JP2015068647A - Pressure measuring device and pressure measuring method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To allow an output circuit to be exchanged without spending much time and many operations in radiation environment and high temperature environment.SOLUTION: At least one place among insides of a pressure introducing passage 6, a wall surface of the pressure introducing passage 6, a pressure receiving chamber wall surface 15, and a space 14 formed between a diaphragm 5 and the pressure receiving wall surface 15 is arranged with a hydrogen adsorbing material 9 that adsorbs a hydrogen atom in a sealing liquid 8 sealed in the space 14 and the pressure introducing passage 6. The output circuit 12 is detachably attached to a main body part 4 with connectors 19 and 20 so as to be connected to a pressure sensor 13.

Description

  The present invention relates to a pressure measuring device and a pressure measuring method for measuring a pressure of a fluid or a pressure difference between two points in a nuclear power plant, an oil refinery plant, a chemical plant, etc. and transmitting a detection signal to the outside. In particular, the present invention relates to a pressure measuring device and a pressure measuring method suitable for use in a radiation environment or a high temperature environment.

  The pressure measuring device receives the pressure of the process in the nuclear power plant and general industrial plant with a diaphragm, transmits it to the pressure sensor by the liquid in the pressure guide (for example, silicon oil), and transmits the detection signal of the pressure sensor to the outside. To do. Some pressure measuring devices measure the absolute pressure of the fluid and others measure the pressure difference between two points of the fluid. These pressure measuring devices are required to have a measurement accuracy of ± 1%, for example, from the viewpoint of ensuring plant safety and product quality.

  However, in a special environment where high-temperature and high-pressure steam is handled, it is difficult to maintain the measurement accuracy for a long time due to the influence of hydrogen that has passed through the diaphragm from the outside of the pressure measuring device. That is, a part of the hydrogen (hydrogen atoms, hydrogen molecules, hydrogen ions) contained in the measurement fluid accumulates as bubbles in the sealed liquid in the pressure guiding path after permeating the diaphragm, and the inside of the pressure guiding path is affected by the influence. The pressure increases. For this reason, a change in pressure applied to the diaphragm cannot be correctly transmitted to the pressure sensor, and measurement accuracy is lowered.

  Therefore, conventionally, a technique for reducing the influence of hydrogen that has permeated through the diaphragm from the outside of the pressure measuring device by forming a hydrogen storage film on one surface of the diaphragm that is in contact with the sealed liquid has been disclosed (for example, patents). Reference 1).

JP 2005-114453 A

  The above-described conventional technique is for reducing the influence of hydrogen that has passed through the diaphragm from the outside of the pressure measuring device, but does not take into account the use in a radiation environment or a high-temperature environment. In other words, the sealed liquid sealed in the pressure guiding path is decomposed by radiation and heat to generate hydrogen and hydrocarbons (methane, ethane, propane, etc.), but these gases accumulate in the sealed liquid, and a certain amount If it exceeds, bubbles are formed and the pressure inside the pressure guiding path is increased. For this reason, when the amount of bubbles increases, the tolerance of error of the pressure measuring device (for example, accuracy of ± 1%) cannot be maintained. Also, regular and irregular inspections must be performed to maintain accuracy, increasing maintenance work. Furthermore, if the permissible accuracy is not maintained as a result of the inspection, the pressure measuring device needs to be replaced, resulting in a problem that the replacement cost becomes enormous.

  When the pressure measuring device is installed in a radiation environment or a high temperature environment, the output circuit for transmitting the detection signal of the pressure sensor to the outside of the pressure measuring device may be damaged. In that case, even if the diaphragm, the pressure guiding path, and the pressure sensor are healthy, the pressure cannot be measured. Conventionally, when the output circuit is damaged, it is necessary to replace the entire pressure measuring device including the diaphragm, pressure guiding channel, and sensor that are connected together by the pressure guiding channel, or the pressure measuring device is isolated from the plant and replaced. A great deal of time and work has occurred.

  The present invention has been made in view of the above-described points, and an object thereof is to facilitate replacement of an output circuit in a radiation environment or a high temperature environment.

In order to solve the above-described problems and achieve the object of the present invention, a pressure measuring device of the present invention includes a diaphragm, a pressure receiving chamber wall surface, a pressure guiding path, a sealed liquid, a hydrogen storage material, a pressure sensor, and a memory. An apparatus and an output circuit.
The diaphragm receives the pressure of the measurement fluid. A diaphragm is provided on the wall surface of the pressure receiving chamber. The pressure guiding path is connected to the pressure receiving chamber wall surface. The sealed liquid is sealed in a space and a pressure guiding path formed between the diaphragm and the pressure receiving chamber wall surface. The hydrogen storage material is disposed in at least one of the inside of the pressure guiding path, the wall surface of the pressure guiding path, the pressure receiving chamber wall surface, and the space between the diaphragm and the pressure receiving chamber wall surface, and stores hydrogen atoms in the sealed liquid. Occlude. The pressure sensor detects the pressure of the measurement fluid received by the diaphragm transmitted by the sealing liquid. The output circuit is detachably attached with a connector to the main body provided with the pressure sensor, thereby being connected to the pressure sensor and transmitting a detection signal output from the pressure sensor to the outside.

  Further, the pressure measuring method of the present invention encloses the sealing liquid in a space between the diaphragm for receiving the pressure of the measurement fluid and the pressure receiving chamber wall surface provided with the diaphragm, and the pressure guiding path connected to the pressure receiving wall surface. To do. A hydrogen occlusion material that occludes hydrogen atoms in the sealed liquid is disposed in at least one of the inside of the pressure guiding path, the wall surface of the pressure guiding path, the pressure receiving chamber wall surface, and the space between the diaphragm and the pressure receiving chamber wall surface. To do. A pressure sensor that detects the pressure of the measurement fluid received by the diaphragm transmitted by the sealing liquid outputs a detection signal. Then, an output circuit that transmits a detection signal output from the pressure sensor to the outside is detachably attached to the main body provided with the pressure sensor with a connector, thereby connecting the output circuit to the pressure sensor.

  According to the present invention, the output circuit is detachably attached to the main body with a connector so that the output circuit can be easily removed from the main body and replaced with a new output circuit in a radiation environment or a high temperature environment. Can do.

It is a figure which shows the structure of the pressure measuring device which concerns on the 1st Embodiment of this invention. It is a figure which shows the example of arrangement | positioning of the hydrogen storage material which concerns on the 1st Embodiment of this invention. It is a figure which shows the example of arrangement | positioning of the hydrogen storage material which concerns on the 1st Embodiment of this invention. It is a figure which shows the method of occluding with the hydrogen storage material the hydrogen atom which generate | occur | produced when the sealing liquid which concerns on the 1st Embodiment of this invention is radiolyzed. It is a figure which shows the method of occluding the hydrogen atom in hydrocarbons which concerns on the 1st Embodiment of this invention with a hydrogen storage material. It is a figure which illustrates the shape of the hydrogen storage material which concerns on the 1st Embodiment of this invention. It is a figure which illustrates the shape of the hydrogen storage material which concerns on the 1st Embodiment of this invention. It is a figure which illustrates the shape of the hydrogen storage material which concerns on the 1st Embodiment of this invention. It is a figure which illustrates the shape of the hydrogen storage material which concerns on the 1st Embodiment of this invention. It is a figure which illustrates the shape of the hydrogen storage material which concerns on the 1st Embodiment of this invention. It is a figure which shows the state which removed the output circuit which concerns on the 1st Embodiment of this invention. It is a figure which shows the structure of the output circuit which concerns on the 1st Embodiment of this invention. It is a figure which shows the pressure-voltage characteristic of the sensor which concerns on the 1st Embodiment of this invention. It is a figure which shows the structure of the computer used as an output circuit based on the 2nd Embodiment of this invention. It is a figure which shows the structure of the pressure measuring device which concerns on the 3rd Embodiment of this invention.

<1. First Embodiment>
[Configuration example of pressure measuring device]
Hereinafter, a first embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a cross-sectional view showing a configuration of a pressure measuring device according to a first embodiment of the present invention.
This pressure measuring device 1 is a device that measures a pressure difference between two points (high pressure side and low pressure side) of a fluid. The pressure measuring device 1 is provided with a main body 4 to which an output circuit 12 is attached, a high-pressure side pressure transmission unit 16, and a low-pressure side pressure transmission unit 17. The high-pressure side pressure transmission unit 16 and the low-pressure side pressure transmission unit 17 are each provided with a replacer unit 2 and a capillary unit 3 (however, illustration of the replacer unit 2 of the low-pressure side pressure transmission unit 17 is omitted in the figure). In addition, illustration of a part of the capillary section 3 is omitted).

  A flange 18 is formed at the position of the tip of the replacer unit 2 (the left side of the drawing in the high pressure side pressure transmission unit 16), and a pressure receiving diaphragm 5 as a first diaphragm is formed on the pressure receiving chamber wall surface 15. Is provided. The flange 18 is fastened to a flange 32 at the tip of a pipe 31 provided on the plant side for introducing the measurement fluid 30 by bolts and nuts (not shown). The pressure receiving diaphragm 5 receives the pressure of the measurement fluid 30 in the pipe 31.

  In addition, a pressure receiving chamber 14 that is a space surrounded by the pressure receiving diaphragm 5 and the pressure receiving chamber wall surface 15 is formed in the replacer unit 2, and a pressure guiding path 6 connected to the pressure receiving chamber wall surface 15 is provided. Yes. A sealed liquid (for example, silicon oil) 8 is sealed in the pressure receiving chamber 14 and the pressure guiding path 6. In the following description, all of the pressure guiding paths provided in the pressure measuring device 1 and filled with the sealing liquid 8 are referred to as pressure guiding paths 6. Further, in FIG. 1, a portion (the pressure receiving chamber 14, the pressure guiding path 6, and each pressure receiving chamber described later) in which the sealing liquid 8 is sealed in the pressure measuring device 1 is shown deeply.

  An intermediate diaphragm 7 as one of the second diaphragms is provided at the position of the terminal end of the replacer unit 2 (the right side end of the high pressure side pressure transmission unit 16). The intermediate diaphragm 7 receives the pressure of the measurement fluid 30 received by the pressure receiving diaphragm 5 and transmitted by the sealing liquid 8 in the pressure guiding path 6 of the displacement unit 2.

  Similarly to the pressure receiving chamber 14, a pressure receiving chamber (no symbol) surrounded by the intermediate diaphragm 7 and the pressure receiving chamber wall surface (no symbol) is formed in the replacer unit 2. The wall surface of the pressure receiving chamber is connected to a pressure guiding path 6 provided in the capillary section 3. An enclosed liquid 8 is also enclosed in the pressure receiving chamber and the pressure guiding path 6.

  The pressure guiding path 6 of the capillary portion 3 communicates with the main body portion 4. In the main body 4, a seal diaphragm 10 as another one of the second diaphragms is opposed to the pressure guide paths 6 of the capillary portions 3 of the high pressure side pressure transmission unit 16 and the low pressure side pressure transmission unit 17. Is provided. The seal diaphragm 10 receives the pressure transmitted by the sealing liquid 8 in the pressure guiding path 6 of the capillary section 3.

  Further, in the main body portion 4, similarly to the pressure receiving chamber 14 of the replacer portion 2, a pressure receiving chamber (no symbol) surrounded by the seal diaphragm 10 and the pressure receiving chamber wall surface (no symbol) is formed. The pressure receiving chamber wall surface is connected to a pressure guiding path 6 provided in the main body 4. An enclosed liquid 8 is also enclosed in the pressure receiving chamber and the pressure guiding path 6.

  A center diaphragm 11 is provided in the main body 4 to separate the pressure guiding path 6 of the main body 4 between the high pressure side and the low pressure side. The center diaphragm 11 is an overload protection diaphragm with a small amount of deformation corresponding to the applied pressure. Even when an excessive pressure is applied to one of the high pressure side and the low pressure side, the center diaphragm 11 itself is not greatly deformed, so that the deformation amount of the pressure receiving diaphragm 5, the intermediate diaphragm 7, and the seal diaphragm 10 is not increased, and those diaphragms are not. Damage is less likely to occur.

  In the main body 4, a sensor (for example, a semiconductor pressure sensor) 13 as an example of a pressure sensor is provided. The lower surface of the sensor 13 is in contact with the pressure guiding path 6 on the high pressure side of the main body 4. Therefore, the pressure of the measurement fluid 30 received by the pressure receiving diaphragm 5 of the high pressure side pressure transmission unit 16 is transmitted to the lower surface of the sensor 13. This pressure is transmitted by the sealing liquid 8 in the pressure guiding path 6 from the replacer section 2 to the main body section 4 of the high pressure side pressure transmission section 16, and the intermediate diaphragm 7 and the seal diaphragm 10 interposed in the middle of the pressure guiding path 6. Is done.

  The upper surface of the sensor 13 is in contact with the pressure guiding path 6 on the low pressure side of the main body 4. Therefore, the pressure of the measurement fluid 30 received by the pressure receiving diaphragm 5 of the low pressure side pressure transmission unit 17 is transmitted to the upper surface of the sensor 13. This pressure is transmitted by the sealing liquid 8 in the pressure guiding path 6 from the replacer section 2 to the main body section 4 of the low pressure side pressure transmission section 17, the intermediate diaphragm 7 interposed in the middle of the pressure guiding path 6, and the seal diaphragm 10. Is done. The sensor 13 detects the pressure transmitted to the lower surface and the pressure transmitted to the upper surface. Then, the difference between the pressure transmitted to the lower surface and the pressure transmitted to the upper surface is output to the output circuit 12 as a voltage signal.

  In the pressure measuring device 1 having such a configuration, hydrogen in the measurement fluid 30 that has passed through the pressure receiving diaphragm 5 from the outside of the pressure measuring device 1 (for example, the pipe 31) is bubbled in the sealed liquid 8, thereby The pressure inside the passage 6 increases. As a result, it is known that a change in pressure applied to the pressure receiving diaphragm 5 cannot be correctly transmitted to the sensor 13 and the measurement accuracy is lowered. Specifically, when the amount of gas bubbled inside the pressure guiding path 6 differs between the high pressure side pressure transmission unit 16 and the low pressure side pressure transmission unit 17, the pressure value varies from the normal value.

  Furthermore, when the pressure measuring device 1 is installed in a radiation environment or a high temperature environment, the sealed liquid 8 is decomposed by radiation or heat to generate hydrogen and hydrocarbons (methane, ethane, propane, etc.). The gas is bubbled in the sealing liquid 8. As a result, the pressure inside the pressure guiding path 6 rises, and the change in pressure applied to the pressure receiving diaphragm 5 cannot be correctly transmitted to the sensor 13 and the measurement accuracy is lowered.

  Hydrogen that has passed through the pressure-receiving diaphragm 5 from the outside of these pressure measuring devices 1 and hydrogen and hydrocarbons generated inside the sealing liquid 8 are bubbled when the amount of the sealing liquid 8 inside the pressure guiding path 6 exceeds the dissolved amount. Turn into. Furthermore, the closer the pressure of the measurement fluid is to a vacuum, the smaller the amount of dissolution, so the amount of gas that is bubbled increases and the measurement accuracy decreases significantly.

Therefore, in the pressure measuring device 1, a hydrogen storage material that stores hydrogen atoms in the sealing liquid 8 is disposed at least at one of the following <1> to <10> for each of the high pressure side and the low pressure side. doing.
<1> Inside of the pressure guide path 6 of the replacer section 2, capillary section 3 or main body section <2> Wall surface of the pressure guide path 6 of the replacer section 2, capillary section 3 or main body section <3> Wall surface of the pressure receiving chamber 15
<4> Inside of pressure receiving chamber 14 <5> Pressure receiving chamber wall surface of intermediate diaphragm 7 <6> Side opposite to the pressure receiving chamber wall surface of intermediate diaphragm 7 (in the high pressure side pressure transmission section 16, the left side of intermediate diaphragm 7 in FIG. 1. ) Wall surface <7> Inside of pressure receiving chamber for intermediate diaphragm 7 <8> Pressure receiving chamber wall surface for seal diaphragm 10 <9> Wall surface opposite to pressure receiving chamber wall surface for seal diaphragm 10 <10> About seal diaphragm 10 Inside of the pressure chamber

FIG. 1 shows an example in which the hydrogen storage material 9 is arranged inside or on the wall surface of the pressure guiding path 6 of the replacer section 2 as an example of the above locations <1> and <2>.
FIG. 2 shows an example in which the hydrogen storage material 9 is arranged on the pressure receiving chamber wall surface 15 which is the location <3>.
FIG. 3 shows an example in which the hydrogen storage material 9 is arranged inside the pressure receiving chamber 14 which is the location <4>.

  In addition to the locations <1> to <10> described above, the hydrogen storage material 9 is disposed on one side of the pressure receiving diaphragm 5 that is in contact with the sealed liquid 8, on both sides of the pressure receiving diaphragm 5, or any one side thereof. May be. Further, the hydrogen storage material 9 may be disposed on both surfaces or any one surface of the seal diaphragm 10 or both surfaces or any one surface of the center diaphragm 11.

  As the hydrogen storage material 9, palladium, magnesium, vanadium, titanium, manganese, zirconium, nickel, niobium, cobalt, calcium, or an alloy thereof is used.

[Method of storing hydrogen atoms by hydrogen storage material]
FIG. 4 shows a method in which hydrogen atoms generated by the radioactive decomposition of the sealing liquid 8 are occluded by the hydrogen occlusion material 9.
As shown on the left side of FIG. 4, when the sealing liquid 8 receives radiation such as gamma rays 42, as shown in the composition formula 41 of the sealing liquid 8, the combination of C and H that composes the sealing liquid 8, Si and C Breaks. When the hydrogen storage material 9 is not used, the methyl group 45 and the hydrogen atom 46 generated by the influence of radiation combine with each other to become methane 47 and hydrogen 48 as shown in the upper right frame 43 of FIG. .

  On the other hand, when the hydrogen storage material 9 is used, as shown in the lower right frame 44 in FIG. 4, hydrogen atoms 46 in which the bond between Si and C is broken are stored in the hydrogen storage material 9. The amount of the group 45 bonded to the hydrogen atom 46 is reduced, and the amount of methane 47 generated can be suppressed. The methyl group 45 that is not bonded to the hydrogen atom 46 returns to the sealing liquid 8 again. Thereby, it is possible to prevent an increase in pressure inside the pressure guiding path 6 due to the hydrocarbons such as methane 47 being accumulated as bubbles in the sealing liquid 8.

FIG. 5 shows a method for storing hydrogen atoms in methane 47 as an example of a method for storing hydrogen atoms in hydrocarbons by the hydrogen storage material 9.
As described with reference to FIG. 4, the methyl group 45 and a part of the hydrogen atom 46 generated by radiolysis are combined with each other to become methane 47. Thereafter, when the methane 47 comes into contact with the surface of the hydrogen storage material 9, it dissociates into a methyl group 45 and a hydrogen atom 46. The hydrogen atoms 46 are occluded by the hydrogen occlusion material 9, and the methyl groups 45 eventually become carbon atoms and are adsorbed on the surface of the hydrogen occlusion material 9.

  Such a hydrogen storage material 9 is disposed in the places <1> to <10> described above. The hydrogen storage material 9 not only transmits hydrogen that has passed through the pressure receiving diaphragm 5 from the outside of the pressure measuring device 1, but also hydrogen generated in the sealing liquid 8 and hydrogen atoms in the hydrocarbons in the hydrogen storage material 9 itself. It can occlude up to 935 times its volume. For this reason, it is possible to prevent an increase in the pressure inside the pressure guiding path 6 due to the accumulation of hydrogen and hydrocarbons as bubbles in the sealing liquid 8.

  In addition, if the hydrogen storage material 9 is arrange | positioned especially in the location where radiation dose increases among the locations of said <1>-<10>, or the location where it becomes especially high temperature, the hydrogen and carbonization which generate | occur | produced inside the sealing liquid 8 are carried out. Hydrogen atoms in hydrogen can be stored in the hydrogen storage material 9 more efficiently. Also, if the hydrogen storage material 9 is disposed at a location as shown in FIGS. 1 to 3, the hydrogen storage material 9 is disposed at a location close to the pressure receiving diaphragm 5. Hydrogen that has passed through the pressure receiving diaphragm 5 can also be stored more efficiently.

[Example of arrangement and shape of hydrogen storage material]
6 to 9 show examples of the shape of the hydrogen storage material 9 when the hydrogen storage material 9 is disposed inside the pressure guiding path 6.
FIG. 6 shows an example in which a powdered hydrogen storage material 9 a is sealed inside the pressure guiding path 6 as the hydrogen storage material 9. The powdered hydrogen storage material 9 a becomes a colloidal liquid when mixed with the sealing liquid 8. The smaller the particle diameter, the larger the area where the powdered hydrogen storage material 9a comes into contact with hydrogen atoms and hydrocarbons, so that the storage rate of hydrogen atoms can be increased.

  FIG. 7 shows an example in which a solid hydrogen storage material 9 b is enclosed as the hydrogen storage material 9 inside the pressure guiding path 6. The solid hydrogen storage material 9b may be a pellet, a plate, or a sphere. Further, if the solid hydrogen storage material 9b is made porous, the area in contact with hydrogen and hydrocarbons is increased, so that hydrogen atoms can be stored more efficiently.

  The solid hydrogen storage material 9b may be mixed with the sealing liquid 8 in the pressure guiding path 6, but is preferably fixed to the wall surface 6a of the pressure guiding path 6 by welding. If fixed to the wall surface 6a in this way, it is possible to prevent the solid hydrogen storage material 9b from colliding with the diaphragms such as the pressure receiving diaphragm 5 and the intermediate diaphragm 7 and the wall surface 6a and deteriorating them.

  FIG. 8 shows an example in which a rod-shaped hydrogen storage material 9 c is sealed as the hydrogen storage material 9 inside the pressure guiding path 6. The rod-like hydrogen storage material 9c may be in the form of a wire, but if it is formed in a wide shape such as it is expanded, the area in contact with hydrogen and hydrocarbons is increased, so that hydrogen atoms can be stored more efficiently. can do. Further, if the rod-shaped hydrogen storage material 9c is made porous, the area in contact with hydrogen and hydrocarbons is increased, so that hydrogen atoms can be stored more efficiently. The rod-shaped hydrogen storage material 9c is easy to process and can reduce the cost. Furthermore, the rod-shaped hydrogen storage material 9c can be easily sealed into the inside of the narrow diameter pressure guiding path 6 disposed in the capillary portion 3.

  FIG. 9 shows an example in which the hydrogen occlusion material 9d obtained by processing the rod-like hydrogen occlusion material 9c shown in FIG. Since the spiral hydrogen storage material 9d has a larger area in contact with hydrogen and hydrocarbons than the rod-shaped hydrogen storage material 9c having the same length, it can store hydrogen atoms more efficiently.

  The rod-shaped hydrogen storage material 9c shown in FIG. 8 and the spiral-shaped hydrogen storage material 9d shown in FIG. 9 may be merely enclosed in the pressure guide path 6, but the pressure guide path as shown in FIG. It is suitable to fix to the wall surface 6a of 6 by welding (surface welding or spot welding, etc.) or adhesion. If fixed to the wall surface 6a in this way, the rod-shaped hydrogen storage material 9c and the spiral hydrogen storage material 9d are prevented from colliding with the diaphragms such as the pressure receiving diaphragm 5 and the intermediate diaphragm 7 and the wall surface 6a and deteriorating them. become able to.

  In addition, the shape of the hydrogen storage material 9 demonstrated using FIGS. 6-9 and the form of enclosure are not only the case where the hydrogen storage material 9 is arrange | positioned inside the pressure guide path 6, but said <4>, < It may also be adopted when the hydrogen storage material 9 is disposed inside each pressure receiving chamber such as the pressure receiving chamber 14 as in <7> and <10>.

FIG. 10 shows an example of the shape of the hydrogen storage material 9 when the hydrogen storage material 9 is arranged on the wall surface of the pressure guiding path 6, and a film 9 e of the hydrogen storage material is formed on the wall surface 6 a of the pressure guiding path 6 by plating or sputtering. An example is shown.
If the hydrogen storage material film 9e is formed on the wall surface 6a of the pressure guide path 6 in this manner, the hydrogen storage material 9 is disposed inside the pressure guide path 6 as illustrated in FIGS. The viscosity of the sealing liquid 8 in the pressure guiding path 6 and the amount of the sealing liquid 8 do not change. For this reason, the possibility that the measurement performance of the pressure measuring device 1 itself deteriorates can be greatly reduced.

  The shape of the hydrogen storage material 9 shown in FIG. 10 is not limited to the case where the hydrogen storage material 9 is arranged on the wall surface of the pressure guiding path 6, and the above <3>, <5>, <6>, <8 >, <9>, and the case where the hydrogen storage material 9 is disposed on each pressure receiving chamber wall surface or the wall surface opposite to the pressure receiving chamber wall surface.

  As described above, in this pressure measuring device 1, not only hydrogen that has passed through the pressure receiving diaphragm 5 from the outside of the pressure measuring device 1, but also hydrogen generated in the sealing liquid 8 and hydrogen atoms in the hydrocarbons. Occlude with the hydrogen storage material 9. As a result, it is possible to prevent an increase in pressure inside the pressure guiding path 6 due to hydrogen and hydrocarbons remaining as bubbles in the sealing liquid 8.

  However, when the pressure measuring device 1 is installed in a radiation environment or a high temperature environment, the output circuit for transmitting the detection signal of the sensor 13 to the outside may be damaged. In that case, even if the pressure receiving diaphragm 5, the intermediate diaphragm 7, the seal diaphragm 10, the center diaphragm 11, the pressure guiding path 6, and the sensor 13 are healthy, the pressure cannot be measured. When the output circuit is damaged, the pressure measuring device including the pressure receiving diaphragm 5, the intermediate diaphragm 7, the seal diaphragm 10, the center diaphragm 11, the pressure guiding path 6, and the sensor 13 that are integrally connected by the pressure guiding path 6. The entire one needs to be replaced. Moreover, it is necessary to isolate and replace the pressure measuring device 1 from the plant. However, in order to replace the pressure measuring device 1 in this way, a great amount of time and work are required.

  Therefore, in the pressure measuring apparatus 1, as shown in FIG. 1, a connector (socket side) 19 for outputting a detection signal of the sensor 13 is provided on the surface of the main body portion 4. The output circuit 12 having a connector (plug side) 20 corresponding to the connector 19 is connected to the sensor 13 by being detachably attached to the main body 4 with the connectors 19 and 20. A housing 21 for protecting the output circuit 12 from mechanical impact is detachably fitted to the main body 4.

[Example of output circuit removed from main unit]
FIG. 11 shows a state in which the housing 21 is removed from the main body 4, the connector 20 is removed from the connector 19, and the output circuit 12 is removed from the main body 4.
Thus, in this pressure measuring device 1, only the output circuit 12 can be easily detached from the main body 4.

[Example of output circuit configuration]
FIG. 12 is a block diagram showing the configuration of the output circuit 12.
The output circuit 12 includes an amplifier circuit 22, a correction circuit 23, a transmission circuit 24, a storage device 25, and a display device 26. Further, the output circuit 12 has an information writing terminal 27 for writing information in the storage device 25 as an input / output terminal other than the connector 20, and an output terminal 28 for transmitting the output signal of the transmission circuit 24 to the outside. Is provided.

  The storage device 25 stores pressure-voltage correction information for correcting the detection signal of the sensor 13 in accordance with the pressure-voltage characteristics of the sensor 13 in the main body 4.

[Sensor pressure-voltage correction characteristics]
Here, the pressure-voltage characteristics of the sensor 13 will be described.
FIG. 13 is a diagram showing the pressure-voltage characteristics of the sensor 13, with the pressure P on the vertical axis and the voltage V on the horizontal axis.
As indicated by a broken line in FIG. 13, the ideal pressure-voltage characteristic is that the pressure P and the voltage V are directly proportional. However, as indicated by a solid line in FIG. 13, in the actual sensor 13, the pressure P and the voltage V are not directly proportional. The pressure-voltage characteristics are different for each sensor 13. For this reason, in the storage device 25 shown in FIG. 12, before the output circuit 12 is attached to the main body 4, pressure-voltage correction information adjusted according to the pressure-voltage characteristics of the sensor 13 in the main body 4 is used for information writing. Writing from terminal 27. The pressure-voltage correction information and the like stored in the storage device 25 are individually managed by a manufacturing number as an example of unique information allocated to the sensor 13. For this reason, the newly written information in the storage device 25 does not erase the existing information. Further, the location of information can be reliably specified in the storage device 25.

  The voltage signal detected by the sensor 13 and input from the connector 20 to the output circuit 12 is amplified by the amplifier circuit 22 and sent to the correction circuit 23. The correction circuit 23 corrects the voltage value of the voltage signal from the amplifier circuit 22 based on the pressure-voltage correction information stored in the storage device 25 and sends it to the transmission circuit 24 and the display device 26. The transmission circuit 24 converts the voltage signal from the correction circuit 23 into a current signal of 4 to 20 mA and transmits it from the output terminal 28 to the outside of the output circuit 12. The display device 26 displays the pressure difference measurement result based on the voltage signal from the correction circuit 23.

  In this pressure measuring device 1, even when the output circuit 12 is damaged due to radiation or high temperature, only the output circuit 12 can be easily removed from the main body 4 by replacement of the connectors 19 and 20 and replaced with a new output circuit 12. can do. For this reason, the time and work amount required for replacing the output circuit 12 can be greatly reduced.

  Further, before the new output circuit 12 is attached to the main body 4, the same pressure-voltage correction information stored in the storage device 25 of the damaged output circuit 12 is used as the information writing terminal 27 of the new output circuit 12. Are stored in the storage device 25. Thereby, it becomes easy to write the pressure-voltage correction information to the storage device 25, and the storage device 25 can be created promptly. Further, even after the output circuit 12 is replaced, the detection signal of the sensor 13 can be corrected using the pressure-voltage correction information adjusted for each sensor 13 as before the output circuit 12 is replaced. Therefore, even after the output circuit 12 is replaced, it is possible to continue measuring the pressure difference with high accuracy.

<2. Second Embodiment>
[Example of output circuit configured by computer]
Next, the output circuit 12 according to the second embodiment of the present invention will be described.
In the above-described first embodiment, the example in which the output circuit 12 is configured by a hardware circuit as illustrated in FIG. 12 has been described. However, as another example, the output circuit 12 may be realized using a computer.

FIG. 14 is a block diagram illustrating a configuration example of a computer used as the output circuit 12 according to the second embodiment of the present invention.
The computer 50 includes a CPU (Central Processing Unit) 51, a ROM (Read Only Memory) 52, and a RAM (Random Access Memory) 53 connected to a bus 54. Further, the computer 50 includes a display unit 55, an operation unit 56, a nonvolatile storage 57, a network interface 58, and the connector 20. The connector 20 is the same as that described with reference to FIG.

  The CPU 51 reads out the program code of software that realizes functions corresponding to the amplifier circuit 22, the correction circuit 23, and the transmission circuit 24 of FIG. In the RAM 53, variables, parameters, and the like generated during the arithmetic processing are temporarily written. As the display unit 55, for example, a liquid crystal display monitor is used, and the measurement result of the pressure difference is displayed as in the display device 26 of FIG. For example, a keyboard, a mouse, or the like is used for the operation unit 56, and a user can perform predetermined operation input and instruction.

  As the non-volatile storage 57, for example, a hard disk drive (HDD), a flexible disk, an optical disk, a magneto-optical disk, a CD-ROM, a CD-R, a magnetic tape, a non-volatile memory card, or the like is used. The nonvolatile storage 57 stores a program for causing the computer 50 to function in addition to an OS (Operating System) and various parameters. As the network interface 58, for example, a NIC (Network Interface Card) or the like is used, and various types of data can be transmitted / received via any of a LAN, a dedicated line, and a network to which terminals are connected. The network interface 58 serves both as the information writing terminal 27 and the output terminal 28 in FIG.

<3. Third Embodiment>
[Example of pressure measuring device that measures the absolute pressure of fluid]
Next, a pressure measuring device 60 according to a third embodiment of the present invention will be described.
In the above-described embodiment, the example in which the present invention is applied to the pressure measuring device that measures the pressure difference between two points of the fluid has been described. However, as another example, the present invention may be applied to a pressure measuring device that measures the absolute pressure of a fluid.

FIG. 15 is a cross-sectional view showing a configuration example of a pressure measuring device according to a modified example of the present invention, and the same reference numerals are given to portions common to FIG. 1 (however, reference numerals of the pressure receiving chamber wall surface and the pressure receiving chamber are Omitted).
The pressure measuring device 60 is a device that measures the absolute pressure of the fluid, and the pressure of the measuring fluid 30 received by the pressure receiving diaphragm 5 is transmitted to the sensor 13 by the sealed liquid 8 in the pressure guiding path 6. In FIG. 15, the pressure receiving chamber and the pressure guiding path 6, which are portions where the sealing liquid 8 is sealed in the pressure measuring device 60, are shown darkly.

  A hydrogen occlusion material 9 that occludes hydrogen atoms in the sealing liquid 8 is disposed in at least one of the inside of the pressure guiding path 6, the wall surface of the pressure guiding path 6, the pressure receiving chamber wall surface, and the inside of the pressure receiving chamber. . FIG. 15 shows an example in which the hydrogen storage material 9 is arranged inside the pressure guiding path 6.

  The sensor 13 detects the transmitted pressure as a voltage signal. A connector 19 is provided on the surface of the main body (not indicated) of the pressure measuring device 60 provided with the sensor 13. The output circuit 12 having the connector 20 corresponding to the connector 19 is connected to the sensor 13 by being detachably attached to the main body by the connectors 19 and 20. Moreover, the housing | casing 21 for protecting the output circuit 12 from a mechanical impact is detachably fitted with respect to the main-body part. The configuration of the output circuit 12 is the same as that shown in FIG.

  This pressure measuring device 60 can provide the same effects as those described for the pressure measuring device 1 according to the embodiment of the present invention. That is, not only hydrogen that has passed through the pressure-receiving diaphragm 5 from the outside of the pressure measuring device 60 but also hydrogen generated in the sealing liquid 8 and hydrogen atoms in the hydrocarbons are occluded by the hydrogen occlusion material 9. As a result, it is possible to prevent an increase in pressure inside the pressure guiding path 6 due to hydrogen and hydrocarbons remaining as bubbles in the sealing liquid 8. In addition, even when the output circuit 12 is damaged due to radiation or high temperature, the time and work required for replacement can be greatly reduced. Further, even after the output circuit 12 is replaced, the measurement of the absolute pressure with high accuracy can be continued.

<4. Modification>
The pressure measuring devices 1 and 60 described above can be applied not only to instrumentation systems such as nuclear power plants but also to instrumentation systems such as nuclear fuel reprocessing facilities and accelerator facilities.

  Moreover, you may comprise the whole pressure measuring device 1,60 with the material which is hard to receive the influence of a radiation, temperature, hydrogen, etc. FIG. For example, various circuits including an amplifier (not shown) used for the output circuit 12 may be manufactured using SiC. Further, the sensor 13 may receive the pressure of the measurement fluid 30 using a strain gauge having heat resistance and radiation resistance characteristics. As a result, the pressure of the measurement fluid 30 can be continuously measured even in an environment of high radiation, high temperature, high hydrogen, or the like.

  Further, instead of using the connectors 19 and 20 when connecting the output circuit 12 and the main body 4, a long-distance communication cable may be used. In this case, the failure frequency of the output circuit 12 can be reduced by installing the output circuit 12 in an environment that is not high radiation, high temperature, and high hydrogen away from the main body 4. For this reason, the frequency | count of replacement | exchange of the output circuit 12 can also be reduced, and maintainability can be improved.

  Further, the periphery of the output circuit 12 may be sealed with a shielding material (for example, lead) that shields radiation or a heat insulating material that shields heat. In this case, the housing 21 may be made of a shielding material, and the periphery of the housing 21 may be further sealed with a shielding material. Thereby, the influence of the radiation and heat with respect to the output circuit 12 can be suppressed, and the failure of the output circuit 12 can be reduced. In addition, a design change or the like for improving the radiation resistance and heat resistance of the output circuit 12 becomes unnecessary.

The embodiment of the present invention has been described above. However, the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the spirit of the invention described in the claims.
For example, in the above-described embodiment, the configuration of the apparatus and the system is described in detail and specifically in order to explain the present invention in an easy-to-understand manner, and is not necessarily limited to the one having all the configurations described. Absent. Further, a part of the configuration of one embodiment can be replaced with the configuration of another embodiment, and the configuration of another embodiment can be added to the configuration of one embodiment. Moreover, it is also possible to add, delete, and replace other configurations for a part of the configuration of each embodiment.
Further, the control lines and information lines indicate what is considered necessary for the explanation, and not all the control lines and information lines on the product are necessarily shown. Actually, it may be considered that almost all the components are connected to each other.

  DESCRIPTION OF SYMBOLS 1,60 ... Pressure measuring device, 2 ... Displacer part, 3 ... Capillary part, 4 ... Main-body part, 5 ... Pressure receiving diaphragm, 6 ... Pressure-inducing path, 7 ... Intermediate diaphragm, 8 ... Filling liquid, 9 ... Hydrogen storage material DESCRIPTION OF SYMBOLS 10 ... Sealing diaphragm, 11 ... Center diaphragm, 12 ... Output circuit, 13 ... Sensor, 14 ... Pressure receiving chamber, 15 ... Pressure receiving chamber wall surface, 16 ... High pressure side pressure transmission part, 17 ... Low pressure side pressure transmission part, 19, 20 …connector

Claims (11)

A diaphragm for receiving the pressure of the measurement fluid;
A pressure-receiving chamber wall surface provided with the diaphragm;
A pressure guiding path connected to the pressure receiving chamber wall surface;
A space formed between the diaphragm and the pressure-receiving chamber wall surface and a sealing liquid sealed in the pressure guiding path;
A hydrogen storage material that is disposed in at least one of the inside of the pressure guiding path, the wall surface of the pressure guiding path, the wall surface of the pressure receiving chamber, and the interior of the space;
A pressure sensor that detects a pressure of the measurement fluid received by the diaphragm transmitted by the sealing liquid and outputs a detection signal;
An output circuit that is connected to the pressure sensor by being detachably attached to the main body provided with the pressure sensor, and transmits the detection signal output from the pressure sensor to the outside. Pressure measuring device. The output circuit includes a storage device that stores pressure-voltage correction information corresponding to pressure-voltage characteristics of the pressure sensor, a correction circuit that corrects the detection signal of the pressure sensor based on the pressure-voltage correction information, and The pressure measurement device according to claim 1, further comprising: a transmission circuit that transmits the detection signal corrected by the correction circuit to the outside. The pressure measuring device according to claim 2, wherein the output circuit has an information writing terminal for writing the pressure-voltage correction information in the storage device based on unique information of the pressure sensor. A first diaphragm that receives the pressure of the measurement fluid as the diaphragm on each of the high-pressure side of the measurement fluid and the low-pressure side of the measurement fluid, and the pressure guiding path from the first diaphragm to the pressure sensor With one or more second diaphragms intervening in the middle,
The pressure sensor measures a pressure difference between a high pressure side and a low pressure side of the measurement fluid;
The hydrogen storage material includes the inside of the pressure guiding path, the wall surface of the pressure guiding path, the pressure receiving chamber wall surface for the first diaphragm, the interior of the space for the first diaphragm, and the second diaphragm. The pressure receiving chamber wall surface of the second diaphragm, the wall surface of the second diaphragm opposite to the pressure receiving chamber wall surface, and the interior of the space with respect to the second diaphragm are disposed at at least one place. The pressure measuring device described. The pressure measuring device according to claim 2, wherein the hydrogen storage material is palladium, magnesium, vanadium, titanium, manganese, zirconium, nickel, niobium, cobalt, calcium, or an alloy thereof. The pressure measuring device according to claim 5, wherein the hydrogen storage material is in a powder form and is mixed in at least one of the sealed liquid in the pressure guiding path and the sealed liquid in the space. The hydrogen storage material is in a solid state and is mixed in at least one of the sealed liquid in the pressure guiding path and the sealed liquid in the space, or the wall surface of the pressure guiding path, the pressure receiving chamber wall surface The pressure measurement device according to claim 5, wherein the pressure measurement device is fixed to at least one of the two. The hydrogen storage material has a rod shape or a spiral shape, and is sealed in at least one of the sealed liquid in the pressure guiding path and the sealed liquid in the space, or a wall surface of the pressure guiding path, the pressure receiving pressure The pressure measuring device according to claim 5, wherein the pressure measuring device is fixed to at least one of the chamber wall surfaces. The pressure measuring device according to claim 5, wherein the hydrogen storage material has a film shape and is formed at least at one of a wall surface of the pressure guiding path and a wall surface of the pressure receiving chamber. The pressure sensor outputs the detection signal to the output circuit via a communication cable connected between the connector provided in the main body and the connector provided in the output circuit. The pressure measuring device according to any one of 1 to 9. A sealing liquid is sealed in a diaphragm formed to receive the pressure of the measurement fluid, a space formed between a pressure receiving chamber wall surface provided with the diaphragm, and a pressure guiding path connected to the pressure receiving chamber wall surface;
A hydrogen occlusion material that occludes hydrogen atoms of the sealing liquid is disposed in at least one of the inside of the pressure guiding path, the wall surface of the pressure guiding path, the wall surface of the pressure receiving chamber, and the interior of the space,
A pressure sensor that detects the pressure of the measurement fluid received by the diaphragm transmitted by the sealing liquid outputs a detection signal;
The output circuit for transmitting the detection signal output from the pressure sensor to the outside is detachably attached to the main body provided with the pressure sensor with a connector, thereby connecting the output circuit to the pressure sensor. Measurement method.

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