INERTIAL FORCE SENSOR
An inertial force sensor includes a detector element, a supporting body supporting the detector element, and a case holding the detector element via the first supporting body. The supporting body has flexibility and has a plate shape. The detector element includes a weight, a flexible coupling portion extending along a plane and supporting the weight, a fixing portion holding the weight via the coupling portion, and a detector detecting angular velocities about at least two axes non-parallel to each other. The supporting body extends in parallel with the plane from the detector element, and bends at a bending portion in a direction away from the plane. This inertial force sensor can detect the angular velocities while preventing erroneous detection caused by external impacts and vibrations.
The present invention relates to an inertial force sensor capable of detecting angular velocity, which is used in various electronic devices for attitude control or navigation of movable objects, such as aircrafts, automobiles, robots, boats, ships, and vehicles.
BACKGROUND ARTAn inertial force sensor, such as an angular velocity sensor and an acceleration sensor, detects angular velocity, acceleration, or both of them.
In order to detect axial components of an acceleration along an X-axis, a Y-axis, and a Z-axis which are perpendicular to each other, total three acceleration sensors: an acceleration detector element for detecting acceleration in a direction of the X-axis; an acceleration detector element for detecting acceleration in a direction of the Y-axis; and an acceleration detector element for detecting acceleration in a direction of the Z-axis. Angular velocities about the axes can be detected by total three angular-velocity detector elements: an angular-velocity detector element for detecting angular velocity about the X-axis; an angular-velocity detector element for detecting angular velocity about the Y-axis; and an angular-velocity detector element for detecting angular velocity about the Z-axis.
It is, however, difficult to reduce the size of a sensor which includes plural detector elements that detect acceleration in plural axis directions and angular velocities about plural axes.
Patent Literature 1 discloses a conventional inertial force sensor in which one detector element detects acceleration in plural axis directions or angular velocities about plural axes. This inertial force sensor includes a weight, a fixing portion for holding the weight, and a coupling portion for connecting the weight to the fixing portion. The weight has a mass large enough to detect inertial forces. The coupling portion has flexibility and detects the inertial forces based on deformations thereof or variations in location of the weight, which are caused by the inertial forces applied to the weight.
Patent Literature 2 discloses a conventional vibration-isolation structure of an inertial force sensor that detects angular velocities. The vibration-isolation structure includes an elastic body that can easily warp in a direction in which a Coriolis force occurs.
In the conventional inertial force sensors described above, it is difficult to provide a vibration-isolation structure for one detector element that detects angular velocities about plural axes. For example, while the weight of the detector element is driven to vibrate in an X-axis direction, an angular velocity about a Z-axis generates a Coriolis force which acts on the weight in a Y-axis direction to cause a coupling portion to deflect. The angular velocity about the Z-axis is detected based on the deflection. However, the angular velocity may be erroneously detected in the case where the weight is subjected to an inertial force caused by external impacts or vibrations, thereby resulting in a deflection of the coupling portion in the Y-axis direction. To prevent such erroneous detection of angular velocity, it is necessary to provide the inertial force sensor with a vibration-isolation structure against external impacts and vibrations. In this case, the vibration-isolation structure is designed to decrease vibrations in the Y-axis direction, which requires that a supporting member for supporting the detector element be easy to deflect in the Y-axis direction. However, such a vibration-isolation structure of conventional inertial force sensors can hardly prevent vibrations not only in the Y-axis direction but also in plural axis directions, such as the X-axis and Z-axis directions.
CITATION LIST Patent Literature
- Patent Literature 1: Japanese Patent Laid-Open Publication No. 2008-046058A
- Patent Literature 2: WO2006/132277
An inertial force sensor includes a detector element, a supporting body supporting the detector element, and a case holding the detector element via the first supporting body. The supporting body has flexibility and has a plate shape. The detector element includes a weight, a flexible coupling portion extending along a plane and supporting the weight, a fixing portion holding the weight via the coupling portion, and a detector detecting angular velocities about at least two axes non-parallel to each other. The supporting body extends in parallel with the plane from the detector element, and bends at a bending portion in a direction away from the plane.
This inertial force sensor can detect the angular velocities while preventing erroneous detection caused by external impacts and vibrations.
Arms 3A to 3D have U-shapes extend perpendicularly from arms 2A and 2B, extend perpendicularly in parallel with arms 2A and 2B, and further extend perpendicularly in parallel with portions of arms 3A to 3D connected with arm 2A or 2B. Distal ends of arms 3A to 3D are connected with weights 7A to 7D, respectively. Arms 2A and 2B are arranged symmetrically to one another with respect to holding portion 4. Arms 3A to 3D are symmetrically arranged with respect to holding portion 4.
A configuration of detector element 1 will be described in detail. Three axes perpendicular to each other: an X-axis; a Y-axis; and a Z-axis are defined. Positive direction 1A and negative direction 1B opposite to each other along the X-axis are defined. Positive direction 1C and negative direction 1D opposite to each other along the Y-axis are defined. Positive direction 1E and negative direction 1F opposite to each other along the Z-axis are defined. Arm 2A extends in direction 1B from holding portion 4, in parallel with the X-axis. Arm 2B extends in direction 1A opposed to direction 1B, in parallel with the X-axis. Arm 2A has end 22A connected with fixing portion 106 and has end 12A connected with holding portion 4. Arm 2B has end 22B connected with fixing portion 106 and has end 12B connected with holding portion 4.
Arm 3A is has a substantial U-shape including extension bar portions 13A and 23A that extend in parallel with the Y-axis, separated end 43A that is one end of extension bar portion 13A, separated end 53A that is one end of extension bar portion 23A, and closed end 33A connecting respective other ends of extension bar portions 13A and 23A with each other. Separated ends 43A and 53A are separated from each other. Separated end 43A is connected with holding portion 4. Separated end 53A is connected with weight 7A. Separated ends 43A and 53A are located in direction 1D parallel to the Y-axis from closed end 33A. Extension bar portion 23A having separated end 53A is located in direction 1B from extension bar portion 13A having separated end 43A.
Arm 3B has a substantial U-shape including extension bar portions 13B and 23B that extend in parallel with the Y-axis, separated end 43B that is one end of extension bar portion 13B, separated end 53B that is one end of extension bar portion 23B, and closed end 33B connecting respective other ends of extension bar portions 13B and 23B with each other. Separated ends 43B and 53B are separated from each other. Separated end 43B is connected with holding portion 4. Separated end 53B is connected with weight 7B. Separated ends 43B and 53B are located in direction 1D from closed end 33B. Extension bar portion 23B having separated end 53B is located in direction 1A connected extension bar portion 13B having separated end 43B.
Arm 3C has a substantial U-shape including extension bar portions 13C and 23C that extend in parallel with the Y-axis, separated end 43C that is one end of extension bar portion 13C, separated end 53C that is one end of extension bar portion 23C, and closed end 33C connecting respective other ends of extension bar portions 13C and 23C. Separated ends 43C and 53C are separated from each other. Separated end 43C is connected with holding portion 4. Separated end 53C is connected with weight 7C. Separated ends 43C and 53C are located in direction 1C opposite to direction 1D parallel to the Y-axis from closed end 33C. Extension bar portion 23C having separated end 53C is located in direction 1B from extension bar portion 13C having separated end 43C.
Arm 3D has a substantial U-shape including extension bar portions 13D and 23D that extend in parallel with the Y-axis, separated end 43D that is one end of extension bar portion 13D, separated end 53D that is one end of extension bar portion 23D, and closed end 33D connecting respective other ends of extension bar portions 13D and 23D with each other. Separated ends 43D and 53D are separated from each other. Separated end 43D is connected with holding portion 4. Separated end 53D is connected with weight 7D. Separated ends 43D and 53D are located in direction 1C from closed end 33D. Extension bar portion 23D having separated end 53D is located in direction 1A from extension bar portion 13D having separated end 43D.
Thus, coupling portion 1P including arms 2A, 2B, and 3A to 3D having flexibility extends along a plane in parallel with an XY-plane including the X-axis and the Y-axis, and supports weights 7A to 7D. Fixing portion 106 holds weights 7A to 7D via coupling portion 1P. Supporting body 112 having a plate shape with flexibility supports detector element 1. Case 11 holds detector element 1 via supporting body 112. Supporting body 112 extends in parallel with the XY-plane from detector element 1, and then bends at bending portion 13 in a direction away from a plane in which coupling portion 1P extends.
Driving electrodes 8A and 8B to drive weights 7A and 7B to vibrate are disposed on extension bar portions 13A and 13B of arms 3A and 3B connected with holding portion 4, respectively. Driving electrodes 9C and 9D to drive weights 7C and 7D to vibrate are disposed on extension bar portions 13C and 13D of arms 3C and 3D connected with holding portion 4, respectively. Sensing electrodes 10A to 10D to sense strains of arms 3A to 3D are disposed on extension bar portions 13A to 13D of arms 3A to 3D, respectively. Each of driving electrodes 8A, 8B, 9C, and 9D and sensing electrodes 10A to 10D is formed by laminating a lower electrode, a piezoelectric body, and an upper electrode on respective one of arms 3A to 3D. The piezoelectric layer is composed of piezoelectric material, such as lead zirconate titanate (PZT). Arms 2A and 2B and 3A to 3D are disposed in a plane parallel to the XY-plane including the X-axis and the Y-axis.
An operation of detector element 1 for detecting angular velocities will be described below.
According to the embodiment, the AC voltages applied to driving electrodes 8A and 8B has the same phase. The AC voltages applied to driving electrodes 9C and 9D are identical to each other, and have a phase inverse to that of the AC voltages applied to driving electrodes 8A and 8B. These voltages causes driving vibration 1G to displace weights 7A and 7B in directions opposite to each other, to displace weights 7C and 7D in directions opposite to each other, to displace weights 7A and 7C in directions opposite to each other, and to displace weights 7B and 7D in directions opposite to each other. That is, when a distance between weights 7A and 7B decreases, a distance between weights 7C and 7D increases.
Thus, sensing electrodes 10A to 10D constitute detector 110 that detects angular velocities A1 and A2. Detector 110 detects angular velocities A1 and A2 about at least two axes, i.e. the Y-axis and the Z-axis, respectively, which are non-parallel to each other.
As shown in
In detector element 1, when weights 7A to 7D perform driving vibration 1G in parallel with the X-axis, Coriolis forces 1H and 1J due to angular velocities A1 and A2 produce strains on arms 3A to 3D. The strains appear as vibrations accompanying driving vibration 1G in the directions of the Y-axis and Z-axis. That is, arms 3A and 3D perform driving vibration 1G in the direction of the X-axis, and perform the vibrations in the directions of the Y-axis and Z-axis due to the angular velocities. Arms 3A to 3D connected with weights 7A to 7D have a resonance frequency of the vibration in the direction of the X-axis, a resonance frequency of the vibration in the direction of the Y-axis, and a resonance frequency of the vibration in the direction of the Z-axis. These arms vibrate at the respective resonance frequencies in the X-axis, Y-axis, and Z-axis due to driving vibration 1G and Coriolis forces 1H and 1J. Strains on arms 3A to 3D are detected with reference to frequencies of the vibrations in the direction of the X-axis of arms 3A to 3D. Therefore, in each of arms 3A to 3D, a difference between the resonance frequencies in the directions of the X-axis and Y-axis and a difference between the resonance frequencies in the directions of the X-axis and Y-axis are preferably small to raise sensitivity of detector element 1 in detecting angular velocity A1 and A2.
Detector element 1 of inertial force sensor 16 can detect acceleration. Arms 2A and 2B are thinner than arms 3A to 3D, accordingly causing arms 2A and 2B to be more flexible than arms 3A to 3D. Strains are applied on arms 2A and 2B due to acceleration applied to detector element 1. By sensing the strains, the acceleration can be detected. Acceleration in the direction of the Y-axis generates strains that cause arms 2A and 2B to deform in the direction of the Y-axis. By sensing the strains, the acceleration in the directions of the Y-axis can be detected. Also, acceleration in the direction of the Z-axis generates strains that cause arms 2A and 2B to deform in the direction of the Z-axis. By sensing the strains, the acceleration in the Z-axis direction can be detected. Thus, inertial force sensor 16 including detector element 1 can detect the acceleration as well as angular velocities.
In order to detect acceleration, detector element 1 may further include an opposed substrate facing weights 7A and 7B in the direction of the Z-axis, electrodes disposed on weights 7A to 7D, and opposed electrodes facing these electrodes. Arms 2A and 2B are thinner than arms 3A to 3D, hence causing arms 2A and 2B to be more flexible in the direction of the Z-axis than arms 3A to 3D. Acceleration changes the distances between electrodes disposed on weights 7A and 7B and corresponding opposed electrodes facing these electrodes, and changes capacitances between the electrodes accordingly. By sensing the change of the capacitances, detector element 1 can detect the acceleration. In detector element 1, since acceleration in the direction of the Y-axis changes capacitances between the electrodes and the opposed electrodes, the acceleration in the Y-axis direction can be detected by sensing the change of the capacitances. Also, since acceleration in the direction of the Z-axis changes capacitances between the electrodes and the opposed electrodes, the acceleration in the Y-axis direction can be detected by sensing the change of the capacitances. Thus, inertial force sensor 16 including detector element 1 can detect acceleration as well as angular velocities.
Inertial force sensor 16 including a vibration-isolation mechanism of detector element 1 will be described in detail below.
As shown in
Adhesion layer 114 made of adhesive fixes detector element 1 onto supporting body 112. Supporting body 112 has a surface facing positive direction 1E of the Z-axis and a surface facing negative direction 1F of the Z-axis. Detector element 1 is fixed on the surface of supporting body 112 facing positive direction 1E of the Z-axis. Adhesion layer 15 made of adhesive fixes supporting body 112 to case 11. Positive direction 1E of the Z-axis is directed upward. Detector element 1 is supported from underneath by supporting body 112.
A method of manufacturing inertia force sensor 16 will be described below.
Lower electrodes, piezoelectric material thin films, and upper electrodes are formed on a silicon substrate by a thin-film technology, and then, are processed to have a predetermined shape by etching, thereby providing detector element 1 shown in
As shown in
As shown in
As shown in
Next, as shown in
Then, as shown in
Next, bending portions 13 are formed by bending supporting bodies 112 by processing, such as pressing.
A vibration-isolation mechanism of inertia force sensor 16 will be described below.
Weights 7A and 7B vibrate due to driving vibration 1G in order to detect angular velocities A1 and A2, as shown in
f=1/2π·(k/m)1/2
As shown in this equation, the smaller the spring constant k is, the lower the natural frequency f.
As shown in
The direction of width W1 of each of supporting bodies 112 at bending portion 13 is parallel with the XY-plane and the plane in which arms 2A, 2B, and 3A to 3D are arranged. In
Since arms 2A, 2B, and 3A to 3D are arranged in a plane parallel with the XY-plane, these arms can easily deflect in the direction of the Z-axis perpendicular to the plane. Therefore, upon an external force being applied to, arms 2A, 2B, and 3A to 3D tend to deflect in the direction of the Z-axis. When the arms deflect excessively, weights 7A to 7D may hit surrounding components, providing detector element 1 with damage. The directions of the widths of supporting bodies 112 at bending portions 13 are parallel with the XY-plane, and the directions of the thicknesses smaller than the widths are parallel with the Z-axis. Therefore, supporting bodies 112 easily deflect in the direction of the Z-axis perpendicular to the XY-plane, and easily absorb external forces in the direction of Z-axis. Thus, although detector element 1 is weak against external forces in the direction of the Z-axis, supporting bodies 112 can absorb the external forces in the direction of the Z-axis, hence reducing external forces in the direction of the Z-axis that act on detector element 1.
As shown in
As shown in
Inertial force sensors according to the embodiment are not limited to the configurations described above. For example, detector element 1 may have a diaphragm construction. Detector element 1 may detect not only angular velocities about the Y-axis and the Z-axis, but also an angular velocity about the X-axis, the Y-axis, and the Z-axis. Furthermore, detector element 1 may detect acceleration in the directions of the X-axis, the Y-axis, and the Z-axis. Besides, detector element 1 may necessarily be designed not to detect acceleration.
INDUSTRIAL APPLICABILITYAn inertial force sensor according to the present invention can detect an angular velocity while preventing erroneous detection caused by external impacts or vibrations. This sensor is useful as an inertial force sensor detecting an angular velocity, and is useful for various electronic devices for attitude control or navigation of mobile objects such as aircrafts, automobiles, robots, boats and ships, and other vehicles.
DESCRIPTION OF REFERENCE MARKS
- 1 Detector Element
- 1P Coupling Portion
- 7A Weight
- 7B Weight
- 7C Weight
- 7D Weight
- 11 Case
- 13 Bending Portion (First Bending Portion, Second Bending Portion)
- 106 Fixing Portion
- 110 Detector
- 112 Supporting Body (First Supporting Body, Second Supporting Body)
- 612 Supporting Body (First Supporting Body)
- 712 Supporting Body (Second Supporting Body)
- 613 Bending Portion (First Bending Portion)
- 713 Bending Portion (Second Bending Portion)
Claims
1. An inertial force sensor comprising
- a detector element including: a first beam; a second beam parallel with the first beam; a third beam, a fourth beam, a fifth beam, and a sixth beam which connect between the first beam and the second beam; a seventh beam connected to the fourth beam and extending in parallel with the first beam; and a eighth beam connected to the fifth beam and extending in parallel with the first beam,
- wherein a first slit is provided between the third beam and the fourth beam,
- wherein a second slit is provided between the fifth beam and the sixth beam,
- wherein a width of the fourth beam is smaller than a width of the first beam,
- wherein a width of the fifth beam is smaller than a width of the second beam,
- wherein a width of the third beam is larger than the width of the fourth beam and larger than a width of the first slit,
- wherein a width of the sixth beam is larger than the width of the fifth beam and larger than a width of the second slit,
2. The inertial force sensor according to claim 1, wherein the first slit is parallel with the second slit.
3. The inertial force sensor according to claim 2, wherein the detector element further includes:
- a ninth beam and a tenth beam which are connected to the seventh beam and are parallel with the third beam; and
- an eleventh beam and a twelfth beam which are connected to the eighth beam and are parallel with the third beam.
4. The inertial force sensor according to claim 3, wherein each of the ninth beam, the tenth beam, the eleventh beam, and the twelfth beam has two bending portions.
5. The inertial force sensor according to claim 3, further comprising:
- a supporting body supporting the detector element; and
- a member connected to the detector element via the supporting body,
- wherein the supporting body has at least two bending portions.
6. The inertial force sensor according to claim 5, wherein the supporting body bends perpendicularly at the at least two bending portions.
7. The inertial force sensor according to claim 6,
- wherein the detector element is parallel with a plane, and
- wherein the supporting body bends perpendicularly at the at least two bending portions viewing in a direction perpendicular to the plane.
8. The inertial force sensor according to claim 5, wherein the supporting body is made of a material different from a material of the detector element.
9. The inertial force sensor according to claim 1, wherein the detector element is configured to detect an angular velocity about one axis.
10. The inertial force sensor according to claim 1, wherein the detector element is configured to detect angular velocities about two axes.
11. The inertial force sensor according to claim 1, wherein the detector element is configured to detect angular velocities about three axes.
Type: Application
Filed: Sep 10, 2014
Publication Date: Dec 25, 2014
Inventors: HIDEO OHKOSHI (Osaka), SHIGEHIRO YOSHIUCHI (Kyoto), TSUYOSHI SAKAUE (Hyogo)
Application Number: 14/482,152
International Classification: G01P 3/02 (20060101); G01P 15/02 (20060101);