JP2013053569A - Steam turbine facility - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide steam turbine facility that recovers energy in exhaust steam and keeps the pressure in a gland seal steam receiver within a predetermined pressure range.SOLUTION: The steam turbine facility includes: a spill steam pipe 52 which guides steam in the gland seal steam receiver 51 to a spill steam condenser 44; an exhaust pipe 61 which guides the steam in the gland seal steam receiver 51 to a main condenser 37; and a controller which outputs a control signal for opening/closing a spill steam control valve 63 provided in the middle of the spill steam pipe 52 and an exhaust valve 64 for adjusting pressure of the gland seal steam receiver, provided in the middle of the exhaust pipe 61, to the spill steam control valve 63 and the exhaust valve 64 for adjusting the pressure of the gland seal steam receiver, to keep the pressure in the gland seal steam receiver 51 within the predetermined pressure range.

Description

  The present invention relates to, for example, a steam turbine facility mounted on a ship equipped with at least one propeller.

  As the steam turbine equipment, for example, the one disclosed in Patent Document 1 is known.

Japanese Patent Laid-Open No. 11-93611

  Now, in what was disclosed by FIG. 2 of patent document 1, when the load of a turbine raises and the vapor | steam leaking from the high voltage | pressure side gland | grand | ground part 7 comes to exceed the sealing steam required in the low voltage | pressure side gland | grand | ground part 8, The supply valve 4 is fully closed and the discharge valve 6 is fully opened. Excess leakage steam is discharged through the discharge valve 6 and led to a condenser to be condensed. Therefore, in what was disclosed by FIG. 2 of patent document 1, there existed a problem that the energy which the discharge | evaporation vapor | steam discharge | released to the condenser via the discharge valve 6 was thrown away was wasted.

  Therefore, as a solution to such a problem, the one disclosed in FIG. 1 of Patent Document 1, that is, the exhaust valve 6 is configured to communicate with the turbine low pressure stage below the steam receiver pressure, and the gland seal portion is configured. In this case, the exhaust steam that becomes surplus in the exhaust gas and flows downstream through the exhaust valve 6 is introduced into the turbine low-pressure stage, so that the energy held by the exhaust steam is recovered as turbine rotational energy without being wasted, and the output of the turbine. What improved (performance improvement) is known.

  However, in the one disclosed in FIG. 1 of Patent Document 1, in order to keep the inside of the gland seal steam receiver 5 in a predetermined steam receiver pressure range (for example, 0.1078 MPa to 0.1177 MPa), When the discharge valve 6 is opened and closed in response to the above, if the discharge valve 6 is fully open and the pressure in the gland seal steam receiver 5 tends to increase thereafter, the pressure in the gland seal steam receiver 5 is maintained at a predetermined pressure. There was a problem that it was impossible.

  The present invention has been made to solve the above-described problems, and is a steam turbine facility that can recover the energy held by the exhaust steam and can maintain the inside of the gland seal steam receiver in a predetermined pressure range. The purpose is to provide.

The present invention employs the following means in order to solve the above problems.
A steam turbine facility according to the present invention is a steam turbine facility including a ground seal steam receiver that communicates with a high-pressure side gland part and a low-pressure side gland part of the steam turbine, and recovers heat from the steam in the gland seal steam receiver. A spill steam pipe leading to a spill steam condenser installed for the purpose, or a ground seal steam communication pipe leading to a turbine low pressure stage which is lower than the steam receiver pressure of the steam turbine, and steam in the ground seal steam receiver And an spill steam control valve provided in the middle of the spill steam pipe or in the middle of the ground seal steam communication pipe so as to keep the inside of the ground seal steam receiver in a predetermined pressure range. Gland seal steam discharge valve and gland seal provided in the middle of the exhaust pipe A controller that outputs a control signal for opening / closing a discharge valve for adjusting the steam receiver pressure of the steam receiver to the spill steam control valve, or the ground seal steam discharge valve, and the discharge valve for adjusting the pressure of the ground seal steam receiver. ing.

According to the steam turbine equipment according to the present invention, the steam in the gland seal steam receiver becomes a spill steam condenser through the spill steam pipe or the steam receiver pressure of the steam turbine through the gland seal steam communication pipe. The stored energy is recovered by being guided to the low pressure stage.
In addition, the spill steam control valve provided in the middle of the spill steam pipe or the gland seal steam discharge valve provided in the middle of the gland seal steam communication pipe is fully opened, and thereafter the pressure in the gland seal steam receiver tends to increase. Even if there is, the steam in the gland seal steam receiver is released to the main condenser by opening the discharge valve for adjusting the pressure of the gland seal steam receiver provided in the middle of the exhaust pipe.
As a result, the energy held by the exhaust steam can be recovered, and the inside of the gland seal steam receiver can be kept in a predetermined pressure range.

  In the steam turbine equipment, it is more preferable that the discharge valve for adjusting the pressure of the ground seal steam receiver is opened and closed when the spill steam control valve or the ground seal steam discharge valve is fully opened.

According to such steam turbine equipment, the spill steam control valve or gland seal steam discharge valve is fully closed until the spill steam control valve or gland seal steam discharge valve is fully opened, and the spill steam control valve or gland seal valve is completely closed. The discharge valve for adjusting the pressure of the gland seal steam receiver is opened only when the pressure in the gland seal steam receiver tends to increase after the steam discharge valve is fully opened.
As a result, the energy held by the exhaust steam can be recovered to the maximum, and the output (performance) of the steam plant or steam turbine can be further improved.

  In the steam turbine facility, it is more preferable that the spill steam condenser and the main condenser are communicated via a vent line.

According to such steam turbine equipment, the inside of the spill steam condenser is held at a lower pressure than in the gland seal steam receiver.
Thereby, it is possible to prevent the flow of steam from the ground seal steam receiver to the spill steam condenser from changing (being easy to flow or difficult to flow) depending on the load of the steam turbine.

  A ship according to the present invention includes any one of the steam turbine facilities described above.

  According to the ship according to the present invention, the steam turbine equipment capable of recovering the energy held by the exhaust steam and maintaining the gland seal steam receiver in a predetermined pressure range is provided. The heat recovery rate of the ship can be improved, and the reliability of the ship can be improved.

  The operation method of the steam turbine equipment according to the present invention includes a ground seal steam receiver communicating with the high pressure side gland part and the low pressure side gland part of the steam turbine, and the steam in the gland seal steam receiver is installed for heat recovery. A spill steam pipe leading to a spill steam condenser, or a ground seal steam communication pipe leading to a turbine low pressure stage which is lower than the steam receiver pressure of the steam turbine, and an exhaust pipe leading the steam in the ground seal steam receiver to the main condenser A spill steam control valve provided in the middle of the spill steam pipe so as to keep the inside of the gland seal steam receiver in a predetermined pressure range, or the gland seal. A gland seal steam discharge valve provided in the middle of the steam communication pipe, and the exhaust pipe The gland seal steam receivers pressure regulating outlet valve provided in the so as to open and close operations.

According to the operation method of the steam turbine equipment according to the present invention, the steam in the gland seal steam receiver is below the steam receiver pressure of the steam turbine through the spill steam pipe to the spill steam condenser or through the gland seal steam communication pipe. Then, the stored energy is recovered by being guided to the turbine low pressure stage.
In addition, the spill steam control valve provided in the middle of the spill steam pipe or the gland seal steam discharge valve provided in the middle of the gland seal steam communication pipe is fully opened, and thereafter the pressure in the gland seal steam receiver tends to increase. Even if there is, the steam in the gland seal steam receiver is released to the main condenser by opening the discharge valve for adjusting the pressure of the gland seal steam receiver provided in the middle of the exhaust pipe.
As a result, the energy held by the exhaust steam can be recovered, and the inside of the gland seal steam receiver can be kept in a predetermined pressure range.

  In the operation method of the steam turbine equipment, it is more preferable that the discharge valve for adjusting the pressure of the gland seal steam receiver is opened and closed while the spill steam control valve or the gland seal steam discharge valve is fully opened.

According to such an operation method of the steam turbine equipment, the spill steam control valve or the gland seal steam discharge valve is fully opened, the gland seal steam receiver pressure adjustment discharge valve is fully closed, the spill steam control valve, Alternatively, the gland seal steam receiver pressure adjusting discharge valve is opened only when the gland seal steam discharge valve is fully opened and the pressure in the gland seal steam receiver tends to increase thereafter.
As a result, the energy held by the exhaust steam can be recovered to the maximum, and the output (performance) of the steam turbine can be further improved.

  According to the steam turbine equipment according to the present invention, it is possible to recover the energy held by the exhaust steam and to maintain the gland seal steam receiver in a predetermined pressure range.

It is a figure which shows the principal part of the steam turbine equipment which concerns on 1st Embodiment of this invention, Comprising: It is a systematic diagram of ground steam. (A) is a chart showing the relationship between the valve opening of the auxiliary steam supply valve and the control signal, (b) is a spill steam control valve, or a gland seal steam discharge valve, and a gland seal steam receiver pressure adjustment valve It is a graph which shows the relationship between an opening degree and a control signal. It is a schematic structure figure of the steam turbine equipment concerning a 1st embodiment of the present invention. It is a figure which shows the principal part of the steam turbine equipment which concerns on 2nd Embodiment of this invention, Comprising: It is a systematic diagram of ground steam.

[First Embodiment]
Hereinafter, the steam turbine equipment according to the first embodiment of the present invention will be described with reference to FIGS. 1 to 3.
FIG. 1 is a diagram showing a main part of the steam turbine equipment according to the present embodiment, and is a system diagram of ground steam. FIG. 2A is a chart showing the relationship between the opening degree of the auxiliary steam supply valve and the control signal. 2 (b) is a chart showing the relationship between the opening degree of the spill steam control valve, the gland seal steam discharge valve, and the gland seal steam receiver pressure adjustment discharge valve and the control signal, and FIG. 3 shows the present embodiment. It is a schematic block diagram of the steam turbine equipment which concerns.

  As shown in FIG. 3, the steam turbine equipment 1 according to the present embodiment is a marine main engine steam turbine equipment used for propulsion of a ship such as an LNG ship. The steam turbine facility 1 includes a steam turbine 2 as a main engine, a speed reducer (drive transmission means) (not shown), and a propeller (propulsion unit) (not shown).

  The steam turbine 2 is, for example, a reheat three-pressure steam turbine used as a main power machine of the steam turbine equipment 1, and includes a high-pressure turbine (hereinafter referred to as “HP turbine”) 21 and an intermediate-pressure turbine (hereinafter referred to as “ "IP turbine") 22, a low pressure turbine (hereinafter referred to as "LP turbine") 23, a generator turbine (hereinafter referred to as "GEN turbine") 24, and a reverse turbine (AST turbine) not shown. And a reheater 25.

The main steam from the main boiler 32 is supplied to the HP turbine 21 and the GEN turbine 24 via the main steam pipe 31, respectively, whereby the HP turbine 21 and the GEN turbine 24 are rotationally driven.
The reheater 25 is disposed between the HP turbine 21 and the IP turbine 22, and heats the steam exhausted from the HP turbine 21 (low temperature) and guided through the reheat steam pipe 33. The steam heated by the reheater 25 is supplied to the IP turbine 22 via the (hot) reheat steam pipe 34.

  The IP turbine 22 is supplied with reheated steam heated by the reheater 25, and thereby the IP turbine 22 is rotationally driven. The IP turbine 22 and the HP turbine 21 are provided on a common first shaft 26. The function of the IP turbine 22 may be considered as a part of the LP turbine 23, but it is coaxial with the HP turbine 21 instead of the LP turbine 23 for the purpose of equalizing the restrictions on arrangement and the load sharing transmitted to the speed reducer. Deployed above.

The LP turbine 23 is supplied with the steam exhausted from the IP turbine 22 and guided through the steam pipe 35, and thereby the LP turbine 23 is rotationally driven. The steam exhausted from the LP turbine 23 and the GEN turbine 24 and led to the main condenser 37 via the (first) exhaust pipe 36 is condensed in the main condenser 37 and becomes condensate.
The AST turbine is used when the ship moves backward, and main steam from the main boiler 32 is directly supplied via a reverse main steam pipe (not shown) branched from the middle of the main steam pipe 31, thereby rotating the AST turbine. It is designed to be driven. Further, the AST turbine and the LP turbine are provided on a common second shaft (not shown).

  The above-described first shaft 26 and the second shaft are connected as input shafts to the speed reducer, and a main shaft (drive transmission means) (not shown) is connected to the output side of the speed reducer. Further, a propeller is connected to the main shaft, and the propeller is rotated by the main shaft. And the propulsive force of a ship is obtained by rotation of this propeller.

  In addition, the code | symbol 41 in FIG. 3 is a water supply pipe which guides the condensate condensed with the main condenser 37 to the main boiler 32. FIG. In the middle of the water supply pipe 41, a main condensate pump 42, a ground condenser 43, a spill steam condenser 44, from the upstream side (the main condenser 37 side) toward the downstream side (the main boiler 32 side), (First stage) A feed water heater 45, a dearator (deaeration feed water heater) 46, a main feed water pump 47, and an economizer (a economizer) 48 are provided.

Leaked steam (ground exhaust) from the turbine gland part or the like is guided to the ground condenser 43, and the leaked steam led from the turbine gland part or the like exchanges heat with condensate (feed water) passing through the inside of the ground condenser 43. And the condensate is warmed.
The spill steam condenser 44 is guided by spill steam from a gland (packing) seal steam receiver 51 through a spill steam pipe 52, and the spill steam guided from the ground seal steam receiver 51 passes through the spill steam condenser 44. Heat is exchanged with the condensate, and the condensate is warmed.

  Here, when the steam turbine 2 (more specifically, the HP turbine 21, the IP turbine 22, and the LP turbine 23) is stopped and at a low load, as shown in FIG. The ground seal steam (auxiliary steam) is supplied from the steam supply source to the gland seal steam receiver 51 via the auxiliary steam supply pipe 57. An auxiliary steam supply valve 58 is provided in the middle of the auxiliary steam supply pipe 57.

Steam fed from the middle stage of the LP turbine 23 and steam drain taken from the middle stage of the IP turbine 22 and heat-exchanged by the air heater (air preheater) 53 are guided to the feed water heater 45. The steam guided to the feed water heater 45 is heat-exchanged with the condensate passing through the feed water heater 45 to warm the condensate.
A part of the steam taken out from the intermediate stage of the IP turbine 22 and guided to the air heater 53 is guided to the deaerator 46, and the steam guided to the deaerator 46 degass the condensate passing through the interior of the dearator 46. It promotes and exchanges heat to warm the condensate.

  Drain generated as a result of heat exchange by the ground condenser 43, the spill steam condenser 44, and the feed water heater 45 is guided to an atom drain tank 54, and the drain accumulated in the atom drain tank 54 is fed to the feed water heater 45 and the deaerator. The water supply pipe 41 located between the feed water heater 45 and the delator 46 via the drain pipe 55 connected to the water supply pipe 41 located between the water supply pipe 46 and the drain pump 56 provided in the middle of the drain pipe 55. To the condensate flowing through the water supply pipe 41.

As shown in FIGS. 1 and 3, the steam turbine equipment 1 according to the present embodiment includes a spill steam pipe 52 that guides spill steam from the ground seal steam receiver 51 to the spill steam condenser 44, and a ground seal steam receiver 51. (Second) exhaust pipe 61 that guides the steam exhausted from the main condenser 37. In the middle of the spill steam pipe 52 and the exhaust pipe 61, a spill steam control valve 63 and a ground seal that are opened and closed according to a valve opening / closing signal (control signal: command signal) output from the controller 62 (see FIG. 1). A steam receiver pressure adjusting discharge valve 64 is provided.
Further, the spill steam condenser 44 and the main condenser 37 are communicated with each other via a vent line 65, and the spill steam condenser 44 is held at a lower pressure than the ground seal steam receiver 51. An orifice 66 is provided in the middle of the vent line 65.

The gland seal steam receiver 51 is provided with a pressure sensor PT that measures the pressure in the gland seal steam receiver 51, converts the pressure into an electric signal, and outputs the electric signal. Data measured by the pressure sensor PT is output to the controller 62, and the controller 62 opens and closes the auxiliary steam supply valve 58, the spill steam control valve 63, and the ground seal steam receiver pressure adjusting discharge valve 64. Converted to a valve opening / closing signal. A valve opening / closing signal (4-20 mA electric signal in this embodiment) output from the controller 62 is transmitted to the auxiliary steam supply valve 58, the spill steam control valve 63, and the ground seal steam receiver pressure adjusting discharge valve 64, respectively. The The auxiliary steam supply valve 58, the spill steam control valve 63, and the gland seal steam receiver pressure adjusting discharge valve 64 each keep the gland seal steam receiver 51 in a predetermined pressure range (for example, 0.1078 MPa to 0.1177 MPa). As described above, the opening / closing operation is performed in accordance with the valve opening / closing signal output from the controller 62.
In addition, the code | symbol 3 in FIG. 1 shows the high voltage | pressure side ground part, and the code | symbol 4 has shown the low voltage | pressure side ground part.

  Here, in this embodiment, as shown in FIG. 2A, the auxiliary steam supply valve 58 has the steam turbine 2 (more specifically, the HP turbine 21, the IP turbine 22, and the LP turbine 23) stopped. At the time of load and low load, an electric signal of 4 mA is sent from the controller 62 to be fully opened (valve opening degree 100%), and when rated operation is being performed (no supply of ground seal steam from outside the system is required) ), An electric signal of 20 mA is sent from the controller 62 to be fully closed (valve opening degree 0%).

  On the other hand, as shown by the solid line in FIG. 2B, the spill steam control valve 63 is used when the steam turbine 2 (more specifically, the HP turbine 21, the IP turbine 22, and the LP turbine 23) is stopped and at a low load. The valve open / close signal output from the controller 62 during the rated operation (when the supply of gland seal steam from outside the system is not required) In the embodiment, the electric signal is opened and closed in a range from fully closed to fully open based on 4-20 mA electric signal). When the steam turbine 2 (more specifically, the HP turbine 21, the IP turbine 22, and the LP turbine 23) is in rated operation, the spill steam control valve 63 receives an electric signal of 4 mA from the controller 62. When the electric signal of 12-20 mA is sent, it is fully opened.

  Further, the discharge valve 64 for adjusting the gland seal steam receiver pressure stops the steam turbine 2 (more specifically, the HP turbine 21, the IP turbine 22, and the LP turbine 23) as shown by a one-dot chain line in FIG. The valve opening / closing signal (from the controller 62) is output when the valve is fully closed (valve opening degree 0%) when the engine is running and when the load is low, the rated operation is performed, and the spill steam control valve 63 is fully opened. In this embodiment, it is opened and closed in the range from fully closed to fully open based on 4-20 mA electric signal). When the steam turbine 2 (more specifically, the HP turbine 21, the IP turbine 22, and the LP turbine 23) is rated and the spill steam control valve 63 is fully open, the discharge for adjusting the pressure of the ground seal steam receiver is performed. The valve 64 is fully closed when an electric signal of 4-12 mA is sent from the controller 62, and is fully opened when an electric signal of 20 mA is sent.

According to the steam turbine equipment 1 and the operation method of the steam turbine equipment 1 according to the present embodiment, the steam in the gland seal steam receiver 51 is guided to the spill steam condenser 44 via the spill steam pipe 52 and stored. Will be recovered.
Further, even if the spill steam control valve 63 provided in the middle of the spill steam pipe 52 is fully opened and the pressure in the gland seal steam receiver 51 tends to increase thereafter, the spill steam control valve 63 is provided in the middle of the exhaust pipe 61. By opening the discharge valve 64 for adjusting the pressure of the gland seal steam receiver, the steam in the gland seal steam receiver 51 is released to the main condenser 37.
As a result, the energy held by the exhaust steam can be recovered, and the inside of the gland seal steam receiver 51 can be maintained within a predetermined pressure range.

Moreover, according to the steam turbine equipment 1 and the operation method of the steam turbine equipment 1 according to the present embodiment, the gland seal steam receiver pressure adjusting discharge valve 64 is fully closed until the spill steam control valve 63 is fully opened, Only when the spill steam control valve 63 is fully opened and the pressure in the gland seal steam receiver 51 tends to increase thereafter, the gland seal steam receiver pressure adjusting discharge valve 64 is opened.
Thereby, the energy which exhaust steam has can be collect | recovered to the maximum, and the output (performance) of the steam turbine 2 can further be improved.

Furthermore, according to the steam turbine equipment 1 according to the present embodiment, the inside of the spill steam condenser 44 is held at a lower pressure than the inside of the gland seal steam receiver 51 by the vent line 65.
Thereby, it is possible to prevent the steam flow from the ground seal steam receiver 51 to the spill steam condenser 44 from changing (being easy to flow or difficult to flow) due to the load of the steam turbine 2.

  On the other hand, according to the ship (not shown) according to the present invention, the steam turbine equipment capable of recovering the energy held by the exhaust steam and maintaining the gland seal steam receiver 51 in a predetermined pressure range. 1 is provided, the heat recovery rate of the ship can be improved, and the reliability of the ship can be improved.

[Second Embodiment]
A steam turbine facility according to a second embodiment of the present invention will be described with reference to FIG.
FIG. 4 is a diagram showing a main part of the steam turbine equipment according to the present embodiment, and is a system diagram of ground steam.

In the steam turbine equipment 81 according to the present embodiment, the spill steam condenser 44 is omitted, and a ground seal steam communication pipe 82 and a ground seal steam discharge valve 83 are provided instead of the spill steam pipe 52 and the spill steam control valve 63. This is different from the first embodiment described above. Since other components are the same as those of the first embodiment described above, description of these components is omitted here.
In addition, the same code | symbol is attached | subjected to the member same as 1st Embodiment mentioned above.

  As shown in FIG. 4, the gland seal steam communication pipe 82 is connected from the gland seal steam receiver 51 to the intermediate stage of the turbine of the HP turbine 21 (turbine low pressure stage lower than the steam receiver pressure), and the intermediate stage of the turbine of the IP turbine 22 (atmospheric pressure). Turbine low-pressure stage), and pipes for guiding the ground seal steam to the turbine intermediate stage of the LP turbine 23 (turbine low-pressure stage at atmospheric pressure or lower). A gland seal steam discharge valve 83 that is opened and closed in response to a valve opening / closing signal (control signal: command signal) output from the controller 62 is provided in the middle of the gland seal steam communication pipe 82.

  Here, in this embodiment, as shown in FIG. 2A, the auxiliary steam supply valve 58 has the steam turbine 2 (more specifically, the HP turbine 21, the IP turbine 22, and the LP turbine 23) stopped. At the time of load and low load, an electric signal of 4 mA is sent from the controller 62 to be fully opened (valve opening degree 100%), and when rated operation is being performed (no supply of ground seal steam from outside the system is required) ), An electric signal of 20 mA is sent from the controller 62 to be fully closed (valve opening degree 0%).

  On the other hand, as shown by the solid line in FIG. 2B, the gland seal steam discharge valve 83 is low when the steam turbine 2 (more specifically, the HP turbine 21, the IP turbine 22, and the LP turbine 23) is stopped. The valve open / close signal output from the controller 62 when the load is fully closed (the valve opening is 0%) and the rated operation is being performed (when the supply of gland seal steam from outside the system is not required) In the embodiment, it is opened and closed in a range from fully closed to fully open based on 4-20 mA electric signal). In addition, when the steam turbine 2 (more specifically, the HP turbine 21, the IP turbine 22, and the LP turbine 23) is in rated operation, the grand seal steam discharge valve 83 receives an electric signal of 4 mA from the controller 62. Then, it is fully closed, and when a 12-20 mA electric signal is sent, it is fully opened.

  Further, the discharge valve 64 for adjusting the gland seal steam receiver pressure stops the steam turbine 2 (more specifically, the HP turbine 21, the IP turbine 22, and the LP turbine 23) as shown by a one-dot chain line in FIG. The valve opening / closing signal output from the controller 62 when the valve is fully closed (valve opening degree 0%) when the engine is running or when the load is low, the rated operation is performed, and the gland seal steam discharge valve 83 is fully opened. Based on (in this embodiment, an electric signal of 4-20 mA), it is opened and closed in a range from fully closed to fully open. When the steam turbine 2 (more specifically, the HP turbine 21, the IP turbine 22, and the LP turbine 23) is rated and the gland seal steam discharge valve 83 is fully open, the gland seal steam receiver pressure is adjusted. The discharge valve 64 is fully closed when an electric signal of 4-12 mA is sent from the controller 62, and is fully opened when an electric signal of 20 mA is sent.

According to the steam turbine equipment 81 and the operation method of the steam turbine equipment 81 according to the present embodiment, the steam in the gland seal steam receiver 51 becomes equal to or lower than the steam receiver pressure of the steam turbine 2 through the gland seal steam communication pipe 82. The stored energy is recovered by being guided to the turbine low pressure stage.
Even if the gland seal steam discharge valve 83 provided in the middle of the gland seal steam communication pipe 82 is fully opened and the pressure in the gland seal steam receiver 51 tends to increase thereafter, By opening the provided gland seal steam receiver pressure adjusting discharge valve 64, the steam in the gland seal steam receiver 51 is released to the main condenser 37.
As a result, the energy held by the exhaust steam can be recovered, and the inside of the gland seal steam receiver 51 can be maintained within a predetermined pressure range.

Further, according to the steam turbine equipment 81 and the operation method of the steam turbine equipment 81 according to the present embodiment, the gland seal steam receiver pressure adjusting discharge valve 64 is fully closed until the gland seal steam discharge valve 83 is fully opened. The gland seal steam receiver pressure adjusting discharge valve 64 is opened only when the gland seal steam discharge valve 83 is fully opened and the pressure in the gland seal steam receiver 51 tends to increase thereafter.
Thereby, the energy which exhaust steam has can be collect | recovered to the maximum, and the output (performance) of the steam turbine 2 can further be improved.
Other functions and effects are the same as those of the above-described first embodiment, and thus description thereof is omitted here.

  In addition, this invention is not limited to embodiment mentioned above, It can also implement by changing and changing suitably as needed.

DESCRIPTION OF SYMBOLS 1 Steam turbine equipment 2 Steam turbine 3 High pressure side gland part 4 Low pressure side gland part 37 Main condenser 44 Spill steam condenser 51 Ground seal steam receiver 52 Spill steam pipe 61 Exhaust pipe 62 Controller 63 Spill steam control valve 64 Ground seal steam Receiver pressure adjusting discharge valve 65 Vent line 81 Steam turbine equipment 82 Gland seal steam communication pipe 83 Gland seal steam discharge valve

Claims (6)

A steam turbine facility comprising a ground seal steam receiver communicating with a high pressure side gland part and a low pressure side gland part of a steam turbine,
A spill steam pipe that leads the steam in the ground seal steam receiver to a spill steam condenser installed for heat recovery, or a ground seal steam communication pipe that leads to a turbine low pressure stage that is below atmospheric pressure of the steam turbine;
An exhaust pipe for guiding the steam in the ground seal steam receiver to the main condenser;
A spill steam control valve provided in the middle of the spill steam pipe, or a gland seal steam discharge valve provided in the middle of the gland seal steam communication pipe so as to keep the inside of the gland seal steam receiver in a predetermined pressure range, And a control signal for opening / closing a discharge valve for adjusting the pressure of the gland seal steam receiver provided in the middle of the exhaust pipe, the control signal for adjusting the pressure of the spill steam control valve or the gland seal steam discharge valve, and the pressure of the gland seal steam receiver A steam turbine facility comprising a controller for outputting to a discharge valve.   2. The steam turbine equipment according to claim 1, wherein the discharge valve for adjusting the pressure of the gland seal steam receiver is operated to open and close in a state where the spill steam control valve or the gland seal steam discharge valve is fully opened.   The steam turbine equipment according to claim 1 or 2, wherein the spill steam condenser and the main condenser are communicated with each other through a vent line.   A ship provided with the steam turbine equipment according to any one of claims 1 to 3. A gland seal steam receiver communicating with the high pressure side gland part and the low pressure side gland part of the steam turbine;
A spill steam pipe that leads the steam in the ground seal steam receiver to a spill steam condenser installed for heat recovery, or a ground seal steam communication pipe that leads to a turbine low pressure stage that is below atmospheric pressure of the steam turbine;
An exhaust pipe for guiding the steam in the gland seal steam receiver to a main condenser, and an operation method of steam turbine equipment comprising:
A spill steam control valve provided in the middle of the spill steam pipe, or a gland seal steam discharge valve provided in the middle of the gland seal steam communication pipe so as to keep the inside of the gland seal steam receiver in a predetermined pressure range, And a method of operating a steam turbine facility, wherein a gland seal steam receiver pressure adjusting discharge valve provided in the middle of the exhaust pipe is opened and closed.   The steam turbine equipment according to claim 5, wherein the discharge valve for adjusting the pressure of the gland seal steam receiver is operated to open and close in a state where the spill steam control valve or the gland seal steam discharge valve is fully open. Operation method.

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