.
Moreover, in the second aspect of the present invention, there is provided a steam inlet structure of a low pressure steam turbine for supplying steam heated by the moisture separation heater to the inside of the low pressure steam turbine, the steam from the moisture separation heater. A T-shaped pipe composed of two crossover pipes through which the two crossover pipes circulate, a merging section where the two crossover pipes merge, a merging pipe communicating with the merging section and the inside of the low-pressure steam turbine, and the merging pipe The T-tube is provided above a low-pressure steam turbine, and the adjusting valve is a plug valve.

  By providing an adjusting valve in the junction pipe constituting the T-shaped tube, the position of the adjusting valve can be made closer to the low-pressure steam turbine. As a result, overspeed can be prevented. Further, by providing the adjusting valve not in the crossover pipe but in the T-shaped pipe, it is possible to make a plug valve having a high operating speed instead of a butterfly valve having a low operating speed. As a result, overspeed can be prevented more reliably.

  Further, since the position of the adjusting valve can be made close to the low-pressure steam turbine, a check scaffold for checking the adjusting valve can be a simple scaffold provided on the outer periphery of the low-pressure steam turbine. Therefore, the cost related to the check valve scaffold can be kept small, and the cost related to the entire plant can be kept small.

  Further, when the adjusting valve is provided as a plug valve in the T-shaped tube and the adjusting valve is fully opened, the pressure loss received by the steam supplied to the low-pressure steam turbine by the T-shaped tube is substantially equal to the pressure loss received by the conventional T-shaped tube. . Therefore, the pressure loss of the steam supplied to the low-pressure steam turbine can be reduced by an amount corresponding to the pressure loss received by the conventional control valve (butterfly valve).

Moreover, it is good to provide a stop valve in the crossover pipe | tube upstream of the said steam flow rather than the junction part of the said T-shaped pipe.
As a result, the crossover pipe can be shut off more reliably when the low-pressure steam turbine is stopped.

The stop valve may be located above the low pressure steam turbine.
As a result, the check valve check scaffold can be a simple scaffold provided on the outer periphery of the low-pressure steam turbine. Therefore, the cost for the check valve check scaffold can be kept small, and the cost can be kept small by providing the stop valve.

While reducing the pressure loss of the steam supplied to the low pressure steam turbine, you are possible to provide a steam inlet structure of the low-pressure steam turbine capable of preventing overspeed.

It is the schematic of the nuclear power plant to which the steam inlet structure of the low pressure steam turbine of an Example is applied. It is a schematic block diagram of the steam inlet structure of the low pressure steam turbine at the time of full opening of the regulating valve in the nuclear power plant according to the embodiment. It is a schematic block diagram of the steam inlet structure of the low pressure steam turbine at the time of full closing of the regulating valve in the nuclear power plant according to the embodiment. It is a perspective view of the low pressure steam turbine vicinity in a nuclear power plant. It is a schematic block diagram of the steam inlet structure of the low pressure steam turbine in the conventional nuclear power plant.

  Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the drawings. However, the dimensions, materials, shapes, relative arrangements, and the like of the components described in this embodiment are not intended to limit the scope of the present invention unless otherwise specified, but are merely illustrative examples. Not too much.

First, an outline of a nuclear power plant to which a steam inlet structure of a low-pressure steam turbine of the present invention is applied will be described based on FIG.
FIG. 1 is a schematic view of a nuclear power plant to which the steam inlet structure of the low-pressure steam turbine of the embodiment is applied. The nuclear power plant shown in FIG. 1 includes a steam generator 52 for taking out thermal energy generated in a nuclear reactor as steam. The steam generated by the steam generator 52 is sent to the high-pressure steam turbine 56 through the main steam pipe 54. The steam sent to the high-pressure steam turbine 56 drives the high-pressure steam turbine 56, is heated by the moisture separation heater 60, and is sent to the low-pressure steam turbine 58 through the crossover pipe 62.

  The rotating shaft of the generator 64 is connected to the turbine shaft of the low-pressure steam turbine 58, and the steam sent to the low-pressure steam turbine 58 drives the low-pressure steam turbine 58, and then is converted from steam to water (hereinafter referred to as water) by the condenser 66. , Called condensate). A suction port of a condensate pump 68 is connected to the condenser 66 via a condensate pump inlet pipe 70, and the condensate is boosted by the condensate pump 68 and then supplied to the low-pressure feed water heater 72. .

  The condensate supplied to the low-pressure feed water heater 72 is heated by the low-pressure feed water heater 72 and then sent to the high-pressure feed water heater 76 by the feed water pump 74. The condensed water heated by the high-pressure feed water heater 76 is supplied to the steam generator 52.

Next, based on FIG. 2, FIG. 3, the steam inlet structure of the low pressure steam turbine in an Example is demonstrated.
Here, in the nuclear power plant in the embodiment, two moisture separation heaters 60 are provided as in the conventional nuclear power plant shown in FIG. Is arranged beside the low-pressure steam turbine 58.

FIG. 2 is a schematic configuration diagram of the steam inlet structure of the low-pressure steam turbine when the adjusting valve is fully opened in the nuclear power plant according to the embodiment. Moreover, FIG. 3 is a schematic block diagram of the steam inlet structure of the low pressure steam turbine when the regulating valve is fully closed in the nuclear power plant according to the embodiment.
The steam inlet structure 11 of the low-pressure steam turbine 58 in the nuclear power plant includes a merging portion 13b where two crossover pipes 62 merge at the upper portion of the low-pressure steam turbine 58, and a merging tube communicating between the merging portion 13b and the low-pressure steam turbine 58. A T-shaped tube 13 formed from 13a is disposed. Thereby, the steam from the moisture separator / heater 60 flowing through each of the two crossover pipes 62 joins at the joining part 13b and is supplied to the low-pressure steam turbine 58 through the joining pipe 13a.

  The T-shaped tube 13 is provided with an adjusting valve 30. The adjusting valve 30 is a plug valve, and includes a plug 30a and a support shaft 30b. The adjusting valve 30 passes through the T-shaped tube 13 by adjusting the distance between the plug 30a and the valve seat 13c, which is a part of the wall surface forming the joining tube 13a, by moving the support shaft 30b in the vertical direction. Thus, the amount of steam supplied to the low-pressure steam turbine 58 can be adjusted.

  The two crossover pipes 62 are each provided with a stop valve 32. The stop valve 30 is a butterfly valve. The stop valve 30 is provided as close to the T-shaped tube 13 as possible and above the low-pressure steam turbine 58.

  In the above configuration, when the nuclear power plant shown in FIG. 1 is operated, the control valve 30 and the stop valve 32 are opened. When the nuclear power plant is operated, the steam heated by the moisture separator / heater 60 flows in the direction of the T-tube 13 through the crossover pipe 62. The steam that has flowed in the direction of the T-shaped tube 13 is supplied to the low-pressure steam turbine 58 via the T-shaped tube 13 as shown by a in FIG.

  In order to stop the low-pressure steam turbine 58, first, the low-pressure steam turbine 58 is disconnected from the generator 64, and the control valve 30 is fully closed and the stop valve 32 is closed. Thereby, when the control valve 30 as shown in FIG. 3 is fully closed, the steam in the crossover pipe 62 is not supplied to the low-pressure steam turbine 58. Further, since the adjusting valve 30 is a plug valve, the operation time is fast and no overspeed occurs. Further, the crossover pipe can be more reliably shut off by closing the stop valve 32.

  According to the present embodiment, the control valve 30 and the stop valve 32 can be positioned closer to the low-pressure steam turbine 58 by providing the control valve 30 in the T-shaped tube 13. As a result, overspeed can be prevented. Furthermore, by providing the adjusting valve 30 not in the crossover pipe 62 but in the T-shaped pipe 13, it is possible to make a plug valve having a high operating speed instead of a butterfly valve having a low operating speed. As a result, overspeed can be prevented more reliably.

  Further, since the position of the adjusting valve 30 and the stop valve 32 can be made closer to the low-pressure steam turbine 58 than in the prior art, a check scaffold for the adjusting valve 30 and the stop valve 32 is shown in FIGS. A simple scaffold 34 provided on the outer periphery of the low-pressure steam turbine 58 can be provided. Therefore, the cost relating to the inspection scaffold for the adjusting valve 30 and the stop valve 32 can be kept small, and the cost relating to the entire plant can be kept small.

  Furthermore, when the regulating valve 30 is provided as a plug valve in the T-shaped tube 13 and the regulating valve 30 is fully opened, the pressure loss received by the steam supplied to the low-pressure steam turbine by the T-shaped tube 13 is the pressure loss received by the conventional T-shaped tube 63. It is almost equivalent. Conventionally, the steam supplied to the low-pressure steam turbine 30 has been subjected to pressure loss at the stop valve 82, the adjusting valve 80, and the T-shaped pipe 63. In this embodiment, the steam supplied to the low-pressure steam turbine 30 is only subjected to pressure loss at the stop valve 32 and the T-shaped tube 13, and the pressure loss corresponding to the pressure loss conventionally received by the adjusting valve 80 is reduced. can do. That is, the pressure loss of the steam supplied to the low-pressure steam turbine via the crossover pipe 62 can be reduced.

While reducing the pressure loss of the steam supplied to the low pressure steam turbine can be utilized as a steam inlet structure of the low-pressure steam turbine capable of preventing overspeed.

DESCRIPTION OF SYMBOLS 11 Steam inlet structure 13 T-shaped pipe 13a Merge pipe 13b Merge part 30 Control valve 32 Stop valve 58 Low pressure steam turbine 60 Moisture separation heater 62 Crossover pipe

Claims (4)

The air steam a steam inlet structure of the low-pressure steam turbine to be supplied to the internal low-pressure steam turbine,
Two of the crossover tube steam flows,
A T-shaped pipe composed of a merge section where two crossover pipes merge, and a merge pipe communicating with the merge section and the inside of the low-pressure steam turbine;
An adjusting valve provided in the junction pipe, and the T-shaped pipe is provided above the low-pressure steam turbine,
A steam inlet structure for a low-pressure steam turbine, wherein the control valve is a plug valve. A steam inlet structure of a low-pressure steam turbine that supplies steam heated by a moisture separator and heater to the inside of the low-pressure steam turbine,
Two crossover tubes through which steam from the moisture separator heater flows;
A T-shaped pipe composed of a merge section where two crossover pipes merge, and a merge pipe communicating with the merge section and the inside of the low-pressure steam turbine;
An adjusting valve provided in the junction pipe,
The T-tube is provided above the low-pressure steam turbine,
A steam inlet structure for a low-pressure steam turbine, wherein the control valve is a plug valve . The steam inlet structure for a low-pressure steam turbine according to claim 1 or 2, wherein a stop valve is provided in the crossover pipe on the upstream side of the steam flow with respect to the joining portion of the T-shaped pipe . The steam inlet structure of a low-pressure steam turbine according to claim 3, wherein the stop valve is located above the low-pressure steam turbine.