KR20150100886A - Condenser and steam-turbine plant provided therewith - Google Patents

Abstract

The condenser 30 includes a heat transfer pipe group 32, a main body 35 covering the heat transfer pipe group, and a steam supply pipe 35 for leading the exhaust steam ES from the steam turbine 3 to the heat transfer pipe group And a bypass steam receiving portion 51 for receiving the bypass steam as the steam bypassing the steam turbine and guiding the bypass steam to the heat transfer pipe group in the body body. The bypass steam accommodating portion 51 is disposed outside the steam supply passage 42 and the opening of the body body 35 with respect to the bypass steam accommodating portion 51 is connected to the exhaust steam passage (BS) is mainly introduced into the heat transfer pipe group (32) from a region (34) different from the inflow region (33) into which the heat transfer gas (ES) mainly flows.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a condenser and a steam turbine plant having the same,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a condenser for condensing and returning exhaust steam, which is steam exhausted from a steam turbine, and a steam turbine plant having the condenser. The present application claims priority based on Japanese Patent Application No. 2013-065403, filed on March 27, 2013, which is incorporated herein by reference.

The steam turbine plant is provided with a bypass steam line for leading the steam bypassed by the steam turbine to the condenser. By-pass steam, which is the vapor that is drawn into the condenser from the bypass steam line, is hotter and higher pressure than the exhaust steam operating in the steam turbine because it is not operating in the steam turbine.

As such a steam turbine plant, there is, for example, a steam turbine plant described in Patent Document 1 below. The steam turbine of this steam turbine plant is an axial discharge steam turbine that exhausts the steam in the axial direction in which the turbine rotor extends. A condenser is disposed at an axial position with respect to the steam turbine, that is, in the exhaust direction of the steam. The condenser is connected to a bypass steam line through which bypass steam bypasses the steam turbine.

As a condenser of an axial flow exhaust type steam turbine, there is a condenser described in Patent Document 2 below, for example. The condenser includes a heat transfer tube group including a plurality of heat transfer tubes through which seawater or the like passes, a body body covering the heat transfer tube group, a steam turbine connecting the steam turbine and the body body to transfer steam from the steam turbine to the heat transfer tube group As shown in Fig. The body body is disposed at an axial position with respect to the steam turbine, and the intermediate body is connected to a side portion of the body body.

The steam turbine plant disclosed in Patent Document 3 has two steam turbines. The two steam turbines are all downward evacuated steam turbines that exhaust the steam downward. At the lower position of each steam turbine, a plurality of units are disposed. The bodies of the two condensers are connected to each other by the lug body at the upper portion thereof. A steam receiving box is disposed below the lid body. This vapor receiving box is connected to a bypass steam line through which steam that bypasses the steam turbine passes. Vapor introduced into the vapor receiving box from the bypass steam line flows into the body of the two condensers via the communicating body.

Japanese Patent Application Laid-Open No. 2003-148111 Japanese Patent Application Laid-Open No. 9-273875 Japanese Patent Application Laid-Open No. 7-167571

In the steam turbine plant described in Patent Document 1, since the energy of the bypass steam, which is higher in temperature and higher in pressure than the exhaust steam, needs to be diffused to some extent, the end portion of the bypass steam line is connected to the intermediate body of the condenser. In such a structure, since the length of the intermediate body is increased in order to introduce the bypass steam into the main body, the installation space of the steam turbine plant can not be effectively utilized. In such a structure, there is a fear that the bypass steam of high temperature and high pressure introduced into the intermediate body flows back to the steam turbine side, thereby damaging the turbine rotor, its bearing, the shaft seal, and the like. Also, since the exhaust steam from the steam turbine and the bypass steam from the bypass steam line also flow into the heat transfer tube group in the body body via the intermediate body, the region facing the intermediate body in the heat transfer tube group There is also a possibility of significant damage.

Further, in the steam turbine plant of Patent Document 3, as described above, the vapor containing box is disposed below the lid body for connecting the upper portions of the bodies of the two condensers to each other, and the bypass steam is introduced into the box . Therefore, in the steam turbine plant of Patent Document 3, it is not necessary to lengthen the length of the intermediate body for inducing the exhaust steam from the steam turbine in the body body covering the heat transfer pipe group among the plural bodies of the condenser, The possibility that the bypass steam will flow back to the steam turbine side is also small. In this steam turbine plant, it is also considered that the lug body is connected to the intermediate body of each of the condensers. As a result, the exhaust steam from the steam turbine and the bypass steam from the bypass steam line also flow into the heat transfer tube group in the body body via the intermediate body, so that the portion of the heat transfer tube group, which faces the intermediate body, It is presumed to be remarkably damaged.

That is, the steam turbine plant disclosed in Patent Document 1 and the steam turbine plant disclosed in Patent Document 3 have a problem that the heat transfer pipe group of the condenser is locally damaged.

Accordingly, it is an object of the present invention to provide a condenser capable of suppressing local damage of a heat transfer tube group, and a steam turbine plant having the same.

According to an aspect of the invention for solving the above problems,

A heat transfer tube group including a plurality of heat transfer tubes for passing the heat exchange medium with the exhaust steam exhausted from the steam turbine through the inside thereof and returning the exhaust steam to water; a body body covering the heat transfer tube group; An intermediate body connecting the steam turbine and the steam turbine and forming a steam main passage for leading the exhaust steam from the steam turbine to the group of heat transfer tubes in the main body body; And a bypass steam receiving portion for receiving the bypass steam and guiding the bypass steam to the heat transfer pipe group in the body body through an opening formed in the body body,

Wherein the bypass steam receiving portion is disposed outside the steam main oil passage and the opening of the main body body is connected to the heat transfer pipe group from the region different from the inflow region where the exhaust steam mainly flows into the heat transfer pipe group And is formed at a position where the bypass steam mainly flows.

However, in the above, "mainly introduced" means that the steam is introduced into the heat transfer pipe group from the corresponding region of the heat transfer pipe group.

In this condenser, bypass steam mainly flows into the heat transfer pipe group from a region different from the inflow region where the exhaust steam mainly flows into the heat transfer pipe group. Therefore, in this condenser, since the region into which the steam flows into the heat transfer tube group is dispersed, the local damage of the heat transfer tube group can be suppressed.

In addition, in this condenser, since the bypass steam receiving portion is provided in addition to the steam lube, the length of the intermediate body can be shortened as compared with the case where the bypass steam is led to the intermediate body of the condenser, Space can be used effectively. In this condenser, since bypass steam does not directly flow into the steam lube, it is very unlikely that the bypass steam will flow back to the steam turbine side, and the damage to the turbine rotor, bearing or shaft rod of the steam turbine is suppressed . Further, in this condenser, since the steam sprayer or the water sprayer for spraying the bypass steam in the intermediate body is not disposed, the resistance of the exhaust steam passing through the intermediate body can be reduced.

Here, in the above-mentioned condenser, a flow restraining member may be provided for suppressing the flow of the bypass steam accommodated in the bypass steam receiving portion toward the heat transfer pipe group.

In this condenser, the flow of the bypass steam toward the heat transfer tube group can be suppressed, so that damage to the heat transfer tube group can be further suppressed.

In some of the above-mentioned condensers, a water spouting portion for spraying water into the bypass steam containing portion may be provided.

In this condenser, since the bypass steam can be cooled in the bypass steam receiving portion, damage to the heat transfer tube group can be suppressed.

In some of the above-mentioned condensers, the steam turbine is of a horizontal exhaust type that exhausts steam in the axial direction of the rotor of the steam turbine or laterally of the steam turbine, Wherein the bypass steam receiving portion is provided at one of an upper portion of the body body and a portion of the body body opposite to the portion to which the intermediate body is connected with respect to the heat transfer tube group as a side portion of the body body .

In the condenser except for the condenser for the horizontal exhaust steam turbine among the above-mentioned several condensers, the steam turbine is a downward exhaust type for exhausting the steam to a position below the steam turbine, And the bypass steam receiving portion may be provided at a position opposite to the heat transfer pipe group in the horizontal direction as a side portion of the body body.

A steam turbine plant as one aspect of the invention for solving the above-

A plurality of said plurality of condensers, a steam supply for supplying steam to the steam turbine, and a bypass valve for bypassing the steam turbine by using the steam from the steam supply as the bypass steam, And a bypass steam line leading to the storage portion.

According to another aspect of the present invention, there is provided a steam turbine plant,

A steam feeder for supplying steam to the steam turbine; a water feed pump for returning water obtained by condensation of the exhaust steam to the steam feeder in the condenser; A bypass steam line for bypassing the steam turbine and introducing the steam from the steam supplier to the bypass steam receiving portion; And an ejection number line for ejecting the ink.

In the above-mentioned steam turbine plant, since several condensers are provided, the local damage of the heat transfer pipe group can be suppressed.

According to one aspect of the present invention, since the region into which the steam flows into the heat transfer tube group is dispersed, the local damage of the heat transfer tube group can be suppressed.

1 is a flow diagram of a steam turbine plant according to a first embodiment of the present invention.
2 is a flow diagram of a steam turbine plant according to a second embodiment of the present invention.
3 is a flow diagram of a steam turbine plant according to a third embodiment of the present invention.
4 is a schematic sectional view of a condenser according to a first modification of the present invention.
5 is a schematic cross-sectional view of a condenser according to a second modification of the present invention.
6 is a schematic sectional view of a condenser according to a third modification of the present invention.

Hereinafter, various embodiments and various modifications of the steam turbine plant according to the present invention will be described with reference to the drawings.

"First embodiment"

A first embodiment of a steam turbine plant according to the present invention will be described with reference to Fig.

The steam turbine plant of the present embodiment includes a steam generator 1 (steam generator) such as a boiler, a high-pressure steam turbine 2 and a low-pressure steam turbine 3 driven by steam generated in the steam generator 1, (Steam feeder) 6 for reheating steam exhausted from the high-pressure steam turbine 2, a low-pressure steam turbine 3, and a high-pressure steam turbine 3. The generator 5 generates electricity by driving each of the steam turbines 2 and 3, A condenser 30 for condensing the exhaust steam ES as exhaust steam back to water and a water feed pump 7 for returning water in the condenser 30 to the steam generator 1.

The steam turbine plant also includes a high pressure steam line 11 for leading the high pressure steam HS as steam generated in the steam generator 1 to the high pressure steam turbine 2, Steam reheating steam line (13) for leading the reheated steam (RS) which is heated by the reheater (6) to the low pressure steam turbine (3) A bypass high pressure steam line 12 branched from the high pressure steam line 11 to lead the high pressure steam HS to the condenser 30 and a bypass high pressure steam line 12 branching from the reheat steam line 13 to reheat steam RS A plurality of lines 16 for leading the water in the condenser 30 to the water feed pump 7 and water from the water feed pump 7 to the steam generator 1 And a jetted water line 18 that branches water from the water supply line 17 and guides the water to the condenser 30. The water supply line 17,

The high-pressure steam line (11) is provided with a high-pressure steam control valve (21) for regulating the flow rate of the high-pressure steam (HS) flowing into the high-pressure steam turbine (2). The reheat steam line 13 is provided with a reheat steam control valve 23 for regulating the flow rate of the reheat steam RS flowing into the low pressure steam turbine 3. The bypass high-pressure vapor line (12) is provided with an on-off valve (22). The bypass reheat steam line 14 is also provided with an on-off valve 24. A water supply control valve 27 for regulating the flow rate of water flowing into the steam generator 1 is provided on the side of the steam generator 1 rather than the position where the spray water line 18 diverges from the water supply line 17. The effluent water line (18) is provided with an effluent water control valve (28) for controlling the flow rate of water to be jetted into the condenser (30).

Both the high-pressure steam turbine 2 and the low-pressure steam turbine 3 have a turbine rotor that rotates about an axis and a casing that rotatably covers the turbine rotor. The turbine rotor of the high-pressure steam turbine 2 and the turbine rotor of the low-pressure steam turbine 3 are connected to each other by being rotated about the same axis. The generator rotor of the generator 5 is connected to the turbine rotor of the high-pressure steam turbine 2.

The low pressure steam turbine (3) is an axial flow exhaust steam turbine that exhausts steam in the axial direction in which the turbine rotor extends. Accordingly, the casing of the low-pressure steam turbine 3 is opened as an exhaust port 4 in the axial direction and on the rear side opposite to the high-pressure steam turbine 2. [

The condenser 30 corresponds to the axial flow exhaust type steam turbine and is arranged on the rear side of the low pressure steam turbine 3. [ The condenser 30 includes a heat transfer tube group 32 composed of a plurality of heat transfer tubes 31, a body body 35 covering the heat transfer tube group 32, a low pressure steam turbine 3, (BHS), which is a steam from the bypass high-pressure steam line (12), and a bypass reheat steam line (14), which are steam from the bypass high-pressure steam line (12) A bypass steam receiving portion 51 for receiving the steam BRS and a water jetting unit 56 for jetting water from the jetting water line 18 in the condenser 30. [ Hereinafter, one or both of the bypass high-pressure steam (BHS) and the bypass reheat steam (BRS) may be simply referred to as bypass steam (BS).

The main body 35 is disposed behind the low-pressure steam turbine 3 at an interval. The intermediate body 41 extends rearward from the exhaust port 4 of the low pressure steam turbine 3 and connects the exhaust port 4 of the low pressure steam turbine 3 and the body body 35. The portion of the main body 35 to which the intermediate body 41 is connected is the side of the main body 35 and the side of the low pressure steam turbine 3. The connecting portion of the main body 35 with the intermediate body 41 is open. The exhaust steam ES which is steam discharged from the low pressure steam turbine 3 flows into the main body 35 from the opening (hereinafter referred to as the exhaust steam inlet 36) through the intermediate body 41. Accordingly, the intermediate body 41 forms a part of the steam oil passage 42 for leading the exhaust steam ES from the low-pressure steam turbine 3 to the group of heat transfer tubes 32 in the main body 35. The steam supply passage 42 is formed in the inner space of the intermediate body 41 and the space between the heat transfer pipe group 32 and the exhaust steam inlet 36 of the body body 35 in the body body 35 . A cooling medium such as seawater flows to the plurality of heat transfer tubes 31 constituting the heat transfer tube group 32, for example. Each of the heat transfer tubes 31 heat-exchanges the cooling medium flowing in the inside with the exhaust steam ES outside, condenses the exhaust steam ES and returns it to water. The lower portion of the interior of the main body 35 constitutes a hot well 38 in which water obtained by the condensation of the exhaust steam ES condenses. A plurality of lines 16 are connected to a lower portion of the main body 35.

The bypass steam receiving portion 51 includes a bypass steam receiving box 52 in which a space for receiving bypass steam is formed and a bypass high pressure vapor line connected to the bypass high pressure steam line 12, A high pressure steam injector 53 for injecting bypass high pressure steam (BHS) in the receiving box 52 and a high pressure steam injector 53 connected to the bypass reheating steam line 14 for bypass reheat And a reboiler 54 for ejecting steam (BRS).

The bypass steam containing box 52 is connected and fixed to the upper portion of the main body 35. The connecting portion between the bypass steam containing box 52 and the body body 35 is opened and the steam discharged from the bypass steam inlet box 37 into the bypass steam receiving box 52 Pass steam (BS) flows into the body body (35). Both the high-pressure steam sprayer 53 and the reheated steam sprayer 54 are perforated tubes having a plurality of through-holes formed therein. In addition, in the bypass steam accommodation box 52, at a position below the high-pressure steam sprayer 53 and the reheated steam sprayer 54, in other words, at the position on the side of the heat transfer pipe group 32, 56 are disposed. The water sprayer (56) is provided with a plurality of nozzles for spraying water on a pipe. A plurality of nozzles are provided on the upper portion of the pipe to eject water upwardly, that is, toward the high-pressure steam sprayer 53 and the reheat steam sprayer 54 side.

Next, the operation of the above-described steam turbine plant will be described.

The steam generated in the steam generator 1 flows into the casing of the high-pressure steam turbine 2 as high-pressure steam (HS) through the high-pressure steam line 11 to drive the high-pressure steam turbine 2. At this time, the high-pressure steam control valve 21 regulates the flow rate of the high-pressure steam (HS) flowing into the casing of the high-pressure steam turbine (2). The open / close valve 22 provided in the bypass high-pressure vapor line 12 is in the fully closed state. Pressure steam (HS) exhausted from the high-pressure steam turbine (2) flows into the reheater (6) through the exhaust high-pressure steam line (15) and reheated. The steam heated by the reheater 6 flows into the casing of the low pressure steam turbine 3 as reheat steam RS through the reheat steam line 13 to drive the low pressure steam turbine 3. At this time, the reheat steam control valve 23 regulates the flow rate of the reheat steam (RS) into the casing of the low-pressure steam turbine (3). The on-off valve 24 provided in the bypass reheat steam line 14 is in a fully closed state.

When the high-pressure steam turbine 2 and the low-pressure steam turbine 3 are driven, the generator 5 generates electricity.

The reheat steam RS driven by the low pressure steam turbine 3 is exhausted from the exhaust port 4 of the low pressure steam turbine 3 as exhaust steam ES and passes through the intermediate body 41 of the condenser 30 And into the heat transfer pipe group 32 in the main body 35. That is, the exhaust steam (ES) flows from the exhaust port (4) of the low-pressure steam turbine (3) through the steam oil passage (42) in the condenser (30) and flows into the heat transfer pipe group (32). At this time, the exhaust steam (ES) mainly flows into the heat transfer pipe group (32) from the side region (33) of the heat transfer pipe group (32) opposed to the exhaust steam inlet (36) of the body body (35). It is to be noted that the term "mainly introduced" means that the heat transfer pipe group 32 is provided with the largest amount of heat transfer from the region 33 of the side portion opposed to the exhaust steam inlet 36 of the body body 35 to the heat transfer pipe group 32 This means that the exhaust steam (ES) is introduced.

The exhaust steam ES flowing into the heat transfer pipe group 32 or around the heat transfer pipe group 32 is heat-exchanged with the cooling medium flowing in the heat transfer pipe 31 constituting the heat transfer pipe group 32, do. This water is held in the hot well 38 under the main body 35. The water remaining in the hot well 38 is returned to the steam generator 1 through the plurality of lines 16, the water feed pump 7, and the water feed line 17. At this time, the water supply control valve 27 regulates the flow rate of the water flowing into the steam generator 1. In addition, the spray water control valve 28 is in the fully closed state.

In the case of stopping the high-pressure steam turbine 2 and the low-pressure steam turbine 3 by an instruction to stop the power supply from the power system connected to the generator 5 during the normal operation as described above, The high-pressure steam control valve 21 and the reheat steam control valve 23 from the open state to the fully closed state. The open / close valves 22 and 24 provided in the bypass high-pressure steam line 12 and the bypass reheat steam line 14 are brought into a fully opened state from a fully closed state. As a result, the high-pressure steam (HS) from the steam generator 1 is supplied to the high-pressure steam line 11, the bypass high-pressure steam line 12, and the high-pressure steam injector 53 as bypass high-pressure steam (BHS) Into the bypass vapor receiving box 52 through the bypass duct 52. [ The reheat steam RS from the reheater 6 is supplied to the reheat steam line 13, the bypass reheated steam line 14 and the reheated steam ejector 54 as the bypass reheat steam BRS Into the bypass vapor receiving box 52 through the bypass duct 52. [ The bypass high pressure steam (BHS) ejected into the bypass steam receiving box 52 is higher in temperature than the high pressure steam (HS) operated in the high pressure steam turbine (2) because it is not operating in the high pressure steam turbine It is also high pressure. Since the bypass reheated steam BRS ejected into the bypass steam receiving box 52 is not operated by the low pressure steam turbine 3, the reheated steam RS operated in the low pressure steam turbine 3 Exhaust Steam (ES)) and high pressure. Therefore, the bypass steam (BS), which is higher in temperature and higher in pressure than the exhaust steam (ES) flowing into the main body 35 through the intermediate body 41, flows into the bypass steam receiving box 52.

In the above case, the spray water control valve 28 is also opened so that a part of the water from the water feed pump 7 flows into the bypass steam receiving box 52 through the spray water line 18 and the water sprayer 56, Lt; / RTI > The water ejected into the bypass steam receiving box 52 is heat exchanged with the high temperature and high pressure bypass steam BS to lower the temperature of the bypass steam BS. The water ejected into the bypass vapor receiving box 52 functions as a curtain for the bypass vapor BS to suppress the inflow of the bypass vapor BS into the body body 35. [ However, water is mostly steam in this process.

By-pass steam (BS) and water vaporized by heat exchange with the bypass steam (BS) are introduced into the heat transfer pipe group (32). At this time, the bypass steam (BS) or the like mainly flows into the heat transfer pipe group 32 from the upper region 34 opposed to the bypass steam inlet 37 of the main body 35 in the heat transfer pipe group 32 ≪ / RTI > The bypass steam BS or the like that has flowed into the heat transfer pipe group 32 or around the heat transfer pipe group 32 is heat-exchanged with the cooling medium flowing in the heat transfer pipe 31 constituting the heat transfer pipe group 32 and condensed , And water. This water is held in the hot well 38 under the main body 35. A part of the water which has been heated in the hot well 38 is returned to the steam generator 1 through the plurality of lines 16, the water feed pump 7 and the water feed line 17. The remaining water is injected into the bypass steam receiving box 52 through the jetted water line 18 and the water jet 56.

As described above, in the present embodiment, the exhaust steam ES passes through the steam oil passage 42 to the region 33 opposed to the exhaust steam inlet 36 of the main body 35 as a side portion of the heat transfer pipe group 32, The bypass steam BS mainly flows into the heat transfer pipe group 32 from the region 34 above the heat transfer pipe group 32 while the bypass steam BS mainly flows into the heat transfer pipe group 32 from the heat transfer pipe group 32. [ That is, in the present embodiment, the region 33 in the heat transfer pipe group 32 into which the exhaust steam ES flows into the heat transfer pipe group 32 and the heat transfer pipe group 32 into which the bypass steam BS flows into the heat transfer pipe group 32 (34) in the second region (32). Thus, in the present embodiment, local damage of the heat transfer pipe group 32 can be suppressed.

When the bypass steam BS is introduced into the intermediate body 41 of the condenser 30, the energy of the high-temperature and high-pressure bypass steam BS is diffused to some extent and then the bypass steam BS , The length of the intermediate body 41 becomes long. In this case, the bypass steam (BS) of high temperature and high pressure introduced into the intermediate body 41 may flow back to the steam turbine side, which may damage the turbine rotor of the steam turbine, its bearing or the shaft rod. In this case, the resistance of the exhaust steam ES passing through the intermediate body 41 becomes larger due to the arrangement of the steam ejector or the water ejector for ejecting the bypass steam BS into the intermediate body 41. [

However, in this embodiment, since the bypass steam receiving portion 51 is provided in addition to the steam main oil passage 42, the bypass steam is supplied to the intermediate body 41 of the condenser 30 The length of the intermediate body 41 can be shortened, and the installation space of the steam turbine plant can be effectively utilized. In this embodiment, since the bypass steam BS does not flow directly into the steam oil passage 42 in the intermediate body 41, the possibility that the bypass steam BS flows back to the steam turbine side is very low, It is possible to suppress the damage of the turbine rotor of the steam turbine, the bearing thereof, and the shaft rod. In this embodiment, since the steam sprayer or the water sprayer for spraying the bypass steam (BS) is not disposed in the intermediate body 41, the resistance of the exhaust steam ES passing through the intermediate body 41 Can be reduced.

"Second Embodiment &

A second embodiment of the steam turbine plant according to the present invention will be described with reference to Fig.

The steam turbine plant of this embodiment is basically the same as the steam turbine plant of the first embodiment. However, the present embodiment is different from the first embodiment in that the bypass steam receiving portion 51a of the condenser 30a is provided on the side portion of the main body 35a.

The bypass steam receiving portion 51a of the present embodiment also includes the bypass steam receiving box 52, the high-pressure steam sprayer 53, And a steam ejector 54. The bypass steam receiving box 52 is connected to and fixed to a portion of the main body 35a opposite to the portion to which the intermediate body 41 is connected with respect to the heat transfer tube group 32 as a reference. The connecting portion of the bypass steam receiving box 52 and the body body 35a is opened so that the bypass steam (BS) from the bypass steam receiving box 52 flows into the main body 35a Thereby forming a bypass steam inlet 37a.

As described above, in the present embodiment, the exhaust steam ES passes through the intermediate body 41 and passes through the region 33 facing the exhaust steam inlet 36 of the body body 35a as a side portion of the heat transfer pipe group 32, The bypass steam BS flows into the heat transfer pipe group 32 in a region opposite to the bypass steam inlet 37a opposite to the exhaust steam inlet 36 with respect to the heat transfer pipe group 32 34a to the heat transfer pipe group 32 as shown in Fig. That is, in the present embodiment as well, as in the first embodiment, the region 33 in the heat transfer pipe group 32 into which the exhaust steam ES flows into the heat transfer pipe group 32 and the bypass steam BS in the heat transfer pipe group 32) of the heat transfer pipe group (32). Also in this embodiment, as in the first embodiment, the bypass steam receiving portion 51a is provided in addition to the steam oil passageway 42. [ Therefore, the same effects as those of the first embodiment can be obtained in this embodiment as well.

However, in this embodiment, since the bypass steam receiving portion 51a is provided on the side of the main body 35a, the present embodiment is advantageous in that the usability of the flat installation space of the steam turbine plant is smaller than that of the first embodiment Falls. On the other hand, in the present embodiment, since the bypass steam receiving portion 51a is provided on the side opposite to the side to which the intermediate body 41 is connected with respect to the heat transfer pipe group 32, bypass steam (BS) It is possible to lower the possibility of backflow to the steam turbine side than in the first embodiment.

It should be noted that the first embodiment and the second embodiment are all examples in which the low pressure steam turbine 3 is of the axial flow exhaust type and the condensers 30 and 30a are of the corresponding type but the low pressure steam turbine is of the lateral exhaust type, The present invention can be applied to the embodiments described above. However, when the steam turbine is of the lateral exhaust type, the condenser is disposed on the side of the steam turbine.

"Third Embodiment &

A third embodiment of the steam turbine plant according to the present invention will be described with reference to Fig.

The components of the steam turbine plant of this embodiment are also the same as those of the steam turbine plant of the first and second embodiments. However, the low-pressure steam turbine 3b and the condenser 30b, which are components of the steam turbine plant of the present embodiment, are the same as the low-pressure steam turbine 3 and the condenser 30, 30a of the steam turbine plants of the first and second embodiments ).

The low-pressure steam turbine 3b of the present embodiment is a down-exhaust type that exhausts steam downward. Due to this, the casing of the low-pressure steam turbine 3b of the present embodiment opens on the lower side as an exhaust port 4b.

The condenser 30b corresponds to the downward evacuation type steam turbine and is disposed on the lower side of the low pressure steam turbine 3b. Similarly to the condensers 30 and 30a of the first and second embodiments, this condenser 30b also includes a heat transfer pipe group 32, a body body 35b covering the heat transfer pipe group 32, a low pressure steam turbine 3b An intermediate body 41b which is located between the main body 35b and the main body 35b and connects them together, a bypass steam receiving portion 51b and a water ejector 56 (water ejecting portion).

The main body 35b is disposed below the low-pressure steam turbine 3b with an interval therebetween. The intermediate body 41b extends downward from the exhaust port 4b of the low pressure steam turbine 3b and connects the exhaust port 4b of the low pressure steam turbine 3b and the body body 35b. The portion of the body body 35b to which the intermediate body 41b is connected is the upper portion of the body body 35b. The connecting portion of the body body 35b with the intermediate body 41b is open and forms an exhaust steam inlet 36b through which the exhaust steam ES flows into the body body 35b. The intermediate body 41b is provided at a portion of the steam oil passage 42b for leading the exhaust steam ES from the low pressure steam turbine 3b to the heat transfer tube group 32 in the body body 35b . Also in this embodiment, the inside of the main body 35b forms a hot well 38 in which the water obtained by the condensation of the exhaust steam ES is collected.

The bypass steam receiving portion 51b includes a bypass steam receiving box 52, a high-pressure steam sprayer 53 for spraying a bypass high-pressure steam (BHS), a bypass reheat steam And a reheated steam ejector 54 for ejecting the BRS.

The bypass steam containing box 52 is connected and fixed to the side of the main body 35b. The connecting portion of the bypass steam receiving box 52 and the body body 35b is opened and forms an bypass steam inlet 37b through which the bypass steam BS flows into the body body 35b. Both the high-pressure steam sprayer 53 and the reheated steam sprayer 54 are disposed in the bypass steam receiving box 52, as in the first and second embodiments. The water sprayer 56 is also disposed in the bypass steam receiving box 52 as in the first and second embodiments in the same manner as the high pressure steam sprayer 53 and the reheat steam sprayer 54, 32). The plurality of nozzles of the water ejector 56 eject water into the high-pressure steam ejector 53 and the reheat steam ejector 54 side.

As described above, in the present embodiment, the exhaust steam ES mainly flows into the heat transfer pipe group 32 from the upper region 33b of the heat transfer pipe group 32 via the intermediate body 41b, whereas the bypass steam (BS) are mainly introduced into the heat transfer pipe group (32) from the side region (34b) of the heat transfer pipe group (32). That is, in the present embodiment, as in the first and second embodiments, the region 33b of the heat transfer pipe group 32 into which the exhaust steam ES flows into the heat transfer pipe group 32 and the bypass steam BS The area 34b in the heat transfer pipe group 32 flowing into the heat transfer pipe group 32 is different. Also in this embodiment, as in the first and second embodiments, the bypass steam receiving portion 51b is provided in addition to the steam oil passage 42b. Therefore, the same effects as those of the first and second embodiments can be obtained in this embodiment as well. That is, even in the present embodiment, local damage to the heat transfer tube group 32 can be suppressed. Also in the present embodiment, the length of the intermediate body 41b can be shortened as compared with the case where the bypass steam BS is introduced into the intermediate body 41b of the condenser 30b. In addition, in this embodiment, not only the possibility that the bypass steam BS flows back to the low-pressure steam turbine 3b can be extremely reduced, but also the resistance of the exhaust steam ES passing through the intermediate body 41b Can be made small.

As described above, the present invention can be applied even if the low-pressure steam turbine 3b is of the down-exhaust type and the condenser 30b is of the type corresponding thereto. That is, as described above, the present invention can be applied depending on whether the steam turbine is an axial exhaust type or a lateral exhaust type, a horizontal exhaust type, a steam turbine is a downward exhaust type, or an exhaust type of a steam turbine.

"First variation of the condenser"

A first modification of the condenser 30 according to the first embodiment will be described with reference to Fig.

The condenser 30 of the first embodiment is provided with the water vapor accumulator 53 and the reheat steam sprayer 54 in the bypass vapor receiving box 52 at a position closer to the heat transfer pipe group 32 than the high- And an ejector 56 is disposed. In the condenser 30c of the present modification example, the heat transfer pipe group 32 is disposed in the bypass steam receiving box 52 of the bypass steam receiving portion 51c, rather than the high pressure steam injector 53 and the reheated steam injector 54. [ The water sprayer 56 is disposed at a position far from the water sprayer 56. [ In other words, in this modified example, the high-pressure steam sprayer 53 and the reheated steam sprayer 54 are disposed at a position closer to the heat transfer pipe group 32 than the water sprayer 56. The nozzle of the water sprayer 56 ejects water toward the high-pressure steam sprayer 53 and the reheat steam sprayer 54, as in the above-described embodiments. The bypass steam BS blown from the high pressure steam injector 53 and the reheated steam injector 54 into the bypass steam receiving box 52 is ejected from the water injector 56 It can be cooled with one water.

However, this modification is a modified example of the condenser 30 of the first embodiment, but it is also possible to modify the condensers 30a and 30b of the second and third embodiments as well.

"Second variation of the condenser"

Referring to Fig. 5, a second modification of the condenser 30c according to the first modification will be described.

The condenser 30d according to the present modification differs from the condenser 30c according to the first modification in that the bypass steam BS accommodated in the bypass steam receiving portion 51c of the condenser 30c is supplied to the condenser 30c of the first modification, In addition to the flow-restraining member. This flow restraining member is composed of an ejector group 55 which is a group of a high pressure steam ejector 53, a reheat steam ejector 54 and a water ejector 56 in a bypass steam receiving box 52, 35 disposed between the heat transfer pipe group 32 and the heat transfer pipe group 32. The impingement plate 58 is widened in the direction perpendicular to the accommodating portion-tube group direction from the ejector group 55 or the bypass steam accommodating portion 51c toward the heat transfer tube group 32.

The impingement plate 58 is disposed between the group of the ejector groups 55 and the group of the heat conductive pipes 32 so that the flow velocity of the steam flowing into the group of heat transfer tubes 32 from the group of the ejector groups 55 So that damage to the heat transfer pipe group 32 can be suppressed.

"Third variation of the condenser"

Referring to Fig. 6, a third modification of the condenser 30c according to the first modification will be described.

As in the second modification, the condenser 30e of the present modification has the bypass steam BS accommodated in the bypass steam receiving portion 51c of the condenser 30c in the condenser 30c of the first modification, And a flow restraining member for restricting the flow toward the group (32). The flow restraining member of this modification is a plurality of impingement rods 59 disposed between a group of gusher groups 55 and a group of heat transfer tubes 32 in the body body 35. The plurality of impingement rods 59 extend in the direction perpendicular to the accommodating portion-tube group direction from the ejector group 55 or the bypass steam accommodating portion 51c toward the heat transfer tube group 32, , The receiving portion-to-tube direction, and the direction in which each impingement rod 59 extends.

The plurality of impingement rods 59 are disposed between the group of ejector groups 55 and the group of heat transfer tubes 32 so that the flow rate of the steam flowing into the group of heat transfer tubes 32 from the group of ejector groups 55 So that damage to the heat transfer pipe group 32 can be suppressed.

In the second and third modified examples, the flow restraining member is disposed in the body body 35. However, if the flow restraining member is disposed between the group of the blower groups 55 and the group of heat transfer tubes 32, It may be disposed in the bypass steam receiving box 52.

The second modification example and the third modification example are all modifications of the condenser 30 according to the first modification. However, it is possible to modify the same plural modifications of the first to third embodiments.

In the condenser 30c according to the first modification, the high-pressure steam sprayer 53 and the reheated steam sprayer 54 are positioned closer to the heat transfer pipe group 32 than the water sprayer 56, It is impossible to expect a curtain effect that suppresses the flow of the bypass steam BS toward the heat transfer pipe group 32 by the water ejected from the heat exchanger 56. [ Therefore, it is more effective to provide the flow restraining member in the condenser of the first modification to the first to third embodiments than the first to third embodiments.

"Other variations"

Each of the above embodiments and modifications applies the present invention to a steam turbine plant having a high pressure steam turbine, a low pressure steam turbine, and a condenser for returning exhaust steam from the low pressure steam turbine to water. However, the present invention may be applied to a steam turbine plant having a high-pressure steam turbine, an intermediate-pressure steam turbine, a low-pressure steam turbine, and a condenser for returning exhaust steam (ES) from some of the steam turbines to water. The present invention may also be applied to a steam turbine plant having a kind of steam turbine and a condenser for returning exhaust steam from the steam turbine to water. That is, the present invention may be applied to any steam turbine plan as long as it is a steam turbine plant having a steam turbine and a condenser therefor.

According to one aspect of the present invention, local damage to the heat transfer pipe group can be suppressed.

1 Steam generator (steam supply)
2 High pressure steam turbine
3, 3b low pressure steam turbine (or briefly steam turbine)
5 generator
6 Reheater (steam supply)
7 water pump
11 High pressure steam line
12 bypass high pressure steam line
13 Reheat steam line
14 Bypass Reheat Steam Line
15 Exhaust High Pressure Steam Line
16 multiple lines
17 water line
18 squirt line
30, 30a, 30b, 30c, 30d, and 30e.
31 Heat Transfer Tube
32 Heat pipe group
33, 33b, 34, 34a, and 34b
35, 35a, 35b body body
36, 36b Exhaust steam inlet (opening)
37, 37a, 37b Bypass steam inlet (opening)
41 intermediate body
42 Steam Furnace
51, 51a, 51b, 51c Bypass steam receiving portion
52 Bypass Vapor Containment Box
53 High Pressure Steam Injector
54 Reheat steam ejector
55-thrusters
56 Water Spout (Water Spout)
58 Impingement plate
59 Impingement Road

Claims (7)

A heat transfer pipe group composed of a plurality of heat transfer tubes for passing the heat exchange medium with the exhaust steam exhausted from the steam turbine and returning the exhaust steam to water,
A body body covering the heat transfer pipe group,
An intermediate body disposed between the steam turbine and the body body to connect the steam turbine and the body body to form a steam oil passage for leading the exhaust steam from the steam turbine to the group of heat transfer tubes in the main body body,
A bypass steam receiving portion for receiving the bypass steam bypassing the steam turbine and guiding the bypass steam to the heat transfer tube group in the body body through an opening formed in the body body,
And,
Wherein the bypass steam receiving portion is disposed outside the steam oil passage,
The opening of the main body body is formed at a position where the bypass steam mainly flows into the heat transfer pipe group from a region different from the inflow region where the exhaust steam mainly flows into the heat transfer pipe group via the steam main oil passage
Conspiracy. The method according to claim 1,
And a flow restraining member for suppressing the flow of the bypass steam received in the bypass steam receiving portion toward the heat transfer pipe group
Conspiracy. The method according to claim 1 or 2,
And a water jetting portion for jetting water into the bypass steam receiving portion
Conspiracy. The method according to any one of claims 1 to 3,
The steam turbine is of a horizontal exhaust type that exhausts steam in the axial direction of the rotor of the steam turbine or laterally of the steam turbine,
Wherein the intermediate body is connected to a side portion of the body body,
Wherein the bypass steam receiving portion is provided at one of an upper portion of the body body and a portion of the body body opposite to the portion to which the intermediate body is connected with respect to the heat transfer tube group as a side portion of the body body
Conspiracy. The method according to any one of claims 1 to 3,
Wherein the steam turbine is a downward exhaust type for exhausting steam downward of the steam turbine,
Wherein the intermediate body is connected to an upper portion of the body body,
The bypass steam receiving portion is a side portion of the body body and is provided at a position facing the heat transfer tube group in the horizontal direction
Conspiracy. A device according to any one of claims 1 to 5,
The steam turbine,
A steam supplier for supplying steam to the steam turbine,
A bypass steam line for bypassing the steam turbine and guiding the steam from the steam supplier to the bypass steam receiving section,
≪ / RTI > A device according to any one of claims 3 to 5,
The steam turbine,
A steam supplier for supplying steam to the steam turbine,
A water supply pump for returning water obtained by condensation of the exhaust steam to the steam supplier in the condenser,
A bypass steam line for bypassing the steam turbine and guiding the steam from the steam supplier to the bypass steam receiver,
And a water discharge line for guiding the water pressurized by the water supply pump to the water discharge portion
≪ / RTI >

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