JPH11166481A - Discharge regulator of condensate pump - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide the discharge regulator of a codensate pump which is used in a condensing and water-supplying device of a plant using commonly the minimum flow bypass line of high pressure condensate pump and nuclear reactor water-supplying pump and which protects the high pressure condensate pump through regulation of its/their rate of flow in case there is a difference in the Q-H characteristics between a plurality of high pressure condensate pumps. SOLUTION: The discharge regulator of a condensate pump is configured so that a plurality of high pressure condensate pumps 4a and 4b are in parallel connection for boosting the condensate for water heaters 5 and 8 and water- supplying pumps 6 and 7 of a nuclear power plant, wherein circulative pipings 25a and 25b in which circulation stopping valves 22a and 22b, circulation check valves 23a and 23b, and orifices 24a and 24b are interposed in series arrangement are connected between the discharge side and suction side of each high pressure condensate pump 4a/4b.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a condensate and water supply device in a power plant, and more particularly to a condensate pump flow control device for securing and protecting a minimum flow rate of a high-pressure condensate pump.

[0002]

2. Description of the Related Art A condensate and water supply device in a power plant will be described by taking as an example a condensate and water supply device that shares a minimum flow bypass system of a high-pressure condensate pump and a motor-driven reactor feed pump in a nuclear power plant. As shown in the system configuration diagram of FIG. 6, exhaust steam from a steam turbine (not shown) exchanges heat with cooling water in a cooling pipe in a condenser 1, is condensed and condensed, and is stored in a well. You.

The stored condensate is supplied to a low-pressure condensate pump 2
a, 2b, high-pressure feed water heaters from a condensate purification device 3, high-pressure condensate pumps 4a, 4b and a low-pressure feed water heater 5, and a turbine-driven reactor feed water pump 6 or a motor-driven reactor feed water pump 7. After being raised to a predetermined temperature and pressure via 8, it is supplied to a nuclear reactor (not shown).

The low-pressure condensate pumps 2a and 2b and the high-pressure condensate pumps 4a and 4b are generally provided with three 50% capacity pumps, one of which is operated as a standby unit. For simplicity, FIG. 6 shows the low-pressure condensate pumps 2a and 2b and the high-pressure condensate pumps 4a and 4b
Only the stand is shown.

The motor-driven reactor feed pump 7 (usually two units) having a capacity of 25% of the feed water flow rate is used when starting and stopping the plant. At other times, the 50% capacity of the feed water flow rate is reduced. Of the turbine-driven reactor feed pump 6 (usually two units). In addition,
For easy understanding, FIG. 6 shows the turbine-driven reactor feed pump 6 and the motor-driven reactor feed pump 7.
Indicates only one unit.

Further, a minimum flow bypass pipe having a minimum flow bypass valve 9 and a minimum flow bypass stop valve 10 inserted in series between the discharge side of the turbine-driven reactor feed pump 6 and the condenser 1 is provided. 11 is connected. Further, a minimum flow bypass pipe 14 in which a minimum flow bypass valve 12 and a minimum flow bypass stop valve 13 are inserted in series is connected between the discharge side of the electric motor driven reactor feed pump 7 and the condenser 1. ing.

The low-pressure condensate pumps 2 a and 2 b and the condensate purifying device 3 have a condensate recirculation valve 15 interposed between the discharge side of the condensate purifying device 3 and the condenser 1. A water recirculation pipe 16 is connected. Further, the high-pressure condensate pump 4a,
The suction pipes 17a and 17b on the suction side of 4b have suction valves 18a and 18b, respectively, and the discharge pipes 19a and 19b on the discharge side have discharge check valves 20a and 20b and discharge valves 21a and 21b in series. Has been inserted.

When starting up a nuclear power plant, first,
Low-pressure condensate pumps 2a and 2b, and high-pressure condensate pump 4
a and 4b are started, and at this time, the supply water flow rate required by the reactor is small. At this time, if the minimum flow rate of the high-pressure condensate pump is larger than the supply flow rate required by the reactor, the minimum flow rate should be ensured in order to stably maintain the operation of the high-pressure condensate pumps 4a and 4b. Is required.

Therefore, the minimum flow bypass pipes for the high pressure condensate pumps 4a, 4b and the electric motor driven reactor feed pump 7 are provided.
At this time, in the condensate and water supply device sharing the same 14, the minimum flow bypass valve 12 of the minimum flow bypass pipe 14 is opened to secure the minimum flow in the high-pressure condensate pumps 4a and 4b. I have. The minimum flow rate of the low-pressure condensate pumps 2a and 2b is shared with the condensate recirculation pipe 16 interposed with the condensate recirculation valve 15 used for the condensate purification operation.

[0010]

With respect to nuclear power plants that are currently in operation, various techniques have been taken to maintain plant performance as the aging progresses.
In order to regenerate the condensate pump, it is conceivable to replace the impellers in the high-pressure condensate pumps 4a and 4b. At this time, the following problem occurs.

The impeller of the high-pressure condensate pump is manufactured by casting. Naturally, the discharge-head characteristics (hereinafter QH characteristics) of the high-pressure condensate pump largely depends on the shape of the impeller. Therefore, the same mold is used in the manufacture of the impeller of the high-pressure condensate pump operated in parallel.

When replacing the impeller for some of the high-pressure condensate pumps operated in parallel in the aging plant, if the impeller manufacturing mold used during construction is not stored. Must create a new mold and use that mold to produce an impeller. However, this causes a difference in QH characteristics between the high-pressure condensate pump whose impeller is replaced and the high-pressure condensate pump whose impeller is not replaced.

[0013] In this state, in the condensate and water supply device sharing the minimum flow bypass line of the high-pressure condensate pump and the motor-driven reactor water supply pump, the high-pressure condensate pumps having different QH characteristics are operated in parallel. Then, as shown in the QH characteristic curve diagram of FIG. 7, a flow rate imbalance occurs, so that an event occurs in which one of the high-pressure condensate pumps cannot secure its own minimum flow rate. The QH characteristic curve and the like in FIG. 7 show the following, respectively.

L ₁ : QH characteristic curve of one high-pressure condensate pump. L ₂ ... QH characteristic composite curve when two high pressure condensate pumps having the QH characteristic of L ₁ are operated in parallel. L ₃ ... Q-H characteristic curve of one high-pressure condensate pump after Q-H characteristic is changed due to replacement of the impeller.

L ₄ ... QH characteristic composite curve when two high pressure condensate pumps having QH characteristics of L ₁ and L ₃ are operated in parallel. P _{1 -4} … Operation state. Q ₁ ... The minimum flow rate of the high-pressure condensate pump having the QH characteristic of L ₁ . Q ₂ : The minimum flow rate of the high-pressure condensate pump having the QH characteristic of L ₃ .

Q ₃ : High-pressure condensate pump flow rate in the operating state P ₃ . That is, conventionally, the condensate flow rate during operation of two high-pressure condensate pumps is Q
If the operation is performed at ₁ × 2, the minimum flow rates of the two operating high-pressure condensate pumps are secured (operation state P ₁ ).

However, when the QH characteristic of one of the high-pressure condensate pumps changes (the QH characteristic curve changes from L _{1 to} L ₃ ), the condensate flow rate is changed to the conventional minimum flow rate operating state P ₁ . If I left, since it becomes as shown in the operating state P _2, the high-pressure condensate pump when this is operated at operating conditions P ₃ and P _4.

Here, when the minimum flow rate Q ₂ > Q ₁ , at least the minimum flow rate Q ₃ <Q _1. Therefore, the high-pressure condensate pump having the QH characteristic of L ₁ operates at the minimum flow rate or less. I will. Therefore, if the operation of the high-pressure condensate pump is continued in this state, there is a problem that the operation of the high-pressure condensate pump becomes extremely unfavorable from the viewpoint of maintaining stable operation and protection due to generation of vibrations.

An object of the present invention is to provide a condensing and water supply system for a plant that shares a minimum flow bypass system for a high-pressure condensate pump and a reactor water supply pump. An object of the present invention is to provide a condensate pump flow control device that controls the flow rate of a high-pressure condensate pump and protects the high-pressure condensate pump when a difference occurs in characteristics.

[0020]

According to a first aspect of the present invention, there is provided a flow control device for a condensate pump, comprising:
In a condensate pump flow control device for operating a plurality of high-pressure condensate pumps for increasing condensate water in a feedwater heater and a feedwater pump of a nuclear power plant, a discharge side and a suction side of each of the high-pressure condensate pumps A circulation pipe having a stop valve, a check valve, and an orifice inserted in series is connected between them.

When a plurality of high-pressure condensate pumps are operated in parallel, a stop valve in the circulation pipe of the high-pressure condensate pump, which is operating at the minimum flow rate, is opened, and a part of the discharge flow from the discharge side of the high-pressure condensate pump is reduced. The addition at the suction side of the high-pressure condensate pump via the circulation pipe increases the suction flow rate of the high-pressure condensate pump to avoid occurrence of the minimum flow rate operation.

According to a second aspect of the present invention, there is provided a condensate pump flow control device for operating a plurality of high-pressure condensate pumps for increasing condensate pressure in a feedwater heater and a feedwater pump of a power plant in parallel. In the adjusting device, a circulation pipe in which a stop valve, a check valve, and an orifice are inserted in series is connected between an integrated discharge side and an integrated suction side of the plurality of high-pressure condensate pumps.

In the parallel operation of a plurality of high-pressure condensate pumps, when the high-pressure condensate pump is operating at the minimum flow rate, the stop valve inserted in the circulation pipe is opened to adjust the discharge flow rate of the total high-pressure condensate pump. By adding a part to the suction side of the full high-pressure condensate pump via the circulation pipe, the total suction flow rate is increased to avoid the occurrence of the minimum flow rate operation.

According to a third aspect of the present invention, there is provided a condensate pump flow control device for operating a plurality of high-pressure condensate pumps for increasing the condensate pressure in a feedwater heater and a feedwater pump of a power plant in parallel. In the adjusting device, a flow control pipe in which a stop valve, a check valve, and an orifice are inserted in series is connected between a discharge side of the high-pressure condensate pump and a suction side of a different high-pressure condensate pump. I do.

When a plurality of high-pressure condensate pumps are operated in parallel, a stop valve in the flow control pipe of the high-pressure condensate pump, which is operating at the minimum flow rate, is opened, and the discharge flow rate from the discharge side of the normally operating high-pressure condensate pump is reduced. By adding a part to the suction side of the high-pressure condensate pump via the flow control pipe, the suction flow rate of the high-pressure condensate pump is increased to avoid the occurrence of the minimum flow rate operation.

According to a fourth aspect of the present invention, there is provided a condensate pump flow rate adjusting device for operating a plurality of high pressure condensate pumps for increasing the condensate pressure in a feed water heater and a feed water pump of a power plant in parallel. In the adjusting device, between the integrated discharge side of the plurality of high-pressure condensate pumps and the minimum flow bypass pipe of the turbine-driven reactor feed pump, a flow control pipe in which a stop valve, a check valve, and an orifice are inserted in series is provided. It is characterized by being connected.

In the parallel operation of a plurality of high-pressure condensate pumps, when the high-pressure condensate pump is operating at the minimum flow rate, the stop valve inserted in the flow control pipe is opened, and the discharge flow rate of the total high-pressure condensate pump is increased. Is flowed through the flow control pipe to the minimum flow bypass pipe of the turbine-driven reactor feed pump, thereby increasing the discharge flow rate of the full high-pressure condensate pump and avoiding the minimum flow operation.

According to a fifth aspect of the present invention, in the condensate pump flow control device according to the fourth aspect, the stop valve inserted into the flow control pipe is a remotely operated stop valve and a plurality of high pressure condensate pumps are simultaneously operated. An interlock for forcibly opening the remote control stop valve when starting is provided.

When the high-pressure condensate pump is operating at the minimum flow rate, the discharge flow rate of the entire high-pressure condensate pump can be easily controlled by opening a remote control stop valve inserted in the flow control pipe by remote control. To avoid the occurrence of the minimum flow rate operation. In addition, when starting a plurality of high-pressure condensate pumps at the same time, the interlock provided beforehand forcibly opens the stop valve of the remote control before starting, thereby avoiding the occurrence of the minimum flow rate operation for all the high-pressure condensate pumps. Is done.

According to a sixth aspect of the present invention, there is provided a condensate pump flow control apparatus for operating a plurality of high-pressure condensate pumps for increasing condensate pressure in a feedwater heater and a feedwater pump of a power plant in parallel. The adjusting device is characterized in that a suction valve that can be throttled is inserted on the suction side of each of the high-pressure condensate pumps.

In parallel operation of a plurality of high-pressure condensate pumps, when the high-pressure condensate pump is operating at the minimum flow rate, the throttle-operable suction valve of the high-pressure condensate pump in the normal operation state is appropriately throttled. The head of the high-pressure condensate pump in the normal operation state rises and the flow rate decreases. In addition, this reduced flow rate is added to the suction flow rate in the high-pressure condensate pump which is being operated in the minimum flow rate operation, so that the flow rate is increased and the occurrence of the minimum flow rate operation is avoided.

According to a seventh aspect of the present invention, there is provided a condensate pump flow control device according to the seventh aspect, wherein the squeezable suction valve inserted on the suction side of each high-pressure condensate pump is remotely operated. It is characterized by having. When the high-pressure condensate pump is starting to operate at the minimum flow rate, the discharge flow rate of the high-pressure condensate pump is increased by an easy operation by appropriately squeezing the suction valve that can be throttled by remote control, thereby performing the minimum flow rate operation. Avoid the occurrence of

[0033]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described with reference to the drawings. Note that the same components as those of the above-described related art are denoted by the same reference numerals, and detailed description thereof will be omitted. The first embodiment relates to claim 1, wherein the condensate pump flow control device is configured such that, as shown in the system configuration diagram of FIG. 1, exhaust steam from a steam turbine (not shown) is introduced into a condenser 1 and condensed. However, the condenser 1 includes a low-pressure condensate pump 2
A plurality of high-pressure condensate pumps 4a, 4b are connected in parallel with the a, 2b and the condensate purification device 3.

The high-pressure condensate pumps 4a and 4b are connected to a turbine-driven reactor feed pump 6 and an electric motor-driven reactor feed pump 7, which are connected in parallel with the low-pressure feed heater 5 in series. Is connected to a high-pressure feed water heater 8 that raises the temperature to a predetermined temperature and pressure and supplies it to a reactor (not shown). The low-pressure condensate pumps 2a and 2b and the high-pressure condensate pumps 4a and 4b are generally provided with three units each having a capacity of 50%, and one of them is operated as a spare unit. 2 each to make
Only the stand is shown.

The motor-driven reactor water supply pump 7 (usually two units) having a capacity of 25% of the feed water flow rate is used when starting and stopping the plant. At other times, the 50% capacity of the feed water flow rate is reduced. Of the turbine-driven reactor feed pump 6 (usually two units). In addition,
For ease of understanding, only one turbine-driven reactor feedwater pump 6 and one motor-driven reactor feedwater pump 7 are shown.

Further, a minimum flow bypass pipe having a minimum flow bypass valve 9 and a minimum flow bypass stop valve 10 inserted in series between the discharge side of the turbine-driven reactor water supply pump 6 and the condenser 1. 11 is connected. Further, a minimum flow bypass pipe 14 in which a minimum flow bypass valve 12 and a minimum flow bypass stop valve 13 are inserted in series is connected between the discharge side of the electric motor driven reactor feed pump 7 and the condenser 1. ing.

In the low-pressure condensate pumps 2a and 2b and the condensate purifier 3, the minimum flow rate in the low-pressure condensate pumps 2a and 2b is set between the discharge side of the condensate purifier 3 and the condenser 1. In order to secure the condensate, a condensate recirculation pipe 16 interposed with a condensate recirculation valve 15 used for a condensate purification operation is connected. The suction pipes 17a, 17b on the suction side of the high-pressure condensate pumps 4a, 4b are respectively provided with suction valves 18a, 18b.
However, discharge check valves 20a and 20b and discharge valves 21a and 21b are inserted in series in the discharge pipes 19a and 19b on the discharge side, respectively.

Further, in order to secure the minimum flow rate in the high-pressure condensate pumps 4a and 4b, the connection between the discharge check valves 20a and 20b and the discharge valves 21a and 21b, which are the respective discharge sides, and the suction side. A configuration in which circulation pipes 25a and 25b in which circulation stop valves 22a and 22b, circulation check valves 23a and 23b, and flow restriction orifices 24a and 24b are inserted in series between certain suction pipes 17a and 17b. And

Next, the operation of the above configuration will be described. When the nuclear power plant is started, first, the low-pressure condensate pumps 2a and 2b and the high-pressure condensate pumps 4a and 4b are started. At this start-up, the supply flow rate required by the nuclear reactor is small. As described above, when the feedwater flow rate required by the reactor is small and, therefore, the minimum flow rate of the high-pressure condensate pump is larger than the feedwater flow rate to the reactor, the high-pressure condensate pump 4
In order to stably maintain the operations of a and 4b, it is necessary to secure the minimum flow rates respectively.

In this case, the minimum flow bypass pipe 14 connected to the discharge side of the electric motor driven reactor water supply pump 7 is used.
Then, the minimum flow rate in the high-pressure condensate pumps 4a and 4b is secured by opening the minimum flow rate bypass valve 12 and bypassing the water supply to the condenser 1. However, as described above, for example, by replacing the impeller in one of the high-pressure condensate pumps 4a, the Q-H
Assume that the characteristics have changed.

Thus, the two high pressure condensate pumps 4a,
It is assumed that one of the high-pressure condensate pumps 4a is in the state of the minimum flow rate operation during the parallel operation even though the start of the operation of the high-pressure condensate pump 4b is completed. In this case, by opening the circulation stop valve 22a inserted in the circulation pipe 25a, a part of the condensate discharged from the discharge side of the high-pressure condensate pump 4a, which is in the minimum flow rate operation, , Circulation stop valve
It flows into the high-pressure condensate pump 4a from the suction pipe 17a via the 22a, the circulation check valve 23a and the orifice 24a.

Further, a part of the circulated condensed water is supplied to suction pipes 17a, which are suction sides of the high-pressure condensate pumps 4a and 4b.
At 17b, the water condenses with the condensate from the condensate purification device 3 and flows into the high-pressure condensate pumps 4a and 4b. As a result, the suction flow rate in the high-pressure condensate pump 4a, which has been in the minimum flow rate operation, is effectively increased, so that the occurrence of the minimum flow rate operation can be avoided.

The flow rate of a part of the condensed water circulated to the suction pipe 17a via the circulation pipe 25a by the high pressure condensate pump 4a is previously determined by the operation of the high pressure condensate pump 4a in the orifice 24a. By setting the limit flow rate in consideration of the characteristics and the like, the minimum flow rate operation can be avoided without imposing an excessive burden on the high-pressure condensate pump 4a and the like. Further, after the minimum flow rate operation of the high-pressure condensate pump 4a, which is becoming the minimum flow rate operation, is avoided, as the start-up of the reactor proceeds, the required feedwater flow rate increases. The discharge flow rate in the pumps 4a and 4b increases.

When this state is reached, the circulation stop valve 22
a by closing the high pressure condensate pump 4a.
Since the total discharge flow rate is supplied to the reactor via the low-pressure feed water heater 5 and the like together with the high-pressure condensate pump 4b, highly efficient operation can be performed. In the above description, the high pressure condensate pump 4a has been described as an example.
b, and also for the high pressure condensate pump of the spare
Needless to say, the same operation and effect can be obtained.

The second embodiment relates to claim 2.
For the same components as those in the first embodiment, detailed description of the functions and effects together with this configuration is omitted,
The different parts will be described. As shown in the system configuration diagram of FIG. 2, the condensate pump flow control device has a condenser 1 in which low-pressure condensate pumps 2a and 2b and a condensate purifying device 3 are connected in series. Condensate pump 4a,
4b is connected.

The high-pressure condensate pumps 4a and 4b are connected to a turbine-driven reactor feed pump 6 and an electric motor-driven reactor feed pump 7, which are connected in series with the low-pressure feed heater 5 in parallel. The heater 8 is connected.

Further, a minimum flow bypass pipe having a minimum flow bypass valve 9 and a minimum flow bypass stop valve 10 inserted in series between the discharge side of the turbine-driven reactor water supply pump 6 and the condenser 1 is provided. 11 is connected. Further, a minimum flow bypass pipe 14 in which a minimum flow bypass valve 12 and a minimum flow bypass stop valve 13 are inserted in series is connected between the discharge side of the electric motor driven reactor feed pump 7 and the condenser 1. ing.

The suction pipes 17a, 17b on the suction side of the high-pressure condensate pumps 4a, 4b are respectively connected to suction valves 18a, 17b.
a and 18b, and discharge check valves 20a and 20b and discharge valves 21a and 21b are inserted in series in the discharge pipes 19a and 19b on the discharge side, respectively. Further, the high-pressure condensate pumps 4a, 4
b, a circulation stop valve 22 and a circulation check valve 23 are provided between the integrated discharge pipe 26 as an integrated discharge side and the integrated suction pipe 27 as an integrated suction side. The configuration is such that a circulating pipe 25 in which a restricting orifice 24 is inserted in series is connected.

Next, the operation of the above configuration will be described. When the reactor is started, the water supply flow rate required by the reactor is small. Therefore, in this case, if the minimum pressure of the high-pressure condensate pump is larger than the flow rate of the feedwater required by the reactor, the operation of the high-pressure condensate pumps 4a and 4b is stably maintained.
It is necessary to ensure a minimum flow rate for each of the high-pressure condensate pumps 4a and 4b.

Here, two high pressure condensate pumps 4a, 4b
In this parallel operation, for example, it is assumed that one of the high-pressure condensate pumps 4a is in the state of the minimum flow rate operation despite the completion of the start. In this case, by opening the circulation stop valve 22 inserted in the circulation pipe 25, the high-pressure condensate pump 4a which is in the minimum flow rate operation and the high-pressure condensate pump 4b in the normal operation state are discharged. Part of the condensed water that has merged in the integrated discharge pipe 26 flows into the integrated suction pipe 27 via the circulation stop valve 22, the circulation check valve 23, and the orifice 24.

Therefore, a part of this condensate is supplied to the integrated suction pipe 27 on the integrated suction side of the high-pressure condensate pumps 4a and 4b.
It merges with the condensate from the condensate purification device 3 and flows into the high-pressure condensate pumps 4a and 4b. As a result, the suction flow rate in the high-pressure condensate pump 4a, which is in the minimum flow rate operation, increases, so that the occurrence of the minimum flow rate operation can be avoided.

The flow rate of the condensed water circulated to the integrated suction pipe 27 via the integrated discharge pipe 26 by the high-pressure condensate pumps 4a and 4b is previously determined in the orifice 24.
By setting the limit flow rate in consideration of the operation characteristics of the high-pressure condensate pumps 4a and 4b,
The minimum flow rate operation can be avoided without imposing an excessive burden on a, 4b, and the like.

Further, after the minimum flow rate operation of the high-pressure condensate pump 4a, which is becoming the minimum flow rate operation, is avoided, the required feedwater flow rate increases as the start-up of the reactor proceeds. The discharge flow rate in the high-pressure condensate pumps 4a and 4b increases. In this state, the high-pressure condensate pump 4a is closed by closing the circulation stop valve 22.
Supplies water to the reactor via the low-pressure feedwater heater 5 and the like together with the high-pressure condensate pump 4b, so that highly efficient operation can be performed.

In the second embodiment, the number of circulation systems such as the circulation pipe 25 and the circulation stop valve 22, and the circulation check valve 23 and the orifice 24 is smaller than that of the first embodiment. The configuration is simplified. Further, since the avoidance of the minimum flow rate operation of the two high-pressure condensate pumps 4a and 4b is performed by a collective operation, the operation can be simplified.

The third embodiment is based on claim 3.
For the same components as those in the first embodiment, detailed description of the functions and effects together with this configuration is omitted,
The different parts will be described. As shown in the system configuration diagram of FIG. 3, the condensate pump flow control device includes a condenser 1 in which low-pressure condensate pumps 2a and 2b and a condensate purifier 3 are connected in series. Condensate pump 4a,
4b is connected.

The high-pressure condensate pumps 4a and 4b are connected to a turbine-driven reactor feed pump 6 and a motor-driven reactor feed pump 7, which are connected in series and parallel to the low-pressure feed heater 5, respectively. The heater 8 is connected. Further, a minimum flow bypass valve 9 is provided between the discharge side of the turbine-driven reactor feed pump 6 and the condenser 1.
And a minimum flow bypass pipe 11 in which a minimum flow bypass stop valve 10 is inserted in series.

A minimum flow bypass valve 12 is provided between the discharge side of the motor-driven reactor water supply pump 7 and the condenser 1.
And a minimum flow bypass pipe 14 in which a minimum flow bypass stop valve 13 is inserted in series. In addition, the suction pipes 17a and 17b on the suction side of the high-pressure condensate pumps 4a and 4b include:
The suction valves 18a and 18b respectively, and the discharge pipe on the discharge side
19a and 19b have discharge check valves 20a and 20b and discharge valves, respectively.
21a and 21b are interposed in series.

Further, in order to secure the minimum flow rate in the high-pressure condensate pumps 4a and 4b, the connection between the discharge check valve 20a and the discharge valve 21a, which is the discharge side of one high-pressure condensate pump 4a, A flow control pipe 30b in which a flow control stop valve 28b, a flow control check valve 29b, and a flow restricting orifice 24b are inserted in series with the suction pipe 17b on the suction side of the high pressure condensate pump 4b. Connecting.

The connection between the discharge check valve 20b on the discharge side of the other high-pressure condensate pump 4b and the discharge valve 21b and the suction pipe 17a on the suction side of the one high-pressure condensate pump 4a. Further, a flow control stop valve 28a, a flow control check valve 29a, and a flow control pipe 30a in which a flow restricting orifice 24a is inserted in series are connected.

Next, the operation of the above configuration will be described. When the reactor is started, the water supply flow rate required by the reactor is small. Therefore, in this case, if the minimum pressure of the high-pressure condensate pump is larger than the flow rate of the feedwater required by the reactor, the operation of the high-pressure condensate pumps 4a and 4b is stably maintained.
It is necessary to ensure a minimum flow rate for each of the high-pressure condensate pumps 4a and 4b.

Here, two high pressure condensate pumps 4a, 4b
In this parallel operation, for example, it is assumed that one of the high-pressure condensate pumps 4a is in the state of the minimum flow rate operation despite the completion of the start. In this case, by opening the flow control stop valve 28 inserted in the flow control pipe 30, a part of the condensate discharged from the discharge side of the other high pressure condensate pump 4b during the normal operation is removed. , Flow control stop valve 28a
Then, it flows into the high-pressure condensate pump 4a from the suction pipe 17a via the flow control check valve 29a and the orifice 24a.

Further, a part of the condensed water that has flowed in is drawn into suction pipes 17a, 17 on the suction side of the high-pressure condensate pumps 4a, 4b.
At b, it merges with the condensate from the condensate purification device 3 and flows into the high-pressure condensate pumps 4a and 4b. As a result, the suction flow rate of the high-pressure condensate pump 4a, which has been in the minimum flow rate operation, is effectively increased, so that the occurrence of the minimum flow rate operation can be avoided.

The flow rate of the condensed water flowing into the suction pipe 17a via the flow rate control pipe 30b by the high pressure condensate pump 4b depends on the operating characteristics of the high pressure condensate pump 4a in advance in the orifice 24a. In consideration of the above, by setting the limit flow rate, the minimum flow rate operation can be avoided without imposing an excessive load on the high-pressure condensate pump 4a and the like. Further, after the minimum flow rate operation of the high-pressure condensate pump 4a, which is approaching the minimum flow rate operation, is avoided, the required feedwater flow rate increases as the start-up of the reactor proceeds. The discharge flow rate in the water pumps 4a, 4b increases.

In this state, when the flow control stop valve 28a is closed, the high-pressure condensate pump 4a controls the total discharge flow rate together with the high-pressure condensate pump 4b via the low-pressure water heater 5 and the like. Since water is supplied to the nuclear reactor, highly efficient operation can be performed. The same operation and effect can be obtained with the other high-pressure condensate pump 4b and the high-pressure condensate pump of the standby unit (not shown).

The fourth embodiment is defined in claims 4 and 5
Regarding the same components as those in the first embodiment, detailed description of the functions and effects together with this configuration will be omitted, and different components will be described.

As shown in the system configuration diagram of FIG. 4, the condensate pump flow control device includes low-pressure condensate pumps 2a and 2b
The condensate purification device 3 is connected in series, and a plurality of high-pressure condensate pumps 4a and 4b are connected in parallel. The high-pressure condensate pumps 4a and 4b are connected with a turbine-driven reactor feed pump 6 and an electric motor-driven reactor feed pump 7 which are connected in series and in parallel with the low-pressure feed heater 5, respectively. Are connected.

Further, a minimum flow bypass pipe having a minimum flow bypass valve 9 and a minimum flow bypass stop valve 10 inserted in series between the discharge side of the turbine driven reactor feed pump 6 and the condenser 1 is provided. 11 is connected. Further, a minimum flow bypass pipe 14 in which a minimum flow bypass valve 12 and a minimum flow bypass stop valve 13 are inserted in series is connected between the discharge side of the electric motor driven reactor feed pump 7 and the condenser 1. ing.

The suction pipes 17a, 17b on the suction side of the high-pressure condensate pumps 4a, 4b are respectively connected to suction valves 18a, 17b.
a and 18b, and discharge check valves 20a and 20b and discharge valves 21a and 21b are inserted in series in the discharge pipes 19a and 19b on the discharge side, respectively.

Further, in order to secure a minimum flow rate in the high-pressure condensate pumps 4a and 4b, an integrated discharge pipe 26, which is an integrated discharge side, and a minimum discharge pipe 26, which is a discharge side of the turbine-driven reactor feed pump 6, are provided. A flow control stop valve 28, a flow control check valve 29, and a flow restricting orifice 24 are provided between a connection portion between the minimum flow bypass valve 9 and the minimum flow bypass stop valve 10 inserted in the flow bypass pipe 11. Are connected to a flow control pipe 30 interposed in series (claim 4).

The flow control stop valve 28 is a remote control flow control stop valve 31 that can be remotely controlled, and the remote control flow control stop valve 31 is connected to the high pressure condensate pump 4.
An interlock for forcibly opening the high-pressure condensate pumps 4a and 4b at the start of startup based on operation signals (not shown) of a and 4b is provided (claim 5).

Next, the operation of the above configuration will be described. When the reactor is started, the water supply flow rate required by the reactor is small. Therefore, in this case, if the minimum pressure of the high-pressure condensate pump is larger than the flow rate of the feedwater required by the reactor, the operation of the high-pressure condensate pumps 4a and 4b is stably maintained.
It is necessary to ensure a minimum flow rate for each of the high-pressure condensate pumps 4a and 4b.

Here, two high pressure condensate pumps 4a, 4b
In this parallel operation, for example, it is assumed that one of the high-pressure condensate pumps 4a is in the state of the minimum flow rate operation despite the completion of the start. In this case, the flow control stop valve 28 inserted in the flow control pipe 30 and the minimum flow bypass valve 9 inserted in the minimum flow bypass pipe 11 are opened.

Accordingly, the high-pressure condensate pump 4a, which is operating at the minimum flow rate, and the high-pressure condensate pump 4b, which is operating normally.
Part of the condensed water discharged from the outlet and merged in the integrated discharge pipe 26 passes through the flow control pipe 30 and the minimum flow bypass pipe 11 from the flow control pipe 30 via the flow control stop valve 28, the flow control check valve 29 and the orifice 24. Flows into the condenser 1 via the As a result, since the flow rate of the condensate in the integrated discharge pipe 26 increases, the suction flow rate in the high-pressure condensate pump 4a that is now in the minimum flow rate operation also increases, so that the occurrence of the minimum flow rate operation can be avoided. .

The high-pressure condensate pumps 4a and 4b are connected to the minimum flow bypass pipe 11 via the integrated discharge pipe 26.
The flow rate of the condensate flowing through the orifice 24 is set in advance in the orifice 24 in consideration of the operating characteristics of the high-pressure condensate pumps 4a and 4b and the like. The minimum flow operation can be avoided without imposing an excessive burden on the vehicle.

By opening the flow control stop valve 28 and the minimum flow bypass valve 9, the high pressure condensate pump 4
The discharge flow rate at the time of low flow rate operation near the minimum flow rate operation in a and 4b is added to the capacity of the minimum flow rate bypass system of the motor-driven reactor water supply pump 7 and the capacity of the minimum flow rate bypass system of the turbine drive reactor water supply pump 6. Also available.

Thus, each high-pressure condensate pump 4
Since the flow rates of a and 4b can be increased, the minimum flow rate operation can be avoided. Further, after the minimum flow rate operation of the high-pressure condensate pump 4a, which is becoming the minimum flow rate operation, is avoided, the start-up of the reactor proceeds and the feedwater flow rate increases if necessary. Condensate pump 4
The discharge flow rates at a and 4b increase.

In this state, by closing the flow control stop valve 28 and the minimum flow bypass valve 9, the high-pressure condensate pump 4 a controls the total discharge flow to the high-pressure condensate pump 4 b
At the same time, since water is supplied to the reactor via the low-pressure feedwater heater 5 and the like, highly efficient operation can be performed.

By replacing the flow control stop valve 28 with a remote control flow control stop valve 31 which can be remotely controlled, the operation for avoiding the minimum flow rate operation in the high pressure condensate pumps 4a and 4b can be controlled by a central control. Remote control from the room,
It can be easily performed by the start signal of the high-pressure condensate pumps 4a and 4b and the like.

Further, the remote control flow control stop valve 31 is
By providing an interlock for forcibly opening when starting the high-pressure condensate pumps 4a and 4b, the minimum flow rate operation is automatically avoided by a start signal or the like of the high-pressure condensate pumps 4a and 4b to further operate. Operation can be facilitated.

The fifth embodiment is defined in claims 6 and 7.
Regarding the same components as those in the first embodiment, detailed description of the functions and effects together with this configuration will be omitted, and different components will be described.

As shown in the system configuration diagram of FIG. 5, the condensing pump flow control device includes low-density condensing pumps 2a and 2b
The condensate purification device 3 is connected in series, and a plurality of high-pressure condensate pumps 4a and 4b are connected in parallel. The high-pressure condensate pumps 4a and 4b are connected with a turbine-driven reactor feed pump 6 and an electric motor-driven reactor feed pump 7 which are connected in series and in parallel with the low-pressure feed heater 5, respectively. Are connected.

Further, a minimum flow bypass pipe having a minimum flow bypass valve 9 and a minimum flow bypass stop valve 10 inserted in series between the discharge side of the turbine driven reactor feed pump 6 and the condenser 1 is provided. 11 is connected.

A minimum flow bypass valve 12 is provided between the discharge side of the motor-driven water supply pump 7 and the condenser 1.
And a minimum flow bypass pipe 14 in which a minimum flow bypass stop valve 13 is inserted in series.

The suction pipes 17a and 17b on the suction side of the high-pressure condensate pumps 4a and 4b have throttle suction valves 32a and 32b which can be throttled, respectively, and the discharge pipes 19a and 32b on the discharge side.
19b includes discharge check valves 20a and 20b and discharge valves 21a and 21b, respectively.
21b is configured to be interposed in series (claim 6). Further, the throttle suction valves 32a and 32b are configured as remote control throttle suction valves 33a and 33b that can be remotely controlled (claim 7).

Next, the operation of the above configuration will be described. When the reactor is started, the water supply flow rate required by the reactor is small. Therefore, in this case, if the minimum pressure of the high-pressure condensate pump is larger than the flow rate of the feedwater required by the reactor, the operation of the high-pressure condensate pumps 4a and 4b is stably maintained.
It is necessary to ensure a minimum flow rate for each of the high-pressure condensate pumps 4a and 4b.

Here, two high pressure condensate pumps 4a, 4b
In this parallel operation, for example, it is assumed that one of the high-pressure condensate pumps 4a is in the state of the minimum flow rate operation despite the completion of the start. In this case, the throttle operation of the throttle suction valve 32b on the suction side of the other high-pressure condensate pump 4b is performed. As a result, the head of the high-pressure condensate pump 4b rises, and the suction flow rate decreases. The suction flow rate of the high-pressure condensate pump 4a, which is in the minimum flow rate operation, is reduced by the reduced flow rate in the high-pressure condensate pump 4b. To increase.

As a result, the suction flow rate of the high-pressure condensate pump 4a, which has been reduced to the minimum flow rate operation, is effectively increased, and the occurrence of the minimum flow rate operation can be avoided. Further, after the minimum flow rate operation of the high-pressure condensate pump 4a that is becoming the minimum flow rate operation is avoided,
As the start-up of the nuclear reactor progresses, the required feedwater flow rate increases, and accordingly, the discharge flow rate of the high-pressure condensate pumps 4a and 4b increases.

When this state is reached, the throttle suction valve
When the valve 32a is fully opened, the high-pressure condensate pump 4b supplies the total discharge flow to the reactor via the low-pressure feedwater heater 5 and the like together with the high-pressure condensate pump 4a. it can. The same operation and effect can be obtained with the other high-pressure condensate pump 4b and the high-pressure condensate pump of the standby unit (not shown).

By replacing the throttle suction valves 32a, 32b with remote control throttle suction valves 33a, 33b capable of remote control, the operation for avoiding the minimum flow rate operation in the high-pressure condensate pumps 4a, 4b can be performed. It can be easily performed by remote control from the central control room, a start signal of the high-pressure condensate pumps 4a and 4b, and the like.

[0090]

As described above, according to the present invention, for example, in a condensate and water supply apparatus in which a minimum flow bypass line of a high-pressure condensate pump and a motor-driven water supply pump is shared in a nuclear power plant, a plurality of high-pressure condensates are operated in parallel. When there is a difference in the QH characteristics between the pumps, adjusting the flow rate of the condensate pump to a low flow rate operation after starting prevents the high pressure condensate pump from operating at a minimum flow rate or less. it can. Thus, the stable operation of the high-pressure condensate pump is maintained and protected, so that the soundness of the high-pressure condensate pump and the operability and reliability of the power plant are improved.

[Brief description of the drawings]

FIG. 1 is a system configuration diagram of a condensate pump flow control device according to a first embodiment of the present invention.

FIG. 2 is a system configuration diagram of a condensate pump flow control device according to a second embodiment of the present invention.

FIG. 3 is a system configuration diagram of a condensate pump flow control device according to a third embodiment of the present invention.

FIG. 4 is a system configuration diagram of a condensate pump flow control device according to a fourth embodiment of the present invention.

FIG. 5 is a system configuration diagram of a condensate pump flow control device according to a fifth embodiment of the present invention.

FIG. 6 is a system configuration diagram of a conventional condensing and water supply device.

FIG. 7 is a QH characteristic curve diagram of a high-pressure condensate pump in a conventional condensate and water supply device.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Condenser, 2a, 2b ... Low pressure condensate pump, 3 ... Condensate purifier, 4a, 4b ... High pressure condensate pump, 5 ... Low pressure feed water heater, 6 ... Turbine drive reactor feed water pump, 7 ... Electric motor Driving reactor feed pump, 8… High pressure feed heater, 9,12…
Minimum flow bypass valve, 10, 13 ... Minimum flow bypass stop valve, 11, 14 ... Minimum flow bypass pipe, 15 ... Condensate recirculation valve, 16 ... Condensate recirculation pipe, 17a, 17b ... Suction pipe, 18
a, 18b: suction valve, 19a, 19b: discharge pipe, 20a, 20
b: discharge check valve, 21a, 21b: discharge valve, 22, 22a, 22b
... Circulation check valves, 23,23a, 23b ... Circulation check valves, 24,24
a, 24b: orifice, 25, 25a, 25b: circulation pipe, 26
... Integrated discharge piping, 27 ... Integrated suction piping, 28, 28a, 28b
… Flow control stop valve, 29, 29a, 29b… Flow control check valve,
30, 30a, 30b: flow control pipe, 31: remote control flow control stop valve, 32a, 32b: throttle suction valve, 33a, 33b: remote control throttle suction valve.

Claims (7)

[Claims] 1. A condensate pump flow control device for operating a plurality of high-pressure condensate pumps for increasing condensate water in a feedwater heater and a feedwater pump of a nuclear power plant in parallel with a discharge side of each high-pressure condensate pump. A circulation valve having a stop valve, a check valve, and an orifice inserted in series between the suction pipe and the suction side. 2. A condensate pump flow control device for operating a plurality of high-pressure condensate pumps for increasing condensate pressure with respect to a feedwater heater and a feedwater pump of a power plant, wherein the integrated discharge of the plurality of high-pressure condensate pumps is performed. Side and the integrated suction side,
A flow rate control device for a condensate pump, wherein a circulation valve having a stop valve, a check valve, and an orifice inserted in series is connected. 3. A condensate pump flow control device in which a plurality of high-pressure condensate pumps for boosting condensate water with respect to a feedwater heater and a feedwater pump of a power plant is different from a discharge side of the high-pressure condensate pump. A flow rate control device for a condensate pump, wherein a flow control pipe having a stop valve, a check valve, and an orifice inserted in series is connected between the suction side of the high-pressure condensate pump and the suction side. 4. A condensate pump flow control device in which a plurality of high-pressure condensate pumps for boosting condensate water with respect to a feedwater heater and a feedwater pump of a power plant, wherein an integrated discharge of the plurality of high-pressure condensate pumps is provided. A flow control pipe having a stop valve, a check valve, and an orifice inserted in series between the side and a minimum flow bypass pipe of a turbine-driven reactor feed pump. 5. A stop valve inserted in said flow control pipe is used as a remotely operated stop valve, and an interlock for forcibly opening said remotely operated stop valve when a plurality of high pressure condensate pumps are started simultaneously. 5. The condensate pump flow control device according to claim 4, further comprising: 6. A condensate pump flow control device for operating a plurality of high-pressure condensate pumps for increasing condensate water with respect to a feedwater heater and a feedwater pump of a power plant in parallel with a suction side of each of the high-pressure condensate pumps. A condensate pump flow control device, wherein a suction valve that can be throttled is interposed. 7. The condensate pump flow control device according to claim 6, wherein the restrictable suction valve inserted on the suction side of each of the high-pressure condensate pumps is a remotely controllable throttle valve. .