JP3321279B2 - Differential pressure type water level measuring device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a differential pressure type water level measuring device, and more particularly to a differential pressure type water level measuring device for detecting a drain water level inside various tanks in a power plant.

[0002]

2. Description of the Related Art A technique related to the present invention is disclosed in Japanese Patent Laid-Open No. 5-9 / 1993.
No. 3642, the known example is
This will be described with reference to FIGS. 12 is a system diagram of a nuclear power plant, FIG. 13 is a configuration diagram of a water level measurement unit in FIG. 12, and FIG. 14 is a longitudinal sectional view of an upper flange in FIG.

In FIG. 12, steam generated in a pressure vessel 34 passes through a main steam line 35, drives a turbine 36, and is condensed in a condenser 38. Condensed water is condenser 3
From 8, the water flows into the feed water heater 1 by the condensate pump 39, is heated by the feed water heater 1, and is returned to the pressure vessel 34.
Heating by the feed water heater 1 is performed by steam sent from the turbine 36 through an extraction line 37. The drain water level in the feed water heater 1 is measured by the differential pressure detector 14 using the upper detection source valve 4 and the lower detection source valve 5.

Next, the water level measuring section will be described. FIG.
As shown in FIG. 3, the small-diameter upper detection pipe 2 has one end connected to the gas phase of the feed water heater 1 and the other end connected to the upper diaphragm 10 via the small-diameter upper detection pipe 40 and the upper flange 8. The pressure of the gaseous phase formed at the upper part of the feed water heater 1 is transmitted to the differential pressure detector 14 via the upper capillary tube 12. Note that a liquid (silicon) for pressure transmission is sealed in the upper capillary tube 12.

On the other hand, the small-diameter lower detection pipe 3 has one end connected to the liquid phase portion of the feed water heater 1 and the other end connected to the lower diaphragm 11 through the lower detection pipe 7 and the lower flange 9. The pressure of the liquid phase formed in the lower part of the heater 1 is transmitted to the differential pressure detector 14 via the lower capillary tube 13. A liquid (silicon) for pressure transmission is sealed in the lower capillary tube 13 as in the upper capillary tube 12 described above. That is, each pressure of the gas phase and the liquid phase formed in the feed water heater 1 is transmitted to the differential pressure detector 14.

An upper detecting valve 4 is provided between the small-diameter upper detecting pipe 2 and an upper detecting pipe 40 having a small diameter, and a lower detecting element is provided between the small-diameter lower detecting pipe 3 and the lower detecting pipe 7. A valve 5 is provided. The upper detection source valve 4 is installed to separate the process side from the instrumentation side, and is closed when an accident occurs on the process side to prevent the influence on the instrumentation side. When the drain water level in the feed water heater 1 is measured, the upper detection source valve 4 and the lower detection source valve 5 are opened to determine whether a specified water level is maintained. Is ensured.

As described above, the upper portion of the feed water heater 1 and the upper detection source valve 4 are connected by the small-diameter upper detection pipe 2, which has a 20A (outer diameter of 27.2 mm, inner diameter of 27.2 mm). 21.4 mm) or more is used to prevent concentration of stress at the connection between the small-diameter upper detection pipe 2 and the upper part of the feed water heater 1. When heat transfer and vibration are large, the diameter is further increased.

As described above, the upper capillary tube 1
2 transmits the pressure (atmospheric pressure) of the gas phase formed in the feed water heater 1 to the differential pressure detector 14, and the gas phase as the pressure medium is transmitted to the upper diaphragm 10, the upper capillary tube 12, and the differential pressure detector 14. Risk of thermal effects. Therefore, as a countermeasure, the upper detection source valve 4 and the upper flange 8
Between them, an upper detection pipe 40 having a smaller diameter than that of the small-diameter upper detection pipe 2 is used.

Further, since the viscous resistance of the sealed liquid (silicon) to the inner peripheral surfaces of the upper capillary tube 12 and the lower capillary tube 13 is extremely high, high-frequency pressure fluctuations are attenuated, which is detected by the differential pressure detector 14. Improves accuracy.

Further, the upper capillary tube 12 and the lower capillary tube 13 are separated from the upper detection pipe 40 and the lower detection pipe 7 each having a small diameter by the upper diaphragm 10 and the lower diaphragm 11, respectively. Therefore, discharged from the pressure vessel 14,
Foreign matter such as rust does not enter each of the upper capillary tube 12 and the lower capillary tube 13, and they do not directly affect the differential pressure detector 14.

FIG. 14 shows the structure of a joint between the upper flange 8 and the upper diaphragm 10. As shown in FIG.

[0012]

However, conventionally, in order to suppress the thermal influence on the water level measuring unit, the diameter between the upper detection source valve and the upper flange is extremely smaller than the small diameter upper detection pipe. The connection is made using an upper detection pipe with a small diameter. Therefore, when a high-humidity vapor layer is formed in the small-diameter upper detection pipe, the steam condenses and becomes condensed water, and the condensed water closes the small-diameter upper detection pipe and causes hunting. And the water level may fluctuate, causing a water level detection error. In addition, since the upper detection pipe having a small diameter has an extremely small diameter, there is a risk of stress being concentrated and breaking.

Although the above is a case where a steam heater is taken as an example, the same phenomenon as described above may occur in a differential pressure type water level measuring device of other turbine equipment, and a water level detection error may occur. is there.

On the other hand, in order to confirm the soundness of the upper diaphragm and the lower diaphragm, the upper flange joined to the upper diaphragm and the lower flange joined to the lower diaphragm may be removed.
In this case, the work of draining water stagnating in each of the upper diaphragm and the lower diaphragm is performed, but there is a risk of being exposed at this time.

Therefore, we want to abolish the draining work,
Since the small-diameter upper detection pipe joined to the upper flange has a small diameter, air and condensed water do not flow out and stay at the upper and lower portions of the upper diaphragm. However, it cannot be removed without disassembling the upper flange.

The present invention relates to a differential pressure type water level measuring device,
The purpose is to eliminate both factors that have an adverse effect on the accuracy of water level measurement and maintenance, and the danger of exposure during disassembly.

[0017]

The above object can be achieved as follows.

(1) An upper detection pipe and a lower detection pipe are respectively connected to upper and lower parts of a container to various tanks and the like in a power plant, and the upper detection pipe communicates with an upper diaphragm via an upper flange to form the container. The pressure of the gas phase formed in the upper part of the pressure sensor is received by the upper diaphragm through the upper detection source valve, the differential pressure detector through the upper capillary tube, and the lower detector through the lower flange to the lower diaphragm. communicating the pressure of the liquid phase is formed in the lower portion of the vessel is pressure in the lower part diaphragm via the lower detection source valve, the differential pressure detector via the lower capillary tube, by being transmitted respectively In the differential pressure type water level measuring device for measuring a drain water level inside the container, the upper detection pipe is sequentially provided with a rising portion, a high level horizontal portion, and a high level portion. Has a bent shape consisting falling portion and the lower horizontal section has lowered to the container side from the horizontal portion,
The end of the upper detection pipe of the raised portion side at the top of the container, the end portion of the upper detecting piping low horizontal portion is connected to said upper flange, said lower horizontal portion tapered together form, characterized in that the lower horizontal portion are lower than the upper flange side.

(2) An upper detection pipe and a lower detection pipe are respectively connected to upper and lower portions of the container to various tanks and the like in the power plant, and the upper detection pipe communicates with an upper diaphragm via an upper flange to form the container. The pressure of the gas phase formed in the upper part of the pressure sensor is received by the upper diaphragm through the upper detection source valve, the differential pressure detector through the upper capillary tube, and the lower detector through the lower flange to the lower diaphragm. communicating the pressure of the liquid phase is formed in the lower portion of the vessel is pressure in the lower part diaphragm via the lower detection source valve, the differential pressure detector via the lower capillary tube, by being transmitted respectively In the differential pressure type water level measuring device for measuring the drain water level inside the container, the upper detection pipe is sequentially provided with a rising portion, a high level horizontal portion, and a Stage falling section, the first-stage low horizontal portion has a bent shape consisting of lower portion trailing second-stage and second-stage low horizontal portion, the end portion of the upper detection pipe of the raised portion side the container And an end of the upper detection pipe on the side of the second-stage lower horizontal portion is connected to the upper flange, and the first-stage lower horizontal portion and the second-stage lower horizontal portion are tapered. And the first-stage low-level horizontal portion
And wherein that you have the second-stage low horizontal portion lower than the upper flange side.

(3) An upper detection pipe and a lower detection pipe are respectively connected to upper and lower portions of the container to various tanks and the like in the power plant, and the upper detection pipe communicates with an upper diaphragm via an upper flange to form the container. The pressure of the gas phase formed in the upper part of the pressure sensor is received by the upper diaphragm through the upper detection source valve, the differential pressure detector through the upper capillary tube, and the lower detector through the lower flange to the lower diaphragm. communicating the pressure of the liquid phase is formed in the lower portion of the vessel is pressure in the lower part diaphragm via the lower detection source valve, the differential pressure detector via the lower capillary tube, by being transmitted respectively In the differential pressure type water level measuring device for measuring a drain water level inside the container, the upper detection pipe is sequentially provided with a first-stage rising section and a first-stage water section. Has a parts and bent shape composed of the second stage rising portion and a second horizontal section, raised the first stage
Part of side the end of the upper detection pipe is connected to the upper portion of the container, an end portion of the upper detection pipe of the second-stage horizontal portion side is connected to the upper flange, the horizontal portion and the first stage
The two-stage horizontal portion is tapered , and the first-stage horizontal portion is
And wherein the from the second-stage horizontal side are higher the upper flange side.

(4) An upper detection pipe and a lower detection pipe are respectively connected to upper and lower parts of the container to various tanks and the like in the power plant, and the upper detection pipe communicates with an upper diaphragm via an upper flange to form the container. The pressure of the gas phase formed in the upper part of the pressure sensor is received by the upper diaphragm through the upper detection source valve, the differential pressure detector through the upper capillary tube, and the lower detector through the lower flange to the lower diaphragm. communicating the pressure of the liquid phase is formed in the lower portion of the vessel is pressure in the lower part diaphragm via the lower detection source valve, the differential pressure detector via the lower capillary tube, by being transmitted respectively In the differential pressure type water level measuring device for measuring the drain water level inside the container, the upper detection pipe is, in order, a rising portion, a high level horizontal portion and Has a bent shape consisting of lower part and low horizontal portion Chi, wherein the raised portion side end portion of the upper detection pipe is connected to the top of the container, the end of the upper detection pipe of the low horizontal portion Part is connected to the upper flange, the lower horizontal part is tapered ,
Characterized in that from the lower horizontal portion are higher the upper flange side.

(5) In (1), (2), (3) or (4), a gas or liquid is provided inside at least one of the upper flange and the lower flange to guide a gas or liquid from a container into the inside. A flow path for discharging gas or liquid from the inside is provided.

(6) In (1), (2), (3) or (4), a communication pipe for communicating the upper detection pipe and the lower detection pipe is provided.

(7) In (6), the communication pipe is provided with a meter calibration valve.

[0025]

According to the present invention, in the differential pressure type water level measuring apparatus, when the gas phase of the feed water heater is at a high pressure, the upper detection pipe is sequentially provided with a rising section, a high level horizontal section, a falling section and a low level horizontal section. Has a bent shape consisting of, the end of the upper detection pipe on the side of the rising part is connected to the upper part of the container, and the end of the upper detection pipe on the side of the lower horizontal part is connected to the upper flange, respectively.
The lower horizontal portion has a tapered shape and uses a lower upper flange side.

Therefore, when the upper detection pipe is cooled by ambient air, the steam in the upper detection pipe is condensed to form condensed water, which is stored in the lowering portion and the lower horizontal portion of the upper detection pipe. Of the heat of the gas phase
The sound is stored in the lower horizontal portion and is blocked by the condensed water, so that the differential pressure measurement portion between the upper diaphragm and the differential pressure detector does not affect the heat held by the gas phase of the upper detection pipe. Therefore, the water level measurement accuracy is improved. Furthermore,
Since the diameter of any part of the upper detection pipe is increased, the strength of the upper detection pipe is also improved.

When the gas phase of the feed water heater is at a high pressure,
In the upper detection pipe, as in a first-stage falling portion, a first-stage lower horizontal portion, a second-stage falling portion, and a second-stage lower horizontal portion,
Since the falling section and the lower horizontal section are each provided in two stages, it is possible to more reliably avoid the thermal effect of the gas phase of the upper detection pipe on the differential pressure measurement section, and to further improve the water level measurement accuracy. improves.

On the other hand, when the gas phase of the feed water heater is at a low pressure,
The upper detection pipe has a bent shape including a first-stage rising portion, a first-stage horizontal portion, a second-stage rising portion, and a second-stage horizontal portion, and the first-stage rising portion has a bent shape. The end of the upper detection pipe on the side is connected to the upper part of the container, the end of the upper detection pipe on the side of the second horizontal part is connected to the upper flange,
The first-stage horizontal portion and the second-stage horizontal portion are tapered, and both have a raised upper flange side.

Therefore, when the upper detection pipe is cooled by the surrounding outside air and the steam in the upper detection pipe is condensed into condensed water, the condensed water can completely flow into the feed water heater. In addition, it is possible to prevent the water level measurement accuracy from being affected by the flash of the condensed water and the rapid flow into the feed water heater. Further, since the diameter of any part of the upper detection pipe is increased, the strength of the upper detection pipe is also improved.

When the gas phase of the feed water heater is at a low pressure,
Depending on the situation, the upper detection pipe has a bent shape consisting of a rising portion, a high level horizontal portion, a falling portion, and a low level horizontal portion, and the end of the upper detection pipe on the side of the rising portion is sequentially formed. The upper detection pipe is connected to the upper portion of the container, and the end of the upper detection pipe on the side of the lower horizontal portion is connected to the upper flange. The lower horizontal portion has a tapered shape, and the upper flange has a higher side. Also in this case, since the condensed water can be separated from the upper flange, the influence on the water level measurement accuracy of the condensed water can be prevented.

[0031] Further, the inside of at least one of the upper flange and the lower flange is connected to a flow path provided for guiding a gas or a liquid from a container to discharge the gas or the liquid from the inside. Is provided, the drainage becomes easy, and the danger of being exposed at the time of drainage can be avoided.

Further, since a communication pipe for connecting the upper detection pipe and the lower detection pipe is provided, an instrument calibration operation using a water manometer can be performed accurately.

Since the communication pipe is provided with the meter calibration gate valve, the instrument calibration work using the pressure gauge can be performed with high accuracy.

[0034]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A first embodiment of the present invention will be described with reference to FIG. FIG. 1 is a configuration diagram of the differential pressure type water level measuring device of the present embodiment, which is applied when the gas phase in the feed water heater 1 is at a high pressure.

FIG. 1 differs from the conventional example (FIG. 13) in the connection between the upper detection source valve 4 and the upper flange 8. That is, in the conventional example, the upper detection pipe 40 having a small diameter is used in that portion, whereas in the present embodiment, the upper detection pipe body 6 has a high horizontal portion, a falling portion, and a low horizontal portion. .

In the case of this embodiment, since the upper detection pipe 6 is configured as described above, it is cooled by the outside air around the upper detection pipe 6, and the vapor in the upper detection pipe 6 is condensed to form condensed water. In this case, the condensed water can be stored in the lower horizontal portion and the lowering portion of the upper detection pipe 6. In this case, since the lower horizontal portion are lower than the upper flange 8 side, since it is possible to the accumulated condensate to the lower horizontal portion to those reliable, condensed water in the upper diaphragm 10
Without stagnation, water draining operation as described in the prior art
Work is no longer necessary.

[0037] That is, since the gas phase in the upper detection pipe 6 is pressing the upper surface of the condensed water, the gas phase of the upper detection pipe 6
Is blocked by the condensed water in the lower horizontal portion , the differential pressure measurement portion is not affected by the heat retained by the gas phase of the upper detection pipe 6, and the accuracy of the water level measurement can be improved.

Further, since the diameters of the upper horizontal portion, the falling portion, and the lower horizontal portion of the upper detection pipe 6 are all increased, the strength is improved as compared with the conventional pipe portion corresponding to the upper detection pipe 6. ing.

A second embodiment of the present invention will be described with reference to FIG. FIG. 2 is a configuration diagram of the differential pressure type water level measuring apparatus of the present embodiment, which is applied when the gas phase in the feed water heater 1 is at a low pressure.

FIG. 2 differs from the conventional example (FIG. 13) in the connection between the upper detection source valve 4 and the upper flange 8 as in the above-described case. However, in this embodiment, the upper detection pipe body 6 has a first-stage horizontal portion, a rising portion, and a second-stage horizontal portion, and the first-stage horizontal portion and the second-stage horizontal portion are tapered. This is a case where the upper flange 8 side is made higher, and is applied when the gas phase in the feed water heater 1 is at a low pressure.

Therefore, when the upper detection pipe 6 is cooled by the surrounding outside air and the steam in the upper detection pipe 6 is condensed into condensed water, the condensed water is caused to completely flow into the feed water heater 1. Therefore, it is possible to reliably prevent the water level measurement accuracy from being adversely affected by flashing of the condensed water and abruptly flowing into the feed water heater 1.

Also, in this embodiment, as in the above-described embodiment, since the diameter of each part of the upper detection pipe 6 is increased, the strength is higher than that of the conventional pipe part corresponding to the upper detection pipe 6. Has improved.

A third embodiment of the present invention will be described with reference to FIG. FIG. 3 is a piping configuration diagram of the differential pressure type water level measuring device of the present embodiment. The measuring principle of the differential pressure type water level measuring device of FIG. 3 is the same as that shown in FIG. 1 described above, and is applied when the gas phase in the feed water heater 1 is at a high pressure. , A two-stage lower horizontal portion, a communication pipe 26 communicating between the upper detection pipe 6 and the lower detection pipe 7, and an upper flange 8 and a lower flange 9, respectively, This is a case where the lower special flange 16 has been replaced.

In FIG. 3, the gas phase in the feed water heater 1 is
The upper part of the feed water heater 1 reaches the upper special flange 15 via the small-diameter upper detection pipe 2, the upper detection pipe 6, and the instrument-side upper detection pipe 17. The components from the upper diaphragm 10 joined to the upper special flange 15 to the differential pressure detector 14 are the same as those in the first embodiment. The small-diameter upper detection pipe 2 is provided with an upper detection source valve 4, and the upper detection pipe 6 is provided with an upper instrument stop valve 19.

On the other hand, the liquid phase in the feed water heater 1 is supplied from the lower part of the feed water heater 1 to the small-diameter lower detection pipe 3 and the lower detection pipe 7.
And, it reaches the lower special flange 16 via the instrument side lower detection pipe 18. The components from the lower diaphragm 11 joined to the lower special flange 16 to the differential pressure detector 14 are the same as those in the first embodiment. In addition, the lower detection source valve 5 is provided in the small-diameter lower detection pipe 3, and the lower detection pipe 7 is provided.
Is provided with a lower instrument stop valve 20.

The upper special flange 15 has an upper drain pipe 21 and the lower special flange 16 has a lower drain pipe 22.
The upper drain pipe 21 is provided with an upper drain valve 23, and the lower drain pipe 22 is provided with a lower drain valve 24, which are used for draining the upper special flange 15 and the lower lower special flange 16, respectively. I have.

Further, the upper drain pipe 21 and the lower drain pipe 22 are integrated at the lower part, and a water filling valve 25 is attached to the integrated pipe, which comprises an upper special flange 15 and a lower lower special flange 16. It is used to fill the water. The communication pipe 26 is provided with an upper test valve 27 and a lower test valve 28.

As described above, in the present embodiment, various valves are provided, and these include an open valve and a closed valve. The opening / closing state at the time of water level measurement is shown.

The communication pipe 26 is used for the operation confirmation test and the instrument calibration of the differential pressure type water level measuring apparatus in the present embodiment. Conventionally, the communicating pipe 26 is used for measuring the water level in the feed water heater 1 or the like. Since the measuring device was not used, the provision of the communication pipe 26 was not considered.

That is, the lower end of the transparent tube 30 of the water manometer 29 is connected to the lower test valve 28 for the operation check test and the instrument calibration of the differential pressure type water level measuring device.
A method of pouring water from a top end of the funnel 31 with a funnel 31 was used. In this case, the upper instrument stop valve 19 and the lower instrument stop valve 20 are closed, and the lower test valve 28 and the upper test valve 27 are closed.
By opening the upper test valve 27, the air in the communication pipe 26 is discharged to the outside, and the accuracy of the above-described operation check test and instrument calibration is enhanced.

Next, the structure of the upper special flange 15 and the lower special flange 16 will be described. Since the upper special flange 15 and the lower special flange 16 have almost the same structure, the upper special flange 15 will be described as an example with reference to FIG. FIG. 4 is a vertical sectional view of the upper special flange of the present invention.

The upper special flange 15 is joined to the upper diaphragm 10 with bolts and nuts, and reduces the pressure of the gas phase in the feed water heater 1 (see FIG. 3) flowing from the upper detection pipe 17 on the instrument side. To communicate.

In this case, the instrument-side upper detection pipe 17 is conventionally extended into the upper special flange 15, but in the present embodiment, the end portion is extended into the upper special flange 15. An upper drain pipe 21 is provided, and an end of the upper detection pipe 17 on the instrument side communicates with an end of the upper drain pipe 21. Therefore, it is possible to remove the air and condensed water accumulated in the upper special flange 15 without disassembling the upper special flange 15, thereby preventing the exposure of the contaminated water when disassembling the upper special flange 15 for drainage. can do. The same effect can be obtained with the lower special flange 16. In the following embodiments, the upper special flange 15
And the lower special flange 16 are used, but since the contents are the same, the description thereof is omitted.

A fourth embodiment of the present invention will be described with reference to FIG. FIG. 5 is a piping configuration diagram of the differential pressure type water level measuring device of the present embodiment.

As in the third embodiment, the present embodiment is also applied when the pressure in the feed water heater is high, and the basic piping configuration is the same as in the third embodiment. The upper test valve 27 can be easily operated only around the instrument.
Also, the mounting position of the lower test valve 28 is changed, and the mounting position of the water manometer 29 (see FIG. 3) is close to the instrument, so that the calibration accuracy can be improved. However, in this case, in addition to the communication pipe 26, the communication pipe 3
2 needs to be installed.

A fifth embodiment of the present invention will be described with reference to FIG. FIG. 6 is a piping configuration diagram of the differential pressure type water level measuring device of the present embodiment.

This embodiment is applied to a case where the pressure in the feed water heater is low, and the principle is the same as that of the second embodiment.
When the low pressure is close to the vacuum, the condensed water in the instrument side upper detection pipe 17 may be drawn into the feed water heater 1 side.
The 6 side is lowered. That is, the instrument side upper detection pipe 1
In order to prevent condensed water from accumulating in 7, the water level measurement accuracy is not affected.

A sixth embodiment of the present invention will be described with reference to FIG. FIG. 7 is a piping configuration diagram of the differential pressure type water level measuring device of the present embodiment.

This embodiment is also applied to the case where the pressure in the feed water heater is low as in the fifth embodiment, and the basic piping configuration is the same as that of the fifth embodiment. The upper test valve 27 can be easily operated only around the instrument.
Also, the mounting position of the lower test valve 28 is changed, and the mounting position of the water manometer 29 (see FIG. 3) is close to the instrument, so that the calibration accuracy can be improved.

The seventh to tenth embodiments of the present invention will be described with reference to FIGS. In the seventh to tenth embodiments, a meter calibration gate valve 33 is attached to the communication pipe 26 or the communication pipe 32 of the third to sixth embodiments, respectively.

At the time of instrument calibration, in the third to sixth embodiments (FIGS. 3, 5 to 7), a water manometer 29 (see FIG. 3) is attached to the lower test valve 28 to calibrate the instrument. However, in the seventh and ninth embodiments, the communication pipe 26 is
In the tenth and tenth embodiments, the communication pipe 32 is provided with the meter calibration gate valve 33, and the upper side and the lower side are separately provided with a piping configuration capable of calibrating the meter by pressure. The instrument calibration gate valve 33 is closed, pressure is applied from the upper test valve 27 and the lower test valve 28, and instrument calibration is performed while measuring this pressure with a pressure gauge (not shown).

That is, when the water manometers of the third to sixth embodiments are used, simultaneous calibration is performed for both the upper and lower sides, but the pressure gauges of the seventh to tenth embodiments are used. In the case where is used, the upper side and the lower side are separately calibrated.

[0063]

According to the present invention , the lower horizontal portion has an upper flat portion.
Because it is lower than the edge side, condensate
Since the reserve can be secured, the upper diamond
The condensate does not stagnate on the flam and
No need for draining work. In addition, the thermal effect of the gas phase of the upper detection pipe is blocked by condensed water in the lower horizontal part, and the differential pressure measurement part is not affected by the heat of the gas phase of the upper detection pipe, improving the accuracy of water level measurement can do.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of a differential pressure type water level measuring device according to a first embodiment of the present invention.

FIG. 2 is a configuration diagram of a differential pressure type water level measuring device according to a second embodiment of the present invention.

FIG. 3 is a piping configuration diagram of a differential pressure type water level measuring device according to a third embodiment of the present invention.

FIG. 4 is a longitudinal sectional view of the upper special flange of FIG. 3;

FIG. 5 is a piping configuration diagram of a differential pressure type water level measuring device according to a fourth embodiment of the present invention.

FIG. 6 is a piping configuration diagram of a differential pressure type water level measuring device according to a fifth embodiment of the present invention.

FIG. 7 is a piping configuration diagram of a differential pressure type water level measuring device according to a sixth embodiment of the present invention.

FIG. 8 is a piping configuration diagram in which an instrument calibration gate valve is added to FIG. 3;

FIG. 9 is a piping configuration diagram in which an instrument calibration gate valve is added to FIG. 5;

FIG. 10 is a piping configuration diagram in which an instrument calibration gate valve is added to FIG. 6;

FIG. 11 is a piping configuration diagram in which an instrument calibration gate valve is added to FIG. 7;

FIG. 12 is a system diagram of a nuclear power plant.

13 is a configuration diagram of a water level measurement unit in FIG.

FIG. 14 is a longitudinal sectional view of the upper flange of FIG.

[Explanation of symbols]

1 ... feed water heater, 2 ... small-diameter upper detection pipe, 3 ... small-diameter lower detection pipe, 4 ... upper detection base valve, 5 ... lower detection base valve,
6 upper detection pipe, 7 lower detection pipe, 8 upper flange, 9 lower flange, 10 upper diaphragm, 11
... lower diaphragm, 12 ... upper capillary tube, 13 ... lower capillary tube, 14 ... differential pressure detector, 15 ... upper special flange, 16 ... lower special flange, 17 ... instrument side upper detection pipe, 18 ... instrument side lower detection pipe , 19 ... upper instrument stop valve, 20 ... lower instrument stop valve,
21 ... upper drain pipe, 22 ... lower drain pipe, 23 ...
Upper drain valve, 24 ... Lower drain valve, 25 ... Water-filled valve,
26, 32: communicating pipe, 27: upper test valve, 28: lower test valve, 29: water manometer, 30: transparent pipe, 31 ...
Funnel, 33: Calibration gate valve, 34: Pressure vessel, 35: Main steam line, 36: Turbine, 37: Bleed line, 38: Condenser, 39: Condensate pump, 40: Small upper detection pipe .

Continuation of the front page (56) References JP-A-5-93642 (JP, A) JP-A-4-204020 (JP, A) JP-A-61-47589 (JP, A) JP-A-4-45945 (JP) , U) (58) Field surveyed (Int.Cl. ⁷ , DB name) G01F 23/16

Claims (6)

(57) [Claims] An upper detection pipe and a lower detection pipe are respectively connected to upper and lower portions of a container to various tanks and the like in a power generation plant, and the upper detection pipe communicates with an upper diaphragm via an upper flange to connect the container to the upper diaphragm. The pressure of the gas phase formed in the upper part is received by the upper diaphragm through the upper detection source valve, and communicates with the differential pressure detector through the upper capillary tube, and the lower detector communicates with the lower diaphragm through the lower flange. to the pressure of the liquid phase is formed in the lower portion of the vessel is pressure in the lower part diaphragm via the lower detection source valve, the differential pressure detector via the lower capillary tube, by being transferred respectively, In the differential pressure type water level measuring device that measures a drain water level inside the container, the upper detection pipe is sequentially provided with a rising portion, a high horizontal portion, and a high horizontal portion. The lower part has a bent shape comprising a falling part and a lower horizontal part that fall from the lower part to the container side, and the end of the upper detection pipe on the rising part side is located above the container, and the lower horizontal part side An end of the upper detection pipe is connected to the upper flange, the lower horizontal portion is tapered , and the lower horizontal portion side is lower than the upper flange side. Measuring device. 2. An upper detection pipe and a lower detection pipe are respectively connected to upper and lower parts of a container to various tanks and the like in a power plant, and the upper detection pipe communicates with an upper diaphragm through an upper flange to connect the container to the upper diaphragm. The pressure of the gas phase formed in the upper part is received by the upper diaphragm through the upper detection source valve, and communicates with the differential pressure detector through the upper capillary tube, and the lower detector communicates with the lower diaphragm through the lower flange. to the pressure of the liquid phase is formed in the lower portion of the vessel is pressure in the lower part diaphragm via the lower detection source valve, the differential pressure detector via the lower capillary tube, by being transferred respectively, In a differential pressure type water level measuring device for measuring a drain water level inside the container, the upper detection pipe is sequentially provided with a rising section, a high level horizontal section, and a first vertical section. Lowering part, first-stage lower horizontal part, second
It has a bent shape consisting of a step lowering section and a second step lower horizontal section, and an end of the upper detection pipe on the rising section side is connected to an upper portion of the container, and the second step lower horizontal section side An end of the upper detection pipe is connected to the upper flange, the first-stage lower horizontal portion and the second-stage lower horizontal portion are tapered , and the first-stage lower horizontal portion and Said
A differential pressure type water level measuring device , wherein a second-stage lower horizontal portion side is lower than the upper flange side. 3. An upper detection pipe and a lower detection pipe are respectively connected to upper and lower portions of a container to various tanks and the like in a power plant, and the upper detection pipe communicates with an upper diaphragm via an upper flange to connect the container to the upper diaphragm. The pressure of the gas phase formed in the upper part is received by the upper diaphragm through the upper detection source valve, and communicates with the differential pressure detector through the upper capillary tube, and the lower detector communicates with the lower diaphragm through the lower flange. to the pressure of the liquid phase is formed in the lower portion of the vessel is pressure in the lower part diaphragm via the lower detection source valve, the differential pressure detector via the lower capillary tube, by being transferred respectively, In a differential pressure type water level measuring device for measuring a drain water level inside the container, the upper detection pipe is sequentially provided with a first-stage rising section, a first-stage horizontal section, and a first-stage horizontal section. And a bent shape comprising a second-stage rising portion and a second horizontal portion, and an end of the upper detection pipe on the first-stage rising portion side is connected to an upper portion of the container, An end of the upper detection pipe on the side of the second horizontal portion is connected to the upper flange, and the first horizontal portion and the second
The step horizontal portion has a tapered shape and the first stage horizontal portion and
A differential pressure type water level measuring device, wherein the upper flange side is higher than the second stage horizontal portion side . 4. An upper detection pipe and a lower detection pipe are respectively connected to upper and lower parts of a container to various tanks and the like in a power plant, and the upper detection pipe communicates with an upper diaphragm via an upper flange to connect the container to the upper diaphragm. The pressure of the gas phase formed in the upper part is received by the upper diaphragm through the upper detection source valve, and communicates with the differential pressure detector through the upper capillary tube, and the lower detector communicates with the lower diaphragm through the lower flange. and, the pressure of the liquid phase is formed in the lower portion of the vessel is pressure in the lower die <br/> Yafuramu through the lower detection source valve, the differential pressure detector via the lower capillary tube is transmitted respectively By this, in the differential pressure type water level measuring device for measuring the drain water level inside the container, the upper detection pipe comprises a rising section, a high level horizontal section and a vertical section in order. Has a bent shape consisting of lower part and low horizontal portion, the said raised portion side end portion of the upper detection pipe is connected to the upper portion of the container, an end portion of the upper detection pipe of the low horizontal portion together but are connected to the upper flange, said lower horizontal portion forms a tapered, the low
A differential pressure type water level measuring device, wherein the upper flange side is higher than a horizontal portion side . 5. Connected to at least one of the upper flange and the lower flange with a flow path provided for guiding gas or liquid from the container to the inside,
Pressure difference type water measuring device according to any one of claims 1, 2, 3 or 4, characterized in that the gas or liquid is provided with a passage for discharging the inside of the. 6. Between the upper detection tube and the lower detection tube.
And a top instrument provided in the communication pipe
A stop valve and a lower instrument stop valve;
Meter calibration partition provided in the communication pipe between the instrument stop valve
Plate, the communication pipe and the upper and lower flanges.
The upper detector tube on the instrument side and the lower detector tube on the
Communicates with the upper detector pipe on the instrument side and the lower detector pipe on the instrument side
And upper test valve to control liquid or gas phase pressure injection
And a lower test valve.
Opening the strike valve and testing the gas pressure
The differential pressure type water level measuring device according to claim 1 .