This patent application claims the benefit of foreign priority to Japanese Patent Application No. JP 2020-018573 filed on Feb. 6, 2020, the disclosure of which is hereby incorporated by reference in its entirety.
The present disclosure relates to a pressure sensor for, for example, sanitary usage.
In order for pressure sensors for detecting the pressure of a fluid to be recognized as pressure sensors for sanitary usage used at manufacturing sites for foods, pharmaceuticals, and the like that require hygienic consideration, the pressure sensors must meet strict requirements regarding reliability and the like. For this reason, pressure sensors for sanitary usage are required to have a structure (oil-free structure) that does not use an encapsulant (see PTL 1 and PTL 2).
In addition, the pressure sensor for sanitary usage has a joint (for example, a ferrule joint) in the portion connected with respect to the pipe through which the fluid to be measured flows. The connection between the pipe and the pressure sensor is achieved by a connecting member such as, for example, a clamp. As described above, in the pressure sensor connected to the pipe via a joint, the diaphragm may be deformed by disturbance and the pressure measurement value may be affected (see PTL 3 and PTL 4). Examples of disturbance include a tightening force of the clamp, vibrations of the pipe, and the like. In particular, since the diaphragm makes direct contact with the fluid to be measured in a pressure sensor for sanitary usage, the effect of disturbance is large and the reliability of the measurement degrades.
In conventional pressure sensors, the effect of such disturbance cannot be grasped easily and the reliability of pressure measurement cannot be managed. The management of such measurement states needs to be improved constantly.
[PTL 1] JP-A-2017-120214
[PTL 2] JP-A-2017-125763
[PTL 3] JP-A-2018-004591
[PTL 4] JP-A-2018-004592
The present disclosure addresses the problems described above with an object of providing a pressure sensor capable of managing the effect of disturbance on the reliability of the pressure measurement value.
A pressure sensor according to the present disclosure includes a cylindrical housing in which an opening is present in at least one end surface; a first diaphragm that has a peripheral edge portion fixed to an inner wall of the housing so as to block the opening and has a first surface facing and being in contact with a fluid to be measured; a first strain sensor configured to detect deformation of the first diaphragm, the first strain sensor being provided on a second surface on an opposite side of the first surface of the first diaphragm; a second diaphragm that has a peripheral edge portion fixed to the inner wall of the housing and has a first surface facing the fluid and a second surface on the opposite side of the first surface, the first surface and the second surface being not in contact with the fluid; and a second strain sensor configured to detect deformation of the second diaphragm, the second strain sensor being provided on the first surface or the second surface of the second diaphragm.
In addition, in one structure example of the pressure sensor according to the present disclosure, the second diaphragm is provided in the housing so that the first surface of the second diaphragm faces the second surface of the first diaphragm.
In addition, in one structure example of the pressure sensor according to the present disclosure, the housing further includes an atmospheric pressure introduction path through which an atmospheric pressure is introduced into a space between the first diaphragm and the second diaphragm.
In addition, one structure example of the pressure sensor according to the present disclosure further includes a blocking member that blocks a second opening of the housing and has a first surface in contact with the fluid, the housing being provided with, as the opening, a first opening and the second opening in parallel with each other, in which the first diaphragm has the peripheral edge portion fixed to the inner wall of the housing so as to block the first opening, and the second diaphragm is provided inside the second opening so that the first surface of the second diaphragm faces a second surface on the opposite side of the first surface of the blocking member.
In addition, in one structure example of the pressure sensor according to the present disclosure, the housing further includes an atmospheric pressure introduction path through which an atmospheric pressure is introduced into a space between the second diaphragm and the blocking member.
In addition, in one structure example of the pressure sensor according to the present disclosure, a position of the first diaphragm from the one end surface of the housing in the first opening coincides with a position of the second diaphragm from the one end surface of the housing in the second opening, and the first diaphragm and the second diaphragm are disposed symmetrically with each other about an axis of the housing.
In addition, in one structure example of the pressure sensor according to the present disclosure, the first diaphragm and the second diaphragm have the same diameter and the same thickness.
In addition, one structure example of the pressure sensor according to the present disclosure further includes a determination unit configured to determine reliability of a pressure measurement value obtained from an output signal of the first strain sensor based on an output signal of the second strain sensor.
In addition, in one structure example of the pressure sensor according to the present disclosure, the determination unit determines that the reliability of the pressure measurement value is maintained when the output signal of the second strain sensor falls within a predetermined allowable range and determines that the reliability of the pressure measurement value is impaired when the output signal of the second strain sensor falls outside the predetermined allowable range.
In addition, in one structure example of the pressure sensor according to the present disclosure, the determination unit further determines a type of disturbance affecting pressure measurement based on the output signal of the second strain sensor.
According to the present disclosure, it is possible to determine whether the reliability of the pressure measurement value is maintained even when the pressure sensor is affected by a plurality of types of disturbance by providing a second diaphragm and a second strain sensor in addition to a first diaphragm and a first strain sensor for pressure measurement. As a result, the present disclosure can manage the effect of disturbance on the reliability of the pressure measurement value.
The inventors have found that the effect of disturbance on the accuracy of pressure measurement can be determined by providing a diaphragm that is deformed by receiving the pressure of a fluid to be measured as well as a dummy diaphragm that is not deformed when receiving the pressure of a fluid and is deformed by the same disturbance as in the diaphragm and detecting the deformation of the dummy diaphragm.
Embodiments of the present disclosure will be described below with reference to the drawings.
A pressure sensor 1 detects a pressure P of a fluid to be measured by detecting the deformation of a diaphragm when the diaphragm is deflected by the pressure P of the fluid described above.
Specifically, the pressure sensor 1 includes a diaphragm 2 (first diaphragm) like a thin plate that receives the pressure of the fluid to be measured, a dummy diaphragm 3 (second diaphragm) like a thin plate that does not make contact with the fluid to be measured, a cylindrical housing 4 that is provided with a circular through-hole 40 opening to one end surface and the other end surface and supports a peripheral edge portion of the diaphragm 2 and a peripheral edge portion of the dummy diaphragm 3, a strain sensor 5 (first strain sensor) that detects the deformation of the diaphragm 2, a strain sensor 6 (second strain sensor) that detects the deformation of the dummy diaphragm 3, a pressure calculation unit 7 that converts an output signal of the strain sensor 5 into the pressure of the fluid to be measured, a determination unit 8 that determines the reliability of a pressure measurement value obtained from the output signal of the strain sensor 5 based on an output signal of the strain sensor 6, and a determination result output unit 9 that outputs a determination result of the determination unit 8.
The cylindrical housing 4 in which the through-hole 40 is formed supports the peripheral edge portion of the diaphragm 2 and the peripheral edge portion of the dummy diaphragm 3. However, the shape of the housing 4 is not limited to a cylinder and may be, for example, a rectangular cylinder. The housing 4 is made of, for example, highly corrosion-resistant stainless steel (SUS), but may be made of another highly corrosion-resistant material such as ceramics or titanium. As illustrated in
In contrast, the end portion of the housing 4 on the opposite side (upper side in
The diaphragm 2 receives the pressure P from the fluid to be measured. The diaphragm 2 is made of, for example, stainless steel (SUS) formed in a circular thin plate in plan view, but may be made of another material such as ceramics or titanium. In addition, the shape of the diaphragm 2 is not limited to a circle and may be, for example, a square in plan view.
The lower surface of the diaphragm 2 is the fluid contact surface (first surface) that receives the pressure P while being in contact with the fluid and the upper surface of the diaphragm 2 is the deformation measurement surface (second surface) on which the strain sensor 5 is provided. The upper surface of the diaphragm 2 also functions as the pressure receiving surface that receives the atmospheric pressure. The diaphragm 2 is fixed to an end portion 43 of the housing 4 on the joint side coupled to the pipe and blocks the through-hole 40 of the housing 4. The outer peripheral edge of the diaphragm 2 is joined to the wall surface of the through-hole 40 without a gap.
The dummy diaphragm 3 is made of, for example, SUS formed in a circular thin plate in plan view, but may be made of another material such as ceramics or titanium, as the diaphragm 2. The shape of the dummy diaphragm 3 is not limited to a circle and may be, for example, a square or rectangle in plan view, a shape having irregularities, a shape having cavities, a structure including a plurality of layers, or a structure including different materials.
The lower surface (first surface) and the upper surface (second surface) of the dummy diaphragm 3 function as pressure receiving surfaces that receive the atmospheric pressure. The upper surface of the dummy diaphragm 3 is the deformation measurement surface on which the strain sensor 6 is provided. However, the strain sensor 6 may be provided on the lower surface of the dummy diaphragm 3. The dummy diaphragm 3 is provided in the through-hole 40 of the housing 4 so that the lower surface thereof faces the upper surface of the diaphragm 2. The outer peripheral edge of the dummy diaphragm 3 is joined to the wall surface of the through-hole 40 without a gap.
The strain sensor 5 detects the deformation of the diaphragm 2 and the strain sensor 6 detects the deformation of the dummy diaphragm 3. The strain sensors 5 and 6 contain semiconductor chips, respectively. A strain gauge that outputs a signal according to the deformation of the diaphragm 2 is formed in the semiconductor chip of the strain sensor 5. Similarly, a strain gauge that outputs a signal according to the deformation of the dummy diaphragm 3 is formed in the semiconductor chip of the strain sensor 6. Since such strain gauges are disclosed in PTL 1, PTL 2, PTL 3, and PTL 4, detailed description is omitted. It should be noted here that the strain sensors 5 and 6 are not limited to the semiconductor strain gauge type and may be, for example, the capacitance type, the metal strain gauge type, or the type in which a resistance gauge is formed as a film by sputtering or the like.
When the pressure sensor 1 is connected to the cylindrical pipe 20, a clamp 30 as illustrated in
In the embodiment, it is desirable that the output signal of the strain sensor 5 substantially coincides with the output signal of the strain sensor 6 when the diaphragm 2 does not receive the pressure P of the fluid. To make the output signal of the strain sensor 5 substantially coincide with the output signal of the strain sensor 6, it is desirable that, for example, the diameter and the thickness of the diaphragm 2 are the same as the diameter and the thickness of the dummy diaphragm 3, and the structure of the strain sensor 5 is the same as the structure of the strain sensor 6. In addition, it is desirable that the mounting position of the strain sensor 5 within the surface of the diaphragm 2 coincides with the mounting position of the strain sensor 6 within the surface of the dummy diaphragm 3, and the distance between the diaphragm 2 and the dummy diaphragm 3 is desirably as small as possible.
However, even if the output signal of the strain sensor 5 does not substantially coincide with the output signal of strain sensor 6, the present disclosure is applicable when a correlation is clearly present between the output signal of the strain sensor 5 and the output signal of the strain sensor 6 as described later.
In the pressure calculation unit 7, a conversion formula that includes the output signal of the strain sensor 5 as a variable or a table that stores the association between the output signal of the strain sensor 5 and the pressure P is preset. The pressure calculation unit 7 converts the output signal of the strain sensor 5 into the pressure P of the fluid via the conversion formula or the table.
Next, the characteristic operation of the present disclosure will be described. Since the pressure P of the fluid is applied only to the diaphragm 2 and not applied to the dummy diaphragm 3, only the strain sensor 5 responds according to the pressure P.
As is clear from
In contrast, since the entire housing 4 is bent by the tightening force of the clamp 30 when the housing 4 of the pressure sensor 1 and the pipe 20 are tightened by the clamp 30, the diaphragm 2 and the dummy diaphragm 3 are deformed equally. Accordingly, the output signal of the strain sensor 5 and the output signal of the strain sensor 6 make substantially identical responses or responses having a correlation.
In addition, when vibrations of the pipe 20 are transmitted to the pressure sensor 1, the diaphragm 2 is deformed so as to bend up and down according to the natural frequencies of the diaphragm 2 and the strain sensor 5 while the dummy diaphragm 3 is deformed so as to bend up and down according to the natural frequencies of the dummy diaphragm 3 and the strain sensor 6. Accordingly, the output signal of the strain sensor 5 and the output signal of the strain sensor 6 make substantially identical responses or responses having a correlation.
Next, the method for determining the reliability of pressure measurement will be described. Here, the case in which a tolerance threshold TH of pressure measurement error due to the effect of disturbance is set to 2% FS will be considered. In the following formulas, the output signal of the strain sensor 5 and the output signal of the strain sensor 6 are represented as normalized values obtained by assuming a predetermined maximum value FS to be 100%. Here, when the output signal of the strain sensor 6 is Vr, the output signal Vr is represented by the following formula.
Vr=Vrt+Vro (1)
When the output signal of the strain sensor 5 and the output signal of the strain sensor 6 make substantially identical responses for both the disturbance of the tightening force of the clamp 30 and the vibrations of the pipe 20, Vrt≅Vt and Vro≅Vo hold.
The following formula holds when an output error Verr of the strain sensor 5 due to the disturbance received by the strain sensor 5 is equal to or less than 2% FS.
Verr=Vt+Vo≤2≅Vrt+Vro≤2≅Vr≤2 (2)
In addition, the determination unit 8 determines that the reliability of the pressure measurement value is impaired (step S102 in
The determination result output unit 9 outputs the determination result of the determination unit 8 (step S103 in
The determination unit 8 and the determination result output unit 9 repeatedly execute the processing from steps S100 to S103 until, for example, the pressure measurement processing is completed according to an instruction from the user (YES in step S104 in
As described above, in the embodiment, even when the pressure sensor 1 is affected by a plurality of types of disturbance, it is possible to determine whether the reliability of the pressure measurement value is maintained and manage the effect of disturbance on the reliability of the pressure measurement value.
Next, the following describes the case in which the output signal of the strain sensor 5 does not coincide with the output signal of the strain sensor 6, but these signals make responses having a correlation. It is assumed that the output signal Vt of the strain sensor 5 with respect to the tightening torque of the clamp 30 is represented by the following formula.
Vt=a×Vrt+b (3)
Here, a and b are constants. In addition, it is assumed that the output signal Vo of the strain sensor 5 with respect to the vibrations of the pipe 20 is represented by the following formula.
Vo=c×Vro+d (4)
Here, c and d are constants. The output signal Vr of the strain sensor 6 is represented by formula (1) as in the case described above.
When the output error Verr of the strain sensor 5 due to the disturbance received by the strain sensor 5 is equal to or less than 2% FS, the following formulas hold.
Verr=Vt+Vo≤2,
a×Vrt+b+c×Vro+d≤2,
a×Vrt+c×Vro≤2−b−d (5)
Here, when it can be determined that the pressure sensor 1 is affected by either the tightening force of the clamp 30 or the vibrations of the pipe 20, for example, when the pressure sensor 1 is affected only by the tightening force of the clamp 30, the following formula holds because the output signal Vro of the strain sensor 6 with respect to the vibrations of the pipe 20 is 0 and Vrt equals Vr.
Verr≅Vr≤(2−b−d)/a (6)
When the tolerance threshold TH is set to (2−b−d)/a, the determination unit 8 can determine whether the reliability of pressure measurement is maintained as in case 1.
Alternatively, when the pressure sensor 1 is affected only by the vibrations of the pipe 20, the output signal Vrt of the strain sensor 6 with respect to the tightening torque of the clamp 30 is 0 and Vro equals Vr, so the following formula holds.
Verr≅Vr≤(2−b−d)/c (7)
Accordingly, the determination unit 8 can determine whether the reliability of pressure measurement is maintained as in case 1 by setting the tolerance threshold TH to (2−b−d)/c.
Alternatively, when the pressure sensor 1 is affected by both the tightening force of the clamp 30 and the vibrations of the pipe 20, the determination formula can be derived by obtaining the relational formula between the output signal Vrt of the strain sensor 6 with respect to the tightening torque of the clamp 30 and the output signal Vro of the strain sensor 6 with respect to the vibrations of the pipe 20. For example, when the relation Vrt=e×Vro is present, the following formula holds.
Vro=Vr/(e+1) (8)
Verr≅Vro≤(2−b−d)/(a×e+c) (9)
As described above, a, b, c, d, and e are constants. The following formula is obtained from formulas (8) and (9).
Vr≤(2−b−d)×(e+1)/(a×e+c) (10)
Accordingly, the determination unit 8 can determine whether the reliability of pressure measurement is maintained as in case 1 by setting the tolerance threshold TH to (2−b−d)×(e+1)/(a×e+c).
For example, when the pressure sensor 1 is affected by the vibrations of the pipe 20, it is possible to obtain the relational formula for setting the tolerance threshold TH based on the periodicity of the output signal of the strain sensor 6 in a preliminary test in which the same type of pressure sensor is attached to the pipe 20. In addition, when the pressure sensor 1 is affected by the tightening force of the clamp 30, it is possible to obtain the relational formula for setting the tolerance threshold TH by obtaining the output signal of the strain sensor 6 in a preliminary attachment test in which the same type of pressure sensor is attached to the pipe 20.
It should be noted here that the determination unit 8 can also determine the type of disturbance based on the output signal of the strain sensor 6. For example, the determination unit 8 determines that the strain sensor 6 has been affected by the vibrations of the pipe 20 when a frequency component having a signal strength exceeding a predetermined strength threshold is present within a predetermined frequency range (within an expected vibrational frequency range) of a frequency spectrum as a result of conversion of the output signal of the strain sensor 6 into the frequency spectrum by Fourier conversion.
Next, a second embodiment of the present disclosure will be described.
A circular through-hole 40a (first through-hole) and a circular through-hole 40b (second through-hole) are formed in parallel with each other in the housing 4a. The housing 4a is made of, for example, SUS as the housing 4, but may be made of another material such as ceramics or titanium. The ferrule flange portion 41 projecting radially outward is provided at the outer peripheral edge of the housing 4a on the joint side (lower side in
The end portion of the housing 4a on the opposite side (upper side in
The diaphragm 2 is made of, for example, SUS, but may be made of another material such as ceramics or titanium. The lower surface of the diaphragm 2 is the fluid contact surface (first surface) that receives the pressure P while being in contact with the fluid to be measured, and the upper surface of the diaphragm 2 is the deformation measurement surface (second surface) on which the strain sensor 5 is provided. The upper surface of the diaphragm 2 also functions as the pressure receiving surface that receives the atmospheric pressure. The diaphragm 2 is fixed to the vicinity of the end portion 43 of the housing 4a on the joint side coupled to the pipe and blocks the through-hole 40a of the housing 4a. The outer peripheral edge of the diaphragm 2 is joined to the wall surface of the through-hole 40a without a gap.
The dummy diaphragm 3 is made of, for example, SUS, but may be made of another material such as ceramics or titanium, as the diaphragm 2. The lower surface (first surface) and the upper surface (second surface) of the dummy diaphragm 3 function as the pressure receiving surfaces that receive the atmospheric pressure. The upper surface of the dummy diaphragm 3 is the deformation measurement surface on which the strain sensor 6 is provided. As in the first embodiment, the strain sensor 6 may be provided on the lower surface of the dummy diaphragm 3. The dummy diaphragm 3 is fixed to the vicinity of the end portion 43 of the housing 4a on the joint side coupled to the pipe and blocks the through-hole 40b of the housing 4a. The outer peripheral edge of the dummy diaphragm 3 is joined to the wall surface of the through-hole 40b without a gap.
In addition, the pressure sensor la according to the embodiment is provided with the barrier 44 (blocking member) that blocks the end of the through-hole 40b on the joint side coupled to the pipe and has the lower surface (first surface) in contact with the fluid to be measured. The barrier 44 is made of, for example, SUS, but may be made of another material such as ceramics or titanium, as the diaphragm 2 and the dummy diaphragm 3. The outer peripheral edge of the barrier 44 is joined to the wall surface of the through-hole 40b without a gap.
Although the diaphragm 2 and the dummy diaphragm 3 may be joined to the housing 4a as described above, another manufacturing method can be selected in the embodiment. Specifically, cutting work is applied to the housing 4a so that the portions of the diaphragm 2 and the dummy diaphragm 3 remain in the through-holes 40a and 40b of the housing 4a. Then, the barrier 44 only needs to be welded to the inner wall of the through-hole 40b.
The strain sensors 5 and 6, the pressure calculation unit 7, the determination unit 8, and the determination result output unit 9 are the same as in the first embodiment.
It is desirable that the output signal of the strain sensor 5 substantially coincides with the output signal of the strain sensor 6 when the diaphragm 2 does not receive the pressure P of the fluid, as in the first embodiment. To make the output signal of the strain sensor 5 substantially coincide with the output signal of the strain sensor 6, it is desirable that, for example, the diameter and the thickness of the diaphragm 2 are the same as the diameter and the thickness of the dummy diaphragm 3, and the structure of the strain sensor 5 is the same as the structure of the strain sensor 6. In addition, it is desirable that the mounting position of the strain sensor 5 within the surface of the diaphragm 2 coincides with the mounting position of the strain sensor 6 within the surface of the dummy diaphragm 3, the formation positions in the longitudinal direction of the housing 4a (vertical direction in
Furthermore, it is desirable to reduce the rigidity of the barrier 44 with respect to the diaphragm 2 and the dummy diaphragm 3 (for example, reduce the plate thickness) so as to reduce the difference in the mounting effects on the diaphragm 2 and the dummy diaphragm 3. However, even if the output signal of the strain sensor 5 does not substantially coincide with the output signal of the strain sensor 6, the present disclosure is applicable when a correlation is clearly present between the output signal of the strain sensor 5 and the output signal of the strain sensor 6 as in the first embodiment.
Since the operations of the determination unit 8 and the determination result output unit 9 are the same as those in the first embodiment, the description is omitted.
Accordingly, in the embodiment, the same effect as in the first embodiment can be obtained. In addition, the first and second embodiments may include a self-diagnosis function that causes the determination unit 8 to determine a “predictive failure” of the pressure sensors 1 and la when time-series changes occur in the relationship between the output signals of the strain sensors 5 and 6 in the reference pressure state in which the pressure P of the fluid is maintained at the reference value.
In addition, in the first and second embodiments, when the pressure sensors 1 and la are only affected by the tightening force of the clamp 30, the determination unit 8 can detect the loosening of the mounting of the pressure sensors 1 and la by obtaining the time-series changes of the output signal of the strain sensor 6 and can manage the mounting states of pressure sensors 1 and 1a. For example, the determination unit 8 determines that the mounting states of the pressure sensors 1 and 1a have changed when the change amount of the output signal of the strain sensor 6 from the initial value exceeds a predetermined change amount threshold.
Although the tightening force of the clamp 30 and the vibrations of the pipe 20 are taken as examples of disturbance in the first and second embodiments, when the strain sensors 5 and 6 are affected substantially similarly by disturbance such as, for example, the temperature, humidity, light, and electromagnetic field, the present disclosure is applicable.
The determination unit 8 according to the first and second embodiments can be realized by a circuit or a computer. Similarly, the pressure calculation unit 7 can be realized by a computer. A structure example of the computer is illustrated in
The present disclosure is applicable to pressure sensors.
1, 1a: pressure sensor, 2: diaphragm, 3: dummy diaphragm, 4, 4a: housing, 5, 6: strain sensor, 7: pressure calculation unit, 8: determination unit, 9: determination result output unit, 20: pipe, 21, 41: ferrule flange portion, 22, 40, 40a, 40b: through-hole, 42: atmospheric pressure introduction path, 44: barrier
Number | Date | Country | Kind |
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2020-018573 | Feb 2020 | JP | national |