JP4281708B2 - Vibrating gyroscope - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To enable to detect a rotation angular velocity with a high sensitivity, without making a projection section of a fixed weight toward a rotation axis direction from a vibrator, when the vibrator is installed, a vibration arm of the vibrator is to be perpendicularly extended to the rotation axis. <P>SOLUTION: The main arm of 101A of the vibrator 2 consists of a base part 3 and at least one set of the inflection vibrator pieces 4A, 4B extending in the direction of crossing a length direction of the base part 3 from the base part 3. The base part 3 and the inflection vibrator pieces 4A, 4B are formed substantially to be extended in a predetermined plane X-Y. One edge part 3a of the base part 3 of the vibrator 2 is fixed. The vibrator 2 rotates on a Z-axis. The vibrator 2 is vibrated like an arrow head D on a fixed portion 26, the inflection vibrator pieces 4A, 4B are vibrating inflectionally like the arrow head A on a connection part 25. <P>COPYRIGHT: (C)2005,JPO&amp;NCIPI

Description

  The present invention relates to a vibrating gyroscope used for detecting a rotational angular velocity in a rotating system.

  Conventionally, as an angular velocity sensor for detecting a rotational angular velocity in a rotating system, a vibratory gyroscope using a piezoelectric body has been used for confirming the position of an aircraft, a ship, a space satellite, or the like. Recently, it is used as a consumer field for car navigation, detection of camera shake of a VTR or a still camera, and the like.

Such a piezoelectric vibrating gyroscope utilizes the fact that when an angular velocity is applied to a vibrating object, a Coriolis force is generated in a direction perpendicular to the vibration. And the principle is analyzed with a mechanical model (for example, refer nonpatent literature 1). Various piezoelectric vibratory gyroscopes have been proposed so far. For example, Sperry tuning fork type gyroscope, Watson tuning fork type gyroscope, equilateral triangular prism type piece gyroscope, cylindrical type piece gyroscope, etc. are known.
“Acoustic wave device technology handbook”, Ohm, pp. 491-497

  The present inventor has been studying various applications of the vibration type gyroscope. For example, the present inventor has examined the use of the vibration type gyroscope as a rotation speed sensor used in a vehicle control method of a vehicle body rotation speed feedback type of an automobile. In such a system, the direction of the steering wheel itself is detected by the rotation angle of the steering wheel. At the same time, the rotational speed at which the vehicle body is actually rotating is detected by the vibration gyroscope. Then, the direction of the steering wheel is compared with the actual rotational speed of the vehicle body to obtain a difference, and based on this difference, correction is made to the wheel torque and the steering angle, thereby realizing stable vehicle body control.

However, in any of the above-described conventional piezoelectric vibration type gyroscopes, the rotational angular velocity cannot be detected unless the vibrator is arranged in parallel with the rotation axis (so-called vertical placement). However, usually, the rotation axis of the rotating system to be measured is perpendicular to the mounting portion. Therefore, when mounting such a piezoelectric vibration type gyroscope, it is possible to achieve a low profile of the piezoelectric vibration type gyroscope, that is, to reduce the size of the vibration type gyroscope when viewed in the direction of the rotation axis. could not.

In recent years, a piezoelectric vibrating gyroscope that can detect the rotational angular velocity even when the vibrator is arranged perpendicular to the rotation axis (so-called horizontal placement) has been proposed in Japanese Patent Laid-Open No. 8-128833. In this example, as shown in FIG. 23 as an example, the vibrator extends in the X and Y directions and extends perpendicular to the rotation axis Z. A weight 53 is provided at the tip of the three elastic bodies 51a, 51b, 51c. The elastic bodies 51a, 51b, 51c are vibrated in opposite phases with each other by the piezoelectric elements 54, 55 in the XY plane. The Coriolis force in the Y direction generated by the rotational angular velocity ω around the Z axis is applied to the position of the center of gravity of the weight 53. Since the surfaces of the elastic bodies 51a, 51b and 51c and the position of the center of gravity of the weight 53 are slightly separated in the Z direction, the tips of the elastic bodies 51a, 51b and 51c are moved in the Z direction by Coriolis force acting on the center of gravity of the weight 53. Turn in opposite directions. By detecting this bending vibration with the piezoelectric elements 56 and 57, the rotational angular velocity ω about the Z axis is obtained.

In the piezoelectric vibration type gyroscope described in Japanese Patent Laid-Open No. 8-128833 described above, the rotational angular velocity can be detected even if the vibrator is placed horizontally in principle. However, since it is necessary to provide the weight 53, the height reduction is insufficient. In addition, if the thickness of the weight 53 is reduced in order to sufficiently reduce the height, the moment due to the Coriolis force is reduced accordingly, bending vibration becomes minute, and the measurement sensitivity is lowered.

An object of the present invention is to provide a protrusion with a constant weight from the vibrator toward the rotation axis even when the vibrator is installed so that the vibration arm of the vibrator extends in a direction perpendicular to the rotation axis. Without being able to detect the rotational angular velocity with sufficiently high sensitivity.

Vibratory gyroscope of the present invention comprises a vibrator that rotates around the rotation shaft by the rotation to be detected, a vibratory gyroscope for detecting a turning angular rate around the rotating shaft, wherein the transducer is, (i) a fixed portion, (ii) formed on said rotary shaft and a plane perpendicular, and first and second base, (iii) the first base portion connected to the fixed part And the second base portion, and the fixed portion, a flexural vibration piece surrounding the space together with the first and second base portions, and (iv) attached to the fixed portion, and in the plane And a bending vibration piece for detection that bends and vibrates in response to vibrations of the first and second bases , (v) excitation means for bending vibration of the bending vibration piece, and (vi) the bending vibration piece. when There are vibrated by the excitation means, or of the rotary shaft By the Coriolis force generated by rotation of the vibrator Ri, the first, the vibration of the second base is vibrated, the first, the detecting bending-vibration pieces produced in response to the vibration of the second base, a detecting means provided to detect, it is characterized in that it comprises a.

According to the present invention, the drive vibration of the vibrator and the vibration for detection are performed in a predetermined plane, and the flexural vibration is used as the vibration to be detected, thereby rotating the vibrator arm of the vibrator. Even when the vibrator is installed so as to extend in a direction perpendicular to the axis, the rotational angular velocity can be detected with sufficiently high sensitivity without providing a protrusion having a constant weight from the vibrator toward the rotation axis. It became so.

In a preferred aspect of the present invention, a fixed piece part having both ends fixed is used as the fixed part, a main arm is provided on one side of the fixed piece part, and the other side of the fixed piece part is provided. A resonance piece is provided, and the fixed piece portion, the main arm, and the resonance piece are formed so as to extend substantially in the predetermined plane. That is, the excitation means and the bending vibration detection means can be provided at a position via the fixed piece portion with both ends fixed. This can prevent adverse effects such as electromechanical mixing between the excitation means and the bending vibration detection means, thereby further improving detection accuracy.

  According to the vibratory gyroscope of the present invention, even when the vibrator is installed so that the vibratory arm of the vibrator extends in a direction perpendicular to the rotation axis, the weight is constant from the vibrator toward the rotation axis. The rotational angular velocity can be detected with sufficiently high sensitivity without providing the protruding portion.

In the above configuration, since the displacement of the vibrator is within one plane, the main arm, the resonance arm, the resonance piece, and the fixed piece portion are made of the same single crystal, for example, quartz, LiTaO ₃ single crystal, LiNbO ₃ single crystal. Can be configured. In this case, measurement sensitivity can be improved. By producing a single crystal thin plate and processing this single crystal thin plate by etching and grinding, the entire vibrator can be produced.

The base and the flexural vibration piece can be configured as separate members, but it is particularly preferable to configure the base and the flexural vibration piece integrally. The material of the vibrator is not particularly limited, but a single crystal made of quartz, LiNbO ₃ , LiTaO ₃ , lithium niobate-lithium tantalate solid solution (Li (Nb, Ta) O ₃ ) single crystal, or the like is used. It is preferable. When such a single crystal is used, detection sensitivity can be improved and detection noise can be reduced.

And since it is especially insensitive to a temperature change, it is suitable for the vehicle-mounted use which requires temperature stability. This point will be further described. As an angular velocity sensor using a tuning fork type vibrator, for example, there is a piezoelectric vibration type gyroscope described in JP-A-8-128833 described above. However, in such a vibrator, the vibrator vibrates in two directions. That is, in FIG. 23, the vibrator vibrates in the XY plane and also vibrates in the Z direction. For this reason, when the vibrator is formed of a single crystal as described above, it is necessary to match the characteristics of the single crystal in two directions. However, in reality, the piezoelectric single crystal has anisotropy.

In general, a piezoelectric vibration type gyroscope is required to maintain a certain vibration frequency difference between the natural resonance frequency of the driving vibration mode and the natural resonance frequency of the detection vibration mode in order to improve measurement sensitivity. ing. However, the single crystal has anisotropy, and when the crystal plane changes, the degree of temperature change of the vibration frequency differs. For example, when cutting along a specific crystal plane, there is almost no change in temperature of the vibration frequency, but when cutting along another crystal plane, the vibration frequency responds sensitively to temperature change.

Here, when the vibrator vibrates in two directions, at least one of the two vibration surfaces becomes a crystal surface having a large temperature change of vibration frequency.

On the other hand, as in the present invention, the entire vibrator is vibrated in a predetermined plane, and the vibrator is formed of a piezoelectric single crystal, thereby being affected by the anisotropy of the single crystal. As a result, only the crystal plane with the best characteristics of the single crystal can be used in the vibrator.

Specifically, because the vibration of the vibrator is all performed within a single plane, the vibrator is manufactured using only the crystal plane of the piezoelectric single crystal that has almost no change in temperature of the vibration frequency. Can do. As a result, a vibratory gyroscope with extremely high temperature stability can be provided.

Among the single crystals described above, the LiNbO ₃ single crystal, the LiTaO ₃ single crystal, and the lithium niobate-lithium tantalate solid solution single crystal have particularly large electromechanical coupling coefficients. Further, when comparing the LiNbO ₃ single crystal and the LiTaO ₃ single crystal, the LiTaO ₃ single crystal has a larger electromechanical coupling coefficient and a better temperature stability than the LiNbO ₃ single crystal.

Hereinafter, preferred embodiments of the present invention will be further described with reference to the drawings. FIG. 1 is a front view showing a vibrator according to an embodiment of the present invention. FIG. 2A is a front view for explaining a vibration direction of a linear vibrator, and FIG. ) Is a front view for explaining the driving direction of the vibrator of FIG. 1. FIGS. 3A, 3 </ b> B, and 3 </ b> C are vibration directions and vibration directions of each part of the vibrator of FIG. 1. It is a schematic diagram for demonstrating a principle.

In the main arm 101 </ b> A of the vibrator 2 of FIG. 1, the base 3 extends vertically from the fixed portion 1, and one end 3 a of the base 3 is fixed to the fixed portion 1. Predetermined excitation means 5A and 5B are provided in the base 3. Two bending vibration pieces 4 </ b> A and 4 </ b> B extending in a direction perpendicular to the base 3 are provided on the other end 3 b side of the base 3.

The vibration mode of the vibrator 2 will be described. As schematically shown in FIG. 3A, a drive voltage is applied to the excitation means 5A and 5B, and the base 3 is bent in the direction of the arrow H around the connection portion 26 with the fixing member 1. Let Along with this bending, not only the base 3 of the vibrator 2 but also each point of each bending vibration piece 4A, 4B moves as indicated by an arrow I. Let V be the vector of the speed of this movement.

In the present embodiment, the Z axis is the rotation axis, and the vibrator 2 is rotated about the z axis. For example, when the vibrator 2 is displaced in the direction of the arrow H and the whole vibrator 2 rotates about the Z axis as shown by w, a Coriolis force acts as shown by the arrow J. As a result, as shown in FIG. 3B, each bending vibration piece 4 </ b> A, 4 </ b> B bends in the direction of arrow J around the connection portion 25 with the other end 3 b of the base 3.

On the contrary, as shown in FIG. 3C, when the base 3 is driven as indicated by an arrow K, as shown by w, the entire vibrator 2 rotates about the Z axis. Coriolis force acts as indicated by L. As a result, each of the bending vibration pieces 4A and 4B is bent in the direction of the arrow L around the connection portion 25 with the other end 3b of the base portion 3. Accordingly, the bending vibration pieces 4A and 4B can be vibrated as indicated by arrows A and B.

As described above, the Coriolis force generated in the XY plane in each of the flexural vibration pieces 4A and 4B due to the flexural vibration of the base portion 3 is converted into the flexural vibration about the connection portion 25 of each of the flexural vibration pieces 4A and 4B. The rotational angular velocity can be obtained from the bending vibration. Thereby, even if the vibrator is arranged perpendicularly to the rotation axis Z (sideways), the rotational angular velocity can be detected with high sensitivity.

The sensitivity of detection by the vibrator 2 shown in FIGS. 1 and 3 will be further described. As shown in FIG. 2A, the present inventor used elongated rod-like vibrators 8A and 8B, installed the vibrator 8B in the XY plane, and expanded and contracted it. However, 8A shows a state where the vibrator is extended, and 8B shows a state where the vibrator is contracted. Here, consider the moment when the vibrator is about to extend from the state of 8B to the state of 8A as indicated by an arrow E. When the vibrator 8B is rotated around the Z axis, a Coriolis force is applied as indicated by an arrow F. However, since the displacement due to the longitudinal vibration of the piezoelectric body is small and the resonance frequency is low, the sensitivity cannot be increased.

On the other hand, in the present invention, as shown in FIG. 2B, the base 3 is vibrated as indicated by an arrow G, whereby the flexural vibration pieces 4A and 4B are vibrated as indicated by an arrow D. As a result, a much larger amplitude and vibration speed can be obtained than in the case of FIG. 2A, and the Coriolis force can be increased.

Further, when the vibrator of FIGS. 1 and 3 is used, bending vibrations as indicated by arrows A and B can be excited with respect to the bending vibration pieces 4A and 4B. When the vibrator 2 rotates in the XY plane, a Coriolis force is applied to each bending vibration piece, and a Coriolis force of each bending vibration piece is applied to the base 3. As a result, the base 3 bends and vibrates as indicated by an arrow G around the connecting portion 26. The bending vibration of the base portion 3 can be detected, and a signal corresponding to the detected bending vibration can be output.

When the vibrator is formed of a piezoelectric single crystal, electrodes are used as the excitation means and detection means 5A, 5B, 6A, 6B, 6C, and 6D. However, the vibrator can be formed of an elastic material, and in this case, a piezoelectric body provided with electrodes can be used as the excitation means and detection means 5A, 5B, 6A, 6B, 6C, and 6D. If there is one of the excitation means (or detection means) 5A and 5B, at least excitation or detection can be performed. If there is one of the detection means (or excitation means) 6A, 6B, 6C, 6D, at least excitation (or detection) can be performed.

4 to 6, the main arm is provided on one side of the fixed piece portion whose both ends are fixed, the resonance piece is provided on the other side of the fixed piece portion, and the fixed piece portion and the main arm are provided. And the resonator element is formed so as to extend substantially in a predetermined plane.

In the embodiment of FIG. 4, the excitation piece side and the detection means side are separated by the fixed piece 12. Specifically, both ends of the fixed piece portion 12 are fixed by the fixing member 11. A main arm 101B is provided on one side of the fixed piece 12. The main arm 101 </ b> B includes an elongated base portion 16 and two bending vibration pieces 4 </ b> A and 4 </ b> B extending from the end portion 16 b of the base portion 16 in a direction orthogonal to the length direction of the base portion 16.

A resonance piece 32 is provided on the other side of the fixed piece portion 12. The resonance piece 32 includes a rectangular support portion 13 extending in the vertical direction from the fixed piece portion 12, and predetermined excitation means 5 </ b> A and 5 </ b> B are provided in the support portion 13. Two vibrating pieces 15 </ b> A and 15 </ b> B extending in a direction perpendicular to the support portion 13 are provided on the other end portion 13 b side of the support portion 13. The end portion 16 a of the base portion 16 and the end portion 13 a of the resonance piece 13 are continuous with the fixed piece portion 12. As described above, both sides of the fixed piece portion 12 have a substantially line-symmetric shape.

The vibration mode of the vibrator 10 will be described. A drive voltage is applied to the excitation means 5A and 5B, and the resonance piece 13 and the pair of vibration pieces 15A and 15B are vibrated as indicated by an arrow M around the connection portion 27 with the fixed piece portion 12. Due to the resonance with respect to the vibration, the base portion 16 and the pair of bending vibration pieces 4A and 4B vibrate as indicated by an arrow D around the connection portion 26 with the fixing member 12.

When the entire vibrator 10 rotates about the rotation axis Z, the Coriolis force acts on the bending vibration pieces 4A and 4B as described above. As a result, each of the bending vibration pieces 4A and 4B vibrates as indicated by arrows A and B around the connection portion 25, respectively.

As described above, the Coriolis force generated in the XY plane in each of the bending vibration pieces 4A and 4B due to the bending vibration of the resonance piece 32 causes the bending vibration about the connection portion 25 of each of the bending vibration pieces 4A and 4B. The rotational angular velocity can be obtained from the bending vibration. Thereby, even if the vibrator is arranged perpendicularly to the rotation axis Z (sideways), the rotational angular velocity can be detected with high sensitivity.

In the embodiment of FIG. 4, in the vibrator 10, the form of the resonance piece 32 and the form of the main arm 101 </ b> B are axisymmetric with respect to the fixed piece portion 12, thereby each of the resonance piece and the main arm. The natural resonance frequency of the vibration mode was matched. However, the form on the side of the resonance piece 32 and the form of the main arm are not necessarily symmetrical with respect to the fixed piece portion 12.

In the vibrator 20 shown in FIG. 5, the form of the main arm 101B including the base 16, the pair of bending vibration pieces 4A and 4B, and the form of the fixed piece 12 are the same as those shown in FIG. Omitted. An elongated rectangular resonance piece 21 extends from the fixed piece 12 in the vertical direction. Excitation means 5A and 5B are provided in the vicinity of the end 21a of the resonance piece 21 on the fixed piece 12 side.

A drive voltage is applied to the excitation means 5A, 5B, and the resonance piece 21 is vibrated as indicated by an arrow M around the connection portion 27 with the fixed piece portion 12. Due to the resonance with respect to the vibration, the base portion 16 and the pair of bending vibration pieces 4A and 4B vibrate as indicated by an arrow D around the connection portion 26 with the fixing member 11.

Thus, by making the resonance piece 21 into an elongated rectangle, the overall structure of the vibrator is simplified as compared with the embodiment of FIG. However, it is necessary to make adjustments so that the moments on both sides are substantially the same so that the difference between the vibration frequency on the excitation side of the fixed piece 12 and the vibration frequency on the detection side does not increase. From this viewpoint, when the resonator element 21 of FIG. 5 is compared with the resonator element 32 of FIG. 4, the resonator elements 15 </ b> A and 15 </ b> B are not present and their mass is not present in FIG. 5. Accordingly, the projecting dimension of the tip 21b of the resonant piece 21 from the fixed piece 12 is made larger than the dimension of the projecting part of the resonant piece 32 from the fixed piece 12, that is, the mass of the resonant piece 21 is set to the support part 13. It is necessary to make it larger than the mass. For this reason, the protrusion dimension from the fixed piece part 12 of the resonance piece 21 tends to increase.

In the vibrator 22 shown in FIG. 6, the form of the base 16, the main arm 101B including the pair of bending vibration pieces 4A and 4B, and the form of the fixed piece 12 are the same as those shown in FIG. Omitted. A resonance piece 31 is provided on the fixed piece. The resonance piece 31 includes a rectangular support portion 30 extending in the vertical direction from the fixed piece portion 12, and excitation means 5 </ b> A and 5 </ b> B are provided on the support portion 30. A wide rectangular extension portion 23 is formed on the distal end side of the support portion 30.

A drive voltage is applied to the excitation means 5A and 5B, and the resonance piece 31 is vibrated as indicated by an arrow M around the connection portion 27 with the fixed piece portion 12. Due to the resonance with respect to the vibration, the base portion 16 and the pair of bending vibration pieces 4A and 4B vibrate as indicated by an arrow D around the connection portion 26 with the fixing member 11.

By providing the extension portion 23 in the resonance piece 31 in this way, the projecting dimension of the resonance piece 31 from the fixed piece portion 12 can be reduced, and the vibration frequency of the resonance piece 31 is set to the base 16 and the bending vibration piece. The vibration frequency on the 4A, 4B side can be approached.

In each vibrator of the present invention, the longitudinal direction of the flexural vibration piece and the longitudinal direction of the base portion do not necessarily have to be at right angles. Further, the shape of the bending vibration piece may be a straight line or a curved line. However, when a pair of bending vibration pieces are provided, it is preferable that both of them are line symmetric with respect to the base.

In the main arm 101 </ b> C of the vibrator 40 of FIG. 7, the bending vibration pieces 33 </ b> A and 33 </ b> B intersect with the direction in which the base 3 extends with a predetermined angle θ. The crossing angle θ is not a right angle, but is preferably 45 ° to 135 °, particularly preferably 70-100 °. As a result, the natural resonance frequencies of the vibration modes N and P of the bending vibration pieces 33A and 33B slightly change compared to the natural resonance frequency of the vibration mode of the bending vibration piece in the vibrator shown in FIG.

In the main arm 101D of the vibrator 41 of FIG. 8, each of the bending vibration pieces 34A and 34B has an arcuate shape that is slightly curved. As a result, the natural resonance frequencies of the vibration modes Q and R of the bending vibration pieces 34A and 34B slightly change with respect to the vibrators shown in FIGS. The configurations shown in FIGS. 7 and 8 can also be adopted in the vibrators shown in FIGS. 4, 5, and 6.

In general, a piezoelectric vibration type gyroscope is required to maintain a certain vibration frequency difference between the natural resonance frequency of the driving vibration mode and the natural resonance frequency of the detection vibration mode in order to improve measurement sensitivity. ing. In each vibrator according to the present invention, when the natural resonance frequency of the vibration mode of the base portion and the natural resonance frequency of the vibration mode of the bending vibration piece are close to each other, the sensitivity is improved, but the response speed is deteriorated. When the difference between the natural resonance frequency of the vibration mode of the base portion and the natural resonance frequency of the vibration mode of the flexural vibration piece is increased, the response speed is improved, but the sensitivity is deteriorated.

For this reason, the natural resonance frequency of the vibration mode of the bending vibration piece can be changed by removing the mass on the tip side of the bending vibration piece. Further, by providing a protruding portion that protrudes from the bending vibration piece on the side opposite to the fixed end portion of the base portion, and removing the mass of this protruding portion, the natural resonance frequency of the vibration mode of the base portion can be changed.

For example, in the main arm 101E of the vibrator 42 in FIG. 9, a protruding portion 35 protruding from the bending vibration pieces 4A and 4B is provided on the other end 3b side of the base portion 3. Then, the natural resonance frequency of the vibration mode of the vibration D of the base is changed by performing processing for removing the mass from the portion 37 of the protruding portion 35. In addition, by performing a process of removing mass from each of the distal ends 36A and 36B of the bending vibration pieces 4A and 4B, the natural resonance frequencies of the vibration modes of the bending vibration pieces A and B can be independently set. Can be changed. This removal process can be performed by laser irradiation or machining.

Next, an aspect in which the vibrator according to the present invention includes at least a pair of resonance arms that resonate with respect to the vibration of the base portion and that protrudes from the fixed portion will be described.

As shown in FIGS. 1 to 9, the vibration type gyroscope using the bending vibration of the bending vibration piece of the main arm or its resonance piece has a conventional structure when a vibrator extending perpendicular to the rotating system is used. High sensitivity could be achieved. However, as a result of further studies by the present inventors, it has been found that the following problems still remain. That is, since the main arm composed of the flexural vibration piece and the base portion protrudes from the fixed portion, for example, the flexural vibration of the flexural vibration piece is used as the drive vibration, and the flexural vibration around the base fixed portion is detected. In this case, since the vibration of the base is easily damped relatively early, it has been found that there is still room for improvement in the Q value of the detected vibration.

As a result of investigations to solve this problem, the present inventor has conceived that at least a pair of resonance arms is projected together with the base portion from the fixed portion, and the resonance arms are caused to resonate with respect to the vibration of the base portion. In this case, the vibration of the resonance arm and the base can be used as the drive vibration, but it is more preferable to use the vibration of the resonance arm and the base as the detection vibration. This is because the detection vibration that bears the gyro signal has a much smaller amplitude than the driving vibration, and thus the effect of improving the Q value is greater.

10 to 12 show the vibratory gyroscope of each embodiment according to this aspect.

In the vibrator 44 of the vibration gyroscope 43 of FIG. 10, the main arm 101F protrudes from the fixed portion 1, and a pair of resonance arms 48A and 48B protrude from both sides of the main arm 101F. The base portion 3 protrudes from the fixed portion 1, and bending vibration pieces 45 </ b> A and 45 </ b> B extending perpendicularly to the base portion 3 are formed on the end portion 3 b side of the base portion 3, and mass portions are formed at the ends of the bending vibration pieces 45 </ b> A and 45 </ b> B. 47A and 47B are formed. Excitation means (detection means) 46A, 46B, 46C, and 46D are provided in the bending vibration pieces 45A and 45B, respectively.

Resonant arms 48A and 48B protruding from the fixed portion 1 are provided with detection means (excitation means) 49A, 49B, 49C and 49D, respectively, and mass parts 50A and 50B are provided at the tips of the respective resonance arms. It has been.

A suitable vibration mode at this time will be described with reference to FIGS. As described above, the bending vibration pieces 45A and 45B are excited to bend and vibrate as indicated by the arrow S shown in FIG. When the entire vibrator is rotated as described above, a Coriolis force acts as shown by an arrow T. There are a plurality of vibrations excited by the Coriolis force on the base and the pair of resonance arms.

FIG. 11B shows the secondary vibration. In this case, the base 3 and each of the resonance arms 48A and 48B bend and vibrate in opposite phases, and at the same time, the bending vibration pieces 45A and 45B vibrate so as to deviate from the straight line 58. FIG. 11C shows the primary vibration. In this case, the base 3 and each of the resonance arms 48A and 48B bend and vibrate in opposite phases, and at the same time, the bending vibration pieces 45A and 45B vibrate so as to deviate from the straight line 58. In the case of the primary vibration and the case of the secondary vibration, the directions of vibration of the bending vibration pieces 45A and 45B are in opposite phases.

Here, either the primary vibration or the secondary vibration may be used as the detection vibration, but it is necessary to select the difference between the natural resonance frequency of the drive vibration and the natural resonance frequency of the detection vibration within a certain range. is there.

In the vibrator 60A of the vibration gyroscope 59A of FIG. 12, the main arm 101G protrudes from the fixed portion 1, the base portion 3 protrudes from the fixed portion 1, and the base portion 3 faces the end portion 3b side with respect to the base portion 3. Bending vibration pieces 61A and 61B extending vertically are formed. Since there is no portion corresponding to the mass portions 47A and 47B, it is necessary to lengthen each bending vibration piece accordingly. Excitation means (detection means) 46A, 46B, 46C, and 46D are provided in the bending vibration pieces 61A and 61B, respectively.

A pair of resonance arms 62A and 62B protrude from the fixed portion 1, and detection means (excitation means) 49A, 49B, 49C, and 49D are provided on each resonance arm.

In the present invention, when the resonance arm is used, the resonance resonance of the so-called spurious mode vibration is made by changing the protrusion dimensions from the fixed portions on both sides of the resonance arm at the protrusion position of the resonance arm from the fixed portion. The frequency can be varied. This embodiment will be described with reference to the vibration type gyroscope 59B of FIGS.

In the vibrator 60B, the main arm 101H protrudes from the protruding portion 1a of the fixed portion 1. That is, the base 3 protrudes, and bending vibration pieces 61 </ b> A and 61 </ b> B extending perpendicularly to the base 3 are formed on the end 3 b side of the base 3. Drive electrodes 46A, 46B, 46C, and 46D are provided on the bending vibration pieces 61A and 61B. A pair of resonance arms 63A and 63B protrude from the fixed portion 1, and detection electrodes 49A, 49B, 49C and 49D are provided on the resonance arms, respectively.

In the perspective view of FIG. 14, the form of the drive electrode and the form of the detection electrode are shown as cross-sectional views.

Here, a notch 74 having a dimension “a” is provided on the outside of each resonance arm, whereby the protruding portion 1 a having a height “a” protrudes from the fixed portion 1. As a result, the natural resonance frequency of the spurious mode vibration can be separated from the natural resonance frequency of the drive vibration.

For example, in the vibrator shown in FIG. 13, when the bending vibrations of the bending vibration pieces 61A and 61B are set as drive vibrations and the natural resonance frequency thereof is adjusted to 8750 Hz, the resonance arms 63A and 63B indicated by arrows U in FIG. The anti-bending bending vibration of the above becomes spurious mode vibration. The natural resonance frequency of this vibration is 8700 Hz as shown in FIG. 15 when a = 0 as shown in FIG. As a result, the difference between the natural resonance frequency of the drive vibration and the natural resonance frequency of the spurious mode is 50 Hz, so that the signal generated by the anti-phase vibration of the resonance arm is very large compared to the gyro signal.

However, as shown in FIG. 15, the natural resonance frequency of the spurious mode changed significantly as the dimension a was increased. In particular, by setting a to 1.0 mm or more, the natural resonance frequency of the spurious mode can be greatly deviated from the natural resonance frequency of the drive vibration.

As described above, in the projecting position of the resonance arm from the fixed part, it is effective to reduce the noise due to the influence of the spurious mode vibration by making the projecting dimensions from the fixed part on both sides of the resonant arm different, For this purpose, it is particularly preferable that a is 1.0 mm or more. This is preferably 6.0 mm or less.

In the vibratory gyroscope of each embodiment described above, in the case where the vibrator is formed of a piezoelectric single crystal, by applying a voltage in a direction perpendicular to the paper surface, each bending vibrator piece, The base or the resonance arm is bent and vibrated. Such a bending vibration system of the arm is particularly useful in the case of, for example, lithium niobate, lithium tantalate, lithium niobate-lithium tantalate solid solution single crystal.

However, as described above, the vibrators of the embodiments of FIGS. 1 to 14 can be applied to other piezoelectric single crystals such as quartz while adopting exactly the same drive vibration and detection vibration modes. It is. However, in this case, since the direction of the effective piezoelectric axis in the piezoelectric single crystal is different from that in the case of lithium niobate or the like, in order to be able to use the effective piezoelectric axis for bending vibration, It is necessary to appropriately change each form of the detection electrode.

In each of FIGS. 16 to 18, a vibrator is formed using a piezoelectric single crystal having a three-fold symmetry axis (a-axis) in a predetermined plane like quartz, and the c-axis is predetermined. The vibration type gyroscope of a particularly preferred embodiment is shown in the case where the direction is perpendicular to the plane.

In this aspect, it is preferable that the voltage application direction in the bending vibration piece and the signal voltage direction in the resonance arm are respectively directed to the a-axis. 16 and 17 relate to this embodiment.

In the vibrator 60C of the vibratory gyroscope 59C of FIG. 16, the main arm 101I or the base part 3 protrudes from the fixed part 1, and the bending vibration piece 64A extends perpendicularly to the base part 3 on the end part 3b side of the base part 3. 64B is formed. Drive electrodes 65A and 65B are provided on the bending vibration pieces 64A and 64B, respectively. The form of the drive electrode is as shown in the A-A ′ cross-sectional view. The drive electrode 65 </ b> A is grounded, and the drive electrode 65 </ b> B is connected to the AC power source 68. As a result, in the bending vibration pieces 64A and 64B, a voltage is applied in the a-axis direction, and bending vibration occurs.

The longitudinal direction of each of the pair of resonance arms 66A and 66B is inclined 120 ° with respect to the bending vibration pieces 64A and 64B. The forms of the detection electrodes 67A and 67B in the resonance arms 66A and 66B are the same as the forms of the drive electrodes 65A and 65B. As a result, a voltage is also applied in the a-axis direction in the resonance arms 66A and 66B. Therefore, the piezoelectric constant used in the bending vibration piece and the piezoelectric constant used in the resonance arm are both high and approximately the same.

In the vibrator 60D of the vibratory gyroscope 59D of FIG. 17, the main arm 101J or the base 3 protrudes from the protrusion 1a of the fixed part 1, and is inclined 120 ° with respect to the base 3 toward the end 3b side of the base 3. Bending vibration pieces 70A and 70B extending in the direction are formed. Mass portions 71B and 71B are provided at the ends of the bending vibration pieces.

The bending vibration pieces 70A and 70B are provided with drive electrodes 72A and 72B, respectively. The form of the drive electrode is as shown in the A-A ′ cross-sectional view. The drive electrode 72 </ b> B is grounded, and the drive electrode 72 </ b> A is connected to the AC power source 68. As a result, in the bending vibration pieces 70A and 70B, a voltage is applied in the a-axis direction, and bending vibration is generated.

The longitudinal direction of each of the pair of resonance arms 75A and 75B is inclined 120 ° with respect to the bending vibration pieces 70A and 70B. The forms of the detection electrodes 76A, 76B, 76C, and 76D in each resonance arm are shown in the B-B 'cross-sectional view. The detection electrode 76D is grounded, and a detection signal is taken out from the detection electrode 76C. As a result, a signal voltage is also generated in the a-axis direction in each of the resonance arms 75A and 75B.

For example, as shown in the embodiment of FIG. 18, when the bending vibration piece and the resonance arm are extended in the vertical direction, the longitudinal direction of the bending vibration piece and the resonance arm is 10 ° to 20 ° with respect to the a-axis. The detection signal can be taken out by preferably tilting by 15 °.

That is, in the vibration type gyroscope 59H, the main arm 101N or the base portion 3 protrudes from the fixed portion 1, and bending vibration pieces 99A and 99B extending perpendicularly to the base portion 3 are formed on the end portion 3b side of the base portion 3. In addition, mass portions 47A and 47B are provided at the ends of the bending vibration pieces. Each bending vibration piece is provided with drive electrodes 65A and 65B. A pair of resonance arms 100A and 100B protrude from the fixed portion 1 in parallel with the base portion 3, and detection electrodes 67A and 67B are provided on the resonance arms, respectively.

Here, both the voltage application direction in each bending vibration piece and the signal voltage direction in each resonance arm are at 15 ° with respect to the a-axis, and therefore the piezoelectric constants used in both arms are the same. is there.

In the present invention, the bending vibration piece or the resonance arm can be provided with a through hole extending in the longitudinal direction. Thereby, the natural resonance frequency of the vibration of the bending vibration piece or the resonance arm can be lowered, the vibration amplitude of the resonance arm can be increased, and the sensitivity of the sensor can be improved. 19 and 20 show a vibrating gyroscope according to this embodiment of the present invention.

In the vibrator 60E of the vibratory gyroscope 59E of FIG. 19, the main arm 101K protrudes from the fixed portion 1, the base portion 3 protrudes from the fixed portion 1, and the base portion 3 faces the end portion 3b. Bending vibration pieces 78A and 78B extending vertically are formed. Mass portions 47A and 47B are provided at the ends of the bending vibration pieces. Each bending vibration piece is formed with through holes 79A and 79B extending in the longitudinal direction of the bending vibration piece. The bending vibration piece is provided with elongate drive electrodes 80A, 80B, 80C, and 80D at positions on both sides of each through hole.

In this embodiment, a 130 ° Y plate of lithium tantalate is used, and the c-axis forms 50 ° with respect to the main surface of the vibrator. This angle provides the best temperature characteristics of the vibrator. In each bending vibration piece, as shown in the AA ′ cross-sectional view, the direction in which the voltage is applied is reversed between the driving electrodes 80A and 80C and the driving electrodes 80B and 80D, so that the bending vibration piece bends. .

A pair of resonance arms 81A and 81B protrude from the fixed portion 1, and detection electrodes 83A, 83B, 83C and 83D are provided on the resonance arms. Each resonance arm is formed with through-holes 82A and 82B extending in the longitudinal direction of the resonance arm. The resonance arm has elongated detection electrodes 83A, 83B, 83C and 83D at positions on both sides of each through-hole. Is provided. In each resonance arm, as shown in the B-B ′ sectional view, the potentials generated between the detection electrodes 83 </ b> A and 83 </ b> C and the detection electrodes 83 </ b> B and 83 </ b> D are in reverse phase.

In the vibrator 60F of the vibratory gyroscope 59F of FIG. 20, the main arm 101L or the base 3 protrudes from the fixed portion 1, and a pair of bending vibration pieces 85A and 85B are formed on the end 3b side of the base 3. Mass portions 71A and 71B are provided at the tip of the bending vibration piece. Each bending vibration piece extends at an angle of 120 ° with respect to the base. Each bending vibration piece is formed with through holes 86A and 86B extending in the longitudinal direction of the bending vibration piece. The drive electrodes 89A and 89D are provided on the outer wall surface of each through hole, and the drive electrodes 89B and 89C are provided on the inner wall surface.

In this embodiment, a piezoelectric single crystal plate having an a-axis that is a three-fold symmetry axis in a predetermined plane is used like a crystal. In each bending vibration piece, as shown in the AA ′ sectional view, the drive electrodes 89A and 89D on the outer surface are connected to the AC power source 68, and the drive electrodes 89B and 89C on the inner surface are grounded. . As a result, between the combination of the drive electrodes 89A-89B and the combination of the drive electrodes 89C-89D, the voltage application direction is in reverse phase, so that the bending vibration piece is bent.

A pair of resonance arms 87A and 87B protrude from the protruding portion 1a of the fixed portion 1, and through holes 88A and 88B extending in the longitudinal direction of the resonance arms are formed in the respective resonance arms. As shown in the B-B ′ sectional view, detection electrodes 90 </ b> A and 90 </ b> D are provided on the outer wall surface of each through hole, and detection electrodes 90 </ b> B and 90 </ b> C are provided on the inner wall surface. In each resonance arm, the generated potential is in a reverse phase between the detection electrodes 90A, 90C side and the 90B, 90D side.

Then, as in the present embodiment, in the through hole of the resonance arm or the bending vibration piece, a pair of drive electrodes are provided on the inner side surface and the outer side surface on both sides of the through hole, thereby providing one bending vibration piece or resonance. The arm can be bent. The same applies to the detection side.

In the present invention, the above-described main arm and at least a pair of resonance arms are provided on one side of the fixed piece portion, and a resonance piece that resonates with respect to the main arm is provided on the other side of the fixed piece portion. Can do. In this case, the drive electrode is provided on the bending vibration piece of the resonance piece, and the detection electrode is provided on the resonance arm. Thereby, the bending vibration of the bending vibration piece of the resonance piece can be used as the driving vibration, and the bending vibration of the resonance arm can be used as the detection vibration. Alternatively, a drive electrode is provided on the resonance arm, and a detection electrode is provided on the bending vibration piece of the resonance piece. Accordingly, the bending vibration of the resonance arm can be used as the driving vibration, and the bending vibration of the bending vibration piece of the resonance piece can be used as the detection vibration.

In this aspect, a second resonance arm can be further provided on the other side of the fixed piece. FIG. 21 is a perspective view schematically showing a vibrating gyroscope 59G according to this embodiment.

In the vibrator 60 </ b> G, the fixed piece portion 12 is provided inside the fixed member 90. On one side of the fixed piece 12, a main arm 101L and a pair of resonance arms 92A and 92B protrude from the protruding portion 94A. In the main arm 101L, bending vibration pieces 91A and 91B extending perpendicularly to the base 3 are formed on the end side of the base 3. Drive electrodes 46A, 46B, 46C, and 46D are provided on the bending vibration piece. Mass portions 93A and 93B are provided at the ends of the respective resonance arms.

In each of the flexural vibration pieces 91A and 91B, as shown in the A-A ′ cross-sectional view, the voltage application direction is opposite between the drive electrodes 46A and 46C and the drive electrodes 46B and 46D.

On the other side of the fixed piece portion 12, a resonance piece 103 and a pair of second resonance arms 97A and 97B are provided from the protruding portion 94B. In the resonance piece 103, bending vibration pieces 95 </ b> A and 95 </ b> B extending perpendicularly to the base portion 98 are formed on the end portion side of the base portion 98.

Mass portions 96A and 96B are provided at the ends of the resonance arms 97A and 97B. As shown in the B-B ′ sectional view, the resonance arm is provided with detection electrodes 49 </ b> A, 49 </ b> B, 49 </ b> C, and 49 </ b> D. Between the detection electrodes 49A and 49C and the detection electrodes 49B and 49D, the generated signal voltage is in reverse phase.

In the vibrator 110 of FIG. 22, the central fixed portion 104 includes a quadrilateral central portion 104a and four extended portions 104b. A pair of main arms 101 </ b> P and 101 </ b> Q extend from the fixed portion 104. In each main arm, the base portion 3 extends from each extended portion 104b, and the bending vibration piece 111 is provided so as to extend from the tip portion 3b of each base portion 3 in a direction perpendicular to the base portion 3, Both ends of each bending vibration piece 111 are connected to the base 3 respectively. As a result, the space 105 is surrounded by the fixed portion 104 a, the pair of base portions 3, and the bending vibration piece 111. A pair of flexural vibration pieces 106 are provided at the central portion 104 a of the fixed portion 104.

A driving voltage is applied to a predetermined excitation means, and each bending vibration piece 111 of each main arm is bent and vibrated as indicated by an arrow U. In this state, when the vibrator is rotated about the z axis, each base 3 is flexibly vibrated about 3a. Correspondingly, each bending vibration piece 106 resonates as indicated by an arrow V, so that the angular velocity can be measured from the detection signal generated along with this vibration.

  The vibratory gyroscope of the present invention is preferably used for confirming the position of an aircraft, a ship, a space satellite, etc., and for car navigation, detection of camera shake of a VTR or a still camera, etc. as a consumer field. it can.

It is a front view of a vibration type gyroscope concerning one embodiment of the present invention. (A) is a front view for demonstrating the vibration direction of a linear vibrator | oscillator, (b) is a front view for demonstrating the drive direction of the vibrator | oscillator of FIG. (A), (b), (c) is a schematic diagram for demonstrating the vibration direction and the principle of vibration of each part of the vibrator | oscillator of FIG. It is a front view of a vibration type gyroscope using a fixed piece. It is a front view of the other vibration type gyroscope which uses a fixed piece part. It is a front view of other vibration type gyroscope which uses a fixed piece part. It is a front view showing a vibrator in which each bending vibration piece is not perpendicular to the base. It is a front view showing a vibrator in which each bending vibration piece has a curved shape. It is a front view of a vibrator provided with a protruding portion that further protrudes from a bending vibration piece. It is a perspective view which shows roughly the vibration type gyroscope using the vibrator | oscillator provided with the main arm 101F and a pair of resonance arm. (A) is a diagram which shows the form of the drive vibration of the vibrator | oscillator of FIG. 10, (b), (c) is a diagram which shows the form of the detection vibration of the vibrator | oscillator of FIG. It is a perspective view showing roughly a vibration type gyroscope using a vibrator provided with a main arm 101G and a pair of resonance arms. It is a perspective view which shows roughly the gyroscope which is provided with the main arm 101G and a pair of resonance arm, and the dimension of the both sides of each resonance arm differs. It is a perspective view of the vibration type gyroscope of FIG. It is a graph which shows the change of the natural resonance frequency of the dimension a of a vibration type gyroscope of FIG. 13, FIG. 14, a drive vibration, and a spurious vibration. FIG. 2 is a perspective view schematically showing a vibrating gyroscope that includes a main arm 101I and a pair of resonance arms, in which a voltage application direction in the main arm and a voltage application direction in each resonance arm form 120 °. FIG. 3 is a perspective view schematically showing a vibrating gyroscope that includes a main arm 101J and a pair of resonance arms, in which a voltage application direction in the main arm and a voltage application direction in each resonance arm form 120 °. A perspective view schematically showing a vibrating gyroscope having a main arm 101N and a pair of resonance arms, in which the voltage application direction in the main arm and the voltage application direction in each resonance arm form 15 ° with respect to the a-axis. FIG. FIG. 3 is a perspective view schematically showing a vibrating gyroscope using a vibrator having a main arm 101K and a pair of resonance arms, and a bending vibration piece and a through hole provided in the resonance arm. FIG. 3 is a perspective view schematically showing a vibrating gyroscope using a vibrator having a main arm 101L and a pair of resonant arms, and a bending vibration piece and a resonant arm provided with a through hole. FIG. 3 is a perspective view schematically showing a vibration type gyroscope including a fixed piece portion 12, a main arm 101L, a pair of resonance arms 92A and 92B, a resonance piece 103, and a pair of second resonance arms 97A and 97B. It is a top view which shows the vibrator | oscillator which concerns on one Embodiment of this invention. It is a perspective view which shows the form of the conventional vibrator | oscillator.

Explanation of symbols

1, 11, 90 fixing member, 2, 10, 20, 22, 40, 41, 42, 44, 60A, 60B, 60C, 60D, 60E, 60F, 60G, 60H vibrator, 3, 16 base of main arm, 4A, 4B, 15A, 15B, 33A, 33B, 34A, 34B, 45A, 45B, 61A, 61B, 64A, 64B, 70A, 70B, 78A, 78B, 85A, 85B, 91A, 91B, 95A, 95B, 99A, 99B Bending vibration piece, 5A, 5B Excitation means (detection means), 6A, 6B, 6C, 6D Detection means (excitation means), 8A, 8B Bar-shaped vibrator, 12 Fixed piece portion, 13, 30 Support in resonance piece Part, 21 rectangular resonance piece, 23 expansion part, 25 connection part to the base of each bending vibration piece, 26 connection part to the fixing member of the base, 31, 32 resonance piece, 35 protrusion, 36A 36B, 37 Mass removed parts, 48A, 48B, 62A, 62B, 63A, 63B, 66A, 66B, 75A, 75B, 81A, 81B, 87A, 87B, 92A, 92B, 100A, 100B Resonant arm, 101A, 101B, 101C, 101D, 101E, 101F, 101G, 101H, 101I, 101J, 101K, 101L, 101N Main arm, A, B, N, P, Q, R Bending vibration piece vibration, I Bending vibration piece moving direction , H, K Bend direction of base, J, L Bend direction of flexural vibration piece, V Vector of vibration of flexural vibration piece, w Rotation of vibrator, predetermined plane on which XY plane vibrator vibrates, z axis Rotation axis

Claims (1)

A vibratory gyroscope comprising a vibrator that rotates around a rotation axis by rotation to be detected, and for detecting a rotational angular velocity around the rotation axis,
The vibrator is
(I) a fixed portion having four extended portions ;
(Ii) a pair of first base portions and a pair of second base portions formed in a plane perpendicular to the rotation axis and extending in parallel with each other across the fixed portion from each of the extended portions ;
(Iii) a pair of flexural vibration pieces that connect the first base and the second base, and surround the space together with the fixed portion and the first and second bases;
(Iv) a bending vibration piece for detection that is attached to the fixed portion and extends in the plane and bends and vibrates in response to vibrations of the first and second base portions;
(V) excitation means for bending vibration of the bending vibration piece;
(Vi) When the bending vibration piece is vibrated by the excitation means, the first and second bases vibrate by the Coriolis force generated by the rotation of the vibrator around the rotation axis, and the first Detection means provided for detecting vibration in the plane of the bending vibration piece for detection generated in response to vibration of the second base,
A vibrating gyroscope characterized by comprising

Images