JP2003324333A - Crystal unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a very small-sized crystal unit mounted with a tuning fork type inflective crystal vibrator which has small equivalent series resistance R<SB>1</SB>and superior shock resistance. <P>SOLUTION: The tuning fork type inflective crystal vibrator which has improved electromechanical transduction efficiency and has small equivalent series resistance R<SB>1</SB>is obtained since a groove is provided on the top and reverse surfaces of a center part across the neutral line of a tuning fork arm and an electrode is provided opposite the groove. Further, the mechanical strength of the vibrator can greatly be increased by arranging a connection part between the groove and a tuning fork base part. Consequently, a very small-sized crystal unit which has small equivalent series resistance R<SB>1</SB>and superior shock resistance can be provided by mounting the vibrator on the unit. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a crystal unit accommodating a tuning fork type bent crystal oscillator. In particular, the present invention relates to a crystal unit having an optimum vibrator shape and electrode formation as a reference signal source for a portable device which is strongly required to be compact, highly accurate, shock resistant, and inexpensive.

[0002]

2. Description of the Related Art FIGS. 8A and 8B show a crystal unit 101 accommodating a conventional tuning fork type bent crystal unit 100.
FIG. 3 is a front view with the lid omitted, and a side view with the lid attached. The tuning fork type bent crystal oscillator 100 is configured to include tuning fork arms 102 and 103 and a tuning fork base portion 104. The tuning fork base portion 104 is fixed to the fixing portion 106 of the case 105 with adhesives 107, 108 and the like. or,
Electrodes 109 and 110 are arranged on the fixed portion 106 to form a two-electrode terminal. Further, the case 105 and the lid 111 are joined via a metal 112. The conventional crystal unit is configured in this way, but if the crystal unit is made smaller, the crystal oscillator is also required to be made smaller. FIG. 9 shows a sectional view of the tuning fork arm of FIG. The cross-sectional shape of the tuning fork arm is generally rectangular. An electrode 203 is arranged on the upper surface and an electrode 204 is arranged on the lower surface of the cross section of one tuning fork arm. Electrodes 205 and 206 are provided on the side surfaces. An electrode 207 is arranged on the upper surface of the other tuning fork arm, an electrode 208 is arranged on the lower surface, and electrodes 209 and 210 are arranged on the side surfaces, forming a two-electrode terminal H-H 'structure. Further, for example, JP-A-56-65517 and JP-A-2000-2239.
92 (P2000-223992A) and Japanese Patent Laid-Open No. 2002-2002.
In 76827 (P2002-76827A), a groove is provided in a tuning fork arm of a tuning fork type bent crystal oscillator, and an electrode configuration thereof is disclosed.

[0003]

Equivalent series resistance R ₁ as the electric field component E _x is greater decreases in tuning-fork flexural crystal oscillator [0005], the quality factor Q value increases. However, as shown in FIG. 9, the conventional tuning fork type bent crystal oscillator has electrodes arranged on the front and back side surfaces of each tuning fork arm. For this reason, the electric field does not work linearly, and when the tuning fork type bent crystal oscillator is downsized, the electric field component _Ex becomes small and the equivalent series resistance R ₁ becomes large. At the same time, there were still problems such as a large change in frequency with temperature. Further, for example, Japanese Patent Laid-Open No. 56-65517 discloses the provision of grooves in the tuning fork arm and the tuning fork base. However, there is no disclosure regarding improvement of frequency-temperature characteristics, and further, regarding a crystal unit. Furthermore, the above-mentioned conventional JP-A-2002-76827 (P2002-7682)
7A), a groove is provided up to the fork of the tuning fork arm. As a result, the mechanical strength of the tuning fork arm is weakened, and the problem that the oscillator is destroyed by the impact remains. Therefore, in order to realize a small-sized crystal unit excellent in impact resistance and frequency-temperature characteristics, it is extremely small, the equivalent series resistance R ₁ is small, the quality factor Q value is high, and the mechanical strength is strong. A crystal unit having a new shape and including a tuning fork type bent crystal oscillator having an electrode arrangement configuration with high electromechanical conversion efficiency has been desired.

[0004]

SUMMARY OF THE INVENTION It is an object of the present invention to provide a crystal unit that advantageously solves the conventional problems by the following method.

That is, a first aspect of the crystal unit of the present invention is a crystal unit including a crystal unit, a surface-mounting type case for housing the crystal unit, and a lid. In the case, as the crystal unit, a tuning fork type bending crystal unit, in which a tuning fork arm and a tuning fork base are integrally formed and vibrates in a bending mode, is fixed to a fixing portion of the case by an adhesive or solder. In the crystal unit in which the case and the lid are joined via a joining member, a groove is provided in the tuning fork arm of the tuning fork type bent crystal oscillator, and the groove connects the tuning fork arm and the tuning fork base of the oscillator. A connection portion is provided at a position above the fork portion and between the groove of the tuning fork arm and the tuning fork base portion, and the side surface of the tuning fork arm, the groove, the tuning fork base portion and the connection portion are provided. The electrodes are arranged, the groove and the The electrodes placed or base be connected through the electrodes arranged in the connecting portion, further,
The electrode on the side face of the tuning fork arm and the electrode on the tuning fork base are connected to each other via the electrode disposed in the vicinity of the fork adjacent to the x-axis (width) direction of the electrode disposed in the connection part. It is a crystal unit characterized in that a connection electrode is provided.

A second aspect of the crystal unit of the present invention is a crystal unit comprising a crystal unit, a surface mount type case for accommodating the crystal unit, and a lid. As the crystal unit, a tuning fork type bending crystal unit, in which a tuning fork arm and a tuning fork base are integrally formed and vibrates in a bending mode, is fixed to a fixing portion of the case, and the case and the lid are provided. Is a crystal unit bonded through a bonding member, wherein a plurality of tuning fork type bent crystal vibrators are fixed to a fixing portion of the case, and the vibrators are electrically parallel to each other. This is a crystal unit in which the electrode and the electrode provided on the back surface of the case are connected and configured.

[0007]

As described above, the present invention is the crystal unit, wherein the tuning fork arm is provided with a groove, the groove is provided above the fork of the vibrator, and the electrode is arranged in the groove. By adopting the vibrator, it is possible to provide a microminiature crystal unit having excellent electrical characteristics and impact resistance.

Further, the crystal unit of the present invention accommodates a plurality of tuning fork type bent crystal oscillators, and the electrodes are configured so as to be electrically parallel to each other, so that a synthesized equivalent series resistance is obtained. Can be made smaller. At the same time, the frequency temperature characteristic can be improved by employing a plurality of vibrators having different frequency temperature characteristics, that is, different peak temperatures.

Further, by providing a tuning fork type bent crystal unit having a new shape and a new electrode structure used in the present invention, it is possible to realize an inexpensive crystal unit which is ultra-compact, excellent in quality.

[0010]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the crystal unit of the present invention will be specifically described below with reference to the drawings.

FIGS. 1 (a) and 1 (b) are a front view of a first embodiment of a crystal unit of the present invention without a lid and a side view with a lid. The crystal unit 1 of this embodiment comprises a case 2, a tuning fork type bent crystal oscillator 3 and a lid 19. Further, the tuning fork type bent crystal oscillator 3 comprises tuning fork arms 4 and 5 and a tuning fork base portion 6, and the tuning fork base portion 6 is attached to a fixing portion 7 provided in the case 2 with a conductive adhesive 8, 9 or It is fixed by solder.
Further, the tuning fork arms 4 and 5 are provided with grooves 10 and 11, and in this embodiment, the grooves provided on the tuning fork arm are provided above the fork portions. The details of the tuning fork type bent crystal oscillator housed in the case of the crystal unit of the present embodiment and other embodiments will be described in detail with reference to FIGS. 2 to 7. In addition, from the base of the tuning fork to the tip of the tuning fork arm, it is defined as bottom to top.

Further, electrodes 12 and 13 are arranged on the fixed portion 7 and are connected to electrodes of different polarities arranged on the tuning fork base portion 6, respectively. That is, it constitutes a two-electrode terminal. Further, the electrode 12 of the fixed portion 7 is arranged so as to extend to one end of the back surface of the case 2 and has the same polarity as the electrode 14. On the other hand, the electrode 13 of the fixed portion 7 is arranged to extend to the other end of the back surface of the case 2 and has the same polarity as the electrode 15.
Further, the case 2 and the lid 19 are joined via the joining member 16.

In this embodiment, the electrodes 14 and 15 are
The electrodes 14 and 15 may be provided at arbitrary positions on the back surface of the case, though the electrodes are provided at opposite ends of the case 2. Further, the electrode structure on the back surface of the case 2 is also applied to the cases of the embodiments described below.

Further, in this embodiment, the case 2 is provided with a hole 17 for sealing in a vacuum and is sealed with a sealing member 18. In this embodiment, ceramics or glass is used as the material of the case, glass or metal is used as the material of the lid, and low melting point glass or metal containing solder is used as the joining member for joining the case and the lid. Similarly, a metal having a low melting point glass or solder is used as a sealing member for sealing the hole.

Further, in this embodiment, the case 2 is provided with the hole 17 for sealing in vacuum, but the case 2 is not provided with the hole 17 for vacuum sealing, and the case and the lid are May be directly sealed in a vacuum via a joining member. The configurations of the case and the lid of this embodiment are also applied to the cases and lids of other embodiments described below.

FIG. 2 shows an external view and a coordinate system of a tuning fork type bent crystal oscillator 21 which is housed in the case 2 and constitutes the crystal unit of this embodiment together with the case and the lid 3 for sealing the case. It is a thing. The coordinate system O, the electric axis x, the mechanical axis y, and the optical axis z constitute O-xyz. The tuning fork type bent crystal oscillator 21 of the present embodiment includes a tuning fork arm 22 and a tuning fork arm 2.
3 and a tuning fork base 24, and a tuning fork arm 22 and a tuning fork arm 23.
Are connected to the tuning fork base 24. In addition, tuning fork arm 22
A groove 25 is provided on the upper surface of the tuning fork arm 23 across the neutral line, and a groove 31 is provided on the upper surface of the tuning fork arm 23 similarly to the tuning fork arm 22. It should be noted that in FIG. 2, the electrodes arranged on the tuning fork type bent crystal oscillator 21 are omitted, and the angle θ is a rotation angle around the x axis and is usually selected in the range of 0 to 10 °.

FIG. 3 is a sectional view of the tuning fork type bent crystal oscillator 21 of FIG. Here, A- of the tuning fork arm 22 in FIG.
A sectional view taken along the line A ′ is shown on the right side of the paper in FIG. 3, and a sectional view taken along the line BB ′ of the tuning fork arm 23 in FIG. 2 is shown on the left side of the paper in FIG. Grooves 25 and 26 are provided on the upper and lower surfaces of the tuning fork arm 22 so as to sandwich the neutral line. Further, the electrode 27 is arranged in the groove 25, the electrode 28 is arranged in the groove 26, and the electrodes 29, 30 are arranged on the side surfaces thereof, so that the electrodes 27, 28 and the electrodes 29, 30 are different electrodes. Is configured. More specifically, two step portions are provided in the width direction of the upper and lower surfaces of each tuning fork arm along the length direction of the tuning fork arm, and electrodes having the same polarity are provided on the two step portions. Is placed
The electrodes arranged on the side surface facing each of the electrodes have different polarities. At the same time, the grooves 25 and 26 of the tuning fork arm 22 and the electrodes 27 and 28 are provided at positions above the forks of the tuning fork arm, and the side electrodes 29 and 30 are provided to extend to the tuning fork base 24. .

Similarly to the tuning fork arm 22, grooves 31 and 32 are provided on the upper and lower surfaces of the tuning fork arm 23 so as to sandwich the neutral line. An electrode 33 is arranged in the groove 31 and an electrode 34 is arranged in the groove 32. Further, electrodes 35 and 36 are arranged on the side surfaces thereof, and the electrodes 33 and 34 and the electrodes 35 and 36 are different electrodes. Also, tuning fork arm 22
And the electrodes of the tuning fork arm 23 are connected as shown in FIG.
A two-electrode terminal structure C-C 'is formed. Now, the electrode terminal C-
When a DC voltage is applied across C ′, tuning fork arm 22 and tuning fork arm 2
3 in the electric field E _x acts in each direction of the arrow. Since this electric field E _x is perpendicular to the electrodes in the tuning fork arms, i.e. linear works,
The electric field _Ex becomes large and the generation of strain becomes large. As a result, even when the tuning fork type bent crystal oscillator 21 is downsized, a tuning fork type bent crystal oscillator with a small loss equivalent series resistance R ₁ and a high quality factor Q value can be obtained.

FIG. 4 is a top view of the tuning fork type bent crystal oscillator 69. In FIG. 4, the arrangement of the grooves 71, 77 and the electrodes will be described in detail. A groove 71 is provided in the tuning fork arm so as to sandwich the neutral line 91 of the tuning fork arm 70, and is provided at a position above the fork portion. Further, an electrode 73 is arranged in the groove 71, and the tuning fork arm 70 and the electrode 73 of the tuning fork base 90 are connected via the electrode 71b arranged in the connecting portion 71a. Further, the electrode 75 on the side surface of the tuning fork arm 70 and the electrode 84 on the tuning fork base portion are connected to the electrode 71b arranged at the connection portion 71a.
Adjacent to each other in the x-axis (width) direction and connected to the tuning fork arm via the electrode 71c (connection electrode) provided on the tuning fork base.

Similarly, the other tuning fork arm 76 is also provided with a groove 77 on the tuning fork arm so as to sandwich the neutral line 92, and is provided above the fork portion. Further, an electrode 79 is arranged in the groove 77, and the electrode 79 of the tuning fork arm 76 and the tuning fork base 90 are connected via the electrode 77b arranged in the connecting portion 77a. Further, the electrode 81 on the side surface of the tuning fork arm 76 and the electrode 88 on the tuning fork base portion are the electrodes 77b arranged in the connection portion 77a.
Are adjacent to each other in the x-axis (width) direction and are connected via an electrode 77c (connection electrode) provided near the fork (tuning fork arm or tuning fork arm and tuning fork base). Further, electrodes 73a and 79a having polarities different from each other are provided at the ends of the tuning fork base 90. The grooves on the back surface and the electrodes are similarly constructed.
The tuning fork arm is composed of at least a groove and a connecting portion.

More specifically, the length l of the groove in the tuning fork arm is
₁ is provided, and the groove is provided at a position higher than a fork portion where the tuning fork arm and the tuning fork base portion of the vibrator are connected. There is a connecting portion between the groove provided on the tuning fork arm and the tuning fork base portion. Electrodes are arranged on the side surface of the arm, the groove, the tuning fork base and the connecting portion, the electrodes arranged on the groove and the tuning fork base are connected through the electrode arranged on the connecting portion, and further arranged on the connecting portion. A connecting electrode is provided so that the electrode on the side surface of the tuning fork arm and the electrode on the tuning fork base are connected via the electrode provided adjacent to the forked portion in the vicinity of the forked portion in the x-axis (width) direction. . Further, the electrode arranged opposite to the electrode on the side surface of the groove is connected to the electrode on the side surface of the connecting portion. As described above, in this embodiment, since the connecting portion is provided between the groove of the tuning fork arm and the tuning fork base portion, the mechanical strength in the vicinity of the fork portion is remarkably increased, and the tuning fork type bending crystal vibration excellent in impact resistance is provided. I have a child.

Further, the overall width W of the tuning fork arms 70 and 76 is W = W
It is given by ₁ + W ₂ + W ₃ , and is usually designed so that W ₁ = W ₃ . Further, the groove width W ₂ is designed under the condition that W ₂ ≧ W ₁ and W ₃ are satisfied. Moreover, specifically by the ratio of the groove width _{W 2} and the tuning fork arm width W _(W 2 / W) is 0.35
It is formed to be 0.85. By forming in this way, the second moment of inertia based on the neutral line 91 and the neutral line 92 of the tuning fork arm becomes large. That is, since the electromechanical conversion efficiency is improved, the equivalent series resistance R ₁ is small,
A tuning fork type bent crystal oscillator having a high Q value and a small capacity ratio can be obtained.

Further, in this embodiment, the tuning fork base 90 is
In FIG. 4, the entire lower part of the length l ₂ of the vibrator 69 is defined as
Further, the tuning fork arm 70 and the tuning fork arm 76 are the oscillator 69 in FIG.
From the length l ₂ portion to the entire upper portion. In this embodiment, the fork of the tuning fork has a rectangular shape, but the present invention is not limited to the above shape, and the fork of the tuning fork may have a U shape. In this case as well, similar to the rectangular shape, the dimensional relationship between the tuning fork arm and the tuning fork base is the same as the above relationship.

Further, in this embodiment, the electrodes adjacent to each other in the x-axis direction (width direction) of the tuning fork base are arranged so that their polarities are different from each other. That is, four electrodes are arranged on the upper and lower surfaces, and in this case, the counter electrodes in the thickness direction have the same polarity. By configuring in this way,
Since the amount of strain of the tuning fork base portion becomes large, it is possible to obtain a tuning fork type bent crystal oscillator having a small equivalent series resistance R ₁ .

Although not shown, a hole for electrode connection may be provided in the tuning fork arm or tuning fork base in order to connect the electrodes on the upper surface and the lower surface of the tuning fork type bent crystal unit.

Further, in the present embodiment, the planar connecting portion is provided between the groove of the tuning fork arm and the tuning fork base portion, but the shape of the connecting portion of the present invention is not limited to this. The connecting portion of the present invention includes any shape as long as the cross section in the length direction of the connecting portion has a stepped portion with respect to the length direction of the tuning fork arm.

FIG. 5 is a front view of the crystal unit of the second embodiment of the present invention with the lid omitted. The crystal unit 400 of this embodiment includes a case 401 and the case 401 shown in FIG.
The tuning fork type bent crystal oscillator 21 has the same groove configuration and electrode arrangement as the tuning fork type bent crystal oscillator 21 and two tuning fork type bent crystal oscillators 402 and 403, and a lid (not shown). Further, one tuning fork type bent crystal oscillator 402 is configured to include tuning fork arms 404 and 405 and a tuning fork base portion 406. Similarly, the other tuning fork type bent crystal oscillator 403
Is composed of tuning fork arms 407 and 408 and a tuning fork base 409.

Further, the tuning fork base portions 406 and 409 are case 4
01 is fixed to a plurality of portions of the fixing portion 411 provided on 01 with conductive adhesives 412, 413, 414, 415 or solder. Further, the groove 4 is formed on the tuning fork arms 404 and 405.
16 and 417, the tuning fork arms 407 and 408 have grooves 418,
419 is provided.

The fixed portion 411 has four electrodes 420,
421, 422, 423 are arranged and the tuning fork base 4
06 and 409 are respectively connected to electrodes having different polarities. That is, in the present embodiment, the tuning fork type bent crystal oscillator 402 and the tuning fork type bent crystal oscillator 40.
3 and 2 respectively form two electrode terminals. Further, as a modification of the electrode configuration of the present embodiment, at least two electrodes, for example, the electrodes 421 and 422 may be configured as a common electrode (one electrode).

Further, although not shown, the fixing portion 411
The four electrodes 420, 421, 422, and 423 are arranged to extend to the back surface of the case 401. Or
At least two of the electrodes are common electrodes, and three electrodes or two electrodes are arranged on the back surface.

More specifically, the electrode on the back surface of the case is constructed so that the tuning fork type bent crystal unit 402 and the tuning fork type bent crystal unit 403 are electrically parallel to each other. That is, when the two tuning fork type bent crystal oscillators 402 and 403 are excited by an electric signal, the electrode configuration in which both oscillators are electrically connected in parallel is called an electrically parallel configuration.

Further, both tuning fork type bent crystal oscillators 402, 4
By changing the angle of the crystal plane of the crystal forming 03, both crystal oscillators can have different frequency temperature characteristics. That is, it is possible to obtain tuning fork type bent crystal oscillators having different peak temperatures. Further, by electrically connecting these crystal oscillators in parallel, it is possible to improve the frequency-temperature characteristic of the tuning fork type bent crystal oscillator. In order to obtain good frequency-temperature characteristics, both oscillators 402, 403
It is preferable that the frequency difference with
Further, in FIG. 6, both tuning fork type bent crystal oscillators 402 and 403 are shown.
The electrical connection diagram of is shown. Furthermore, although not shown,
A capacitor may be connected to at least one of the oscillators 402 and 403 in series with the oscillator to match the frequencies of both oscillators. Further, the capacitor has a groove formed on the back side of the case and is arranged in this groove.

Furthermore, both crystal oscillators 402 and 4 are provided in the case.
A partition part for preventing the interference of the vibration of 03 may be provided between both vibrators 402 and 403. Further, the height of the partition portion is provided so as to be equal to or lower than the height of the case. For example, a partition part for preventing vibration interference of two tuning fork type bent crystal oscillators may be provided between both crystal oscillators so as to be continuous with the case. Even if both crystal oscillators are integrally formed at the base via the connection part and formed so as to be integrated with both crystal oscillators between both crystal oscillators, the interference of the vibrations of both crystal oscillators is prevented. be able to.

FIG. 7 shows the tuning fork type bent quartz crystal resonator 402,
An example of frequency-temperature characteristics of the crystal unit of this embodiment including 403 will be shown. When one oscillator 402 in FIG. 6 has a temperature characteristic 430 and the other oscillator 403 has a temperature characteristic 431, the frequency-temperature characteristics of both crystal oscillators are as shown by a curve 432 when electrically connected in parallel. become. That is, the tuning-fork type flexural vibrator of the present example has the frequency-temperature characteristic as shown by the curve 432, and as a result, a crystal resonator having stable characteristics with little frequency change with respect to temperature change can be obtained. it can. As a result, the crystal unit of the present embodiment can be realized as an ultra-small crystal unit having excellent frequency-temperature characteristics.

Further, although the tuning fork type bent crystal oscillator of the above embodiment is composed of two tuning fork arms, the present invention is not limited to this, and the number of tuning fork arms may be three or more. .

Further, in order to obtain tuning fork type bent crystal oscillators having different frequency temperature characteristics, the oscillators may be formed to have different dimensions.

In the second embodiment, the two individually formed tuning fork type bent crystal oscillators are housed in the crystal unit, but the present invention is not limited to this and three or more. But good. Furthermore, two or more integrally formed tuning fork type bent crystal oscillators may be used. For example, two tuning fork type bent crystal oscillators are integrally formed on the side surface of the tuning fork base of each oscillator via a connecting portion. Further, in the present invention, connection in any shape and integral molding via the connecting portion in the tuning fork base portion are included. Further, the vibrator of this embodiment may be housed in a cylindrical shape. The crystal unit of the above embodiment is formed by using a chemical or physical etching method.

As described above, according to the crystal unit of the present invention, the following remarkable effects can be obtained. (1) Since a groove is provided so as to sandwich the neutral line of the tuning fork arm and the electrode is arranged in the groove, and the groove is provided above the fork, the strength near the fork is increased. Therefore, it is possible to obtain a very small tuning fork type bent crystal oscillator having excellent impact resistance, a small equivalent series resistance R ₁ , and a high quality factor Q value. The crystal unit can be realized with high quality. (2) Since a plurality of tuning fork type bent crystal oscillators are formed individually or integrally and are connected in parallel as electrodes, the equivalent series resistance R ₁ is reduced. For example, when the two have the same equivalent series resistance R ₁ , the vibrator of the present invention has about half the equivalent series resistance. That is, a crystal unit having a small equivalent series resistance can be realized by mounting a plurality of vibrators. (3) Since a plurality of tuning fork type bent crystal oscillators formed individually or integrally are mounted, even if one of them is damaged for some reason, the function as a crystal unit is maintained. be able to. (4) Since a plurality of tuning fork type bent crystal oscillators are housed in the same unit case instead of being housed in separate unit cases, an inexpensive crystal unit can be realized. At the same time, by electrically connecting these vibrators in parallel, a crystal unit having excellent frequency-temperature characteristics can be obtained.

[Brief description of drawings]

1A and 1B are a front view of a first embodiment of a crystal unit of the present invention with a lid omitted, and
It is a side view in the state with a lid.

2A and 2B are an external view and a coordinate system of a tuning fork type bent crystal unit that constitutes the crystal unit of the first embodiment.

3 is a sectional view taken along the line AA ′ and a sectional view taken along the line BB ′ of the tuning fork arm of FIG.

FIG. 4 is a top view of a tuning fork type bent crystal oscillator of the present invention.

FIG. 5 is a front view of a crystal unit according to a second embodiment of the present invention with a lid omitted.

FIG. 6 is an electrical connection diagram of the tuning fork type bent crystal oscillator of FIG.

FIG. 7 is a relationship diagram showing an example of frequency temperature characteristics of the crystal unit of the second embodiment.

8 (a) and 8 (b) are a front view of a conventional crystal unit without a lid and a side view with a lid.

9 is a cross-sectional view showing a tuning fork arm of the conventional tuning fork type bent crystal unit shown in FIG.

[Explanation of symbols]

1, 101, 400, crystal unit 2, 105, 401, case 3, 21, 69, 402, 403, tuning fork type bent crystal oscillator 4,5, 22, 23, 70, 76, 404, 405, 4
07,408 Tuning fork arm 6,24,90,406,409 Tuning fork base 10,11,25,26,31,32,71,77,4
16,417,418,419 Grooves 12,13,14,15,27,28,29,30,3
3,34,35,36,71b, 71c, 73,75,
73a, 77b, 77c, 79, 79a, 81, 84,
88, 203, 204, 205, 206, 207, 20
8,209,210,420,421,422,423
Electrodes 19, 111 Lids 71a, 77a, Connection part l ₁ Groove length l ₂ Tuning fork base part length

[Outer 1]

[Outside 2]

Claims (2)

[Claims] 1. A crystal unit comprising a crystal unit, a surface mount type case for housing the crystal unit, and a lid, wherein the case is a tuning fork as the crystal unit. A tuning fork type bending crystal unit, in which an arm and a tuning fork base are integrally formed and vibrates in a bending mode, is fixed to a fixing portion of the case by an adhesive or solder, and the case and the lid are connected via a joining member. In the joined crystal unit, a groove is provided in the tuning fork arm of the tuning fork type bent crystal oscillator, and the groove is provided at a position above a fork part where the tuning fork arm and the tuning fork base of the oscillator are connected, A connecting portion is present between the groove provided in the tuning fork arm and the tuning fork base, and electrodes are arranged on the side surface of the tuning fork arm, the groove, the tuning fork base and the connecting portion, and the groove and the The electrodes arranged at the base of the tuning fork are The tuning fork is connected via an electrode arranged in the connecting portion, and further, through an electrode provided in the vicinity of the fork adjacent to the electrode arranged in the connecting portion in the x-axis (width) direction. A crystal unit, wherein a connection electrode is provided so that an electrode on a side surface of an arm and an electrode on a base of the tuning fork are connected to each other. 2. A crystal unit comprising a crystal unit, a surface-mounting type case for housing the crystal unit, and a lid, wherein the case includes the tuning fork as the crystal unit. A tuning fork type bending crystal oscillator, which has an arm and a tuning fork base formed integrally and vibrates in a bending mode, is fixed to a fixing portion of the case, and the case and the lid are joined via a joining member. In the crystal unit, a plurality of tuning fork type bent crystal oscillators are fixed to a fixed part of the case, and the electrodes of the oscillator and the back surface of the case are provided so that the oscillators are electrically parallel to each other. A crystal unit characterized by being connected and configured with electrodes.