JPH07218316A - Differential pressure type water level measuring device - Google Patents

Abstract

PURPOSE:To exclude both of the factor exerting adverse effect on water level measuring accuracy and maintenance and the dangerousness of exposure at the time of disassembling. CONSTITUTION:One end of a small caliber upper detection pipe 2 is connected to the gaseous phase part of a water supply heater 1 and the other end thereof communicates with an upper diaphragm 10 through an upper detection pipe 6 and an upper flange 8 and the pressure of the gaseous phase formed in the upper part of the water supply heater 1 is transmitted to a differential pressure detector 14 through an upper capillary tube 12 and, in the same way, the pressure of the liquid phase of the water supply heater 1 is transmitted to the differential pressure detector 14 through a lower capillary tube 13. In the differential pressure type water level measuring device thus constituted, in such a case that the pressure of the gaseous phase is high, the upper detection pipe 6 has high level horizontal part, a falling part and a low level horizontal part all of which have a large caliber and is constituted so that the low level horizontal part has a tapered shape and is low on the side of the upper flange part.

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 the 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 JP-A-5-9.
Since disclosed in Japanese Patent No. 3642,
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 the water level measuring unit of FIG. 12, and FIG. 14 is a vertical cross-sectional view of the upper flange of FIG.

In FIG. 12, steam generated in the pressure vessel 34 passes through a main steam line 35, drives a turbine 36, and then is condensed in a condenser 38. Condensed water is the condenser 3
The water is supplied to the feed water heater 1 from 8 by the condensate pump 39, heated by the feed water heater 1, and then returned to the pressure vessel 34.
The heating by the feed water heater 1 is performed by the steam sent from the turbine 36 through the extraction line 37. Further, 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 unit will be described. Figure 1
As shown in FIG. 3, one end of the small-diameter upper detection pipe 2 is connected to the gas phase portion of the feed water heater 1, and the other end is connected to the upper diaphragm 10 via the upper detection pipe 40 having a small diameter and the upper flange 8. The pressure of the vapor phase formed in the upper portion of the feed water heater 1 is transmitted to the differential pressure detector 14 via the upper capillary tube 12. 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 communicating with the lower diaphragm 11 via the lower detection pipe 7 and the lower flange 9 to supply water. 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 case of the upper capillary tube 12 described above. That is, the 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 detection source valve 4 is provided between the small-diameter upper detection pipe 2 and the small-diameter upper detection pipe 40, and a lower detection source is provided between the small-diameter lower detection pipe 3 and the lower detection pipe 7. A valve 5 is attached. 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. Then, at the time of measuring the drain water level in the feed water heater 1, it is examined whether or not the upper detection source valve 4 and the lower detection source valve 5 are opened to maintain the regulated water level. Are sufficiently secured.

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 as described above, and this is connected to 20 A (outer diameter 27.2 mm, inner diameter). 21.4 mm or more of piping is used, which prevents stress concentration at the connection between the small-diameter upper detection pipe 2 and the upper portion of the feed water heater 1. When heat transfer and vibration are large, the diameter is further increased.

As mentioned 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, but the gas phase as a pressure medium is sent to the upper diaphragm 10, the upper capillary tube 12 and the differential pressure detector 14. There is a risk of heat influence. Therefore, as a countermeasure against this, the upper detection source valve 4 and the upper flange 8
Between the and, there is used an upper detection pipe 40 having a smaller diameter than the small diameter upper detection pipe 2 and having an extremely smaller diameter.

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

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 having a small diameter by the upper diaphragm 10 and the lower diaphragm 11, respectively. Therefore, the pressure vessel 14 is discharged.
Foreign matter such as rust does not mix into the insides 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 the joint between the upper flange 8 and the upper diaphragm 10.

[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 upper detection pipe with a small diameter is used for connection. Therefore, when a high-moisture vapor layer is formed in the small-diameter upper detection pipe, the vapor condenses into condensed water, and the condensed water blocks the small-diameter upper detection pipe to cause hunting. There was a risk that the water level would fluctuate and a water level detection error would occur. Further, since the upper detection pipe having a small diameter has an extremely small diameter, there is a risk that stress concentrates and breaks.

Although the above is the case of using the steam heater as an example, the same phenomenon as described above may occur even in the 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 are sometimes removed.
In this case, the drainage work of water that has stagnated inside the upper diaphragm and the lower diaphragm is performed, but there is a risk of being exposed at this time.

Therefore, we would like to abolish the draining work,
Since the upper detection pipe having a small diameter and joined to the upper flange has a small diameter, air and condensed water do not flow out and remain in the upper and lower portions of the upper diaphragm, so it is necessary to remove them. 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 the factors that adversely affect water level measurement accuracy and maintenance, and the risk of exposure to radiation when disassembling.

[0017]

The above object can be achieved as follows.

(1) An upper detection pipe and a lower detection pipe are respectively connected to the upper and lower parts of a container such as various tanks in a power plant, and the upper detection pipe communicates with an upper diaphragm via an upper flange to form an upper part of the container. The pressure of the gas phase formed in is received by the upper diaphragm, communicates with the differential pressure detector via the upper capillary tube, and the lower detection pipe communicates with the lower diaphragm via the lower flange,
The pressure of the liquid phase formed in the lower part of the container is received by the upper diaphragm and transmitted to the differential pressure detector via the lower capillary tube, respectively, and the differential pressure level measurement is performed to measure the drain water level inside the container. In the device, the upper detection pipe has a bent shape composed of a rising part, a high-level horizontal part, a falling part and a low-level horizontal part in order, and the end part of the upper detection pipe on the side of the rising part is the container. On the upper part, the ends of the upper detection pipes on the side of the lower level horizontal part are connected to the upper flange, respectively, and the lower level horizontal part is tapered and the side of the upper flange is lowered.

(2) An upper detection pipe and a lower detection pipe are respectively connected to the upper and lower parts of a container such as various tanks in a power plant, and the upper detection pipe communicates with an upper diaphragm via an upper flange to form an upper part of the container. The pressure of the gas phase formed in is received by the upper diaphragm, communicates with the differential pressure detector via the upper capillary tube, and the lower detection pipe communicates with the lower diaphragm via the lower flange,
The pressure of the liquid phase formed in the lower part of the container is received by the upper diaphragm and transmitted to the differential pressure detector via the lower capillary tube, respectively, and the differential pressure level measurement is performed to measure the drain water level inside the container. In the device, the upper detection pipe is bent in order of a rising portion, a high-level horizontal portion, a first-stage falling portion, a first-stage lower horizontal portion, a second-stage falling portion, and a second-stage lower horizontal portion. It has a shape, the end of the upper detection pipe on the side of the rising part is connected to the upper part of the container, the end of the upper detection pipe on the side of the second stage lower horizontal part is connected to the upper flange, and the first stage The lower horizontal part and the second lower horizontal part are tapered, and both sides of the upper flange are lower.

(3) An upper detection pipe and a lower detection pipe are respectively connected to the upper and lower parts of a container such as various tanks in a power plant, and the upper detection pipe communicates with an upper diaphragm via an upper flange to form an upper part of the container. The pressure of the gas phase formed in is received by the upper diaphragm, communicates with the differential pressure detector via the upper capillary tube, and the lower detection pipe communicates with the lower diaphragm via the lower flange,
The pressure of the liquid phase formed in the lower part of the container is received by the upper diaphragm and transmitted to the differential pressure detector via the lower capillary tube, respectively, and the differential pressure level measurement is performed to measure the drain water level inside the container. In the apparatus, the upper detection pipe has a bent shape which is composed of a first-stage rising part, a first-stage horizontal part, a second-stage rising part, and a second-stage horizontal part, and the first-stage rising part. The end of the upper detection pipe on the side of the section is connected to the upper part of the container, the end of the upper detection pipe on the side of the second stage horizontal part is connected to the upper flange, and the first stage horizontal part and the second stage horizontal part Has a tapered shape, and both sides of the upper flange are raised.

(4) An upper detection pipe and a lower detection pipe are respectively connected to the upper and lower parts of a container such as various tanks in a power plant, and the upper detection pipe communicates with an upper diaphragm via an upper flange to form an upper part of the container. The pressure of the gas phase formed in is received by the upper diaphragm, communicates with the differential pressure detector via the upper capillary tube, and the lower detection pipe communicates with the lower diaphragm via the lower flange,
The pressure of the liquid phase formed in the lower part of the container is received by the upper diaphragm and transmitted to the differential pressure detector via the lower capillary tube, respectively, and the differential pressure level measurement is performed to measure the drain water level inside the container. In the device, the upper detection pipe has a bent shape composed of a rising part, a high-level horizontal part, a falling part, and a low-level horizontal part in order, and the end part of the upper detection pipe on the side of the rising part is the container. Connected to the upper part, the end of the upper detection pipe on the lower horizontal part side is connected to the upper flange, the lower horizontal part is tapered, and the upper flange side is raised.

(5) In (1), (2), (3) or (4), it is provided inside at least one of the upper flange and the lower flange for guiding gas or liquid from the container into the inside. A channel for discharging gas or liquid from the inside is provided by being connected to the channel.

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

In (7) and (6), a sluice valve for instrument calibration is attached to the communication pipe.

[0025]

According to the present invention, in the differential pressure type water level measuring device, when the gas phase part of the feed water heater is at high pressure, the upper detection pipe is sequentially provided with the rising part, the high level horizontal part, the falling part and the low level horizontal part. Having a bent shape, 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 part is tapered, and the lower side of the upper flange is used.

Therefore, when the upper detection pipe is cooled by the ambient air, the vapor in the upper detection pipe is condensed into condensed water, which is stored in the falling portion and the lower horizontal portion of the upper detection pipe, Since the gas phase of (1) presses the upper surface of the condensed water, the differential pressure measuring portion between the upper diaphragm and the differential pressure detector is not affected by the heat held by the gas phase of the upper detection pipe. Therefore, the water level measurement accuracy is improved. Further, since the diameter of each portion of the upper detection pipe is increased, the strength of the upper detection pipe is also improved.

When the gas phase part of the feed water heater has a high pressure,
In the upper detection pipe, like the first stage falling part, the first stage lower horizontal part, the second stage falling part and the second stage lower horizontal part,
Since the falling part and the low-level horizontal part 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 part, and to further improve the water level measurement accuracy. improves.

On the other hand, when the vapor phase part of the feed water heater has a low pressure,
The upper detection pipe has a bent shape composed of a first-stage rising part, a first-stage horizontal part, a second-stage rising part, and a second-stage horizontal part, in order. The end of the upper detection pipe on the side is connected to the upper part of the container, and the end of the upper detection pipe on the side of the second stage 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 higher upper flange side.

Therefore, when the upper detection pipe is cooled by the ambient air and the steam in the upper detection pipe is condensed to be condensed water, the condensed water can be completely flowed into the feed water heater. Therefore, it is possible to prevent the condensed water from flashing and suddenly flowing into the feed water heater, which may affect the accuracy of water level measurement. Further, since the diameter of each portion of the upper detection pipe is increased, the strength of the upper detection pipe is also improved.

When the vapor phase part of the feed water heater has a low pressure,
Depending on the situation, the upper detection pipe may have a bent shape consisting of a rising part, a high-level horizontal part, a falling part, and a low-level horizontal part in order, and the end part of the upper detection pipe on the rising part side. The end of the upper detection pipe connected to the upper part of the container is connected to the upper flange, and the lower horizontal part has a tapered shape and the upper flange side is raised. Also in this case, since the condensed water can be separated from the upper flange, it is possible to prevent the condensed water from affecting the water level measurement accuracy.

Further, in order to discharge the gas or liquid from the inside, at least one of the upper flange and the lower flange is connected to a flow path provided for guiding gas or liquid from the container into the inside. Since the flow path is provided, water can be drained easily, and the risk of exposure to radiation when draining water can be avoided.

Further, since the communication pipe that connects the upper detection pipe and the lower detection pipe is provided, the instrument calibration work by the water manometer can be performed accurately.

Since the metering valve for calibrating the meter is attached to the communication pipe, the meter calibrating work by the pressure gauge can be performed accurately.

[0034]

EXAMPLE A first example of the present invention will be described with reference to FIG. FIG. 1 is a block diagram of the differential pressure type water level measuring device of the present embodiment, and is applied when the gas phase in the feed water heater 1 is high pressure.

FIG. 1 differs from the conventional example (FIG. 13) in the connecting portion 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-level horizontal part, a falling part, and a low-level horizontal part. .

In the case of the present embodiment, since the upper detection pipe 6 has such a structure, the upper detection pipe 6 is cooled by the ambient air and the vapor in the upper detection pipe 6 is condensed and condensed. When it becomes water, the condensed water is the upper detection pipe 6
It can be stored in the lower horizontal part and the lowering part. Further, in this case, since the lower horizontal portion has a tapered shape and the upper flange 8 side is low, the condensed water can be reliably stored in the lower horizontal portion.

That is, since the gas phase in the upper detection pipe 6 presses the upper surface of the condensed water, the gas phase in the upper detection pipe 6 and the portion between the upper flange 8 and the differential pressure detector 14 are Since it is blocked by the condensed water and the differential pressure measurement part is not affected by the heat held by the gas phase of the upper detection pipe, the water level measurement accuracy is improved.

Further, since the diameters of the high-level horizontal portion, the falling portion, and the low-level horizontal portion of the upper detection pipe 6 are all made large, the strength is improved as compared with the conventional pipe portion corresponding to the upper detection pipe 6. ing.

The 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 device of the present embodiment, and is applied when the gas phase in the feed water heater 1 is low pressure.

The difference between FIG. 2 and the conventional example (FIG. 13) is the connecting portion between the upper detection source valve 4 and the upper flange 8 as in the case described above. 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 the case where both sides of the upper flange 8 are raised, and is applied when the vapor phase in the feed water heater 1 is low pressure.

Therefore, when the upper detection pipe 6 is cooled by the ambient air and the vapor in the upper detection pipe 6 is condensed into condensed water, the condensed water should be made to completely flow into the feed water heater 1. Therefore, it is possible to reliably prevent the influence on the water level measurement accuracy caused by the condensed water causing a flush and suddenly flowing into the feed water heater 1.

Also, in this embodiment, as in the above-described embodiments, since the diameter of any 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.

The 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 measurement 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 has a high pressure. Two lower horizontal parts are provided, and a communication pipe 26 that communicates between the upper detection pipe 6 and the lower detection pipe 7 is provided. Further, the upper flange 8 and the lower flange 9 are provided at the upper special flange 15 and This is the case where the lower special flange 16 is replaced.

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

On the other hand, the liquid phase in the feed water heater 1 is from the bottom of the feed water heater 1 to the small-diameter lower detection pipe 3 and the lower detection pipe 7.
Also, the lower special flange 16 is reached via the instrument-side lower detection pipe 18. The lower diaphragm 11 joined to the lower special flange 16 to the differential pressure detector 14 are the same as in the first embodiment. Further, the lower detection source valve 5 is connected to the small-diameter lower detection pipe 3 and the lower detection pipe 7
A lower instrument stop valve 20 is attached to each of them.

The upper special flange 15 has an upper drain pipe 21 and the lower special flange 16 has a lower drain pipe 22.
, And an upper drain valve 23 is attached to the upper drain pipe 21, and a lower drain valve 24 is attached to the lower drain pipe 22, respectively. These are used for draining each of the upper special flange 15 and the lower lower special flange 16. There is.

Further, the upper drain pipe 21 and the lower drain pipe 22 are integrated in the lower part, and a water filling valve 25 is attached to the integrated pipe, which is an upper special flange 15 and a lower lower special flange 16. It is used when water is filled. Further, an upper test valve 27 and a lower test valve 28 are attached to the communication pipe 26.

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

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

That is, for the operation confirmation test and the instrument calibration of the differential pressure type water level measuring device, the lower end of the transparent pipe 30 in the water manometer 29 is connected to the lower test valve 28, and the transparent pipe 3 is connected.
A method of pouring water with a funnel 31 from the upper end of 0 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
However, 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-mentioned operation confirmation test and instrument calibration is improved.

Next, the structures 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 by bolts and nuts, and the pressure of the gas phase in the feed water heater 1 (see FIG. 3) flowing in from the instrument side upper detection pipe 17 is controlled by the upper diaphragm 10. Have been communicated to.

In this case, the instrument-side upper detection pipe 17 has been extended to the inside of the upper special flange 15 in the past, but in the present embodiment, the end portion is extended to the inside of the upper special flange 15. An upper drain pipe 21 is provided, and the end portion of the instrument-side upper detection pipe 17 and the end portion of the upper drain pipe 21 are communicated with each other. 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, and to prevent exposure of 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 each of the following examples, the upper special flange 15 is used.
Although the lower special flange 16 is used, the description is omitted because the contents are the same.

The 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.

Like the third embodiment, this embodiment is also applied when the inside of the feed water heater is at a high pressure, and the basic piping configuration is the same as that of the third embodiment, but the instrument calibration work is performed. The upper test valve 27
The mounting position of the lower test valve 28 and the lower test valve 28 are 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
It is necessary to install 2.

The 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 when the inside of the feed water heater has a low pressure, and the principle is the same as that of the second embodiment.
When the low pressure is close to vacuum, the condensed water in the instrument side upper detection pipe 17 may be drawn to the feed water heater 1 side. Therefore, the instrument side upper detection pipe 17 is tapered and the communication pipe 2
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 accuracy of water level measurement is not affected.

The 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.

Like the fifth embodiment, this embodiment is also applied when the inside of the feed water heater is at a low pressure, and the basic piping configuration is the same as that of the fifth embodiment, but the instrument calibration work is performed. The upper test valve 27
The mounting position of the lower test valve 28 and 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.

Seventh to tenth embodiments of the present invention will be described with reference to FIGS. 8 to 11, respectively. The seventh embodiment to the tenth embodiment are cases in which an instrument calibration sluice valve 33 is attached to the communication pipe 26 or the communication pipe 32 of the third embodiment to the sixth embodiment, respectively.

At the time of instrument calibration, in the third to sixth embodiments (FIGS. 3 and 5 to 7), a water manometer 29 (see FIG. 3) is attached to the lower test valve 28 to perform instrument calibration. However, in the seventh and ninth embodiments, the communication pipe 26 is
In the embodiment and the tenth embodiment, the communication pipe 32 is provided with a calibrating valve 33 for measuring instruments, respectively, and the upper side and the lower side are separately arranged so that the measuring instrument can be calibrated by pressure. The meter calibration sluice valve 33 is closed, pressure is applied from the upper test valve 27 and the lower test valve 28, and the meter 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 by combining the upper side and the lower side, but the pressure gauges of the seventh to tenth examples are used. When using, the upper side and the lower side are calibrated separately.

[0063]

According to the present invention, in the differential pressure type water level measuring device, factors that adversely affect the water level measuring accuracy and maintenance,
In addition, the risk of exposure to radiation when disassembling can be eliminated together.

[Brief description of 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 vertical cross-sectional view of the upper special flange of FIG.

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 sluice valve is attached to FIG.

FIG. 9 is a piping configuration diagram in which an instrument calibration sluice valve is attached to FIG.

FIG. 10 is a piping configuration diagram in which an instrument calibration sluice valve is attached to FIG. 6.

11 is a piping configuration diagram in which an instrument calibration sluice valve is attached to FIG. 7. FIG.

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

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

14 is a vertical cross-sectional view of the upper flange of FIG.

[Explanation of symbols]

1 ... Water heater, 2 ... Small diameter upper detection pipe, 3 ... Small diameter lower detection pipe, 4 ... Upper detection source valve, 5 ... Lower detection source 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 piping, 22 ... Lower drain piping, 23 ...
Upper drain valve, 24 ... Lower drain valve, 25 ... Water filling valve,
26, 32 ... Communication pipe, 27 ... Upper test valve, 28 ... Lower test valve, 29 ... Water manometer, 30 ... Transparent pipe, 31 ...
Funnel, 33 ... Gate valve for instrument calibration, 34 ... Pressure vessel, 35 ... Main steam line, 36 ... Turbine, 37 ... Extraction line, 38 ... Condenser, 39 ... Condensate pump, 40 ... Upper detection pipe with small diameter .

Claims (7)

[Claims] 1. An upper detection pipe and a lower detection pipe are connected to an upper portion and a lower portion of a container such as various tanks 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, and communicates with the differential pressure detector through the upper capillary tube, and the lower detection pipe communicates with the lower diaphragm through the lower flange, and the lower part of the container. The pressure of the liquid phase formed in the above is received by the upper diaphragm and transmitted to the differential pressure detector through the lower capillary tube, respectively, to measure the drain water level inside the container. In the device, the upper detection pipe has a bent shape composed of a rising part, a high-level horizontal part, a falling part, and a low-level horizontal part in order. A shape, an end of the upper detection pipe on the side of the rising part is connected to the upper part of the container, and an end of the upper detection pipe on the side of the lower horizontal part is connected to the upper flange, respectively, The differential pressure type water level measuring device, wherein the low-level horizontal portion has a tapered shape and the side of the upper flange is lowered. 2. An upper detection pipe and a lower detection pipe are connected to an upper portion and a lower portion of a container such as various tanks 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, and communicates with the differential pressure detector through the upper capillary tube, and the lower detection pipe communicates with the lower diaphragm through the lower flange, and the lower part of the container. The pressure of the liquid phase formed in the above is received by the upper diaphragm and transmitted to the differential pressure detector through the lower capillary tube, respectively, to measure the drain water level inside the container. In the device, the upper detection pipes are arranged in order of a rising part, a high-level horizontal part, a first-stage falling part, and a first part.
It has a bent shape consisting of a step lower horizontal part, a second step lowering part and a second step lower horizontal part, and an end part of the upper detection pipe on the side of the rising part is connected to an upper part of the container, An end portion of the upper detection pipe on the side of the second lower horizontal portion is connected to the upper flange, and the first lower horizontal portion and the second lower horizontal portion are tapered, and both of them are the upper flange. The differential pressure type water level measuring device is characterized in that the side of the water is lowered. 3. An upper detection pipe and a lower detection pipe are connected to an upper portion and a lower portion of a container such as various tanks 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, and communicates with the differential pressure detector through the upper capillary tube, and the lower detection pipe communicates with the lower diaphragm through the lower flange, and the lower part of the container. The pressure of the liquid phase formed in the above is received by the upper diaphragm and transmitted to the differential pressure detector through the lower capillary tube, respectively, to measure the drain water level inside the container. In the apparatus, the upper detection pipe includes, in order, a first stage rising part, a first stage horizontal part, a second stage rising part and a second stage horizontal part. An end portion of the upper detection pipe on the side of the first stage rising portion is connected to an upper portion of the container, and an end of the upper detection pipe on the side of the second stage horizontal portion. A portion is connected to the upper flange, and the first-stage horizontal portion and the second-stage horizontal portion are tapered, and both sides of the upper flange are raised, and a differential pressure type water level measuring device is characterized. 4. An upper detection pipe and a lower detection pipe are connected to an upper portion and a lower portion of a container such as various tanks 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, and communicates with the differential pressure detector through the upper capillary tube, and the lower detection pipe communicates with the lower diaphragm through the lower flange, and the lower part of the container. The pressure of the liquid phase formed in the above is received by the upper diaphragm and transmitted to the differential pressure detector through the lower capillary tube, respectively, to measure the drain water level inside the container. In the apparatus, the upper detection pipe is a refraction part which is composed of a rising part, a high-level horizontal part, a falling part, and a low-level horizontal part, in order. Having a shape, the end of the upper detection pipe on the side of the rising part is connected to the upper part of the container, the end of the upper detection pipe on the side of the lower horizontal part is connected to the upper flange, The differential pressure type water level measuring device, wherein the lower horizontal portion is tapered and the side of the upper flange is raised. 5. A gas flow path is provided inside at least one of the upper flange and the lower flange to guide a gas or a liquid from the container into the inside, and the gas or the liquid is connected to the flow path. The differential pressure type water level measuring device according to claim 1, 2, 3, or 4, wherein a flow path for discharging from the inside is provided. 6. A communication pipe that connects the upper detection pipe and the lower detection pipe is provided.
The differential pressure type water level measuring device described. 7. The differential pressure type water level measuring device according to claim 6, wherein a calibrating valve for measuring instrument is attached to the communicating pipe.