JP7169260B2 - Physical quantity measuring device - Google Patents

Description

The present invention relates to a physical quantity measuring device.

2. Description of the Related Art In general, liquid level gauges are known that measure the liquid pressure in storage tanks, pipes, and the like, and measure the height of the liquid level and the like. As this type of technology, there is a technology that uses a gauge pressure (relative pressure) sensor, calculates the difference between the hydraulic pressure and the external pressure, and obtains only the hydraulic pressure (for example, Patent Document 1).

However, in Patent Document 1, it is necessary to introduce outside air into the sensor, so if there is a large temperature difference between the inside and outside of the sensor, condensation will occur inside the sensor or inside an air tube that introduces outside air into the sensor, resulting in measurement errors. and failure to measure may occur.
Therefore, in this type of liquid level gauge, a technique is known to prevent dew condensation from occurring in the sensor (for example, Patent Document 2).

In Patent Document 2, a housing containing a diaphragm, a substrate, etc. is sealed, and a deformable valve body is provided so as to maintain the pressure inside the housing equal to the pressure outside the housing (atmospheric pressure). The gauge pressure is configured to be measurable.

JP-A-10-111163 Japanese Patent No. 5899576

However, in Patent Document 2, the pressure difference between the inside and outside of the housing is adjusted by deforming the valve body. , there is a possibility that the pressure difference between the inside and outside of the housing cannot be adjusted. Therefore, there was a problem that the gauge pressure could not be measured accurately.

SUMMARY OF THE INVENTION An object of the present invention is to provide a physical quantity measuring device capable of accurately measuring the gauge pressure of a fluid to be measured over a long period of time.

A physical quantity measuring device of the present invention includes a housing whose inside is sealed, and a first absolute pressure sensor that detects the absolute pressure of a fluid to be measured that is housed in the housing and that outputs a first absolute pressure signal based on the detected absolute pressure. a pressure unit; a second absolute pressure unit that is housed in the housing and detects the absolute pressure outside the housing and outputs a second absolute pressure signal based on the detected absolute pressure; a calculator that receives the first absolute pressure signal and the second absolute pressure signal and calculates the gauge pressure of the fluid to be measured , wherein the second absolute pressure unit communicates with the outside of the housing. a sensor case provided with a first chamber and a second chamber communicating with the inside of the housing; a diaphragm portion provided in the sensor case and partitioning the first chamber and the second chamber; and a cylindrical support provided in the second chamber for supporting the diaphragm .

In the present invention, a first absolute pressure unit that detects the absolute pressure of the fluid to be measured, a second absolute pressure unit that detects the absolute pressure outside the housing, that is, the atmospheric pressure, and a signal based on these detection results. and a calculation unit for inputting and calculating the gauge pressure of the fluid to be measured. As a result, the gauge pressure of the fluid to be measured can be obtained without introducing outside air into the housing and without adjusting the pressure difference between the inside and outside of the housing by providing a driving part such as a valve element. . As a result, it is possible to prevent problems caused by dew condensation occurring inside the housing, and to prevent deterioration of the driving part such as the valve body. can be measured.

Furthermore, in this configuration, the pressure outside the housing, that is, the atmospheric pressure acts on the diaphragm. Therefore, the atmospheric pressure can be detected by detecting the amount of deformation of the diaphragm.

In the physical quantity measuring device of the present invention, the sensor case includes a tubular portion, a flange portion extending in an outer peripheral direction from the tubular portion, and a protrusion protruding from the tubular portion toward the outside of the housing. and a communication hole that communicates between the first chamber and the outside of the housing is preferably provided in the projecting portion.
In this configuration, since the communication hole is provided in the projecting portion that projects from the cylindrical portion toward the outside of the housing, atmospheric pressure can be applied to the diaphragm portion via the communication hole.

In the physical quantity measuring device of the present invention, the sensor case includes a tubular portion, a bottom plate portion provided at one opening end of the tubular portion, and a bottom plate portion provided on the bottom plate portion and protruding toward the outside of the housing. It is preferable that a communication hole communicating between the first chamber and the outside of the housing is provided in the projection.
In this configuration, since the communication hole is provided in the projecting portion that projects from the sensor case toward the outside of the housing, atmospheric pressure can be applied to the diaphragm portion via the communication hole.

In the physical quantity measuring device of the present invention, a detection substrate is accommodated inside the support portion, and a closed space is formed by the diaphragm portion, the support portion, and the detection substrate, and the space includes: It is preferable that the sealing liquid is enclosed.
In this configuration, since the space is filled with the sealing liquid, there is no risk of dew condensation occurring in the space. Therefore, it is possible to prevent problems caused by dew condensation in the diaphragm portion, the support portion, and the detection substrate that define the space.

BRIEF DESCRIPTION OF THE DRAWINGS The perspective view which shows the outline of the physical-quantity measuring apparatus which concerns on 1st Embodiment of this invention. FIG. 2 is a cross-sectional view showing an outline of the physical quantity measuring device of the embodiment; The cross-sectional perspective view which shows the outline of the 2nd absolute pressure unit of the said embodiment. The perspective view which shows the outline of the physical-quantity measuring apparatus of 2nd Embodiment. Sectional drawing which shows the outline of the physical-quantity measuring apparatus of 2nd Embodiment. The cross-sectional perspective view which shows the outline of the 2nd absolute pressure unit of 2nd Embodiment.

[First embodiment]
A first embodiment of the present invention will be described based on the drawings. The physical quantity measuring device 1 of the present embodiment is configured as a liquid level gauge that measures the liquid pressure in a storage tank, piping, and the like, and measures the height of the liquid level and the like.
FIG. 1 is a perspective view showing an outline of a physical quantity measuring device 1 of this embodiment, and FIG. 2 is a cross-sectional view showing an outline of the physical quantity measuring device 1. As shown in FIG.
As shown in FIGS. 1 and 2 , the physical quantity measuring device 1 includes a housing 2 , a first absolute pressure unit 3 , a second absolute pressure unit 4 and a circuit board 5 .

[Case 2]
The housing 2 is made of, for example, metal such as stainless steel, and its inside is sealed. Further, the housing 2 includes a first housing 21 and a second housing 22, and accommodates therein the first absolute pressure unit 3, the second absolute pressure unit 4, and the circuit board 5. .
In addition, the housing|casing 2 is not restricted to the said structure, For example, it may be made of resin.

[First housing 21]
The first housing 21 is a cylindrical member and includes a large-diameter cylindrical portion 211 , a small-diameter cylindrical portion 212 , a connecting portion 213 , and a flange portion 214 .
The large-diameter cylindrical portion 211 is a cylindrical member and accommodates the first absolute pressure unit 3 therein.
The small-diameter cylindrical portion 212 is a cylindrical member having a smaller diameter than the large-diameter cylindrical portion 211 and is connected to the large-diameter cylindrical portion 211 by a connecting portion 213 . Further, the small-diameter cylindrical portion 212 is inserted into an insertion hole 2211 of the second housing 22, which will be described later. Thereby, the small-diameter cylindrical portion 212 communicates the inside of the first housing 21 and the inside of the second housing 22 .
The connecting portion 213 is a cylindrical member whose diameter gradually decreases from the large-diameter cylindrical portion 211 toward the small-diameter cylindrical portion 212 . Further, in the present embodiment, the connecting portion 213 is welded and joined to the large-diameter cylindrical portion 211 and the small-diameter cylindrical portion 212 . Thereby, the connecting portion 213 connects the large-diameter cylindrical portion 211 and the small-diameter cylindrical portion 212 .

The flange portion 214 extends from the end portion of the large-diameter cylindrical portion 211 to the outer peripheral side. In this embodiment, the physical quantity measuring device 1 is connected to the pipe by connecting the flange portion 214 and a flange portion provided on the pipe through which the fluid to be measured flows by means of a clamp or the like.
A storage recess 215 is formed at the end of the large-diameter cylindrical portion 211 . The first absolute pressure unit 3 is fitted in the housing recess 215 .

[Second housing 22]
The second housing 22 includes a tubular main body 221 , a lid 222 and a bottom 223 and accommodates the second absolute pressure unit 4 and the circuit board 5 .
The tubular main body 221 is arranged so that its axial direction is orthogonal to the first housing 21 . An insertion hole 2211 is provided in the cylindrical body portion 221 . As described above, the small-diameter cylindrical portion 212 of the first housing 21 is inserted through the insertion hole 2211 .
Further, in the present embodiment, the small-diameter cylindrical portion 212 inserted through the insertion hole 2211 and the cylindrical body portion 221 are joined by welding.
Furthermore, a cylindrical cable extraction portion 224 is connected to the cylindrical body portion 221 . A cable (not shown) extending from the outside can be inserted into the second housing 22 by passing through the cable extraction portion 224 . As a result, various signals can be exchanged with an external device, and power can be supplied from an external power source to the physical quantity measuring device 1 . A sealing member (not shown) is inserted into the cable outlet portion 224 . As a result, air or the like can be prevented from flowing into the inside of the second housing 22 via the cable extraction portion 224 .

The lid portion 222 is arranged so as to cover one opening of the tubular body portion 221 . In this embodiment, the lid portion 222 is detachably attached to the cylindrical body portion 221 . In addition, a display part or the like may be provided inside the lid part 222 . In this case, the gauge pressure or the like calculated by the circuit board 5 may be displayed on the display unit.
The bottom portion 223 is arranged to cover the other opening of the tubular body portion 221 . In this embodiment, the bottom portion 223 is welded and joined to the tubular body portion 221 . Further, the bottom portion 223 has a through hole 225 formed in the central portion thereof, into which a projecting portion 413 of the second absolute pressure unit 4 (to be described later) is inserted.

[First absolute pressure unit 3]
The first absolute pressure unit 3 is configured to detect the absolute pressure of the fluid to be measured and output a first absolute pressure signal based on the detected absolute pressure.
The first absolute pressure unit 3 is housed in the first housing 21 by being fitted into the housing recess 215 of the large-diameter cylindrical portion 211 as described above. , a first output board 33 , a case member 34 and a first signal transmission member 35 .

The first diaphragm part 31 is arranged so as to face the outside from the storage recessed part 215 of the first housing 21, and is configured to be deformable according to the pressure change of the contacting object to be measured. In this embodiment, the first diaphragm part 31 is made of metal such as stainless steel. In addition, the first diaphragm part 31 is not limited to the above configuration, and may be made of, for example, a semiconductor material, ceramics, or the like.

The first detection substrate 32 has a first space 36 between itself and the first diaphragm portion 31 and supports the first diaphragm portion 31 around the first space 36 . That is, the first detection substrate 32 supports the first diaphragm portion 31 at its outer peripheral edge. Note that, in the present embodiment, the first space 36 is a space sealed by the first diaphragm portion 31 and the first detection substrate 32 . The first space 36 is configured such that the internal pressure is lower than the atmospheric pressure. That is, the first space 36 serves as a rarefied air chamber. Thereby, dew condensation in the first space 36 can be prevented. Note that the first space 36 is not limited to the configuration described above, and may be evacuated inside, for example.
The first output substrate 33 detects changes in the pressure of the object to be measured as changes in capacitance between electrodes (not shown) formed on the first diaphragm portion 31 and the first detection substrate 32, respectively. Output as 1 absolute pressure signal. That is, in this embodiment, the first absolute pressure unit 3 is configured as a capacitive pressure sensor.

The case member 34 is a member that supports the first diaphragm portion 31, the first detection board 32, and the first output board 33, and includes a case tubular portion 341, a case flange portion 342, and fasteners 343. .
The case tubular portion 341 is a cylindrical member, and has the first diaphragm 31 and the first detection board 32 attached to one end, and the case flange portion 342 to the other end. .
The case flange portion 342 is formed in a disc shape and attached to the large-diameter cylindrical portion 211 with fasteners 343 . Thereby, the first absolute pressure unit 3 is fixed to the first housing 21 .

The first signal transmission member 35 is a wiring member for electrically connecting the first output board 33 and the circuit board 5 . The first output board 33 is configured to be able to output the first absolute pressure signal to the circuit board 5 via the first signal transmission member 35 .

[Second absolute pressure unit 4]
FIG. 3 is a cross-sectional perspective view showing an outline of the second absolute pressure unit 4. As shown in FIG.
As shown in FIGS. 2 and 3, the second absolute pressure unit 4 detects the absolute pressure outside the housing 2, that is, the atmospheric pressure, and can output a second absolute pressure signal based on the detected absolute pressure. It is
The second absolute pressure unit 4 is accommodated in the second housing 22 as described above, and includes the sensor case 41, the housing 42, the second diaphragm portion 43, the support portion 44, and the second detection board 45. , a second output substrate 46 , an O-ring 47 and a second signal transmission member 48 .

The sensor case 41 is a bottomed cylindrical metal member, and accommodates therein a housing 42, a second diaphragm portion 43, a support portion 44, a second detection board 45, and a second output board 46. is doing. The sensor case 41 includes a tubular portion 411 , a flange portion 412 and a projecting portion 413 .

The cylindrical portion 411 is made of metal and formed in a cylindrical shape. Further, the tubular portion 411 is provided with a flange portion 412 extending from the tubular portion 411 in the outer peripheral direction.
The flange portion 412 is made of metal and has an annular shape, and is welded and joined to the inner peripheral surface of the bottom portion 223 of the second housing 22 . Thereby, the sensor case 41 is fixed to the second housing 22 .
The projecting portion 413 is provided so as to project from one open end side of the cylindrical portion 411 . The projecting portion 413 is inserted into the through hole 225 formed in the bottom portion 223 of the second housing 22 as described above. As a result, the protruding portion 413 protrudes outside the housing 2 . A communication hole 414 is provided in the projecting portion 413 . Further, in this embodiment, the projecting portion 413 is formed in a cylindrical shape with a bottom, and a plurality of communication holes 414 are provided on the peripheral surface of the projecting portion 413 . As a result, the first chamber 415 , which will be described later, and the outside of the housing 2 communicate with each other through the communication hole 414 .

The housing 42 is a tubular metal member, and has a second diaphragm portion 43 at one open end. Further, the housing 42 accommodates the support portion 44 and the second detection board 45 inside. The sensor case 41 is partitioned into a first chamber 415 and a second chamber 416 by the second diaphragm portion 43 .
The first chamber 415 communicates with the outside of the housing 2 through the communication hole 414 provided in the projecting portion 413 as described above. As a result, atmospheric pressure acts on the surface of the second diaphragm portion 43 on the first chamber 415 side. Also, the second chamber 416 communicates with the inside of the second housing 22 .

As described above, the second diaphragm part 43 is arranged so as to partition the space inside the sensor case 41, and is configured to be deformable in accordance with changes in the atmospheric pressure acting through the communication hole 414 of the protruding part 413. It is An electrode (not shown) for detecting the amount of deformation of the second diaphragm portion 43 is formed on the second diaphragm portion 43 .
Further, in the present embodiment, the second diaphragm part 43 is made of metal such as stainless steel. In addition, the second diaphragm part 43 is not limited to the above configuration, and may be made of, for example, a semiconductor material, ceramics, or the like.

The support portion 44 is a member that supports the second diaphragm portion 43 and the second output substrate 46 and is arranged in the second chamber 416 . The support portion 44 is made of metal and formed in a cylindrical shape, and accommodates the second detection substrate 45 therein.
In this embodiment, a sealed second space 49 is formed by the second diaphragm portion 43 , the support portion 44 and the second detection substrate 45 . A sealing liquid S is sealed in the second space 49 .

The second detection board 45 is accommodated inside the support portion 44 as described above, and is provided with a strain gauge (not shown). , is transmitted through the fill fluid S.
The second output board 46 detects the atmospheric pressure acting on the second diaphragm part 43 from the amount of deformation of the strain gauge, and outputs a second absolute pressure signal based on the detected atmospheric pressure to the circuit board 5. It is configured. That is, in this embodiment, the second absolute pressure unit 4 is configured as a strain gauge type pressure sensor.

The O-ring 47 is arranged on the outer peripheral side of the housing 42 and is a member that seals the gap between the sensor case 41 and the housing 42 .
The second signal transmission member 48 is a member for electrically connecting the second output board 46 and the circuit board 5 . The second output board 46 is configured to be able to output the second absolute pressure signal to the circuit board 5 via the second signal transmission member 48 .

[Circuit board 5]
As described above, the circuit board 5 is housed in the second housing 22 and mounted with electronic components (not shown). Then, the circuit board 5, based on the first absolute pressure signal input via the first signal transmission member 35 and the second absolute pressure signal input via the second signal transmission member 48, determines the volume of the fluid to be measured. It is configured to be able to calculate the gauge pressure. Specifically, the circuit board 5 subtracts the atmospheric pressure outside the housing 2 according to the second absolute pressure signal from the absolute pressure of the fluid to be measured according to the first absolute pressure signal to obtain the is configured to calculate the gauge pressure of That is, the circuit board 5 is an example of the calculator of the present invention.

Further, the circuit board 5 is configured to output a signal based on the gauge pressure of the fluid to be measured to an external device via a cable (not shown) inserted through the cable extraction portion 224 of the second housing 22. ing.

The following effects can be obtained in this embodiment as described above.
(1) In this embodiment, a first absolute pressure unit 3 for detecting the absolute pressure of the fluid to be measured, a second absolute pressure unit 4 for detecting the absolute pressure outside the housing 2, that is, the atmospheric pressure, and these and a circuit board 5 for inputting a signal based on the detection result of and calculating the gauge pressure of the fluid to be measured. As a result, the gauge pressure of the fluid to be measured can be obtained without introducing outside air into the housing 2 and without adjusting the pressure difference between the inside and outside of the housing 2 by providing a driving part such as a valve element. be able to. Therefore, it is possible to prevent problems caused by dew condensation generated inside the housing 2, and the driving part such as the valve body is not deteriorated, so that the gauge pressure of the fluid to be measured can be accurately maintained for a long period of time. can be measured to

(2) In the present embodiment, the pressure outside the housing 2 , that is, the atmospheric pressure acts on the second diaphragm portion 43 . Therefore, the atmospheric pressure can be detected by detecting the amount of deformation of the second diaphragm portion 43 .

(3) In the present embodiment, since the communication hole 414 is provided in the projecting portion 413 projecting from the cylindrical portion 411 toward the outside of the housing 2, the second diaphragm portion 43 is connected through the communication hole 414. Atmospheric pressure can be applied to

(4) In the present embodiment, since the second space 49 is filled with the sealing liquid S, there is no risk of condensation occurring inside the second space 49 . Therefore, it is possible to prevent the second diaphragm portion 43 , the support portion 44 , and the second detection substrate 45 that define the second space 49 from causing problems due to dew condensation.

(5) In the present embodiment, since the first absolute pressure unit 3 is configured as a capacitive pressure sensor, an enclosure for transmitting the pressure acting on the first diaphragm portion 31 to the first detection substrate 32 There is no need to enclose liquid in the first space 36 . Therefore, leakage of the sealed liquid from the first absolute pressure unit 3 can be prevented.

[Second embodiment]
Next, a second embodiment of the invention will be described with reference to the drawings.
The second embodiment differs from the first embodiment in that the sensor case 41A of the second absolute pressure unit 4A is configured with a tubular portion 411A, a bottom plate portion 417A, and a projecting portion 413A. In addition, in 2nd Embodiment, the same code|symbol is attached|subjected to the same or similar structure as 1st Embodiment, and description is abbreviate|omitted.

FIG. 4 is a perspective view showing an outline of the physical quantity measuring device 1A of this embodiment, and FIG. 5 is a cross-sectional view showing an outline of the physical quantity measuring device 1A.
As shown in FIGS. 4 and 5, the physical quantity measuring device 1A includes a housing 2A, a first absolute pressure unit 3, a second absolute pressure unit 4A, and a circuit board 5. FIG.

The housing 2A is made of, for example, metal such as stainless steel, and its inside is sealed. The housing 2A includes a first housing 21 and a second housing 22A, and accommodates the first absolute pressure unit 3, the second absolute pressure unit 4A, and the circuit board 5 inside. .

[Second housing 22A]
The second housing 22A includes a cylindrical main body 221A, a lid 222A, and a bottom 223A, and accommodates the second absolute pressure unit 4A and the circuit board 5, as in the first embodiment. .
The cylindrical body portion 221A is arranged so that the axial direction is orthogonal to the first housing 21 . An insertion hole 2211A is provided in the cylindrical body portion 221A. As in the first embodiment described above, the small-diameter cylindrical portion 212 of the first housing 21 is inserted through the insertion hole 2211A.
A cylindrical cable extraction portion 224A is connected to the cylindrical body portion 221A. Furthermore, similarly to the first embodiment described above, a sealing member (not shown) is inserted into the cable extraction portion 224A. As a result, it is possible to prevent air or the like from flowing into the second housing 22A via the cable extraction portion 224A.

The lid portion 222A is arranged to cover one opening of the tubular body portion 221A. In this embodiment, the lid portion 222A is detachably attached to the cylindrical body portion 221A.
The bottom portion 223A is arranged to cover the other opening of the tubular body portion 221A. In this embodiment, the bottom portion 223A is welded and joined to the cylindrical body portion 221A. Further, the bottom portion 223A has a through hole 225A formed in the central portion thereof, into which a projecting portion 413A of the second absolute pressure unit 4A, which will be described later, is inserted.

[Second absolute pressure unit 4A]
FIG. 6 is a cross-sectional perspective view showing an outline of the second absolute pressure unit 4A.
As shown in FIGS. 5 and 6, the second absolute pressure unit 4A is configured to detect atmospheric pressure and output a second absolute pressure signal based on the detected atmospheric pressure, as in the first embodiment. ing.
The second absolute pressure unit 4A includes a sensor case 41A, a housing 42A, a second diaphragm portion 43A, a support portion 44A, a second detection board 45A, a second output board 46A, an O-ring 47A, a second and a signal transmission member 48A.

The sensor case 41A is a bottomed cylindrical metal member, and accommodates therein a housing 42A, a second diaphragm portion 43A, a support portion 44A, a second detection board 45A, and a second output board 46A. is doing. In this embodiment, the sensor case 41A includes a tubular portion 411A, a bottom plate portion 417A, and a projecting portion 413A.

The tubular portion 411A is made of metal and formed in a cylindrical shape. A bottom plate portion 417A is provided at one open end of the cylindrical portion 411A.
The bottom plate portion 417A is made of metal and has a disc shape, and is welded and joined to the inner peripheral surface of the bottom portion 223A of the second housing 22A. Thereby, the sensor case 41A is fixed to the second housing 22A.
The protruding portion 413A is provided so as to protrude from the central portion of the bottom plate portion 417A. The projecting portion 413A is inserted into a through hole 225A formed in the bottom portion 223A of the second housing 22A. Thereby, the protruding portion 413A protrudes to the outside of the housing 2A. A communication hole 414A is provided in the projecting portion 413A. As a result, the first chamber 415A, which will be described later, and the outside of the housing 2A communicate with each other through the communication hole 414A.

The housing 42A is a tubular metal member, and accommodates therein a second diaphragm portion 43A, a support portion 44A, and a second detection board 45A. The sensor case 41A is partitioned into a first chamber 415A and a second chamber 416A by a second diaphragm portion 43A.
As described above, the first chamber 415A communicates with the outside of the housing 2A through the communication hole 414A provided in the projecting portion 413A. As a result, atmospheric pressure acts on the surface of the second diaphragm portion 43A on the side of the first chamber 415A. Also, the second chamber 416A communicates with the inside of the second housing 22A.

The second diaphragm portion 43A is configured similarly to the second diaphragm portion 43 of the first embodiment described above. In this embodiment, the second diaphragm portion 43A is arranged so as to partition the space inside the sensor case 41A, and is configured to be deformable in accordance with changes in the atmospheric pressure acting through the communication hole 414A of the projecting portion 413A. It is

The support portion 44A is configured in the same manner as the support portion 44 of the first embodiment described above, and is a member that supports the second diaphragm portion 43A and the second output substrate 46A.
In this embodiment, a sealed second space 49A is formed by the second diaphragm portion 43A, the support portion 44A, and the second detection substrate 45A. A sealing liquid S is sealed in the second space 49A.

In the present embodiment as described above, the same effects as (1) to (5) of the first embodiment can be obtained.

[Modification]
It should be noted that the present invention is not limited to the above-described embodiments, and includes modifications, improvements, etc. within the scope of achieving the object of the present invention.
In each of the embodiments described above, the housing 2 is configured to include the first housing 21 and the second housings 22 and 22A, but the present invention is not limited to this. For example, the housing may consist of one tubular member.

In each of the above-described embodiments, the first housing 21 includes the large-diameter cylindrical portion 211, the small-diameter cylindrical portion 212, and the connecting portion 213, but is not limited to this. For example, the first housing may have a simple cylindrical shape, or may have a polygonal tube shape such as a square tube or a hexagonal tube.

In each of the above-described embodiments, the second housings 22 and 22A are provided with the cable outlets 224 and 224A, but the present invention is not limited to this, and the cable outlets 224 and 224A may not be provided. Included in the invention. In this case, a battery or the like may be housed in the housing and the battery may be used to supply power to the physical quantity measuring device. Also, a wireless communication unit may be housed in the housing, and various signals may be exchanged with an external device through the wireless communication unit.

In each of the above-described embodiments, the physical quantity measuring devices 1 and 1A are connected to the pipe through which the fluid to be measured flows by the flange portion 214 of the first housing 21, but the present invention is not limited to this. For example, a male threaded portion may be provided on the outer peripheral surface of the end portion side of the large-diameter cylindrical portion of the first housing, and the male threaded portion may be configured to be connected to the pipe.

In each of the embodiments described above, the first absolute pressure unit 3 is configured as a capacitive pressure sensor, but is not limited to this. For example, the first absolute pressure unit may be configured as a strain gauge type pressure sensor, as long as it can detect the absolute pressure of the fluid to be measured.
Further, in each of the above-described embodiments, the first space 36 sealed by the first diaphragm portion 31 and the first detection substrate 32 is configured such that the internal pressure is lower than the atmospheric pressure, but this is not the only option. not. For example, the above-mentioned first space may be configured to be at atmospheric pressure, or the above-mentioned first space may be filled with a sealing liquid.

In each of the above embodiments, the second absolute pressure units 4 and 4A are configured as strain gauge pressure sensors, but are not limited to this. For example, the second absolute pressure unit may be configured as a capacitive pressure sensor. Further, in this case, the second space may not be filled with the sealing liquid.

In the above embodiment, the circuit board 5 is configured to be able to output a signal based on the gauge pressure of the fluid to be measured to an external device, but the invention is not limited to this. For example, it may be configured to be able to output a display signal for displaying the gauge pressure of the fluid to be measured on a display unit configured by a liquid crystal display or the like.

In each of the embodiments described above, the physical quantity measuring devices 1 and 1A are configured as liquid level gauges, but are not limited to this. For example, the physical quantity measuring device may be configured as a gauge pressure measuring device.

Reference Signs List 1, 1A Physical quantity measuring device 2, 2A Housing 3 First absolute pressure unit 4, 4A Second absolute pressure unit 5 Circuit board (calculating unit) 21 First housing 22 , 22A... second housing, 31... first diaphragm part, 32... first detection board, 33... first output board, 34... case member, 35... first signal transmission member, 36... first space, 41, 41A... sensor case, 42, 42A... housing, 43, 43A... second diaphragm part, 44, 44A... support part, 45, 45A... second detection board, 46, 46A... second output board, 47, 47A... O Ring 48, 48A Second signal transmission member 49, 49A Second space 211 Large-diameter cylindrical portion 212 Small-diameter cylindrical portion 213 Connecting portion 214 Flange 215 Storage recess 221, 221A... Cylindrical main body 222, 222A... Lid part 223, 223A... Bottom part 224, 224A... Cable outlet part 225, 225A... Through hole 341... Case tubular part 342... Case flange part 343... Fastener 411, 411A... Cylindrical part 412... Flange part 413, 413A... Protruding part 414, 414A... Communication hole 415, 415A... First chamber 416, 416A... Second chamber 417A... Bottom plate part , 2211, 2211A... Insertion hole, S... Filled liquid.

Claims (4)

a housing whose inside is sealed;
a first absolute pressure unit housed in the housing for detecting the absolute pressure of the fluid to be measured and outputting a first absolute pressure signal based on the detected absolute pressure;
a second absolute pressure unit housed in the housing for detecting the absolute pressure outside the housing and outputting a second absolute pressure signal based on the detected absolute pressure;
a calculator that is housed in the housing and receives the first absolute pressure signal and the second absolute pressure signal to calculate the gauge pressure of the fluid to be measured ;
The second absolute pressure unit is
a sensor case provided with a first chamber communicating with the outside of the housing and a second chamber communicating with the inside of the housing;
a diaphragm part provided in the sensor case and partitioning the first chamber and the second chamber;
a cylindrical support portion provided in the second chamber and supporting the diaphragm portion;
A physical quantity measuring device characterized by: In the physical quantity measuring device according to claim 1 ,
The sensor case has a tubular portion, a flange portion extending from the tubular portion in an outer peripheral direction, and a protruding portion protruding from the tubular portion toward the outside of the housing,
The physical quantity measuring device, wherein the projecting portion is provided with a communication hole that communicates the first chamber with the outside of the housing. In the physical quantity measuring device according to claim 1 ,
The sensor case has a tubular portion, a bottom plate portion provided at one open end of the tubular portion, and a protruding portion provided on the bottom plate portion and protruding toward the outside of the housing,
The physical quantity measuring device, wherein the projecting portion is provided with a communication hole that communicates the first chamber with the outside of the housing. In the physical quantity measuring device according to any one of claims 1 to 3 ,
Having a detection substrate housed inside the support,
A closed space is formed by the diaphragm portion, the support portion, and the detection substrate,
A physical quantity measuring device, wherein a liquid is enclosed in the space.

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