JP2013213474A - Power plant - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power plant in which impurities can be reduced and cost can be reduced.SOLUTION: A power plant 1 includes: a steam generator 2; a turbine 3 in which steam generated by the steam generator is guided; a condenser 4 that collects the steam for driving the turbine 3 as condensed water; a first desalting device 6 into which the condensed water derived from the condenser is introduced; and a main flow path 10 that circulates the steam or the condensed water between the steam generator 2, the turbine, the condenser 4 and the first desalting device 6. The power plant has an outside air contact lines 11, 13 that are connected to bypass the main flow path 10 and where the steam contacts the outside air, and the outside air contact lines 11, 13 have second desalting devices 33, 63 into which the steam is introduced.

Description

  The present invention relates to a power plant.

  In general, in a power plant such as a thermal power plant or a nuclear power plant, a turbine is driven by steam generated by a steam generator to generate power, and the discharged steam is recovered by a condenser and reheated by a heat exchanger. Therefore, a circulation path is provided so as to return to the steam generator in a high temperature state.

Here, for example, in a power plant of a nuclear power plant, if impurities such as Na, Cl, SO ₄ are mixed in the fluid circulating in the circulation path, there is a possibility that the equipment constituting the power plant is corroded. Therefore, in order to suppress the impurity concentration, a purification device is generally installed on the downstream side of the condenser.

Here, as a purification apparatus, a technique is proposed that is constituted by an ion exchange resin composed of a cation exchange resin and an anion exchange resin capable of adsorbing Na ions, Cl ions, and SO ₄ ions (Patent Document 1 below). reference). Thereby, it becomes possible to reduce the impurity concentration in the power plant by adsorbing and removing impurities.

Japanese Patent No. 3760033

  However, in a power plant configured to provide a purification device downstream of the condenser, the amount of fluid flowing through the circulation path is enormous, so a large-scale purification device is provided to sufficiently remove impurities. There is a need. Therefore, there is a problem that the initial cost increases as the scale of the facility increases.

In addition, the ion exchange resin adsorbs impurities or adsorbs pH adjusters such as ammonia added to the circulating fluid even when there are no impurities, so the adsorption performance of the ion exchange resin decreases as the amount of adsorption increases. To do. Therefore, it is necessary to periodically purify the ion exchange resin with a strong alkali or strong acid, or to wash and regenerate it with pure water, which increases the running cost.
Furthermore, since the ion exchange resin deteriorates due to heat and oxidation, it is necessary to periodically exchange the ion exchange resin itself, which also increases the running cost.

  The present invention has been made in view of such circumstances, and provides a power plant that can reduce impurities and reduce costs in the power plant.

  Here, when the inventors of the present invention conducted extensive research on the impurity concentration of such a power plant, there is a correlation between the fluctuation of the impurity concentration in the power plant and the amount of suspended matter in the atmosphere. I finally got some knowledge.

In order to solve the above problems, the present invention proposes the following means based on the above findings.
That is, a power plant according to the present invention includes a steam generator, a turbine into which steam generated by the steam generator is introduced, a condenser that recovers steam that has driven the turbine as condensate, and the condenser. The steam or the condensate is circulated between the first demineralizer into which the condensate derived from the water vessel is introduced, and the steam generator, the turbine, the condenser, and the first demineralizer. A power plant comprising: a main flow path that is connected to bypass the main flow path and includes an outside air contact line that contacts the outside air, and the outside air contact line is a second where the steam is introduced. It has a desalting apparatus.

According to such a power plant, even when there is an impurity in the steam mixed with outside air, the steam is introduced into the second demineralizer in the outside air contact line and the impurity is removed by the second demineralizer. can do. Therefore, since the fluid with reduced impurity concentration can be returned to the main flow path, impurities in the power plant can be reduced.
Moreover, since the amount of steam introduced into the second desalting apparatus is not large, it is possible to employ a second desalting apparatus that suppresses initial cost and running cost.

  In the power plant according to the present invention, the outside air contact line is provided with an ejector device that circulates the outside air mixed in with the steam introduced from the condenser, and the steam provided on the downstream side of the ejector device. It is preferable that the second demineralizer is provided on the downstream side of the exhaust gas cleaning device.

  According to such a power plant, impurities can be reliably removed by the second demineralizer from the steam introduced from the condenser and from which the gas has been removed. Therefore, since the fluid with reduced impurity concentration can be returned to the main channel, impurities in the power plant can be reliably reduced.

  The power plant according to the present invention includes a heat exchanger for exchanging heat of the condensate introduced from the condenser, and the outside air contact line mixes the outside air into the steam leaked from the turbine. And a steam introduction line that introduces the condensed water generated by heat exchange of the steam in the heat exchanger to the downstream side of the exhaust gas cleaning apparatus. It may be composed of two outside air contact lines.

  According to such a power plant, impurities can be reliably removed by the second demineralizer from the steam introduced from the steam turbine and the steam introduced from the condenser and the gas removed. Therefore, since the fluid with reduced impurity concentration can be returned to the main flow path by the cleaning device side lead-out line, impurities in the power plant can be reliably reduced.

  The power plant according to the present invention includes a heat exchanger for exchanging heat of the condensate led out from the condenser, and the outside air contact line mixes the outside air into the steam leaked from the turbine. The third outside air has a steam introduction line that is introduced into the heat exchanger and a condenser-side lead-out line that introduces condensed water generated by heat exchange of the steam in the heat exchanger into the condenser. You may be comprised by the contact line.

  According to such a power plant, impurities can be reliably removed from the steam introduced from the steam turbine by the second demineralizer. Therefore, since the fluid with reduced impurity concentration can be returned to the main flow path by the condenser side outlet line, impurities in the power plant can be reliably reduced.

  According to the power plant according to the present invention, impurities can be removed by the second demineralizer, and the fluid with reduced impurity concentration can be returned to the main flow path, so that impurities in the power plant can be reduced, Cost can be reduced.

1 is a system diagram of a power plant according to a first embodiment of the present invention. It is a systematic diagram of the power plant which concerns on 2nd embodiment of this invention. It is a systematic diagram of the power plant which concerns on the modification of 2nd embodiment of this invention.

(First embodiment)
Hereinafter, a power plant according to a first embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a system diagram of a power plant according to the present embodiment.

(Power plant)
The power plant 1 includes a steam generator 2, a turbine 3, a condenser 4, a ground condenser 5 (heat exchanger), a first demineralizer 6, a heater 7, a main channel 10, One outside air contact line 11 (outside air contact line) and a third outside air contact line 13 (outside air contact line) are provided.

  The steam generator 2 is a device that generates steam by heat exchange. When the power plant 1 is a nuclear power plant, the steam generator 2 generates steam based on the heat extracted from the nuclear reactor. When the power plant 1 is a thermal power plant, the steam generator 2 corresponds to a boiler.

The turbine 3 is rotationally driven by the introduction of steam generated by the steam generator 2.
When the turbine 3 is rotationally driven, it is transmitted to a generator (not shown), and the generator performs a power generation operation.

  The condenser 4 cools the steam that has driven the turbine 3 using cooling water such as seawater and collects it as condensate. The condenser 4 is provided with a cooling water introduction line 51 for introducing cooling water and a discharge line 52 for discharging the used cooling water.

  The ground condenser 5 exchanges heat between the condensate derived from the condenser 4 and steam introduced from a third outside air contact line 13 described later.

The first demineralizer 6 receives the condensate derived from the ground condenser 5 and removes impurities contained in the condensate.
Examples of impurities include K ⁺ , Ca ²⁺ , Na ⁺ , Mg ²⁺ , Cl ⁻ , SO ₄ ^{2−, and the} like.

  The heater 7 exchanges heat between the condensate led out from the first demineralizer 6 and the bleed air introduced from the turbine 3 (not shown) to raise the temperature of the condensate and introduce it into the steam generator 2. To do.

  The main flow path 10 includes a first connection pipe 21 that connects the steam generator 2 and the turbine 3, a second connection pipe 22 that connects the condenser 4 and the ground capacitor 5, and the ground capacitor 5 and the first outlet. A third connection pipe 23 that connects the salt device 6, a fourth connection pipe 24 that connects the first desalination device 6 and the heater 7, and a second connection pipe that connects the heater 7 and the steam generator 2. And five connecting pipes 25.

  Steam and condensate are circulated in the first connection pipe 21, the second connection pipe 22, the third connection pipe 23, the fourth connection pipe 24, and the fifth connection pipe 25.

  The 1st external air contact line 11 and the 3rd external air contact line 13 are connected so that the main flow path 10 may be bypassed, and it becomes the structure which a vapor | steam contacts with external air.

(First outside air contact line)
In the present embodiment, both ends of the first outside air contact line 11 are connected to the condenser 4, and an ejector device 31, an exhaust gas cleaning device 32 provided on the downstream side of the ejector device 31, and the exhaust gas cleaning A washing-side desalination device 33 (second desalination device) provided on the downstream side of the device 32 and a condensate tank 34 for storing condensate provided on the downstream side of the washing-side desalination device 33 are provided. doing.

  Further, the first outside air contact line 11 includes a first bypass pipe 41 that connects the condenser 4 and the ejector device 31, a second bypass pipe 42 that connects the ejector device 31 and the exhaust gas cleaning device 32, A third bypass pipe 43 connecting the exhaust gas cleaning device 32 and the cleaning-side desalination device 33, a fourth bypass pipe 44 connecting the cleaning-side desalting device 33 and the condensate tank 34, and the condensate tank 34 And a fifth bypass pipe 45 connecting the condenser 4.

  The ejector device 31 mixes the outside air purified by a filter (not shown, the same applies hereinafter) into the vapor led out from the condenser 4 and introduced into the first outside air contact line 11 so as to be in a vacuum state. This is a device that circulates toward the position 32.

  This ejector device 31 has a configuration in which a mechanical pump and an air ejector are combined (not shown; the same applies hereinafter). In a low vacuum range, a large volume of air is extracted by a hogging operation using a mechanical pump, and a high vacuum is obtained. In the area, high vacuum can be maintained by holding operation with air ejector.

  The exhaust gas cleaning device 32 makes the vapor derived from the ejector device 31 contact a liquid cleaning liquid such as water to remove volatile gas such as ammonia from the vapor.

(Washing side desalination equipment)
The cleaning-side desalting apparatus 33 is made of, for example, an H—OH type ion exchange resin, and removes impurities contained in the vapor derived from the exhaust gas cleaning apparatus 32.

(Third outside air contact line)
In the present embodiment, the third outside air contact line 13 includes a steam introduction line 61 that connects the turbine 3 and the ground condenser 5, a condenser side lead-out line 62 that connects the ground condenser 5 and the condenser 4, A condenser-side desalinator 63 (second desalter) provided in the condenser-side lead-out line 62.

  In the steam introduction line 61, outside air is mixed into steam leaking from a seal portion (not shown; the same applies hereinafter) between the rotor and the bearing in the turbine 3 and introduced into the ground condenser 5.

  The condenser-side lead-out line 62 introduces the condensed water generated by the ground condenser 5 into the condenser 4, and a sixth bypass pipe 46 that connects the ground condenser 5 and the condenser-side demineralizer 63. And a seventh bypass pipe 47 for connecting the condenser-side desalinator 63 and the condenser 4.

(Capacitor-side desalination equipment)
The capacitor-side desalinator 63 is made of, for example, an H—OH type ion exchange resin, and removes impurities contained in the vapor derived from the ground capacitor 5.

  Next, the steam and condensate flow paths in the power plant according to the present embodiment will be described.

  The steam generated in the steam generator 2 is introduced into the turbine 3 via the first connection pipe 21 to operate the turbine 3. The steam that has driven the turbine 3 is cooled by the cooling water introduced through the cooling water introduction line 51 in the condenser 4 and recovered as condensed water. Condensate derived from the condenser 4 is introduced into the ground capacitor 5 via the second connection pipe 22.

  On the other hand, the steam introduced from the turbine 3 through the steam introduction line 61 and mixed with the outside air into the ground condenser 5 is heat-exchanged with the condensate introduced from the second connection pipe 22 to form condensed water whose temperature has decreased. It leads to the sixth bypass pipe 46.

  The condensed water led out to the sixth bypass pipe 46 is introduced into the condenser-side desalinator 63, impurities are removed in the condenser-side desalinator 63, and introduced into the condenser 4 through the seventh bypass pipe 47. Is done.

  On the other hand, the condensate heat-exchanged in the ground condenser 5 is introduced into the first desalinator 6 via the third connection pipe 23 in a state where the temperature has risen due to heat exchange in the ground condenser 5. The condensate from which impurities have been removed in the first desalting apparatus 6 is introduced into the heater 7 via the fourth connecting pipe 24, and the temperature is raised in the heater 7 and introduced into the steam generator 2. The

  The steam introduced from the condenser 4 via the first bypass pipe 41 into the ejector device 31 is mixed with outside air and introduced into the exhaust gas cleaning device 32 via the second bypass pipe 42. The vapor from which the gas has been removed in the exhaust gas cleaning device 32 is introduced into the cleaning-side desalination device 33 via the third bypass pipe 43.

  The steam from which impurities have been removed in the washing-side desalinator 33 is stored in the condensate tank 34 via the fourth bypass pipe 44 and introduced into the condenser 4 via the fifth bypass pipe 45. The

Next, the operation and effect of the power plant 1 configured as described above will be described.
In the power plant 1 configured as described above, even if there is an impurity in the steam mixed with the outside air, the steam is removed from the washing side desalinator 33 in the first outside air contact line 11 and the condenser in the third outside air contact line 13. It can be introduced into the side demineralizer 63. Then, impurities can be reliably removed in the washing-side desalting apparatus 33 and the capacitor-side desalting apparatus 63. Therefore, since the fluid having a reduced impurity concentration can be returned to the main flow path 10, impurities in the power plant 1 can be reliably reduced.

  Further, since the amount of steam introduced into the washing-side desalinator 33 and the condenser-side desalinator 63 is not large, the initial cost and the running cost can be suppressed.

(Second embodiment)
Hereinafter, the power plant 201 which concerns on 2nd embodiment of this invention is demonstrated using FIG.
In this embodiment, members that are the same as those used in the above-described embodiment are assigned the same reference numerals, and descriptions thereof are omitted.

  The outside air contact line in the first embodiment includes a first outside air contact line 11 and a third outside air contact line 13. On the other hand, the outside air contact line in the present embodiment includes a first outside air contact line 11 and a second outside air contact line 12.

  That is, the second outside air contact line 12 includes a steam introduction line 61 that connects the turbine 3 and the ground condenser 5, and a cleaning device side lead-out line 64 that connects the ground condenser 5 and the first outside air contact line 11. ing.

  The cleaning device side lead-out line 64 has one end connected to the ground capacitor 5 and the other end connected to the third bypass pipe 43 in the first outside air contact line 11. The cleaning device side lead-out line 64 introduces the condensed water generated by the ground condenser 5 to the downstream side of the exhaust gas cleaning device 32.

  In the power plant 201 configured as described above, even when there is an impurity in the steam mixed with outside air, the steam can be introduced into the cleaning-side desalinator 33 in the first outside air contact line 11. And in the washing | cleaning side desalination apparatus 33, an impurity can be removed reliably. Therefore, since the fluid with reduced impurity concentration can be returned to the main flow path 10, impurities in the power plant 201 can be reliably reduced.

  Furthermore, although the system | strain in which external air is mixed is two systems, the 1st external air contact line 11 and the 2nd external air contact line 12, since only the washing | cleaning desalination apparatus 33 is installed as a desalination apparatus installed, Costs can be further reduced than in one embodiment.

(Modification of the second embodiment)
Further, as shown in FIG. 3, as a modification of the second embodiment, a power plant 301 in which the position of the washing-side desalinator 35 in the first outside air contact line 11 is provided on the downstream side of the condensate tank 34. Also good.

  Even in this case, since the steam can be introduced into the washing-side desalinator 35 in the first outside air contact line 11, impurities can be reliably removed. Therefore, since the fluid with reduced impurity concentration can be returned to the main flow path 10, impurities in the power plant 301 can be reliably reduced.

  The various shapes and combinations of the constituent members shown in the above-described embodiments are merely examples, and various modifications can be made based on design requirements and the like without departing from the gist of the present invention.

  For example, since there is no possibility that seawater is mixed into the first outside air contact line 11, the second outside air contact line 12, and the third outside air contact line 13, the washing-side desalting devices 33 and 35 and the condenser-side desalting device 63 are provided. You may comprise with an ammonia type ion exchange resin. In this case, since the exchange of the ion exchange resin becomes unnecessary, the running cost can be further reduced.

  Further, the amount of steam flowing through the first outside air contact line 11, the second outside air contact line 12, and the third outside air contact line 13 is increased and processed by the cleaning side desalting devices 33 and 35 and the condenser side desalting device 63. The amount of steam to be increased may be increased. In this case, since the amount of steam to be processed by the first desalting apparatus 6 can be reduced, the first desalting apparatus 6 can be reduced in size to reduce the cost of the power plant 1, 201, 301 as a whole. Can do.

  Moreover, it is also possible to employ a zeolite-type adsorbent configuration for the washing-side desalting devices 33 and 35 and the capacitor-side desalting device 63. In this case, since the zeolite-type adsorbent has high durability, it is possible to improve the maintainability and reduce the running cost.

  Moreover, it is also possible to employ | adopt the structure of RO membrane (reverse osmosis membrane) for the washing | cleaning side desalination apparatuses 33 and 35 and the capacitor | condenser side desalination apparatus 63. FIG. In this case, since a treatment with a strong alkali or strong acid is not required to regenerate the resin, it is favorable in terms of environment.

  Further, a large number of filters may be provided on the inlet side of the ejector device 31 and the seal portion in the turbine 3, a high performance filter may be provided, or the exhaust gas cleaning device 32 may be provided. Thereby, it becomes possible to reduce the amount of outside air mixed into the first outside air contact line 11, the second outside air contact line 12, and the third outside air contact line 13, and impurities can be reduced.

DESCRIPTION OF SYMBOLS 1 ... Power plant 2 ... Steam generator 3 ... Turbine 4 ... Condenser 5 ... Ground condenser (heat exchanger)
6 ... 1st desalination apparatus 10 ... Main flow path 11 ... 1st outside air contact line (outside air contact line)
12 ... Second outside air contact line (outside air contact line)
13 ... Third outside air contact line (outside air contact line)
31 ... Ejector device 32 ... Exhaust gas cleaning device 33 ... Cleaning-side desalination device (second desalination device)
61 ... Steam introduction line 62 ... Condenser side outlet line 63 ... Condenser side desalination equipment (second desalination equipment)
64 ... Cleaning device side lead-out line

Claims (4)

A steam generator;
A turbine into which steam generated by the steam generator is introduced;
A condenser that collects steam that has driven the turbine as condensate;
A first demineralizer for introducing the condensate derived from the condenser;
A power plant comprising a main flow path for circulating the steam or the condensate between the steam generator, the turbine, the condenser and the first demineralizer,
Connected to bypass the main flow path, comprising an outside air contact line where the steam contacts outside air,
The outdoor air contact line has a second desalination device into which the steam is introduced. The power plant according to claim 1,
The outside air contact line includes an ejector device that mixes and flows the outside air into the steam introduced from the condenser, and an exhaust gas cleaning device that is provided downstream of the ejector device and removes gas in the steam. A first outside air contact line having
Said 2nd desalination apparatus is provided in the downstream of the said waste gas cleaning apparatus, The power plant characterized by the above-mentioned. The power plant according to claim 2,
A heat exchanger for exchanging heat of the condensate introduced from the condenser;
The outside air contact line includes a steam introduction line in which the outside air is mixed into the steam leaked from the turbine and introduced into the heat exchanger, and condensed water generated by heat exchange of the steam in the heat exchanger. A power plant comprising a second outside air contact line having a cleaning device side lead-out line introduced downstream of the exhaust gas cleaning device. In the power plant as described in any one of Claim 1 or Claim 2,
A heat exchanger for exchanging heat of the condensate derived from the condenser;
The outside air contact line includes a steam introduction line in which the outside air is mixed into the steam leaked from the turbine and introduced into the heat exchanger, and condensed water generated by heat exchange of the steam in the heat exchanger. A power plant comprising a third outside air contact line having a condenser side lead-out line to be introduced into the condenser.

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