This application is based upon and claims the benefit of priority from Japanese Patent Application No. 2011-011815, filed Jan. 24, 2011; the entire contents of which are incorporated herein by reference.
The present invention relates to a piezoelectric sensor that can transmit and receive ultrasound through a mechanical vibration of a piezoelectric body.
Such piezoelectric sensors are non-contact type detection sensors which can be used as detectors of automatic doors, etc., and which use ultrasound as detection media. More specifically, a piezoelectric sensor includes a piezoelectric body that mutually converts mechanical energy into electric energy and vice versa. Such functions are so-called a piezoelectric effect and an inverse piezoelectric effect. For example, when a voltage is applied, a piezoelectric body expands and contracts.
JP55-51568 A discloses a structure of a transducer with a combination of a piezoelectric body and a vibration plate. More specifically, a transducer including a piezoelectric body and a vibration plate is disposed on a mount that holds terminals. Electrical continuity is given between the transducer and the terminals by conductive wires. When a voltage is applied to the piezoelectric body through the terminals and the conductive wires, the transducer is inflected together with expansion and contraction of the piezoelectric body, and such an inflection motion generates mechanical vibration (which is referred to as a resonance phenomenon). Hence, the piezoelectric sensor becomes able to transmit ultrasound.
The transmitted ultrasound is reflected by an object, and when the piezoelectric sensor receives the reflected ultrasound, the transducer is inflected. The transducer obtains a voltage upon generation of a piezoelectric effect in response to the inflection. Hence, the piezoelectric sensor is capable of detecting presence/absence of an object approaching a door and a distance to the object, and thus the control unit of an automatic door can output a drive signal to a motor for opening/closing the door.
Meanwhile, according to the transducer of the prior art, the node of such mechanical vibration is supported by the mount, and the whole nodes of such mechanical vibration contact the mount. More specifically, the mount is provided with a cylindrical rib protruding toward the transducer, and the tip surface of this annularly closed rib supports the transducer. Further, a cylindrical bonding part is formed at the inner circumference of the rib, and the transducer is fixed by a bond at the nodes of vibration.
According to such a structure, however, unnecessary vibration so-called spurious vibration is generated to the transducer. That is, even if the mount contacts the transducer through nodes where amplitude becomes zero, when the contact area between the mount and the transducer is large, the mount disturbs vibration of the transducer. As a result, spurious vibration is generated and deteriorates the vibration performance of the transducer.
According to the structure that simply supports the transducer by the cylindrical rib and the bonding parts, no special consideration is given to the generation of spurious vibration, and any measures for reducing the spurious vibration become necessary. Moreover, there is a technique which fixes the mount to the transducer by a bond in a non-contact manner. However this needs a jig, etc., for suspending the transducer, thereby making the production of the piezoelectric sensor difficult. Hence, it is an object of the present invention to provide a piezoelectric sensor which can address the above-explained problem and which can reduce the spurious vibration of a transducer.
To achieve the object, a first aspect of the present invention provides a piezoelectric sensor that includes: a transducer which includes a piezoelectric body and a vibration plate and which transmits/receives ultrasound; and a mount that supports the transducer near nodes of mechanical vibration generated to the transducer, the mount comprising ribs that contact the transducer near nodes of mechanical vibration in a point by point, line by line or partially plane by plane contact manner to support the transducer.
According to the first aspect of the present invention, the piezoelectric sensor has the transducer that includes the piezoelectric body and the vibration plate, and the transducer can transmit/receive ultrasound. The transducer is supported by the mount near nodes of mechanical vibration, and the mount has the ribs that contact the transducer in a point by point, line by line or a partially plane by plane contact manner to support the transducer. As such, the contact area between the mount and the transducer is reduced in comparison with the prior art, the mount does not disturb a vibration of the transducer, thereby reducing spurious vibration. This results in an improvement of the vibration performance of the transducer, and contributes to an improvement of the reliability of the piezoelectric sensor.
A second aspect of the present invention provides the piezoelectric sensor of the first aspect, in which the mount further comprises retract portions which are provided side by side to respective ribs near nodes of mechanical vibration and which are distant from the transducer so as not to support the transducer.
According to the second aspect of the present invention, in addition to the advantage of the first aspect of the present invention, the mount has the ribs and the retract portions, and the ribs contact the transducer in a point by point, line by line or a partially plane by plane contact manner to support the transducer. In contrast, the retract portions are provided near respective nodes of mechanical vibration of the transducer like the ribs, but do not contact the transducer so as not to support the transducer. Hence, the contact area between the mount and the transducer is surely reduced, thereby further reducing spurious vibration.
A third aspect of the present invention provides the piezoelectric sensor of the first and second aspect of the present invention, in which the ribs are disposed at three locations along a circumference of the mount at a substantially equal interval.
According to the third aspect of the present invention, in addition to the advantages of the first and second aspects, the ribs are disposed at the three locations with a substantially equal interval as viewed in a circumferential direction of the mount formed in a substantially columnar shape. Hence, even if the contact area with the transducer is reduced, the transducer can be stably supported. Moreover, when the intervals between respective ribs are uniform, it is easy to provide the ribs on the mount in comparison with a case in which the ribs are simply provided at three locations.
A fourth aspect of the present invention provides the piezoelectric sensor of the first to third aspects of the present invention, in which the ribs each have a tip surface which is formed in a flat shape and which contacts the transducer in a plane by plane contact manner.
According to the fourth aspect of the present invention, in addition to the advantages of the first to third aspects of the present invention, when the ribs contact the transducer in a partially plane by plane contact manner, if respective tip surfaces thereof are flat, a disturbance of a vibration of the transducer by the mount is further suppressed, thereby contributing an improvement of the vibration performance of the transducer.
A fifth aspect of the present invention provides the piezoelectric sensor of the first to fourth aspects of the present invention that further includes: a lead which is drawn from the transducer and which has an electrical continuity between the transducer and a terminal connected to a circuit board; and a case that has the mount on a surface opposite to a surface holding the terminal, in which the surface holding the terminal is provided with a spacer that ensures a space between this surface and the circuit board.
According to the fifth aspect of the present invention, in addition to the advantages of the first to fourth aspects of the present invention, a transmission of vibration from the case to the circuit board is avoidable, and damage to the circuit board and to the case by solders is suppressed.
As described above, according to the present invention, the contact area between the mount and the transducer is made small, and thus the piezoelectric sensor is provided which has the mount not disturbing vibration of the transducer, and which can reduce spurious vibration of the transducer.
An embodiment of the present invention will be explained with reference to the accompanying drawings.
(Configuration)
As shown in
The transducer 2 of this embodiment employs a unimorph structure having a piezoelectric ceramic (a piezoelectric body) 10 superimposed on a metal vibration plate 20. More specifically, the piezoelectric ceramic 10 is formed of, for example, lead-zirconium-titanate-based ceramic (PZT), and has a predetermined thickness in the height direction (the vertical directions in
As shown in
In order to generate large vibration by applying vibration of the piezoelectric ceramic 10 to the vibration plate 20, the piezoelectric ceramic 10 and the vibration plate 20 are superimposed together, and a rear face 24 of the vibration plate 20 and a surface 12 of the piezoelectric ceramic 10 are bonded together by a bond. In
A lead (conductive line) 26 is also fastened to an appropriate position of the rear face 24 of the vibration plate 20 by a solder 28 (see
The case 40 of this embodiment is made of a plastic resin and is in a cup shape. The bottom part of the cup serves as a mount 42 that is formed together with a peripheral wall 70 having openings. More specifically, as shown in
The top face 44 is provided with a total of three supports 46, that are ribs, protruding toward the transducer 2 according to this embodiment. More specifically, as shown in
When the mount 42 and the supports 46 are considered as an integral piece, it can be thought that portions between respective supports 46 are cut out and three notches 50, that are retract portions, are provided on the top face 44. The notches 50 have a shorter height than those of the supports 46 and disposed on a circular trajectory passing through all supports 46. More specifically, as shown in
As shown in
More specifically, the bonding portions 52 are formed at nodes of mechanical vibration generated to the transducer 2. A node of mechanical vibration is a position where amplitude becomes zero. The transducer 2 of this embodiment is in a circular shape, is inflected together with expansion and contraction of the substantially square piezoelectric ceramic 10 in the width direction and the lengthwise direction, and is driven by a voltage with the unique resonant frequency of such vibration. In this case, the node of vibration locates at a position close to the center by φ/4 from a circumference of the circle with a diameter φ. That is to say, the node of vibration locates at a position on circumference of the circle with a diameter substantially φ/2 relative to the center of the transducer 2. Hence, according to this embodiment, the bonding portion 52 partially supports a position close to the center by φ/4 from a circumference of the circle with a diameter φ of the transducer 2. Note that also in the thickness direction, expansion and contraction of the piezoelectric ceramic 10 are generated, although those are smaller than expansion and contraction in the width direction and the lengthwise direction.
In view of this, the mount 42 has a lower face 54 facing the mount surface of the above-explained circuit board. As shown in
Spacers 58 and 60 are provided near the circumference of the lower face 54 (see
One of the spacer 60 among the spacers 58 and 60 is provided with a pin 62 in a protruding manner for identifying the polarities of the terminals 80 and 82. The pin 62 of this embodiment is provided on the spacer 60, but may be provided on the lower face 54.
Furthermore, the mount 42 of this embodiment has protective portions 64, 64 near the circumference thereof (see
Next, the peripheral wall 70 stands from the circumference of the mount 42 and extends upwardly. More specifically, as shown in
The peripheral wall 70 has a portion where the internal side of the peripheral wall 70 and the external side thereof are completely communicated with each other across the height direction of the case 40. More specifically, the peripheral wall 70 of this embodiment has lead-receiving openings 76, 76 (see
The lead receiving opening 76 is continuous from the corner part of the protective portion 64 closest to the circumference of the lower face 54 at a position facing the mount 42 (see
The horn windows 78, 78 are opened with a sufficiently wider width than the width which can retain individual leads 16 and 26, and are formed in a range across the narrow portions of the lead receiving openings 76 in the circumferential direction of the peripheral wall 70 (see
(Assembling)
Returning to
Next, the lead 16 drawn to the external side of the peripheral wall 70 through the horn window 78 is pinched by and drawn in the protective portion 64 from the narrow portion of the nearby lead receiving opening 76. Accordingly, as shown in
The lead 26 drawn to the external side of the peripheral wall 70 through the horn window 78 is drawn in the protective portion 64 from the narrow portion of the nearby lead receiving opening 76. Accordingly, the side part of the lead 26 is held by the internal wall of the protective portion 64, and the tip of the lead 26 is drawn downwardly from the lower face 54 (see
Thereafter, the piezoelectric sensor 1 is finished when the horn 30 is bonded to a surface 22 of the vibration plate 20. The piezoelectric sensor 1 having the above-explained structure can transmit and receive ultrasound. The spacers 58 and 60 are mounted on the mount surface of the circuit board of the detector, and the terminals 80 and 82 are electrically connected to the circuit portion of the detector.
(Operation)
When a voltage is applied to the piezoelectric ceramic 10 through the terminals 80 and 82 and the leads 16 and 26, the piezoelectric ceramic 10 expands and contracts due to the inverse piezoelectric effect in the thickness direction and the width direction and the lengthwise direction both orthogonal to the thickness direction. The expansion and contraction of the piezoelectric ceramic 10 in the width direction and the lengthwise direction generate force that makes the whole transducer 2 flex, and mechanical vibration originating from the inflection motion of the transducer 2 generates ultrasound. The generated ultrasound is amplified by the horn 30. As explained above, the piezoelectric sensor 1 converts electrical signals into ultrasound, and can transmit the ultrasound toward an object from the upper opening 72.
This transmitted ultrasound propagates the air, and reflects toward the piezoelectric sensor 1 when collided with the object. The piezoelectric sensor 1 can convert the received ultrasound into electrical signals. More specifically, when the piezoelectric sensor 1 receives the reflected ultrasound through the horn 30, the piezoelectric ceramic 10 expands and contracts together with the inflection motion of the transducer 2, and a voltage is obtained by a piezoelectric effect.
As explained above, the piezoelectric sensor 1 can transmit and receive ultrasound through the piezoelectric effect and the inverse piezoelectric effect. The control unit of an automatic door 1 using the piezoelectric sensor 1 can detect presence/absence of an object approaching the door and a distance to the object, and becomes able to output a drive signal to a motor for opening/closing the door.
(Effect)
As explained above, according to this embodiment, the piezoelectric sensor 1 includes the unimorph transducer 2 configured by the piezoelectric ceramic 10 and the vibration plate 20, and the transducer 2 can transmit and receive ultrasound. The transducer 2 is supported by the mount 42 near the nodes of mechanical vibration of the transducer 2, but the mount 42 has the supports 46 that partially contact the transducer 2 in a plane by plane contact manner to support the transducer 2. When the contact area between the mount 42 and the transducer 2 is small in this manner in comparison with the prior art, the mount 42 does not disturb vibration of the transducer 2, thereby reducing spurious vibration. This results in the improvement of the vibration performance of the transducer 2, and contributes to the improvement of the reliability of the piezoelectric sensor 1.
Regarding this effect,
It can be estimated that the mount supported the transducer in a complete plane by plane contact manner, which disturbed the transducer to vibrate, and thus spurious vibration was generated. Moreover, according to the first and second comparative examples, no upper peak appeared at the resonant frequency, but an upper peak appeared at a slightly higher range than the resonant frequency (the right to the resonant frequency). It is thought that a peak to be originally generated relative to the resonant frequency was shifted due to the peak appeared at the above-explained lower range.
Furthermore, according to the first comparative example indicated by the single dashed line, the upper peak appeared at the slightly higher peak was smaller than the peak of the second comparative example at the same position and indicated by the double dashed line. It can be expected that such a smaller peak was affected by an upper peak of the first comparative example at the lower range which became larger than the peak of the second comparative example at the same position.
In contrast, according to the piezoelectric sensor 1 of this embodiment, the mount 42 has the supports 46 and the notches 50, and the supports 46 contact the transducer 2 in a partially plane by plane contact manner to support the transducer 2. Conversely, the notches 50 are provided near the nodes of vibration of the transducer 2 like the supports 46 but do not contact the transducer 2 and do not support the transducer 2.
That is, among the cylindrical ribs, portions other than ones left as the supports 46 are eliminated, and as shown by a continuous line in
Furthermore, according to this embodiment that makes the contact area reduced between the mount 42 and the transducer 2, a range from a lower peak to an upper peak appeared at the resonant frequency is widespread in comparison with respective ranges of the first and second comparative examples from a lower peak to an upper peak. That is, the piezoelectric sensor 1 is efficient which accomplishes good vibration and which makes a range of the resonant resistance Z wide.
Moreover, the supports 46 are disposed at the three locations at a substantially equal interval as viewed in the circumferential direction of the mount 42 formed in a substantially columnar shape. The layout with an equal interval does not contribute to a reduction of spurious vibration, but such a layout with an equal interval accomplishes stable support to the transducer 2 even if the contact area with the transducer 2 is reduced. Furthermore, when the supports 46 are provided at an equal interval, it becomes easy to provide the supports 46 on the mount 42 in comparison with a case in which the supports 46 are simply provided at three locations, thereby reducing the production cost of the piezoelectric sensor 1.
Still further, to support the transducer 2 near the nodes of vibration, a bond can be also applied to the notches 50, and thus the surface area of the bonding portions 52 can be increased in comparison with a case in which the bonding portions are provided inwardly of the supports 46 as viewed in the radial direction of the mount 42. Hence, the transducer 2 can be bonded to the mount 42 near the nodes of vibration even if the contact area between the mount 42 and the transducer 2 is reduced.
In the case of the supports 46 that contact the transducer 2 in a partial plane by plane contact manner, when respective tip surfaces are formed to be flat, the disturb by the mount 42 of vibration of the transducer 2 is further suppressed, which contributes improvement of the vibration performance of the transducer 2. Moreover, according to this embodiment, the piezoelectric sensor 1 further has the case 40 that includes the leads 16 and 26 drawn from the transducer 2 and accomplishing an electrical continuity between the transducer 2 and the terminals 80 and 82 connected to a circuit board, and the mount 42 on the top face 44 opposite to the lower face 54 holding the terminals 80 and 82. The lower face 54 is provided with the spacers 58 and 60 for ensuring a space between the lower face 54 and the circuit board. Hence, it is possible to suppress a transmission of vibration of the case 40 to the circuit board, and a damage to the circuit board and the case 40 by solders.
The present invention is not limited to the above-explained embodiment, and can be changed and modified in various forms without departing from the scope and spirit of the present invention set forth in claims. For example, the piezoelectric sensor of the above-explained embodiment is configured to transmit and receive ultrasound, but the piezoelectric sensor of the present invention may have either one of transmission and reception functions only. Moreover, the piezoelectric sensor of the present invention can be built in various modules that operate based on presence/absence of an object and a detection result of a distance thereto in addition to the detector of the automatic door.
More specifically, an example module that uses a detection result of a distance to an object is a liquid level gauge, an automotive back sonar, a distance gauge, or an automatic switch for traffic lights. Moreover, example modules that use presence/absence of an object are an intruder alarm device and an automatic lighting switch. This is because a distance to an object and presence/absence thereof can be detected through a measurement of a reflection time of ultrasound and an observation of the number of vibrations (Doppler effect).
Furthermore, the above-explained embodiment is an optimized example in consideration of the production of the piezoelectric sensor 1. More specifically, according to the above-explained embodiment, the explanation was given of a case in which the mount 42 and the transducer 2 contact in a partially plane by plane contact manner. However, the present invention focuses on reduction of the contact area with the transducer 2, not a large contact area by cylindrical ribs and bonding portions of the prior art. In other words, in addition to a structure in which the mount 42 and the transducer 2 contact in a partially plane by plane contact manner, as long as the mount 42 and the transducer 2 contact at plural locations in a point by point contact manner, line by line contact manner, or the contact area with the transducer 2 is reduced, the transducer 2 may be supported by a combination of such structures.
Still further, according to the above-explained embodiment, the ribs 46 are provided at the three locations, but the present invention is not limited to the structure of this embodiment. The equilibrium of the transducer can be maintained as long as the ribs 46 are provide at greater than or equal to two locations. In such a case, like the above-explained embodiment, an advantage of reducing spurious vibration of the transducer can be obtained.
Number | Date | Country | Kind |
---|---|---|---|
2011-011815 | Jan 2011 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
5802196 | Nakamura | Sep 1998 | A |
5889351 | Okumura et al. | Mar 1999 | A |
6087760 | Yamaguchi et al. | Jul 2000 | A |
7554248 | Oda et al. | Jun 2009 | B2 |
20080309199 | Furukawa | Dec 2008 | A1 |
Number | Date | Country |
---|---|---|
102136546 | Jul 2011 | CN |
1199906 | Apr 2002 | EP |
47-36765 | Sep 1972 | JP |
55-51568 | Apr 1980 | JP |
58-88500 | Jun 1983 | JP |
61-64798 | May 1986 | JP |
6-38399 | May 1994 | JP |
2002-044784 | Feb 2002 | JP |
Entry |
---|
Japanese Application No. 2011-011815 Office Action dated Jun. 11, 2013, 3 pages including English translation. |
Japanese Application No. 2011-011815 Office Action dated Jan. 8, 2013, 4 pages including English translation. |
Chinese Application No. 201210015812.4 Office Action dated Jul. 9, 2014, 9 pages with English translation. |
Number | Date | Country | |
---|---|---|---|
20120187801 A1 | Jul 2012 | US |