KR20040033098A - Quartz crystal - Google Patents

Abstract

PURPOSE: A quartz vibrator is provided to reduce largely a size and improve the productivity by forming a pin and a lead with one body and lowering the height. CONSTITUTION: A quartz vibrator includes a base(10), a lead part(20), a glass part(30), and a piezoelectric element. A receiving groove(11) is formed at an upper part of the base(10). A plurality of through-holes(12) are formed at both sides of the base. A plurality of stoppers(21) are formed at both sides of the lead part(20). A loading part(22) is formed between the stoppers(21). A plurality of ground lead(23) are formed at a front side and a rear side of the lead part. A plurality of lead holes are formed at both sides of the glass part(30). The glass part is inserted between the lead part and the base. The piezoelectric element is installed on the loading part(22).

Description

Crystal Oscillator {QUARTZ CRYSTAL}

The present invention relates to a crystal oscillator, and in particular, it is possible to manufacture a small crystal oscillator even by changing the base structure of the crystal oscillator to form a metal material, and mass production by changing the structure of the lead and forming and assembling a rolled lead It relates to a crystal oscillator capable of.

In general, a crystal oscillator is connected to a conductor electrode so as to be electrically connected to both sides of the crystal oscillation piece is supplied with an electrical signal to vibrate by a piezoelectric effect to supply a stable frequency.

The crystal oscillator is made of metal as the base, but glass is used as insulating material to cut off the current between the base and the lead. Also, Kovar is used as low as hard glass. Cobar is more expensive than metal, but it is possible to produce a small size of crystal oscillator.

On the other hand, crystal oscillators are becoming smaller due to the use of ceramics.

Although the ceramic crystal oscillator is small and can be mounted on the surface of the PCB, it is difficult to use for low frequency use of frequency and the manufacturing cost is high. On the other hand, the crystal oscillator using metal has low manufacturing cost. .

A typical example of such a conventional crystal oscillator is shown in FIG.

In Fig. 1, reference numeral 1 denotes a lead hole, 2 indicates a base, 3 indicates a lead, 4 indicates a glass, 5 indicates a pin, and 6 indicates a piezoelectric element.

As shown in the drawing, a conventional crystal oscillator forms a base 2 having a pair of lead holes 1 formed therein, and inserts a lead 3 into the lead hole 1 of the base 2 and the base 2 ) Is inserted into the lead hole 1 of the base 2 and the lead 3 is inserted into the center of the glass 4 so that the lead and the lead 3 are insulated. After the upper end of the base 2 is coupled to protrude to the upper end of the lead hole 1, the glass 4 is melted and solidified to form the lead 3 and the base 2 to be fixed in an insulating state.

The upper end of the lead 3 formed as described above is contacted and fixed by welding the pin 5, the piezoelectric element 6 is placed on the upper side of the pin and the piezoelectric element 6 vibrates by the piezoelectric effect when the current is applied. To form.

However, the crystal oscillator as described above is easy to manufacture and inexpensive, but the crystal oscillator has high height and overall size due to the shape of the pin, so as a crystal oscillator for reference frequency generator such as high speed wireless LAN, WAN, SOENT, high speed broadband mobile communication, etc. It was not suitable for use, and it was troublesome to assemble the pin-shaped lead and the pin where the piezoelectric element was placed. There was a problem that mass production was difficult due to the lead formed in each shape.

Accordingly, the present invention has been made in view of the above-mentioned problems of the prior art, and the pin and the lead are integrated to reduce the height of the crystal oscillator to reduce the size of the crystal oscillator, thereby expanding the range of use and forming the lead in a large roll shape. The purpose of the present invention is to provide a crystal oscillator capable of mass production by facilitating the use of the present invention.

In order to achieve the above object, the present invention forms a receiving groove of a predetermined size to the upper side and the base formed a through hole on both sides, and forming a locking pin on both sides to be inserted into the through hole of the base and the locking pin Between the lead portion is formed between the bent and connected to the engaging pin and bent downward to form a ground lead in the front and rear, interposed between the lead portion and the base to fix the lead portion and the base in an insulated state A crystal oscillator comprising a glass portion having a lead hole formed therein, and a piezoelectric element placed in the set rest between the engaging pins of the lead portion, the piezoelectric element being placed to cause vibration by a piezoelectric effect when a current is applied to the ground lead. do.

The lead portion is formed with a locking pin in the front and rear on both sides and the bending pins on the horizontal line between the locking pins and bent below the locking pin to form a ground lead in the front and rear, but the end of the ground lead is the upper side And a crystal oscillator, characterized in that formed in the shape of a roll of a lead sheet so as to form a bent portion and bent downwardly between the ground leads to integrally connect the connecting rods connecting the ground leads on both sides and to be continuously connected to the connecting rods. do.

1 is a cross-sectional view showing a conventional crystal oscillator,

2 is an exploded perspective view showing a crystal oscillator according to the present invention,

3 is a cross-sectional view showing a crystal oscillator according to the present invention,

4 is an assembled bottom perspective view showing a crystal oscillator according to the present invention;

5 is a cross-sectional view showing a state before polishing of the crystal oscillator according to the present invention,

6 is an assembled bottom perspective view showing a polishing state of the crystal oscillator according to the present invention;

7 is a perspective view showing a lead sheet of a crystal oscillator according to the present invention.

<Description of Symbols for Main Parts of Drawings>

10: base 11: receiving groove

12: through hole 20: lead portion

21: Hanging piece 22: Rest rest

23: ground lead 24: bend

25: connecting rod 30: glass part

31: lead hole 40: piezoelectric element

Hereinafter, a preferred embodiment of the present invention as described above with reference to the accompanying drawings in detail as follows.

2 is an exploded perspective view showing a crystal oscillator according to the present invention, Figure 3 is a cross-sectional view showing a crystal oscillator according to the present invention and Figure 4 is an assembled bottom perspective view showing a crystal oscillator according to the present invention.

As shown therein, the crystal oscillator of the present invention forms a base 10, but the base 10 forms a receiving groove 11 of a predetermined size upward and a through hole 12 on both sides. do.

The lead part 20 is formed to be inserted into the through hole 12 of the base 10 formed as described above, but the lead part 20 forms a locking pin 21 at both sides, and is placed between the locking pins 21. The base 22 is bent inwardly and connected to the locking pin 21 and bent to be spaced apart by a predetermined distance downward to form a ground lead 23 in the front and rear directions.

A glass portion 30 is formed between the lead portion 20 and the base 10 as described above, but the glass portion 30 has lead holes at both sides such that the locking pins 21 and the rest 22 are inserted. 31 is formed between the bent and spaced apart of the engaging pin 21 and the ground lead 23 is formed to melt and solidify the lead portion 20 and the base 10 to be fixed in an insulating state.

In addition, the piezoelectric element 40 is placed in the rest 22 between the engaging pins 21 of the lead portion 20, but the piezoelectric element 40 has a current in the ground lead 23 of the lead portion 20. When applied, it is formed to cause vibration by the piezoelectric effect.

As shown in FIG. 7, the lead part 20 formed as described above forms a locking pin 21 at both front and rear sides, and a rest 22 bent on a horizontal line between the locking pins 21. And forming the grounding lead 23 in the front and rear by forming the bending pin 21 under the hooking pin 21, and the end of the grounding lead 23 forms the bent portion 24 upwardly. It is bent to the lower side to integrally form a connecting table 25 for connecting the ground lead 23 on both sides and the connecting table 25 is formed in the shape of a roll of the lead sheet 200 to be continuously connected to form a cutting use .

Referring to the operation and effects of the present invention configured as described above are as follows.

First, when assembling the crystal oscillator is formed a lead sheet 200 is formed with the engaging piece 21, the support stand 22, the ground lead 23 and the like, the lead sheet 200 has a plurality of leads 20 Is connected and formed.

When the insert 22 and the engaging piece 21 of the lead portion 20 formed as described above are inserted into the through hole 12 formed in the base 10, the glass part is temporarily molded when the inserted through hole 12 is inserted into the through hole 12. 30 is interposed between the lead portion 20 and the base 10.

In such a state, after cutting the connecting table 25 of the lead sheet 200, the glass unit 30 is fired to melt and infiltrate the glass unit 30 to induce the lead unit 20 and the base 10. To be insulated.

As described above, when the lead portion 20 and the base 10 are fixed by melting the glass portion 30, the glass 20 protrudes in the same state as the connecting rod 25 bent downward as shown in FIGS. 5 to 6. The portion 30 is solidified and solidified in the front and rear by the bent portion 24 to the same width as the base 10.

In the above state, when the protruding glass portion 30 and the connecting rod 25 are ground by grinding, as shown in FIGS. 3 to 4, the ground leads 23 are polished while leaving the ground leads 23 at both sides. The ground lead 23 is formed on the same line as 30, and in this state, the piezoelectric element 40 is placed on the support 22 of the lead part 20 to fix the fixing cap not shown upward. .

As described above, the present invention expands the range of use by integrating the pin and the lead to lower the height of the crystal oscillator to form the crystal oscillator in an ultra-thin shape, thereby forming the lead in a large roll shape to facilitate the assembly and mass production. This improves productivity and increases product efficiency.

In the above, the present invention has been illustrated and described by way of specific preferred embodiments, but the present invention is not limited to the above-described embodiments, and the present invention is not limited to the spirit of the present invention. Various changes and modifications can be made by those who have

Claims (2)

A base having a constant size receiving groove formed on the upper side and a through hole formed on both sides thereof; Lead parts formed with a locking pin on both sides to be inserted into the through hole of the base, and between the locking pins to be bent inward to the inner rest, connected to the locking pin and bent downward to form a ground lead in front and rear; A glass part interposed between the lead part and the base and having lead holes formed at both sides to fix the lead part and the base in an insulated state; Crystalline oscillator, characterized in that consisting of a piezoelectric element which is placed to cause vibration by the piezoelectric effect when the current is applied to the ground lead in the rest band between the engaging pin of the lead portion. The lead portion is formed with a locking pin in the front and rear on both sides and the bending pins on the horizontal line between the locking pins and bent below the locking pin to form a ground lead in the front and rear, but the end of the ground lead is the upper side The crystal oscillator, characterized in that the bent portion and the ground lead is bent to the lower side between the ground lead is formed integrally to connect the connecting leads are integrally formed and the connecting rod is formed in the shape of a roll of the lead sheet to be continuously connected.