JP2013217668A - Physical quantity detection device, physical quantity detector, and electronic apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a physical quantity detection device capable of preventing spuriousness from being generated and improving detection sensitivity.SOLUTION: A physical quantity detection device 100 comprises: a base 10; a movable part 14 provided on the base 10 via a joint 12 and displaced according to a physical quantity; and a physical quantity detection element 20 extending between the base 10 and the movable part 14 in a planar view in a displacement direction. The physical quantity detection element 20 is placed in a groove part 30 provided on the base 10 and the movable part 14.

Description

  The present invention relates to a physical quantity detection device, a physical quantity detector, and an electronic apparatus.

  Conventionally, a physical quantity detection device (for example, an acceleration sensor) using a physical quantity detection element such as a vibrator is known. Such a physical quantity detection device is configured to detect the force applied to the physical quantity detection device from the change in the resonance frequency when the resonance frequency of the physical quantity detection element changes due to the force acting in the detection axis direction. Has been.

  For example, Patent Document 1 includes an outer frame member and a double tuning fork type piezoelectric vibration element, and a part of the outer frame member is formed so as to be more flexible than a groove portion, thereby reducing the height in the Z-axis direction. The illustrated physical quantity sensor is disclosed. In the physical quantity sensor of Patent Document 1, when acceleration is applied, the outer frame member bends with the central portion of the groove serving as a fulcrum. As a result, the stress generated in the double tuning fork type piezoelectric vibration element changes, and the resonance frequency of the double tuning fork type piezoelectric vibration element changes. The applied acceleration can be detected from the change in the resonance frequency.

  In such a physical quantity sensor, it is necessary to obtain a force (tension or compressive force) applied to the double tuning fork type piezoelectric vibrating element as the distance between the double tuning fork type piezoelectric vibrating element and the fulcrum is smaller from the principle of leverage. The force (acceleration) becomes smaller. That is, the detection sensitivity improves as the distance between the double tuning fork type piezoelectric vibration element and the fulcrum is smaller. The physical quantity sensor of Patent Document 1 can have high detection sensitivity because the distance between the double tuning fork type piezoelectric vibration element and the central portion (fulcrum) of the groove portion is small.

JP 2008-309731 A

  However, in a structure with low strength such that the outer frame member with a small width is flexible like the physical quantity sensor of Patent Document 1, spurious due to vibration modes other than main vibration is likely to occur.

  One of the objects according to some aspects of the present invention is to provide a physical quantity detection device capable of suppressing the occurrence of spurious and increasing the detection sensitivity. Another object of some aspects of the present invention is to provide a physical quantity detector and electronic apparatus having the physical quantity detection device.

  SUMMARY An advantage of some aspects of the invention is to solve at least a part of the problems described above, and the invention can be implemented as the following aspects or application examples.

[Application Example 1]
The physical quantity detection device according to this application example is
The base,
A movable portion that is provided on the base portion via a joint portion, and is displaced in accordance with a change in physical quantity;
A physical quantity detection element spanned from the base portion to the movable portion in plan view in the displacement direction;
Including
The physical quantity detection element is disposed in a groove provided in the base and the movable part.

  According to such a physical quantity detection device, since the physical quantity detection element is disposed in the groove, the distance between the physical quantity detection element and the joint portion (fulcrum) can be reduced. From the lever principle, the smaller the distance between the physical quantity detection element and the joint (fulcrum), the smaller the force (acceleration) required to obtain the force (tension or compression force) applied to the physical quantity detection element. . That is, the smaller the distance between the physical quantity detection element and the joint portion, the higher the detection sensitivity. Therefore, such a physical quantity detection device can have high detection sensitivity.

  Furthermore, according to such a physical quantity detection device, since the physical quantity detection element is disposed in the groove part, it is possible to increase the detection sensitivity while suppressing a decrease in the strength of the movable part. Therefore, spurious generation can be suppressed and detection sensitivity can be increased. For example, when the distance between the physical quantity detection element and the fulcrum is reduced by reducing the thickness of the entire movable part, the strength of the movable part may be reduced and spurious may occur.

[Application Example 2]
In the physical quantity detection device according to this application example,
The depth of the groove may be equal to or greater than the thickness of the physical quantity detection element.

  According to such a physical quantity detection device, the physical quantity detection element can be prevented from protruding from the main surface of the movable part. Therefore, for example, since the mass body can be placed on the physical quantity detection element, the mass of the mass body can be increased while downsizing.

[Application Example 3]
In the physical quantity detection device according to this application example,
A mass body that has a portion that overlaps the groove portion of the movable portion in plan view in the displacement direction and is fixed to the movable portion;
The physical quantity detection element may be positioned between a portion of the mass body that overlaps the groove and the movable portion.

  According to such a physical quantity detection device, since the mass body can be placed on the physical quantity detection element, the mass of the mass body can be increased while downsizing.

[Application Example 4]
In the physical quantity detection device according to this application example,
Including a first joining member provided in the groove of the base,
The first joining member may join the physical quantity detection element and the base.

  According to such a physical quantity detection device, the bonding strength between the physical quantity detection element and the base can be increased.

[Application Example 5]
In the physical quantity detection device according to this application example,
Including a second joining member provided in the groove of the movable part;
The second joining member may join the physical quantity detection element and the movable part.

  According to such a physical quantity detection device, the bonding strength between the physical quantity detection element and the movable part can be increased.

[Application Example 6]
In the physical quantity detection device according to this application example,
The physical quantity detection element may be a double tuning fork type vibration element.

  According to such a physical quantity detection device, spurious generation can be suppressed and detection sensitivity can be increased.

[Application Example 7]
The physical quantity detector according to this application example is
A physical quantity detection device according to this application example;
A package containing the physical quantity detection device;
including.

  Such a physical quantity detector can suppress the occurrence of spurious and increase the detection sensitivity.

[Application Example 8]
The electronic device according to this application example is
The physical quantity detection device according to this application example is included.

  Such an electronic device can suppress the occurrence of spurious and increase the detection sensitivity.

The perspective view which shows typically the physical quantity detection device which concerns on this embodiment. The top view which shows typically the physical quantity detection device which concerns on this embodiment. Sectional drawing which shows typically the physical quantity detection device which concerns on this embodiment. Sectional drawing for demonstrating operation | movement of the physical quantity detection device which concerns on this embodiment. Sectional drawing for demonstrating operation | movement of the physical quantity detection device which concerns on this embodiment. The top view which shows typically the physical quantity detector which concerns on this embodiment. Sectional drawing which shows typically the physical quantity detector which concerns on this embodiment. The perspective view which shows typically the electronic device which concerns on this embodiment.

  DESCRIPTION OF EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings. The embodiments described below do not unduly limit the contents of the present invention described in the claims. In addition, not all of the configurations described below are essential constituent requirements of the present invention.

1. Physical Quantity Detection Device First, a physical quantity detection device according to the present embodiment will be described with reference to the drawings. FIG. 1 is a perspective view schematically showing a physical quantity detection device 100 according to this embodiment. FIG. 2 is a plan view schematically showing the physical quantity detection device 100 according to this embodiment. FIG. 3 is a cross-sectional view schematically showing the physical quantity detection device 100 according to this embodiment, and is a cross-sectional view taken along the line III-III in FIG. In FIG. 1 and FIG. 2, for convenience, the first mass body 50 is shown through. 1 to 3 show the X axis, the Y axis, and the Z axis as three axes orthogonal to each other.

  As shown in FIGS. 1 to 3, the physical quantity detection device 100 includes a base 10, a joint part 12, a movable part 14, and a physical quantity detection element 20. The physical quantity detection device 100 can further include a first mass body 50 and a second mass body 52.

  The base portion 10 supports the movable portion 14 via the joint portion 12. The joint portion 12 is provided between the base portion 10 and the movable portion 14 and is connected to the base portion 10 and the movable portion 14. The thickness of the joint portion 12 is smaller than the thickness of the base portion 10 and the thickness of the movable portion 14. For example, the depressions 12a and 12b (see FIG. 3) are formed by half-etching from both the main surfaces 10a and 10b side of the quartz substrate, and the joint portion 12 (the portion between the bottom of the depression 12a and the bottom of the depression 12b) is formed. Can be formed. In the illustrated example, the recesses 12a and 12b are formed along the X axis. The joint portion 12 can be a fulcrum when the movable portion 14 is displaced (rotated) with respect to the base portion 10 and can be a rotation axis along the X axis. That is, the joint portion 12 can be a base point for bending of a cantilever beam including the movable portion 14 and the joint portion 12.

  The movable portion 14 is provided on the base portion 10 via the joint portion 12. In the illustrated example, the movable portion 14 extends from the base portion 10 via the joint portion 12 along the Y axis (in the + Y axis direction). The movable part 14 is plate-shaped. The movable portion 14 intersects the main surfaces 14a and 14b (Z-axis direction) with the joint portion 12 as a fulcrum (rotation axis) according to the acceleration applied in the direction (Z-axis direction) intersecting the main surfaces 14a and 14b. Can be displaced.

  The groove portion 30 is provided in the base portion 10 and the movable portion 14. The groove portion 30 is a combination of groove portions configured to be cut out from the side surfaces of the base portion 10 and the movable portion 14 on the joint portion 12 side toward the center portion of the base portion 10 and the center of the movable portion 14. To the movable part 14. The groove portion 30 extends along the Y-axis direction and intersects (is orthogonal in the illustrated example) with the recess 12a. The depth of the groove part 30 is smaller than the depth of the hollow 12a, for example. The groove part 30 is provided on an axis (not shown) that is parallel to the Y axis and passes through the center of the movable part 14. The groove portion 30 includes a first portion 32 provided on the main surface 10 a of the base portion 10 and a second portion 34 provided on the movable portion 14. The first portion 32 and the second portion 34 of the groove portion 30 communicate with each other through the recess 12a.

A physical quantity detection element 20 is provided in the groove 30. In the illustrated example, the first base portion 22 of the physical quantity detection element 20 is disposed in the first portion 32 of the groove portion 30, and the second base portion 23 of the physical quantity detection element 20 is disposed in the second portion 34 of the groove portion 30. ing. Within the groove portion 30, the base portion 10 and the first base portion 22 are joined via a joining member (first joining member) 60, and the movable portion 14 and the second base portion 23 are joined via a joining member (second joining member) 62. Are joined. In the groove portion 30, the base portion 10 and the first base portion 22 are joined via the joining member 60, so that in the illustrated example, the surface of the base portion 10 that defines the bottom surface and the side surface of the groove portion 30, and the first base portion. The bottom surface and the side surface of 22 are joined via the joining member 60. That is, the base portion 10 includes a protruding portion that protrudes from the arrangement surface in a range from the periphery of the arrangement surface facing the physical quantity detection element 20 to the outer edge of the base portion 10 in a plan view along the Z-axis direction. Yes. The movable portion 14 includes a protruding portion that protrudes from the arrangement surface in a range from the peripheral edge of the arrangement surface facing the physical quantity detection element 20 to the outer edge of the movable portion 14 in plan view along the Z-axis direction. Yes.
Thus, by joining the base 10 and the first base part 22 through the joining member 60 in the groove part 30, the joining surface can be increased and the joining strength can be increased. Further, in the groove portion 30, the movable portion 14 and the second base portion 23 are joined via the joining member 62, so that in the illustrated example, the surface of the movable portion 14 that defines the bottom surface and the side surface of the groove portion 30, The bottom surface and the side surface of the second base portion 23 are joined via the joining member 62. Thus, by joining the movable part 14 and the 2nd base part 23 via the joining member 60 in the groove part 30, a joining surface can be enlarged and joining strength can be raised.

  The depth D of the groove part 30 is not less than the thickness of the physical quantity detection element 20. Further, it is desirable that the surface is shallower than the surface of the joint portion 12. Here, the depth D of the groove portion 30 is a distance (a distance in the Z-axis direction) between the main surface 10a of the base portion 10 (the main surface 14a of the movable portion 14) and the bottom surface of the groove portion 30. In the illustrated example, the depth D of the groove 30 is the same as the sum of the thickness of the physical quantity detection element 20 and the thickness of the bonding members 60 and 62. The depth D of the groove part 30 is, for example, such a depth that the physical quantity detection element 20 does not protrude from the main surface 14 a of the movable part 14. The depth D of the groove part 30 is, for example, about ¼ of the thickness of the movable part 14. The depth D of the groove part 30 is, for example, about 0.1 μm, and the thickness of the movable part 14 is, for example, about 0.4 μm. It is desirable that the groove 30 has a bottom that does not penetrate the movable portion 14. This is because when the groove portion 30 penetrates the movable portion 14, a vibration mode different from the main vibration is likely to occur, and spurious may occur. In the case of this embodiment, the base 10 and the movable part 14 each have a higher rigidity at the periphery of the groove part 30 than at the bottom part. Therefore, since the base 10 and the movable part 14 are configured to have sufficient strength, the occurrence of the above-described spurious can be suppressed.

  Although not shown, when the physical quantity detection element 20 is directly joined to the base 10 and the movable part 14, the depth D of the groove 30 and the thickness of the physical quantity detection element 20 may be the same.

  The base part 10, the joint part 12, and the movable part 14 are integrally formed, for example, by patterning a quartz substrate cut out from a quartz crystal or the like at a predetermined angle by a photolithography technique and an etching technique. Further, the groove 30 may be formed by patterning the quartz substrate. In addition, the material of the base part 10, the joint part 12, and the movable part 14 is not limited to quartz, and may be a semiconductor material such as glass or silicon.

  The physical quantity detection element 20 is stretched between the base portion 10 and the movable portion 14 in a plan view (in a plan view in the Z-axis direction). The physical quantity detection element 20 is provided in the groove 30. The physical quantity detection element 20 includes vibration beam portions 21 a and 21 b, a first base portion 22, and a second base portion 23. For example, when the movable portion 14 is displaced, a force is generated in the vibrating beam portions 21a and 21b, and physical quantity detection information generated in the vibrating beam portions 21a and 21b is changed.

  The vibrating beam portions 21a and 21b extend from the first base portion 22 to the second base portion 23 along the extending direction of the movable portion 14 (along the Y axis). The shape of the vibrating beam portions 21a and 21b is, for example, a prismatic shape. When a driving signal (alternating voltage) is applied to excitation electrodes (not shown) provided on the vibrating beam portions 21a and 21b, the vibrating beam portions 21a and 21b are separated from or close to each other along the X axis. Can bend and vibrate.

  The base portions 22 and 23 are connected to both ends of the vibrating beam portions 21a and 21b. The first base portion 22 is fixed to the base portion 10 via the joining member 60 in the first portion 32 of the groove portion 30. The first base portion 22 is covered with the bottom surface and the side surface by the bonding member 60 in the groove portion 30. Further, the second base portion 23 is fixed to the movable portion 14 via a joining member 62 in the second portion 34 of the groove portion 30. The second base portion 23 is covered at the bottom surface and the side surfaces by the bonding member 62 in the groove portion 30. As shown in FIG. 3, the second base portion 23 is located between the movable portion 14 and the first mass body 50. That is, the second base portion 23 overlaps the first mass body 50 in plan view (as viewed from the Z-axis direction). In the illustrated example, the first mass body 50 is located above the second base portion 23 (+ Z axis direction). As described above, by providing the physical quantity detection element 20 in the groove 30, the first mass body 50 can be disposed so as to overlap the physical quantity detection element 20, and thus the size of the apparatus can be reduced.

  As the joining members 60 and 62, for example, a low melting point glass or an Au / Sn alloy film capable of eutectic joining can be used.

  In addition, when the movable part 14 is displaced, the vibrating beam parts 21a and 21b and the base 10 and the movable part 14 are not in contact with each other between the vibrating beam parts 21a and 21b and the base part 10 and the movable part 14. In addition, a predetermined gap is provided. This gap may be managed by the thickness of the joining members 60 and 62, for example.

  As described above, the physical quantity detection element 20 includes the two vibrating beam portions 21a and 21b and the pair of base portions 22 and 23. That is, the physical quantity detection element 20 is a double tuning fork element (a double tuning fork type vibration element). The physical quantity detection element 20 is formed, for example, by patterning a quartz substrate cut out from a raw quartz or the like at a predetermined angle by a photolithography technique and an etching technique. Thereby, the vibrating beam portions 21a and 21b and the base portions 22 and 23 can be integrally formed.

The material of the physical quantity detection element 20 is not limited to quartz, but lithium tantalate (LiTaO ₃ ), lithium tetraborate (Li ₂ B ₄ O ₇ ), lithium niobate (LiNbO ₃ ), titanate A piezoelectric material such as lead zirconate (PZT), zinc oxide (ZnO), aluminum nitride (AlN), or a semiconductor material such as silicon provided with a piezoelectric material such as zinc oxide (ZnO) or aluminum nitride (AlN) as a film. There may be. However, it is desirable that the physical quantity detection element 20 is the same as the material of the base 10 and the movable part 14 in consideration of reducing the difference between the linear expansion coefficients of the base 10 and the movable part 14.

  On the first base portion 22 of the physical quantity detection element 20, lead electrodes 44a and 44b are provided. The lead electrodes 44a and 44b are electrically connected to excitation electrodes (not shown) provided on the vibrating beam portions 21a and 21b.

  The lead electrodes 44a and 44b are electrically connected to connection terminals 46a and 46b provided on the main surface 10a of the base 10 by a metal wire 48 such as Au or Al. More specifically, the lead electrode 44a is electrically connected to the connection terminal 46a, and the lead electrode 44b is electrically connected to the connection terminal 46b. The connection terminals 46a and 46b are electrically connected to external connection terminals (not shown) by wiring (not shown).

  As the excitation electrode, the extraction electrodes 44a and 44b, the connection terminals 46a and 46b, and the external connection terminal, for example, a laminate in which a Cr layer is used as a base and an Au layer is stacked thereon is used. The excitation electrode, the extraction electrodes 44a and 44b, the connection terminals 46a and 46b, and the external connection terminal are formed by forming a conductive layer (not shown) by sputtering, for example, and patterning the conductive layer. .

  The first mass body 50 is fixed to the main surface 14 a of the movable portion 14 via a joining member 64. The first mass body 50 has a portion that overlaps the groove 30 in plan view (as viewed from the Z-axis direction). In the illustrated example, the physical quantity detection element 20 is positioned between the portion of the first mass body 50 that overlaps the groove portion 30 and the movable portion 14. That is, the first mass body 50 is disposed so as to overlap the physical quantity detection element 20. Therefore, the mass of the 1st mass body 50 can be enlarged, aiming at size reduction.

  The second mass body 52 is fixed to the main surface 14 b of the movable portion 14 via a joining member 66. Examples of the material of the mass bodies 50 and 52 include metals such as Cu and Au. The mass bodies 50 and 52 can improve the detection sensitivity of acceleration applied to the physical quantity detection device 100.

  As the joining members 64 and 66, for example, a silicone resin thermosetting adhesive can be used.

  Although not shown, the number of mass bodies is not limited. For example, a plurality of mass bodies may be provided on one main surface 14a, 14b of the movable portion 14.

  Next, the operation of the physical quantity detection device 100 will be described. 4 and 5 are cross-sectional views for explaining the operation of the physical quantity detection device 100. FIG.

  As shown in FIG. 4, in the physical quantity detection device 100, when acceleration α1 (for example, gravitational acceleration), which is a physical quantity to be measured in the −Z-axis direction, is applied, the movable part 14 supports the joint part 12 according to the acceleration α1. Thus, it is displaced in the -Z-axis direction. As a result, a force (tension) in the direction in which the first base portion 22 and the second base portion 23 are separated from each other along the Y axis is applied to the physical quantity detection element 20, and tensile stress is applied to the vibrating beam portions 21a and 21b. Arise. Therefore, the vibration frequency (resonance frequency) of the vibrating beam portions 21a and 21b is increased.

  On the other hand, as shown in FIG. 5, in the physical quantity detection device 100, when the acceleration α2 is applied in the + Z-axis direction, the movable portion 14 is displaced in the + Z-axis direction with the joint portion 12 as a fulcrum according to the acceleration α2. As a result, a force (compression force) in a direction in which the first base portion 22 and the second base portion 23 approach each other along the Y axis is applied to the physical quantity detection element 20, and a compressive stress is applied to the vibration beam portions 21a and 21b. Occurs. Therefore, the vibration frequency (resonance frequency) of the vibrating beam portions 21a and 21b is lowered.

  The physical quantity detection device 100 detects a change in the resonance frequency of the physical quantity detection element 20 as described above. Specifically, the acceleration applied to the physical quantity detection device 100 is derived by converting it into a numerical value determined by a look-up table or the like according to the detected change rate of the resonance frequency.

  When the physical quantity detection device 100 is used for an inclinometer, the direction in which the gravitational acceleration is applied to the inclinometer changes according to the change in the inclination posture, and tensile stress or compressive stress is applied to the vibrating beam portions 21a and 21b. Arise. Then, the resonance frequency of the vibrating beam portions 21a and 21b changes.

  In the above example, an example using a so-called twin tuning fork element as the physical quantity detection element 20 has been described. However, if the physical quantity can be detected based on the displacement of the movable portion 14, the form of the physical quantity detection element 20 is There is no particular limitation.

  The physical quantity detection device 100 according to the present embodiment has the following features, for example.

  In the physical quantity detection device 100, the physical quantity detection element 20 is disposed in a groove portion 30 provided in the base portion 10 and the movable portion 14. Thereby, the distance (distance in the Z-axis direction) between the physical quantity detection element 20 and the joint portion 12 (fulcrum) can be reduced. From the lever principle, the smaller the distance between the physical quantity detection element and the joint part (fulcrum when the movable part is displaced), the more necessary to obtain the force (tension or compression force) applied to the physical quantity detection element. Force (acceleration) decreases. That is, the smaller the distance between the physical quantity detection element and the joint portion, the higher the detection sensitivity. Therefore, according to the physical quantity detection device 100, since the distance between the physical quantity detection element 20 and the joint portion 12 (fulcrum) can be reduced, high detection sensitivity can be achieved.

  Furthermore, since the physical quantity detection element 20 is disposed in the groove portion 30, it is possible to increase detection sensitivity while suppressing a decrease in strength of the movable portion 14. Therefore, spurious generation can be suppressed and detection sensitivity can be increased. For example, when the distance between the physical quantity detection element and the fulcrum is reduced by reducing the thickness of the entire movable part, the strength of the movable part may be reduced and spurious may occur. On the other hand, in the physical quantity detection device 100, since the distance between the physical quantity detection element and the fulcrum is reduced by the groove part 30 provided in the movable part 14, the thickness of the entire movable part is reduced. In comparison, a decrease in strength can be suppressed and the occurrence of spurious can be suppressed.

  In the physical quantity detection device 100, the depth D of the groove 30 is equal to or greater than the thickness of the physical quantity detection element 20. Therefore, the physical quantity detection element 20 can be prevented from projecting from the main surface 14 a of the movable portion 14. Therefore, since the first mass body 50 can be disposed so as to overlap the physical quantity detection element 20, the mass of the first mass body 50 can be increased while reducing the size. Therefore, the detection sensitivity can be increased while reducing the size. For example, when the physical quantity detection element is arranged on the main surface of the movable part, the mass body has to be provided in a region avoiding the physical quantity detection element on the main surface of the movable part. In the physical quantity detection device 100, since the mass body 50 can be arranged so as to overlap the physical quantity detection element 20, the size of the apparatus can be reduced compared to the case where the mass body is provided in a region avoiding the physical quantity detection element on the main surface of the movable part. It is possible to increase the mass of the mass body while reducing the size.

  In the physical quantity detection device 100, the first mass body 50 has a portion that overlaps the groove 30 in plan view and is fixed to the base 10. The physical quantity detection element 20 is a portion that overlaps the groove 30 of the first mass 50. And the movable portion 14. That is, since the physical quantity detection element 20 and the first mass body 50 are disposed so as to overlap in the Z-axis direction, the mass of the first mass body 50 can be increased while achieving downsizing. Therefore, the detection sensitivity can be increased while reducing the size.

  In the physical quantity detection device 100, the joining member 60 joins the physical quantity detection element 20 and the base 10 in the groove 30. Thereby, the joining strength between the physical quantity detection element 20 and the base 10 can be increased. Further, the joining member 62 joins the physical quantity detection element 20 and the movable part 14 in the groove part 30. Thereby, the joining strength between the physical quantity detection element 20 and the movable part 14 can be increased.

2. Physical Quantity Detector Next, the physical quantity detector according to the present embodiment will be described with reference to the drawings. FIG. 6 is a plan view schematically showing the physical quantity detector 300 according to the present embodiment. FIG. 7 is a cross-sectional view schematically showing a physical quantity detector 300 according to this embodiment. 7 is a cross-sectional view taken along line VII-VII in FIG.

  As shown in FIGS. 6 and 7, the physical quantity detector 300 includes a physical quantity detection device according to the present invention and a package 310. Hereinafter, an example in which the physical quantity detection device 100 is used as a physical quantity detection device according to the present invention will be described.

  The package 310 contains the physical quantity detection device 100. The package 310 can have a package base 320 and a lid 330. In FIG. 6, the lid 330 is not shown for convenience.

  A recess 321 is formed in the package base 320, and the physical quantity detection device 100 is disposed in the recess 321. The planar shape of the package base 320 is not particularly limited as long as the physical quantity detection device 100 can be disposed in the recess 321. As the package base 320, for example, a material such as an aluminum oxide sintered body, crystal, glass, silicon, or the like obtained by forming, laminating and firing ceramic green sheets is used.

  The package base 320 can have a stepped portion 323 that protrudes from the inner bottom surface (bottom surface of the recess) 322 of the package base 320 to the lid 330 side. The step portion 323 is provided, for example, along the inner wall of the recess 321. Internal terminals 340 and 342 are provided on the stepped portion 323.

  The internal terminals 340 and 342 are provided at positions facing the external connection terminals 49a and 49b provided on the physical quantity detection device 100 (positions overlapping in plan view), for example. For example, the external connection terminal 49 a is electrically connected to the internal terminal 340, and the external connection terminal 49 b is electrically connected to the internal terminal 342.

  External terminals 344 and 346 used for mounting on an external member are provided on the outer bottom surface (surface opposite to the inner bottom surface 322) 324 of the package base 320. The external terminals 344 and 346 are electrically connected to the internal terminals 340 and 342 via internal wiring (not shown). For example, the external terminal 344 is electrically connected to the internal terminal 340, and the external terminal 346 is electrically connected to the internal terminal 342.

  The internal terminals 340 and 342 and the external terminals 344 and 346 are made of, for example, a metal film in which a film such as Ni or Au is laminated on a metallized layer such as W by plating.

  The package base 320 is provided with a sealing portion 350 that seals the inside (cavity) of the package 310 at the bottom of the recess 321. The sealing part 350 is disposed in a through hole 325 formed in the package base 320. The through hole 325 penetrates from the outer bottom surface 324 to the inner bottom surface 322. In the illustrated example, the through hole 325 has a stepped shape in which the hole diameter on the outer bottom surface 324 side is larger than the hole diameter on the inner bottom surface 322 side. The sealing portion 350 is formed by disposing a sealing material made of, for example, Au / Ge alloy or solder in the through hole 325, and solidifying after heating and melting. The sealing unit 350 is configured to hermetically seal the inside of the package 310.

  The physical quantity detection device 100 is fixed to the stepped portion 323 of the package base 320 via the joining member 341. Thereby, the physical quantity detection device 100 is mounted on the package base 320 and accommodated in the package 310.

  By fixing the physical quantity detection device 100 to the stepped portion 323, the external connection terminals 49a and 49b provided in the physical quantity detection device 100 and the internal terminals 340 and 342 provided in the stepped portion 323 connect the bonding member 341. Electrically connected. As the bonding member 341, for example, a silicone resin conductive adhesive mixed with a conductive material such as a metal filler can be used.

  The lid 330 is provided so as to cover the recess 321 of the package base 320. The shape of the lid 330 is, for example, a plate shape. As the lid 330, for example, the same material as the package base 320, or a metal such as Kovar, 42 alloy, stainless steel, or the like is used. The lid 330 is bonded to the package base 320 via a bonding member 332 such as a seam ring, low-melting glass, or adhesive.

  After the lid 330 is bonded to the package base 320, a sealing material is disposed in the through hole 325 in a state where the inside of the package 310 is decompressed (high vacuum state), and after heat melting, solidified and sealed. By forming the portion 350, the inside of the package 310 can be hermetically sealed. The interior of the package 310 may be filled with an inert gas such as nitrogen, helium, or argon.

  In the physical quantity detector 300, a drive signal is input to the excitation electrode of the physical quantity detection element 20 via the external terminals 344 and 346, the internal terminals 340 and 342, the external connection terminals 49a and 49b, the connection terminals 46a and 46b, and the like. Then, the vibrating beam portions 21a and 21b of the physical quantity detection element 20 vibrate (resonate) at a predetermined frequency. The physical quantity detector 300 can output, as an output signal, the resonance frequency of the physical quantity detection element 20 that changes according to the applied acceleration.

  The physical quantity detector 300 includes the physical quantity detection device 100 that can suppress the occurrence of spurious and can increase the detection sensitivity. Therefore, the physical quantity detector 300 can suppress the occurrence of spurious and increase the detection sensitivity.

  Although not illustrated, the concave portion in which the physical quantity detection device 100 is disposed may be formed in both the package base 320 and the lid 330, or may be formed only in the lid 330.

3. Next, an electronic device according to the present embodiment will be described. Hereinafter, an inclinometer including a physical detection device according to the present invention (physical quantity detection device 100 in the following example) as an electronic apparatus according to the present embodiment will be described with reference to the drawings. FIG. 8 is a perspective view schematically showing an inclinometer 400 according to the present embodiment.

  As shown in FIG. 8, the inclinometer 400 includes the physical quantity detection device 100 as an inclination sensor.

  The inclinometer 400 is installed at a place to be measured such as a mountain slope, a road slope, or a retaining wall of embankment, for example. The inclinometer 400 is supplied with power from the outside via a cable 410 or has a built-in power supply, and a drive signal is sent to the physical quantity detection device 100 by a drive circuit (not shown).

  Then, the inclinometer 400 changes the attitude of the inclinometer 400 (change in the direction in which the gravitational acceleration is applied to the inclinometer 400) from the resonance frequency that changes according to the gravitational acceleration applied to the physical quantity detection device 100 by a detection circuit (not shown). Is converted into an angle, and data is transferred to the base station by radio, for example. Thereby, the inclinometer 400 can contribute to the early detection of abnormality.

  The inclinometer 400 includes the physical quantity detection device 100 that can suppress the occurrence of spurious and can increase the detection sensitivity. Therefore, the inclinometer 400 can suppress the occurrence of spurious and increase the detection sensitivity.

  The physical quantity detection device according to the present invention is not limited to the inclinometer, but can be suitably used as an acceleration sensor, an inclination sensor, etc. for a seismometer, a navigation device, an attitude control device, a game controller, a mobile phone, etc. Even in this case, it is possible to provide an electronic apparatus that exhibits the effects described in the embodiment and the modification.

  The present invention includes configurations that are substantially the same as the configurations described in the embodiments (for example, configurations that have the same functions, methods, and results, or configurations that have the same objects and effects). In addition, the invention includes a configuration in which a non-essential part of the configuration described in the embodiment is replaced. In addition, the present invention includes a configuration that exhibits the same operational effects as the configuration described in the embodiment or a configuration that can achieve the same object. Further, the invention includes a configuration in which a known technique is added to the configuration described in the embodiment.

α1 ... acceleration, α2 ... acceleration, 10 ... base, 10a ... main surface, 12 ... joint portion, 14 ... movable portion, 14a, 14b ... main surface, 20 ... physical quantity detection element, 21a ... vibrating beam portion, 22 ... first Base part, 23 ... second base part, 30 ... groove part, 32 ... first part, 34 ... second part, 44a ... electrode, 44b ... electrode, 46a, 46b ... connection terminal, 48 ... metal wire, 49a ... external connection Terminals 49b ... External connection terminals 50 ... First mass body 52 ... Second mass body 60, 62, 64, 66 ... Joining member 100 ... Physical quantity detection device 300 ... Physical quantity detector 310 ... Package 320 ... Package base, 321 ... Recess, 322 ... Inner bottom, 323 ... Step, 324 ... Outer bottom, 325 ... Through hole, 330 ... Lid, 332 ... Joint member, 340 ... Internal terminal, 341 ... Joint member, 342 ... Internal terminal, 344 ... External terminal, 346 ... External terminal, 350 ... Sealing part, 400 ... Inclinometer, 410 ... Cable

Claims (8)

The base,
A movable portion that is provided on the base portion via a joint portion, and is displaced according to a physical quantity;
A physical quantity detection element spanned from the base portion to the movable portion in plan view in the displacement direction;
Including
The physical quantity detection device is a physical quantity detection device arranged in a groove provided in the base and the movable part. In claim 1,
The depth of the said groove part is a physical quantity detection device which is more than the thickness of the said physical quantity detection element. In claim 2,
A mass body that has a portion that overlaps the groove portion of the movable portion in plan view in the displacement direction and is fixed to the movable portion;
The physical quantity detection device is a physical quantity detection device that is positioned between a portion of the mass body that overlaps the groove and the movable portion. In any one of Claims 1 thru | or 3,
Including a first joining member provided in the groove of the base,
The first joining member is a physical quantity detection device that joins the physical quantity detection element and the base. In any one of Claims 1 thru | or 4,
Including a second joining member provided in the groove of the movable part;
The second joining member is a physical quantity detection device that joins the physical quantity detection element and the movable part. In any one of Claims 1 thru | or 5,
The physical quantity detection device is a physical quantity detection device which is a double tuning fork type vibration element. The physical quantity detection device according to any one of claims 1 to 6,
A package containing the physical quantity detection device;
Including a physical quantity detector.   An electronic apparatus comprising the physical quantity detection device according to claim 1.

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