KR101452221B1 - Vibration Absorbing Structure for Crystal Oscillator - Google Patents

Abstract

The present invention relates to a vibration absorbing structure for a crystal oscillator to prevent the transmission of vibration and impact from the outside to the crystal oscillator. The crystal oscillator is installed in a case which has a cover at an upper part. A buffer material is connected to at least two support protrusion parts extended in a radial direction along the edge of the case, therefore the buffer material supports the case on an external substrate. Because a crystal oscillator module according to the present structure can be miniaturized and satisfies a vibration property and an impact property together, a light and small product can be manufactured. Also, a phase noise is stable, thereby improving the accuracy of data by reducing errors in internal communications.

Description

{Vibration Absorbing Structure for Crystal Oscillator}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a crystal oscillator module, and more particularly, to a crystal oscillator dustproof structure for preventing external vibrations or shocks from being transmitted to a crystal oscillator.

The reference frequency generator corresponds to the heart of all information communication devices and serves to provide a stable frequency source. In particular, IEXO (Isolator Equipped Crystal Oscillator) is used as a frequency generator for communication and electronic equipment such as a radar, etc., when a general oscillator can not be used because of high intensity of external shock or vibration such as air and missile. Such IEXO needs to maintain a certain level of phase noise even in communication and electronic equipments with large vibrational intensity. Conventional IEXO uses steel wire or Rubber Vibration Isolator to fix the crystal in one direction and improve phase noise due to vibration. A phase noise improvement technique using steel wire for Registration Practical Utility Model No. 20-0459962 ("Crystal Oscillator Vibration Prevention Structure") is disclosed.

However, this method requires a large space in order to simultaneously satisfy the phase noise characteristic and the shock-time survival characteristic at the time of vibration. Therefore, it is necessary to develop a new IEXO technology that satisfies both the phase noise characteristics during shock and the survival characteristics during impact and minimizes the size required in modern equipment.

Also, due to the characteristics of the rubber, performance deteriorates due to wear and deformation over time, and there is a problem that the service life required in the aviation field, especially the missile field, to be maintained for a long time can not be guaranteed. Particularly, in the case of a steel wire, a problem that a part of the wire is cut off during the repetitive test of lowering the lifetime of hundreds or thousands of times is also exposed.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a crystal oscillator dustproof structure including a buffer material for minimizing phase noise by blocking impact or vibration transmitted to a crystal oscillator.

Another object of the present invention is to provide a crystal oscillator dustproof structure having a structure in which a buffer material is inserted into a hollow of a support projection extending from a rim of a case equipped with a crystal oscillator, .

Other objects of the present invention can be achieved by the detailed description of the present invention described with reference to the accompanying drawings.

In order to achieve the above object, a quartz crystal oscillation preventing structure of the present invention includes a quartz crystal oscillator and a frequency utilizing device for receiving and using a frequency generated by the quartz crystal oscillator to prevent vibration or shock transmitted from the external environment to a quartz crystal oscillator Wherein the crystal oscillator is installed inside a case having a cover at the top, and a buffer material is connected to each of the at least two support protrusions formed radially extending along the rim of the case And the case is mounted so as to be supported on the external substrate by the buffer material.

The buffer material is characterized by being a silicone gel.

The supporting protrusions are ring-shaped with a center hollow, and the buffer material is inserted and fixed in the hollow so that the case supports the outer substrate.

And a lower support attached to a lower end of the buffer material to support the buffer material on the external substrate.

A groove recessed inward is formed along an outer periphery of the center region of the buffer material so that the support projection is inserted into the groove and mounted.

Wherein the buffer material comprises a lower cushioning material inserted into the hollow of the support projection, the lower cushioning material having a flange formed at its lower end to support the support projection below, and the buffer material extends through the hollow And an upper cushioning material fastened to the lower cushioning material to fix the supporting protrusion from above, wherein a cushioning material such as a bolt is inserted through the center of the cushioning material so that the cushioning material contacts the upper and lower sides And the case is mounted so as to support the external substrate.

The lower support includes a cylindrical fastening protrusion inserted through the center of the upper buffer material, the hollow of the support protrusion, and the center of the lower buffer material to receive the fastening means.

The supporting protrusions are formed to extend symmetrically in four directions of the case, and the buffering material is connected to the supporting protrusions, and the case is installed to support the external substrate.

According to the vibration damping structure using the cushioning material of the present invention, particularly the silicone gel, the vibration and impact characteristics of IEXO can be satisfied at the same time and the size can be minimized. IEXO, which is small in size and excellent in phase noise characteristics during vibration, can be used in a field of aviation with a large vibration and can provide a stable frequency source. In addition, it is possible to develop lightweight and small size products in unmanned aeronautical field because it can simultaneously produce vibration and shock characteristics, and it is possible to improve the accuracy of data by reducing errors in internal communication because phase noise is stable .

FIG. 1 is an overall perspective view of a crystal oscillator module for showing a crystal oscillator dustproof structure according to an embodiment of the present invention; FIG.
2 is an exploded perspective view of the crystal oscillator module of FIG. 1;
FIG. 3 is a perspective view showing the cushioning material of FIG. 2 separated. FIG. 3 (a) is a vertically separated view, FIG.
FIG. 4 is a perspective view of the lower support of FIG. 2; FIG. And
Fig. 5 is a perspective view showing an inner structure of the cover of Fig. 2;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary meanings and should be construed in accordance with the technical meanings and concepts of the present invention.

FIG. 1 is an overall perspective view of a crystal oscillator module for showing a crystal oscillator dustproof structure according to one embodiment of the present invention, and FIG. 2 is an exploded perspective view of the crystal oscillator module of FIG. Referring to FIGS. 1 and 2, the quartz oscillator dustproof structure of the present invention has a structure in which a buffer material 200 is connected to at least two support protrusions 102 radially extending along the outer circumference of the case 100. In general, the crystal oscillator 10 is provided on an internal substrate 15 including various circuits for stably converting mechanical vibrations formed in the crystal oscillator 10 into an electrical signal, One crystal oscillator module including the case 100 is formed. The oscillation signal converted into an electrical signal by the crystal oscillator provided inside the case 100 is transmitted to the outside through the connection terminal 108 provided in the hole 122 formed in the side wall of the case 100, Device. ≪ / RTI >

As shown in FIG. 1, the case 100 equipped with the crystal oscillator 10 is floated by the buffer material 200 at a predetermined distance from the floor, and external devices using the crystal oscillator module are buffered It is possible to prevent the vibration or the impact transmitted from the external environment to the external device from being directly transmitted to the crystal oscillator 10 mounted in the case 100 by making the contact with the case 100 only through the material 200 do.

That is, the quartz crystal oscillation preventing structure of the present invention for a quartz oscillator module has a function of receiving a frequency generated from the quartz crystal oscillator 15 and the quartz crystal oscillator 15 to prevent vibrations, shocks, etc. transmitted from the external environment to the quartz crystal oscillator 10 (Not shown as a plate-like member to which the lower surface of the lower support 300 is attached in the figure), on which an external frequency-utilizing device (not shown) The crystal oscillator 10 is installed inside a case 100 provided with a lid 110 at an upper portion thereof and includes at least two support protrusions 110 formed radially extending along the rim of the case 100 102 are connected to each other so that the case 100 is supported on the external substrate by the cushioning material 200. Therefore, it is possible to minimize the phase noise by controlling the modulus of elasticity of the cushioning material and to satisfy the survival characteristic during impact by maintaining the up-and-down spacing without colliding with the external upper and lower surfaces in a narrow space due to displacement by the thickness of the cushioning material during impact . The lid 110 installed at the upper end of the case 100 can be closely fixed by fixing means 113 such as a bolt.

As a preferred embodiment, a silicone gel may be selected as the buffer material. In general, silicon gel is a very soft material having silicon as its main material and has excellent ozone resistance, ultraviolet ray resistance, and chemical resistance, so that even when repeatedly compressed, the characteristics are not deformed. In particular, in the case of silicon alpha gel, the elastic modulus is adjusted according to the material to satisfy the vibration characteristic of the standard of MIL-STD-810F, which is a military standard. Therefore, when silicon gel is used as a buffer material, the vibration suppression performance of the crystal oscillator module can be maintained in a good state for a long time. In addition, since the ozone dependency is low, stable performance is exhibited even in a wide temperature range from -40 deg. C to 200 deg. By applying such a silicone gel, the natural frequency of the crystal oscillator module can be set to 50 Hz or less, and the vibration transmission characteristic (or vibration shielding property) of about 10% or less at a frequency of 100 Hz can be provided.

2, the support protrusion 102 is ring-shaped having a center hollow 104, and the buffer material 200 is inserted and fixed in the hollow 104, So that it can be mounted on a support surface. Since the buffer material 200 is inserted and fixed in the hollow 104 of the support protrusion 102, the vibration in the horizontal direction of the case 100 can be suppressed to the maximum, Allowing oscillation in the vertical direction. Therefore, by mounting the crystal oscillator 10 mounted inside the case 100 so as to be perpendicular to the direction in which the vibration is most weak, phase noise during vibration can be improved. By minimizing the phase noise of the crystal oscillator due to the vibration through the optimized structure of the buffer material, the impact characteristics of MIL-STD-180F can be satisfied within the standard size range of the specific size.

FIG. 3 is a perspective view showing the cushioning material 200 of FIG. 2. FIG. 3 (a) is a top view and FIG. 3 (b) is a top view.

The cushioning material 200 according to an embodiment of the present invention includes a groove 211 recessed inwardly along an outer periphery of an area of the cushioning material 200 to insert the supporting protrusion 102 into the groove 211, . The structure of this embodiment may be formed by assembling two members as shown in FIG. 3 (b), but it is not limited thereto, and it is not excluded that the member is integrally manufactured as a single member.

3 (a), when the cushioning material 200 is formed by the assembly of two members, two members may be arranged on the front and rear sides of the supporting projection 102 to be fastened to each other, A flange 208 is formed at the lower end of the support protrusion 102 to protrude upward through the hollow 104 and a lower buffer material 214 supporting the support protrusion 102 from below, And an upper buffer material 212 for fastening the support protrusion 102 with the lower buffer material 214. Therefore, by inserting fastening means such as bolts through the center 219 of the cushioning material 200, the cushioning material 200 fixes the supporting protrusions 102 on both the upper and lower sides so that the case 100 is placed on the external substrate It can be installed to support. The width of the flange 208 of the lower cushioning material 214 and the width of the upper cushioning material 212 are made the same so that the degree of contraction or twisting of the cushioning material 212 due to external vibration or impact is made uniform, It is possible to minimize the transmitted vibration and impact, thereby minimizing the phase noise of the crystal oscillator.

1, the crystal oscillator module for a dust-proof structure according to an embodiment of the present invention is attached to the lower end of the buffer material 200 to support a buffer material 200 on an outer substrate, 300). 4, the lower support 300 includes a fastening projection 314 for fastening through the center 219 of the cushioning material 200 and a cushioning material support portion for supporting the cushioning material 200 in contact with the lower surface of the cushioning material 200 And a substrate fastening part 308 formed with a fastening hole 306 for fastening with an external substrate. The buffer material 200 inserted into the central protrusion 314 and supported by the buffer material support portion 318 may be formed on the outer surface of the outer substrate 318. The width of the buffer material support portion 318 may be greater than the width of the substrate coupling portion 308, So that it can be lifted up to a predetermined height or more. Also, at least two fastening holes 306 may be formed in the substrate fastening portion 308 to fasten the lower support table 300 to the external substrate by fixing means (not shown) such as a bolt.

The center portion of the fastening protrusion of the lower support 300 is provided with a hollow portion through which the centering portion 219 of the cushioning material 200 and the hollow portion 104 of the support protrusion 102 are inserted, 309 may be formed. The washer 207 is inserted into both ends of the cushioning material 200 to fasten the cushioning material 200 and the supporting protrusions 102 and the lower supporting table 300 to each other. The buffer material 200 can be prevented from being damaged by the buffer material support portion 318 of the buffer material 300.

Fig. 5 is a perspective view showing an inner structure of the cover of Fig. 2; 5, the lid 110 covering the upper end of the case 100 may be used to cover the case 100 and to provide a sufficient mass at the upper end of the case 100, Respectively. In the case of reducing the phase noise on the crystal oscillator due to the buffering material in the event of external vibration or impact, the connection structure of the buffer material according to the vibration direction of the crystal oscillator described above is improved by minimizing the phase noise, The noise characteristic can be finely adjusted by the weight of the lid 110, i.e., the weight of the case 100 including the lid 110, in addition to the method of minimizing the noise. For this purpose, as an embodiment of the present invention, a downward protrusion 115 may be formed by thickening the inside of the lid 110, and a recessed hole 117 may be formed to avoid a region occupied by the crystal oscillator 10 have.

In one embodiment of the present invention, the supporting protrusions 102 are formed by four symmetrically extending four sides of the case 100, and the buffering material 200 is connected to the supporting protrusions 102 The case 100 may be installed to support the external substrate. Since the case 100 formed in correspondence with the shape of the rectangular internal substrate 15 has a rectangular shape in order to stably support the rectangular case 100 in the maximum stability, It is preferable that the material 200 is installed and supported.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, Various modifications can be made by those skilled in the art. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. It will not.

Claims (8)

A quartz oscillator dustproof structure for preventing oscillation or shock from being transmitted from an external environment to a quartz oscillator, the quartz crystal oscillator being disposed between an external substrate on which a frequency utilization device for receiving and using a frequency generated by the quartz oscillator is mounted,
The crystal oscillator is installed inside a casing having a cover at the top,
A cushioning material is connected to each of at least two support protrusions formed radially extending along the rim of the case so that the case is supported so as to be supported on the external substrate by the cushioning material,
Wherein the support protrusions are ring-shaped with a center hollow so that the buffer material is inserted and fixed in the hollow to support the case on the external substrate,
Wherein the buffer material comprises a lower cushioning material inserted into the hollow of the support projection, wherein the lower cushioning material has a flange at the lower end to support the support projection below, and the buffer material extends through the hollow And an upper cushioning material fastened to the lower cushioning material to fix the supporting protrusion from above, wherein a cushioning material such as a bolt is inserted through the center of the cushioning material so that the cushioning material contacts the upper and lower sides And the case is mounted on the external substrate so as to support the external substrate.
The method according to claim 1,
Wherein the buffer material is a silicone gel.
delete The method according to claim 1,
Further comprising a lower support attached to a lower end of the buffer material to support the buffer material on the outer substrate.
5. The method of claim 4,
Wherein a groove recessed inward is formed along an outer periphery of the center region of the buffer material so that the support protrusion is inserted into the groove.
delete 5. The method of claim 4,
Characterized in that the lower support comprises a cylindrical fastening protrusion inserted through the center of the upper buffer material, the hollow of the support protrusion and the center of the lower buffer material to receive the fastening means. rescue.
The method according to claim 1,
Wherein the supporting protrusions are formed by four symmetrically extending parts extending in four directions of the case and the buffering material is connected to the supporting protrusions so that the case is supported on the external substrate. .

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