JP2008020337A - Pressure sensor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a highly sensitive and highly precise pressure sensor which can be made compact by simplifying its structure. <P>SOLUTION: One base part 13a of a double-ended tuning fork vibrator 1 is fixed to a fixing part 4 and a terminal part 3 by using a conductive adhesive 8, and an excitation electrode disposed on the double-ended tuning fork vibrator 1 is connected with the terminal part 3. The other base part 13b of the double-ended tuning fork vibrator 1 is fixed to a projecting part 6 of a pressure receiving part 5 by using an adhesive 7. Since one pair of the base parts 13a, 13b is fixed directly to an airtight container 2, the pressure sensor 10 with the simplified structure capable of being made compact can be provided. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a pressure sensor using a piezoelectric element.

Conventionally, it has been known that when a stress is applied to a piezoelectric element typified by a crystal resonator, the resonance frequency of the piezoelectric element changes. And the pressure sensor using this characteristic is proposed.
For example, a pressure sensor as in Patent Document 1 is known. This pressure sensor is a pressure sensor in which a piezoelectric element is hermetically sealed in an airtight container in an inert gas atmosphere or a reduced pressure atmosphere, and a pressure inlet as a pressure receiving portion formed in the hermetic container, and one of the piezoelectric elements The vibration element bonding base is fixed to the base, and the bellows is fixed between the pressure inlet and the vibration element bonding base. In addition, the other base part which opposes one base part of a piezoelectric element is being fixed to the airtight container.
Due to the external pressure applied to the pressure inlet, the bellows expands and contracts and the position of the vibration element adhesion base moves, whereby the stress due to the external pressure is transmitted to the piezoelectric element (see Patent Document 1).

Japanese Patent Laying-Open No. 2005-121628 (pages 5 to 7, FIGS. 1 to 3)

  The structure of the conventional pressure sensor described above is complicated because a plurality of members such as a bellows and a vibration element bonding base are interposed between a pressure inlet as a pressure receiving portion and a vibrator element as a piezoelectric element. Therefore, it is difficult to reduce the size of the pressure sensor.

  The present invention has been made paying attention to such conventional problems, and an object of the present invention is to provide a highly sensitive and highly accurate pressure sensor that simplifies the structure and can be reduced in size and price. It is in.

  In order to solve the above problems, a pressure sensor of the present invention includes a piezoelectric element having bases at both ends, and an airtight container in which the piezoelectric element is housed and a fixed part and a pressure-receiving part are arranged to face each other. One base portion of the piezoelectric element is fixed to the fixing portion, the other base portion of the piezoelectric element is fixed to the pressure receiving portion, and a terminal portion connected to the piezoelectric element is disposed on the outer surface of the airtight container. This is the gist.

  According to this configuration, one base portion of the piezoelectric element is fixed to the fixing portion and connected to the piezoelectric element. The other base portion of the piezoelectric element is fixed to the pressure receiving portion. For this reason, since the piezoelectric element is directly fixed in the airtight container, it is possible to realize a pressure sensor that can be simplified in structure and reduced in size.

  The gist of the pressure sensor of the present invention is that the piezoelectric element is a double tuning fork vibrator.

  According to this configuration, by using a double tuning fork vibrator having a characteristic that the resonance frequency greatly changes when stress is applied from the extension direction of the intermediate line located approximately in the middle of the pair of vibration arms that flexurally vibrate, External pressure can be detected well and accurately.

  The gist of the pressure sensor of the present invention is that one base portion of the piezoelectric element and the fixing portion are fixed by a conductive adhesive, and the piezoelectric element and the terminal portion are connected by a conductive adhesive.

  According to this configuration, the one base portion and the fixing portion of the piezoelectric element are fixed and the piezoelectric element and the terminal portion are connected by the conductive adhesive having both the role of fixing and connection. For this reason, the structure can be simplified, and the fixing and connecting steps can be simplified.

  The gist of the pressure sensor of the present invention is that the shape of the hermetic container is a cylindrical shape, one of two opposed planes is the fixed portion, and the other is the pressure receiving portion.

  According to this configuration, the external pressure applied to the outer peripheral portion of the cylindrical case of the hermetic container acts so as to cancel each other out, so the pressure resistance is improved and the thickness of the outer peripheral portion can be reduced, making it smaller and lighter Can be

  In the pressure sensor of the present invention, the shape of the hermetic container is a rectangular tube that forms a regular polygon that is equal to or greater than a quadrangle, one of two opposing regular polygonal planes is the fixing portion, and the other is the pressure receiving portion. This is the gist.

  According to this configuration, since the outer shape of the airtight container is a regular polygon that is equal to or greater than a quadrangle, one surface of the regular polygon is stably disposed facing the mounting surface, and surface mounting can be performed.

  The gist of the pressure sensor of the present invention is that the inside of the airtight container is in a reduced pressure atmosphere.

  According to this configuration, the double tuning fork vibrator bends and vibrates in a reduced-pressure atmosphere with low air resistance, and thus can bend and vibrate efficiently to reduce current consumption.

  The gist of the pressure sensor of the present invention is that the pressure receiving part of the airtight container is equal to or thinner than the thickness other than the pressure receiving part.

  According to this configuration, since the pressure receiving portion bends with high sensitivity to changes in external pressure, the external pressure can be detected with higher sensitivity.

DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, embodiments of the invention will be described with reference to the drawings.
(First embodiment)

In the following embodiments, an example of a pressure sensor using a crystal resonator as a piezoelectric element will be described.
FIG. 1 shows the configuration of the pressure sensor 10 of the first embodiment, FIG. 1 (a) is a schematic plan view showing an airtight container in cross section, and FIG. 1 (b) is an A- It is a schematic sectional drawing in alignment with A disconnection. FIG. 2 is a schematic left side view of FIG.

  The pressure sensor 10 includes a double tuning fork vibrator 1 as a piezoelectric element and an airtight container 2 made of metal or the like. The double tuning fork vibrator 1 is housed in an airtight container 2.

The airtight container 2 includes a case 16 and a plug body 12.
The case 16 has a cylindrical shape, one of the cylindrical shapes being opened, and the other forming the pressure receiving portion 5. The pressure receiving part 5 is made of metal or the like and is formed in a circular shape. And in the pressure receiving part 5, the prism-shaped convex part 6 which protruded toward the airtight container 2 inner side is formed with the metal. In addition, although the convex part 6 was made into the prismatic shape, what kind of shape may be sufficient if it is the convex shape which protruded toward the airtight container 2 inner side.
Here, the pressure receiving part 5 has a structure that bends according to the direction P of pressure outside the hermetic container 2. Although the pressure receiving portion 5 is formed in a circular shape, any shape such as a polygon or an ellipse may be used as long as the pressure receiving portion 5 is bent according to the direction P of the external pressure. Good. In addition, the pressure receiving portion 5 having a circular shape is formed so as to have a thickness equal to or less than the thickness of the outer peripheral portion, which is the difference between the outer periphery and the inner periphery of the cylindrical shape of the case 16.
The plug body 12 includes a fixed portion 4 and a terminal portion 3.
The fixing part 4 is formed of metal and glass and is press-fitted into one of the opened cases 16 so that the airtight container 2 is hermetically sealed in a reduced-pressure atmosphere. Here, the fixing portion 4 is disposed to face the pressure receiving portion 5 of the case 16. The terminal portion 3 is made of metal or the like, insulated from the fixed portion 4 by an insulator such as glass, and drawn out from a part of the fixed portion 4.

The double tuning fork vibrator 1 is made of a single crystal quartz plate, and includes a pair of vibration arms 11a and 11b that bend and vibrate, and a pair of rectangular base portions 13a and 13b. The vibrating arms 11a and 11b are formed extending from one base portion 13a and connected to the other base portion 13b.
The double tuning fork vibrator 1 having such a configuration has a characteristic that when a stress is applied from an extending direction of an intermediate line located substantially in the middle of the pair of vibration arms 11a and 11b that flexurally vibrate, the resonance frequency changes greatly. ing.

One base portion 13 a of the double tuning fork vibrator 1 is fixed to the fixing portion 4 and the terminal portion 3 by the conductive adhesive 8, and an excitation electrode (not shown) provided in the double tuning fork vibrator 1 and the terminal portion 3 Are electrically connected. Thereby, the double tuning fork vibrator 1 can be connected to the outside of the hermetic container 2, and the double tuning fork vibrator 1 can be vibrated.
The other base portion 13 b of the double tuning fork vibrator 1 is fixed to the convex portion 6 of the pressure receiving portion 5 with an adhesive 7. Accordingly, the pair of base portions 13 a and 13 b of the double tuning fork vibrator 1 is directly fixed to the airtight container 2.
Here, the double tuning fork vibrator 1 is arranged and fixed so that the approximate center of the circular pressure receiving portion 5 is located in the extending direction of the intermediate line located approximately in the middle of the vibration arms 11a and 11b.

Since the pressure receiving portion 5 bends according to the external pressure applied to the pressure sensor 10, the stress according to the direction P of the external pressure is directly applied to the double tuning fork vibrator 1 fixed to the convex portion 6 of the pressure receiving portion 5. Reportedly. The pressure sensor 10 has a structure capable of detecting the external pressure by detecting the resonance frequency of the double tuning fork vibrator 1 that changes due to stress.
Of the external pressure applied to the pressure sensor 10, the external pressure applied to the outer periphery of the case 16 having the cylindrical shape of the hermetic container 2 acts so as to cancel each other. Therefore, a stress corresponding to the direction P of the external pressure applied to the pressure sensor 10 is transmitted to the double tuning fork vibrator 1.

  Although the base portion 13b of the double tuning fork vibrator 1 is fixed to the convex portion 6 of the pressure receiving portion 5, the base portion 13b may be directly fixed to the pressure receiving portion 5 without forming the convex portion 6. In addition, although the shape of the base portion 13b is rectangular, the base 13b may have a shape having a protruding portion formed by extending the substantial center of the base portion 13b in the direction of the pressure receiving portion 5, and the protruding portion of the base portion 13b directly contacts the pressure receiving portion 5. It may be fixed.

  Here, the change in the resonance frequency of the double tuning fork vibrator 1 with respect to the change in the external pressure was measured using the pressure sensor 10 of the present embodiment. Note that the double tuning fork vibrator 1 used in the pressure sensor 10 is formed in a size of 14 mm × 3 mm and a thickness of 0.2 mm. The measurement results are shown in FIG. The vertical axis represents the resonance frequency, and the horizontal axis represents the external pressure. FIG. 3 shows a change in which the resonance frequency decreases as the external pressure increases, and it can be confirmed that the good linearity between the external pressure and the resonance frequency is maintained.

Hereinafter, the pressure sensor 10 according to the present embodiment has the following effects.
(1) One base portion 13a of the double tuning fork vibrator 1 is fixed to the fixed portion 4 and the terminal portion 3 by the conductive adhesive 8, and the excitation electrode provided in the double tuning fork vibrator 1 and the terminal portion 3 are connected. Has been. The other base portion 13 b of the double tuning fork vibrator 1 is fixed to the convex portion 6 of the pressure receiving portion 5 with an adhesive 7. For this reason, since the pair of base portions 13a and 13b of the double tuning fork vibrator 1 are directly fixed to the airtight container 2, it is possible to provide the pressure sensor 10 that can be simplified in structure and reduced in size. .
(2) The double tuning fork vibrator 1 having such a characteristic that when a stress is applied from an extending direction of an intermediate line positioned substantially in the middle of the pair of vibration arms 11a and 11b that undergo bending vibration, the resonance frequency greatly changes. Thus, the external pressure can be detected with high sensitivity and high accuracy.
(3) One base portion 13a and the fixed portion 4 of the double tuning fork vibrator 1 are fixed by the conductive adhesive 8 having both the role of fixing and connection, and the double tuning fork vibrator 1 and the terminal portion 3 are fixed to each other. It is connected. For this reason, the structure can be simplified, and the fixing and connecting steps can be simplified.
(4) Since the external pressure applied to the outer peripheral portion of the cylindrical case 16 of the airtight container 2 acts to cancel each other, the pressure resistance is improved and the thickness of the outer peripheral portion can be reduced, making it smaller and lighter. can do.
(5) Since the vibration arms 11a and 11b of the double tuning fork vibrator 1 flexurally vibrate in a reduced pressure atmosphere with low air resistance, the flexural vibration can be efficiently performed and current consumption can be reduced.
(6) Since the pressure receiving portion 5 bends with high sensitivity to changes in external pressure, the external pressure can be detected with higher sensitivity.
(Second embodiment)

  FIG. 4 shows the configuration of the pressure sensor 20 of the second embodiment, FIG. 4 (a) is a schematic plan view showing the airtight container in cross section, and FIG. 4 (b) is an A- It is a schematic sectional drawing in alignment with A disconnection. FIG. 5 is a schematic left side view of FIG.

  The pressure sensor 20 includes a double tuning fork vibrator 21 as a piezoelectric element and a container 22 made of metal or the like. The double tuning fork vibrator 21 is housed in an airtight container 22.

The airtight container 22 includes a case 26 and a plug body 12.
The case 26 has a cylindrical shape, one of the cylindrical shapes is opened, and the other forms a pressure receiving portion 25. The pressure receiving portion 25 is made of metal or the like and is formed in a circular shape. A penetrating portion 29 is formed substantially at the center of the pressure receiving portion 25.
Here, the pressure receiving portion 25 has a structure that bends according to the direction P of pressure outside the hermetic container 22. Although the pressure receiving portion 25 is formed in a circular shape, any shape such as a polygon or an ellipse may be used as long as the pressure receiving portion 25 is bent according to the direction P of the external pressure. Good. Further, the thickness of the circular pressure receiving portion 25 is formed to be equal to or less than the thickness that is the difference between the outer periphery and the inner periphery of the case 26 that has a cylindrical shape.
The plug body 12 includes a fixed portion 4 and a terminal portion 3.
The fixing portion 4 is formed of metal and glass and is press-fitted into one of the opened cases 26. Here, the fixing portion 4 is disposed to face the pressure receiving portion 25 of the case 26. The terminal portion 3 is made of metal or the like, insulated from the fixed portion 4 by an insulator such as glass, and drawn out from a part of the fixed portion 4.

The double tuning fork vibrator 21 is made of a single crystal quartz plate, and includes a pair of vibration arms 21a and 21b that bend and vibrate, and a pair of rectangular base portions 23a and 23b. The vibration arms 21a and 21b are formed extending from one base portion 23a and connected to the other base portion 23b. And the protrusion part 23c is extended from the other side facing one side of the base 23b to which the vibration arms 21a and 23b are connected.
The double tuning fork vibrator 21 having such a configuration has a characteristic that when a stress is applied from an extending direction of an intermediate line located approximately in the middle of the pair of vibration arms 21a and 21b that flexurally vibrate, the resonance frequency changes greatly. ing.

One base portion 23 a of the double tuning fork vibrator 21 is fixed to the fixed portion 4 and the terminal portion 3 by the conductive adhesive 8, and an excitation electrode (not shown) provided on the double tuning fork vibrator 21 and the terminal portion 3 Are electrically connected. Accordingly, the double tuning fork vibrator 21 can be connected to the outside of the airtight container 22 so that the double tuning fork vibrator 21 can vibrate.
Then, the protrusion 23 c of the other base 23 b in the double tuning fork vibrator 21 passes through the penetration part 29 of the pressure receiving part 25. Then, an adhesive 27 is formed so as to close the gap between the protruding portion 23 c and the penetrating portion 29, and the protruding portion 23 c is fixed to the penetrating portion 29 of the pressure receiving portion 25 by the adhesive 27.
Thus, the pair of base portions 23a and 23b of the double tuning fork vibrator 21 are directly fixed to the airtight container 22, and the inside of the airtight container 22 is hermetically sealed in a reduced pressure atmosphere.
Here, the double tuning fork vibrator 21 is arranged and fixed so that the approximate center of the circular pressure receiving portion 25 is located in the extending direction of the intermediate line located approximately in the middle of the vibration arms 21a and 21b.

When the pressure receiving portion 25 bends according to the external pressure applied to the pressure sensor 20, the stress according to the direction P of the external pressure is directly applied to the double tuning fork vibrator 21 fixed to the through portion 29 of the pressure receiving portion 25. Reportedly. The pressure sensor 20 has a structure capable of detecting the external pressure by detecting the resonance frequency of the double tuning fork vibrator 21 that changes due to stress.
Of the external pressure applied to the pressure sensor 20, the external pressure applied to the outer peripheral portion of the cylindrical case 26 of the airtight container 22 acts so as to cancel each other. Therefore, a stress corresponding to the direction P of the external pressure applied to the pressure sensor 20 is transmitted to the double tuning fork vibrator 21.

  Here, the same measurement as in the first embodiment was performed using the pressure sensor 20 of the present embodiment. Similar to the measurement result of the first embodiment shown in FIG. 3, the measurement result shows a change in which the resonance frequency decreases as the external pressure increases, and the linearity between the external pressure and the resonance frequency is maintained. Was confirmed.

Hereinafter, according to the pressure sensor 20 of the present embodiment, there are the following effects.
(1) One base portion 23a of the double tuning fork vibrator 21 is fixed to the fixed portion 4 and the terminal portion 3 by a conductive adhesive 8 in which conductive particles such as silver are contained in a resin having bonding strength. The excitation electrode provided in the vibrator 21 and the terminal portion 3 are connected. Then, the protruding portion 23 c of the other base portion 23 b of the double tuning fork vibrator 21 is fixed to the penetrating portion 29 of the pressure receiving portion 25 with an adhesive 27. For this reason, since the pair of base portions 23a and 23b of the double tuning fork vibrator 21 are directly fixed to the hermetic container 22, it is possible to provide the pressure sensor 20 that can be simplified in structure and reduced in size. .
(2) The double tuning fork vibrator 21 having such a characteristic that the resonance frequency changes greatly when stress is applied from the extending direction of the intermediate line located substantially in the middle between the pair of vibration arms 21a and 21b that bend and vibrate. Thus, the external pressure can be detected with high sensitivity and high accuracy.
(3) One base 23a and the fixed portion 4 of the double tuning fork vibrator 21 are fixed by the conductive adhesive 8 having both the role of fixing and connection, and the double tuning fork vibrator 21 and the terminal portion 3 are fixed. It is connected. For this reason, the structure can be simplified, and the fixing and connecting steps can be simplified.
(4) Since the external pressure applied to the outer periphery of the cylindrical case 26 of the hermetic container 22 acts to cancel each other, the pressure resistance is improved, the thickness of the outer periphery can be reduced, and the size and weight can be reduced. can do.
(5) Since the vibration arms 21a and 21b of the double tuning fork vibrator 21 flexurally vibrate in a reduced pressure atmosphere with low air resistance, the flexural vibration can be efficiently performed and current consumption can be reduced.
(6) Since the pressure receiving portion 25 bends with high sensitivity to changes in external pressure, the external pressure can be detected with higher sensitivity.

In the above-described embodiment, the shape of the hermetic container is a cylindrical shape, but considering the ease of grounding, the shape of the outer side of the hermetic container may be any shape such as an elliptical shape or a regular polygon shape of a quadrilateral or more, The inner shape of the airtight container may be any shape as long as it has a recess that can accommodate the piezoelectric element.
Hereinafter, modified examples related to the shape of the airtight container in the above-described embodiment will be described.
(Modification)

6 (a) to 6 (c) are schematic diagrams showing modified examples of FIGS. 2 and 5. FIG.
6A shows that the outer shape of the airtight container 32 of the pressure sensor 30 is an ellipse, the inner shape of the airtight container 32 is also an ellipse, and a piezoelectric element is provided at the approximate center of the circular pressure receiving portion 35. The double tuning fork vibrator 31 is positioned and fixed.
In FIG. 6B, the outer shape of the airtight container 42 of the pressure sensor 40 forms an octagon, and the double tuning fork vibrator 41 as a piezoelectric element is positioned at the approximate center of the circular pressure receiving portion 45. It is fixed.
In FIG. 6C, the outer shape of the airtight container 52 of the pressure sensor 50 forms a quadrangle, and the double tuning fork vibrator 51 serving as a piezoelectric element is positioned at the approximate center of the circular pressure receiving portion 55 and fixed. Has been.
As described above, even in the pressure sensor 30 in which the shape of the hermetic container 32 is elliptical, the same effect as that of the above-described embodiment can be obtained.
And since the shape of the airtight containers 42 and 52 is a square or more regular polygon, the pressure sensor 40 and the pressure sensor 50 are stably arranged so that one surface of the regular polygon faces the mounting surface. Can be surface mounted.

It should be noted that the present invention is not limited to the above-described embodiments, and modifications, improvements, and the like within the scope that can achieve the object of the present invention are included in the present invention.
For example, in the above-described embodiment, the double tuning fork vibrator is used as the piezoelectric element, but a surface acoustic wave resonator or a thickness shear vibrator may be used.
In addition, the material of the piezoelectric element is not limited to a single crystal crystal, and lithium tantalate (LiTaO ₃ ), lithium niobate (LiNbO ₃ ), or the like can be used.
One base portion of the piezoelectric element is fixed to the pressure receiving portion of the container with an adhesive, but may be fixed using an alloy such as a conductive adhesive, solder, or a brazing material.
The other base of the piezoelectric element is fixed to the fixing part of the container and the external terminal with a conductive adhesive, and the excitation electrode provided on the piezoelectric element is connected to the external terminal. It may be fixed and connected using an alloy such as a material. Alternatively, the base portion of the piezoelectric element may be fixed to the fixing portion of the container with an adhesive and connected to an external terminal with a metal wire or the like.

(A) is the schematic plan view which showed the airtight container in the cross section, (b) is the schematic sectional drawing which follows the AA disconnection of (a). The schematic left view of FIG.1 (b). The graph which shows the change of the resonant frequency with respect to the change of an external pressure. (A) is the schematic plan view which showed the airtight container in the cross section, (b) is the schematic sectional drawing which follows the AA disconnection of (a). The schematic left view of FIG.4 (b). Schematic which shows a modification.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Double tuning fork vibrator as piezoelectric element, 2 ... Airtight container, 3 ... Terminal part, 4 ... Fixed part, 5 ... Pressure receiving part, 10 ... Pressure sensor, 13a ... One base of a double tuning fork vibrator, 13b ... Double The other base of the tuning fork vibrator, 20 ... pressure sensor, 21 ... double tuning fork vibrator, 22 ... airtight container, 23a ... one base, 23b ... the other base, 25 ... pressure receiving part.

Claims (7)

A piezoelectric element having bases at both ends;
The piezoelectric element is housed, and includes a hermetic container in which a fixed portion and a pressure receiving portion are arranged to face each other.
One base portion of the piezoelectric element is fixed to the fixing portion, the other base portion of the piezoelectric element is fixed to the pressure receiving portion, and a terminal portion connected to the piezoelectric element is disposed on the outer surface of the hermetic container. A pressure sensor characterized by The pressure sensor according to claim 1.
The pressure sensor, wherein the piezoelectric element is a double tuning fork vibrator. The pressure sensor according to claim 1 or 2,
A pressure sensor, wherein one base portion of the piezoelectric element and the fixing portion are fixed by a conductive adhesive, and the piezoelectric element and the terminal portion are connected by a conductive adhesive. The pressure sensor according to any one of claims 1 to 3,
The pressure sensor according to claim 1, wherein the shape of the hermetic container is a cylindrical shape, one of two opposing planes is the fixing portion, and the other is the pressure receiving portion. The pressure sensor according to any one of claims 1 to 3,
The pressure sensor is characterized in that the shape of the hermetic container is a rectangular tube having a regular polygon of a square or more, one of the two planes of the regular polygon facing each other is the fixing portion, and the other is the pressure receiving portion. . In the pressure sensor according to any one of claims 1 to 5,
A pressure sensor characterized in that the inside of the airtight container is in a reduced pressure atmosphere. In the pressure sensor according to any one of claims 1 to 6,
The pressure sensor, wherein the pressure receiving part of the airtight container is equal to or thinner than the thickness other than the pressure receiving part.

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