JPH06334472A - Piezoelectric resonance component - Google Patents

Abstract

PURPOSE:To make nodes caused on a face of a piezoelectric resonator surely coincident between the piezoelectric resonators by changing the size of the plural piezoelectric resonators. CONSTITUTION:Piezoelectric resonators 21-24 are rectangular flat elements utilizing an area spread vibration mode. The size of the piezoelectric resonators 21, 24 is smaller than the size of the piezoelectric resonators 22, 23 by size differences d1, d2. Terminal boards 31-34 are in contact with nodes produced on a face of the piezoelectric resonators 21-24. The piezoelectric resonators 21-24 and the terminal boards 31-34 are laminated to form a ladder circuit and arranged in an internal space 11 of a case 1. Positioning means 41-43 have steps a, b having a step difference corresponding to the size differences d1, d2 at a side opposite to the piezoelectric resonators 21-24 and the terminal boards 31-34. Nodes caused on the face of the piezoelectric resonators 21-24 are controlled in a direction coincident between the piezoelectric resonators by the steps a, b.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a piezoelectric resonator component used for a ladder type ceramic filter or the like, and more specifically, when a plurality of piezoelectric resonators to be provided have different sizes, the piezoelectric resonator is provided on the surface of the piezoelectric resonator. The present invention relates to a technique for matching generated nodes between piezoelectric resonators.

[0002]

2. Description of the Related Art A piezoelectric resonance component of this type is disclosed, for example, in Japanese Utility Model Laid-Open No. 63-5724. As a basic configuration, having a plurality of piezoelectric resonators and a plurality of terminal plates,
The piezoelectric resonator and the terminal plate are laminated so as to form a ladder circuit, and the laminated body is arranged in the internal space of the case with a space from the inner wall surface. Each of the piezo-resonators is a flat plate-shaped element that utilizes a surface-spreading vibration mode. Each of the terminal plates is arranged so as to contact the piezoelectric resonator at a node generated on the surface of the piezoelectric resonator and apart from the surface of the piezoelectric resonator at portions other than the contact points.

[0003]

In the piezoelectric resonance component, it may be necessary to change the size of a plurality of piezoelectric resonators provided in order to obtain the required characteristics. For example, in a ladder type filter, a case where a high selectivity is achieved and a group delay characteristic is improved is a typical example. However, as a basic structure of this type of piezoelectric resonance component, a laminated body of piezoelectric resonators and terminal plates laminated to form a ladder circuit is arranged in the internal space of the case at a distance from the inner wall surface. Since each of the terminal plates is arranged so as to contact the piezoelectric resonator at a node generated on the surface of the piezoelectric resonator, the position of the piezoelectric resonator in the case and the position of the node are not determined. If the external dimensions of multiple piezoelectric resonators are all the same, the nodes between the piezoelectric resonators can be matched by using the inner wall surface of the case as a positioning surface. If the inner wall surface of the case is used as a positioning surface, it is difficult to match the nodes generated on the surface of each piezoelectric resonator between the piezoelectric resonators. When each piezoelectric resonator is positioned with reference to the inner wall surface of the case, the distance from one side of the piezoelectric resonator positioned by the inner wall surface of the case to the node that occurs at approximately the center of the surface of the piezoelectric resonator is Since the size depends on the size of the piezoelectric resonator, the nodes do not match between piezoelectric resonators of different sizes. Therefore, the terminal plate comes into contact with the piezoelectric resonator at a position deviating from the node generated on the surface thereof, causing fluctuations in the resonance impedance and generation of unnecessary vibration modes, which deteriorates the characteristics.

As means for avoiding such problems,
Conventionally, the external shape of a plurality of piezoelectric resonators are almost the same, instead, a notch is provided in the central portion of the side of the piezoelectric resonator, or the corner of the piezoelectric resonator is cut off,
The resonance frequency was shifted. But this method
Designing, manufacturing and assembling the piezoelectric resonator is troublesome and complicated, and it is difficult to adjust the resonance frequency to a desired value. In Japanese Utility Model Publication No. 63-25779, the case is
Disclosed is a technique for preventing the above-mentioned misalignment and improper placement by providing a protrusion that is in linear contact with the piezoelectric resonator. It does not disclose a technique for matching the nodes generated in the piezoelectric resonators.

An object of the present invention is to provide a piezoelectric resonance component which can minimize the influence of the terminal plate on the surface expansion vibration mode of the piezoelectric resonator.

Another object of the present invention is to provide a ladder-type piezoelectric resonance component in which a piezoelectric resonator is incorporated in a case without causing a characteristic variation due to contact with the case.

Still another object of the present invention is to change the size of a plurality of piezoelectric resonators provided to achieve a high selectivity and improve the group delay characteristics, and to improve the node generated on the surface of the piezoelectric resonator. It is an object of the present invention to provide a piezoelectric resonance component that can surely match the piezoelectric resonators and prevent fluctuations in resonance impedance and generation of unnecessary vibration modes.

Still another object of the present invention is to provide a piezoelectric resonance component in which the piezoelectric resonator and the terminal plate are less likely to be misaligned or misplaced due to externally applied vibration or drop impact.

[0009]

In order to solve the above problems, the present invention provides a piezoelectric resonance component including a case, a plurality of piezoelectric resonators, a plurality of terminal plates, and a positioning means, wherein the case Has an internal space, the piezoelectric resonator is a rectangular flat plate-shaped element that utilizes a surface-spreading vibration mode, and at least one piezoelectric resonator has a horizontal width or a vertical width that is equal to that of another piezoelectric element. Different from that of the resonator, each of the terminal plates is in contact with a node generated on the surface of the piezoelectric resonator, and a portion except a contact point is apart from the surface of the piezoelectric resonator, and the piezoelectric resonance The child and the terminal plate are stacked so as to form a ladder circuit, and at least the periphery of the piezoelectric resonator is arranged in the internal space so as to be spaced from the inner wall surface of the internal space,
The positioning means is provided in the gap along the stacking direction of the piezoelectric resonator and the terminal plate, including the position corresponding to the node generated in the peripheral portion of the piezoelectric resonator, and the piezoelectric resonator and the terminal plate. Has a step portion having a step corresponding to the difference in the horizontal width or the vertical width on the side facing with, and by the step portion, the node generated on the surface of the piezoelectric resonator is controlled in a direction in which the piezoelectric resonators are aligned with each other. To do.

[0010]

[Function] Each of the piezoelectric resonators is a rectangular flat plate-shaped element that utilizes the surface-spreading vibration mode, and each of the terminal plates is in contact with a node generated on the surface of the piezoelectric resonator, and a portion other than the contact point is in contact. Since it is far from the surface of the piezoelectric resonator, it is possible to minimize the influence of the terminal plate on the surface expansion vibration mode of the piezoelectric resonator.

The piezoelectric resonator and the terminal plate are laminated to form a ladder circuit, and at least the periphery of the piezoelectric resonator is arranged in the internal space so as to be spaced from the inner wall surface of the internal space. It is possible to obtain a ladder-type piezoelectric resonance component incorporated in a case without causing characteristic fluctuation due to contact with.

The plurality of piezoelectric resonators provided are rectangular flat plate-shaped elements that utilize the surface-spreading vibration mode, and at least one of the piezoelectric resonators has a horizontal width or a vertical width different from that of the other piezoelectric resonators. Therefore, depending on the size of the piezoelectric resonator, high selectivity can be achieved and group delay characteristics can be improved.

The positioning means is provided in the space between the case and the piezoelectric resonator and the terminal plate along the stacking direction of the piezoelectric resonator and the terminal plate, and has a horizontal or vertical width on the side facing the piezoelectric resonator and the terminal plate. Since there is a step with a step corresponding to the difference in width, and the step controls the nodes generated on the surface of the piezoelectric resonator in the same direction between the piezoelectric resonators, there is a difference between piezoelectric resonators of different sizes. In, the nodes generated on the surface of each piezoelectric resonator can be surely matched. Therefore, it is possible to prevent the resonance impedance from fluctuating and the unnecessary vibration mode from occurring and obtain desired characteristics. Further, the positioning means can prevent the displacement of the piezoelectric resonator and the terminal plate due to the vibration applied from the outside or the drop impact, and the positional displacement of the piezoelectric resonator and the terminal plate and the incorrect arrangement can be reliably prevented.

Since the positioning means is provided within the space along the stacking direction of the piezoelectric resonator and the terminal plate, including the position corresponding to the node generated in the peripheral portion of the piezoelectric resonator, the positioning means is provided to the piezoelectric resonator. The vibration disturbance can be minimized.

[0015]

1 is an exploded perspective view of a piezoelectric resonance component according to the present invention, FIG. 2 is a partial sectional view of the piezoelectric resonance component according to the present invention shown in FIG. 1, and FIG. 3 is a line A3-A3 in FIG. FIG. Reference numeral 1 is a case, reference numerals 21 to 24 are piezoelectric resonators, reference numerals 31 to 34 are terminal plates, and reference numeral 41.
Numerals 43 are positioning means. Case 1 has internal space 11
have. The internal space 11 is open on one side of the case 1. The opening is filled with the insulating sealing resin 6. A terminal lead-out hole 12 is provided in the bottom of the case 1 on the side opposite to the opening side where the insulating sealing resin 6 is filled.

Each of the piezoelectric resonators 21 to 24 is a rectangular flat plate-shaped element that utilizes a surface expansion vibration mode. Specifically, it has a structure in which electrodes are provided on both sides of the flat piezoelectric ceramic body in the thickness direction, and when the electrolysis is applied between the electrodes on both sides of the piezoelectric ceramic body, electrostriction is generated in the diagonal direction. It is polarized to produce the phenomenon. In the face-spreading vibration mode, a node is generated at the center of the plane of the piezoelectric ceramic body. Among the piezoelectric resonators 21 to 24, the piezoelectric resonators 21 and 24 have a dimensional difference d1 in horizontal and vertical widths than that of the piezoelectric resonators 22 and 23.
And d2. In an actual embodiment, only one of the horizontal width and the vertical width may be different.

Each of the terminal plates 31 to 34 comes into contact with a node generated on the surface of the piezoelectric resonators 21 to 24, and a contact point P
The parts other than are arranged apart from the surfaces of the piezoelectric resonators 21 to 24. The terminal plates 31 to 34 are made of a copper plate, a phosphor bronze plate, or the like, and are made by pressing or the like.
The plate material used has a thickness of, for example, about 0.1 mm.
The terminal plates 31 are the first contact pieces 3 facing each other with a space therebetween.
11 and the second contact piece 312 are connected by a connecting piece 313. A protrusion 314 forming a contact point P is provided on the substantially central portion of the surface of the first contact piece 311, and a similar protrusion 315 (a lower surface The protrusions are not shown). The second contact piece 312 constitutes a kind of cantilever leaf spring. The terminal plates 32 to 34 have contact pieces 321 to 341 that form a leaf spring. Contact piece 32
1 to 341 are protrusions 322 that form a contact point P in the substantially central portion.
˜342. Reference numerals 323 to 343 are terminal portions.

Piezoelectric resonators 21-24 and terminal plates 31-3
4 are stacked so as to form a ladder circuit, and are arranged in the internal space 11 such that at least the periphery of the piezoelectric resonators 21 to 24 is spaced from the inner wall surface 12 of the internal space 11. Piezoelectric resonator 21 for forming a ladder circuit
~ 24 and the terminal boards 31 to 34 will be described with reference to Figs. 1 and 2. After inserting the terminal plate 31 into the case 1, the first contact piece 311 provided on the terminal plate 31 is inserted.
And the second contact piece 312 between the piezoelectric resonator 21, the terminal piece 32, the piezoelectric resonator 22, the terminal piece 33, and the piezoelectric resonator 23.
Are inserted in this order. Next, after inserting the terminal plate 34 into the space between the second contact piece 312 of the terminal plate 31 and the inner wall surface of the case 1, the piezoelectric resonator is inserted between the terminal plate 34 and the second contact piece 312. Insert 24. The terminal portions 322 to 342 of the terminal pieces 32 to 34 are pulled out to the outside of the case 1 and bent in the same direction along the outer surface of the case 1. As a result, a planar mounting type piezoelectric resonance component is obtained. Reference numeral 7 in FIG. 2 is a sealing resin.

FIG. 4 is an electrical symbol diagram of the piezoelectric resonance component according to the present invention. The piezoelectric resonators 21 and 24 are series resonators, the piezoelectric resonators 22 and 23 are parallel resonators, and the terminal plate 3
A ladder connection circuit having 2 as an output terminal, the terminal plate 33 as a ground terminal, and the terminal plate 34 as an input terminal is obtained.

The positioning means 41 to 43 are the piezoelectric resonator 2
The piezoelectric resonators 21 to 24 and the terminal plates 31 to 34 are provided at intervals including the positions corresponding to the nodes generated in the peripheral portions of 1 to 24 along the stacking direction. Then, on the side facing the piezoelectric resonators 21 to 24 and the terminal plates 31 to 34, step portions a and b having steps corresponding to the dimensional differences d1 and d2 of the horizontal width or the vertical width are provided. The steps a and b control the nodes generated on the surfaces of the piezoelectric resonators 21 to 24 in a direction in which the piezoelectric resonators coincide with each other. Positioning means 41-43
May be formed integrally with the case 1, or may be a separate component from the case 1 and assembled at a predetermined position. Further, it is desirable that the width be formed as narrow as possible within a range in which necessary mechanical strength can be secured.

Although not shown, the number of piezoelectric resonators,
Arrangement and size are arbitrary. The same applies to the terminal board.

As described above, the piezoelectric resonators 21 to 24 and the terminal plates 31 to 34 are laminated so as to form a ladder circuit, and at least the periphery of the piezoelectric resonators 21 to 24 is spaced from the inner wall surface of the internal space 11. Since they are arranged in the internal space 11 so as to be separated from each other, the ladder in which the piezoelectric resonators 21 to 24 and the terminal plates 31 to 34 are incorporated in the case 1 without causing characteristic variations due to contact with the case 1 A piezoelectric resonant component of the type is obtained.

Each of the piezoelectric resonators 21 to 24 is a flat plate-shaped element that utilizes a surface-spreading vibration mode, and the terminal plate 3
The piezoelectric resonators 21 to 24 are in contact with the nodes generated on the surfaces of the piezoelectric resonators 21 to 24, and the portions other than the contact points P are apart from the surfaces of the piezoelectric resonators 21 to 24.
Terminal plates 31 to 34 for the surface expansion vibration modes of
The effect of can be minimized.

Of the plurality of piezoelectric resonators 21 to 24 provided, the piezoelectric resonators 21 and 24 are smaller in lateral width and vertical width than the piezoelectric resonators 22 and 23 by the dimensional differences d1 and d2. Depending on the size of the children 21 to 24, high selectivity can be achieved and group delay characteristics can be improved.

The positioning means 41 to 43 are the piezoelectric resonator 2
1 to 24 and the terminal plates 31 to 34 are provided in the space between the case 1 and the piezoelectric resonators 21 to 24 and the terminal plates 31 to 34 along the stacking direction of the piezoelectric resonators 21 to 24 and the terminal plate 31. Width difference of vertical width and vertical width d on the side facing
Since it has step portions a and b having steps corresponding to 1 and d2, the step portions a and b control the nodes generated on the surfaces of the piezoelectric resonators 21 to 24 in the same direction between the piezoelectric resonators. ,
Piezoelectric resonators 21 and 24 and piezoelectric resonator 2 having different sizes
The nodes generated on the surfaces of the piezoelectric resonators 21 to 24 can be reliably matched between 2 and 23. Therefore, it is possible to prevent fluctuations in resonance impedance and generation of unnecessary vibration modes, and obtain desired characteristics. Also,
Piezoelectric resonator 21 due to externally applied vibration or drop impact
The positioning means 41 to 43 can prevent the positional displacement of the .about.

In the embodiment, the case 1 has an opening at one end side as viewed in the widthwise direction, and the piezoelectric resonators 21 to 24.
The terminal plates 31 to 34 are adapted to be inserted into the case 1 through the openings. Under such a structure, the positioning means 41 to 43 are arranged on one side in the lateral width direction on the side opposite to the opening side and on both sides in the longitudinal width direction. Therefore, by simply inserting the piezoelectric resonators 21 to 24 and the terminal plates 31 to 34 into the case 1, the piezoelectric resonators 21 to
24 is subjected to the positioning action by the positioning means 41 to 43. Unlike the embodiment, the positioning means 41 to 43 may be arranged on the side opposite to the opening side in the lateral width direction and on the longitudinal width direction side. Also in this case, the piezoelectric resonators 21 to 24 can be positioned at predetermined positions in the case 1.

The positioning means 41 to 43 are the piezoelectric resonator 2
Since the piezoelectric resonators 21 to 24 and the terminal plates 31 to 34 are provided at positions corresponding to the nodes generated around the peripheral portions 1 to 24 along the stacking direction, the positioning means 41 to
Vibration disturbances to the piezoelectric resonators 21 to 24 due to 43 can be minimized.

[0028]

As described above, according to the present invention, the following effects can be obtained. (A) It is possible to provide a ladder-type piezoelectric resonance component in which the piezoelectric resonator and the terminal plate are incorporated in the case without causing characteristic variations due to contact between the piezoelectric resonator and the terminal plate and the case. (B) It is possible to provide a piezoelectric resonance component that can minimize the influence of the terminal plate on the surface expansion vibration mode of the piezoelectric resonator. (C) It is possible to provide a piezoelectric resonance component that can minimize the influence of the terminal plate on the surface expansion vibration mode of the piezoelectric resonator. (D) without causing characteristic variations due to contact with the case,
We can provide a ladder type piezoelectric resonance component built in a case. (E) Due to the size of the piezoelectric resonator, it is possible to provide a piezoelectric resonance component that can achieve high selectivity and improve group delay characteristics. (F) It is possible to provide a piezoelectric resonance component capable of reliably matching the nodes generated on the surface of each piezoelectric resonator between piezoelectric resonators of different sizes, and preventing fluctuations in resonance impedance and generation of unnecessary vibration modes. (G) It is possible to provide a piezoelectric resonance component that can prevent the positional displacement of the piezoelectric resonator and the terminal plate due to the vibration applied from the outside and the drop impact, and can reliably prevent the positional displacement and the incorrect arrangement of the piezoelectric resonator and the terminal plate. . (H) It is possible to provide a piezoelectric resonance component that can minimize vibration disturbance to the piezoelectric resonator due to the positioning means.

[Brief description of drawings]

FIG. 1 is an exploded perspective view of a piezoelectric resonance component according to the present invention.

FIG. 2 is a partial front sectional view of a piezoelectric resonance component according to the present invention.

3 is a cross-sectional view taken along the line A3-A3 in FIG.

FIG. 4 is an electrical symbol diagram of the piezoelectric resonance component according to the present invention.

[Explanation of symbols]

 21-24 Piezoelectric resonator 31-34 Terminal plate 41-43 Positioning means

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Satoshi Tsushima Shima 13-1, Nihonbashi, Chuo-ku, Tokyo TDC Corporation (72) Inventor Takashi Yamamoto 1-13-1 Nihonbashi, Chuo-ku, Tokyo TDC Within the corporation

Claims (3)

[Claims] 1. A piezoelectric resonance component including a case, a plurality of piezoelectric resonators, a plurality of terminal plates, and a positioning means, wherein the case has an internal space, and the piezoelectric resonator is , A rectangular flat plate-shaped element utilizing the surface-spreading vibration mode, at least one of the piezoelectric resonator is different from that of the other piezoelectric resonator in either the width or the vertical width, each of the terminal plate The piezoelectric resonator and the terminal plate are stacked so as to form a ladder circuit, and are in contact with a node generated on the surface of the piezoelectric resonator, and parts other than contact points are apart from the surface of the piezoelectric resonator. And is arranged in the internal space so that at least the periphery of the piezoelectric resonator is spaced from the inner wall surface of the internal space, and the positioning means corresponds to a node generated in the peripheral portion of the piezoelectric resonator. Do And a step corresponding to the difference in the horizontal width or the vertical width on the side facing the piezoelectric resonator and the terminal plate, the step being provided along the stacking direction of the piezoelectric resonator and the terminal plate. A piezoelectric resonance component that has a step, and controls the node generated on the surface of the piezoelectric resonator in a direction in which the piezoelectric resonators are aligned with each other by the step. 2. The at least one piezoelectric resonator is different from the other piezoelectric resonators in both the width and the width, and the positioning means is provided on one side in the width direction and on one side in the width direction, respectively. The piezoelectric resonance component according to claim 1, wherein the piezoelectric resonance component is arranged. 3. The case has an opening at one end side when viewed in the lateral width direction, and the piezoelectric resonator and the terminal plate are inserted into the case through the opening. The piezoelectric resonance component according to claim 1, wherein the positioning means is arranged on one end side in the lateral width direction on the side opposite to the opening side and on both sides in the longitudinal width direction.