KR102624470B1 - Vibration reduction device of crystal oscillator - Google Patents

Abstract

The present invention relates to a vibration reduction device for a crystal oscillator, and more specifically, to a vibration reduction device that blocks or reduces external vibration or shock from being transmitted to a crystal oscillator.
To this end, the vibration reduction device of a crystal oscillator of the present invention includes a first elastic member that reduces vibration generated from a first direction; a second elastic member that reduces vibration occurring in a second direction that is different from the first direction; and a flat member formed between the first elastic member and the second elastic member and blocking vibration in the first direction from being directly transmitted to the second elastic member.

Description

Vibration reduction device of crystal oscillator}

The present invention relates to a vibration reduction device for a crystal oscillator, and more specifically, to a vibration reduction device that blocks or reduces external vibration or shock from being transmitted to a crystal oscillator.

The performance of radars used in transportation vehicles including aircraft, vehicles, and ships related to aviation, land, and sea is degraded by the external environment. In particular, it is greatly affected by the engines that make up the means of transportation and the vibrations caused by movement or flight, which is a task that must be given priority especially in a battlefield environment. In this battlefield environment, a crystal oscillator that supplies a stable frequency is essential.

Generally, a crystal oscillator is used as a part of a communication device by mounting a crystal oscillator, a translator that converts a signal, and a driving element that drives the crystal oscillator on a printed circuit board (PCB).

Korean Patent No. 10-0983413 (name of invention: crystal oscillator) includes a PCB on which wiring is formed on the upper surface and a crystal oscillator, a translator, and multiple driving elements are surface-mounted, and one side is flat at a corner of the PCB. A conductive and elastic metal that is electrically connected by contacting the wiring, the hook-shaped other end is in contact with the lower surface of the PCB, and the flat side and the other end are spaced apart from the lower surface of the PCB. A crystal oscillator is proposed that includes a formed J-lead type clip. The proposed crystal oscillator can be soldered at a high temperature, preventing electrical opening with the main board of the system due to cold soldering. The contact area between the solder and the system's main board is increased, preventing the soldered part from being easily separated by mechanical shock.

Korean Patent Publication No. 2004-0082272 (title of the invention: piezoelectric oscillator) is equipped with a piezoelectric oscillator and an oscillation transistor, and the collector load resistance between the collector of the transistor and an AC grounded power source is set, and the collector load resistance is set between the emitter and the collector. A first capacitor is connected between the first capacitance, a parallel circuit between a resistor and a second capacitance between the emitter and the ground, and at least the piezoelectric vibrator is connected between the base and the ground, and the first capacitance value is 0.1 times the second capacitance value. A piezoelectric oscillator is proposed, which is characterized by a value greater than the value.

As described above, electronic equipment mounted on recent transportation vehicles includes a crystal oscillator inside, and due to the characteristics of the crystal oscillator mounted on transportation vehicles, a constant frequency must be provided regardless of external vibration.

Korean Patent No. 10-0983413 (Name of invention: Crystal oscillator) Korean Patent Publication No. 2004-0082272 (Title of invention: Piezoelectric oscillator)

The problem to be solved by the present invention is to propose a crystal oscillator having an anti-vibration structure that can reduce external vibration.

Another problem that the present invention aims to solve is to propose an anti-vibration structure for a crystal oscillator that can prevent phase noise caused by external vibration.

Another problem that the present invention aims to solve is to propose a vibration reduction structure for a crystal oscillator that can reduce vibration applied in at least two directions.

To this end, the vibration reduction device of a crystal oscillator of the present invention includes a first elastic member that reduces vibration generated from a first direction; a second elastic member that reduces vibration occurring in a second direction that is different from the first direction; and a flat member formed between the first elastic member and the second elastic member and blocking vibration in the first direction from being directly transmitted to the second elastic member.

The vibration reduction device of a crystal oscillator according to the present invention does not reduce vibration in a specific direction, but reduces vibration transmitted in at least two directions, so that the crystal oscillator stably outputs an oscillation frequency.

To elaborate, the crystal oscillator proposed in the present invention proposes a method of reducing vibration transmitted in the up-down and left-right directions, and also proposes a method of reducing vibration transmitted in the front-back direction. In this way, the present invention can relatively use vibration as a reference frequency source in the aviation field, thereby stabilizing phase noise, thereby reducing errors in internal communication and improving data accuracy.

Figure 1 shows a crystal oscillator having a double anti-vibration structure according to an embodiment of the present invention.
Figure 2 shows an exploded perspective view of a crystal oscillator with a double anti-vibration structure according to an embodiment of the present invention.
Figure 3 shows a spring fixing member including a spring according to an embodiment of the present invention.
Figure 4 shows a crystal oscillator having an anti-vibration structure according to another embodiment of the present invention.
Figure 5 shows a crystal oscillator having an anti-vibration structure according to another embodiment of the present invention.
Figure 6 shows a crystal oscillator having an anti-vibration structure according to another embodiment of the present invention.

The foregoing and additional aspects of the present invention will become more apparent through preferred embodiments described with reference to the accompanying drawings. Hereinafter, these embodiments of the present invention will be described in detail so that those skilled in the art can easily understand and reproduce them.

Figure 1 shows a crystal oscillator having a double anti-vibration structure according to an embodiment of the present invention. Hereinafter, a crystal oscillator having a double anti-vibration structure according to an embodiment of the present invention will be described in detail using FIG. 1.

According to Figure 1, the crystal oscillator 100 includes a crystal oscillator 105, a PCB 110, a storage case 115, a silicon pad 120, a flat member 125, a first spring fixing member 130, and a spring. (135) and a second spring fixing member 140. Of course, other configurations other than those described above may be included in the crystal oscillator proposed in the present invention.

As described above, the crystal oscillator 105 generates an oscillation frequency using power supplied from the outside and outputs the generated oscillation frequency.

The PCB 110 is equipped with a crystal oscillator 105, and in addition, various elements implementing the crystal oscillator 100 are mounted. The PCB 110 is formed with holes for the first fastening member and the second fastening member.

The storage case 115 accommodates the PCB 110. Figure 1 shows a storage case 115 in a square shape, but is not limited thereto.

The silicone pad 120 is located on the bottom of the storage case 115 and reduces vibration transmitted to the storage case 115. That is, the silicon pad 120 performs a function of relatively reducing vertical vibration among vibrations transmitted to the storage case 115.

The flat member 125 is located between the silicone pad 120 and the first spring fixing member 130. The flat member 125 is made of SUS material, but may be formed of other materials. When the elastic silicon pad 120 is directly fastened to the first spring fixing member 130, there is a high possibility that the silicon pad 120 will be damaged on the contact surface of the first spring fixing member 130. In order to solve this problem, the present invention forms a flat member 125 at the bottom of the silicon pad 120 to prevent the silicon pad 120 from being directly fastened to the first spring fixing member 130, while the contact surface is The silicon pad 120 is prevented from being damaged by being in close contact with the wide flat member 125.

The first spring fixing member 130 is composed of two members, and a circular hole is formed so that the spring 135 can be inserted. That is, the 1-1 spring fixing member 130a located at the top has a hole formed so that a part of the spring 135 can be inserted, and the 1-2 spring fixing member 130b located at the bottom has a hole formed in the spring 135. A hole is formed so that the remaining part can be inserted.

The spring 135 is located between the first spring fixing member 130 and the second spring fixing member 140 and reduces vibration transmitted to the storage case 115. That is, the spring 135 performs a function of relatively reducing vibration in the left and right directions among vibrations transmitted to the storage case 115.

The second spring fixing member 140 is located at the bottom of the spring 135 and functions to fix the spring 135. The second spring fixing member 140 is composed of two members, and a circular hole is formed to allow the spring to be inserted. That is, the 2-1 spring fixing member 140a located at the top has a hole formed so that a part of the spring 135 can be inserted, and the 2-2 spring fixing member 140b located at the bottom has a hole formed in the spring 135. A hole is formed so that the remaining part can be inserted. The lower end of the second spring fixing member 140 is fixed to other members such as transportation means.

The crystal oscillator 100 reduces left-right vibration by a spring 135 including spring fixing members 130 and 140 located at the bottom, and reduces up-and-down vibration by a silicon pad 120 located at the top. As such, the crystal oscillator 100 proposed in the present invention has a dual structure, reducing vibration not only in the vertical direction but also in the left and right directions.

Figure 2 shows an exploded perspective view of a crystal oscillator with a double anti-vibration structure according to an embodiment of the present invention. Hereinafter, an exploded perspective view of a crystal oscillator having a double anti-vibration structure according to an embodiment of the present invention will be described in detail using FIG. 2.

According to Figure 2, the crystal oscillator 100 includes a crystal oscillator 105, a PCB 110, a storage case 115, a silicon pad 120, a flat member 125, a first spring fixing member 130, and a spring. (135), a second spring fixing member 140, a first fastening member 145, a second fastening member 150, and a bushing 155. Of course, other configurations other than those described above may be included in the crystal oscillator proposed in the present invention. Below, we will look at the structure of the crystal oscillator, focusing on configurations not described in FIG. 1.

The first fastening member 145 functions to fasten the PCB 110 to the first spring fastening member 130. That is, the first fastening member 145 fastens the PCB 110, the storage case 115, the silicone pad 120, the flat member 125, and the first spring fixing member 130. For this purpose, a hole through which the first fastening member 145 penetrates is formed in the storage case 115, the silicone pad 120, and the flat member 125.

The second fastening member 150 performs the function of fixing the PCB 110 to the storage case 115. That is, the PCB 110 to which the crystal oscillator 105 is fastened must be fixed to the storage case 115, and the PCB 110 is fixed to the storage case 115 using the second fastening member 150.

The bushing 155 is inserted into a hole to be formed in the silicon pad 130, and the first fastening member 145 penetrates therein. That is, when the first fastening member 145 penetrates the hole formed in the silicon pad 130, there is a high possibility that the silicon pad 130 will be damaged due to external impact. Therefore, the present invention uses the bushing 155 to block the first fastening member 145 from directly contacting the silicon pad.

Figure 3 shows a spring fixing member including a spring according to an embodiment of the present invention. Hereinafter, a spring fixing member including a spring according to an embodiment of the present invention will be described in detail using FIG. 3.

As shown in FIG. 3, the spring 135 is fastened to the first spring fixing member 130 and the second spring fixing member 140. As described above, the spring 135 can move in the left and right directions while fastened to the first spring fixing member 130 and the second spring fixing member 140.

The first spring fixing member 130 is composed of a 1-1 spring fixing member 130a and a 1-2 spring fixing member 130b, and the 1-1 spring fixing member 130a and the 1-2 spring With the spring 135 inserted between the fixing members 130b, the 1-1 spring fixing member 130a and the 1-2 spring fixing member 130b are fixed using the third fastening member 160. do.

The second spring fixing member 140 is composed of a 2-1 spring fixing member 140a and a 2-2 spring fixing member 140b, and the 2-1 spring fixing member 140a and the 2-2 spring With the spring 135 inserted between the fixing members 140b, the 2-1 spring fixing member 140a and the 2-2 spring fixing member 140b are fixed and fastened using the third fastening member 160. do.

Figure 4 shows a crystal oscillator having an anti-vibration structure according to another embodiment of the present invention. Hereinafter, a crystal oscillator having an anti-vibration structure according to another embodiment of the present invention will be described in detail using FIG. 4.

According to Figure 4, unlike Figure 1, the crystal oscillator has a triple anti-vibration structure. That is, it has a first anti-vibration structure with a spring structure, a second anti-vibration structure with a silicon pad, and a third anti-vibration structure with a spring structure.

However, the arrangement direction of the spring having the first vibration isolation structure is different from the arrangement direction of the spring having the third vibration isolation structure. That is, the arrangement direction of the spring having the first vibration isolation structure and the arrangement direction of the spring having the third vibration isolation structure are at right angles to each other. In this way, by forming the arrangement direction of the spring with the first vibration isolation structure and the arrangement direction of the spring with the third vibration isolation structure in a right angle direction, vibration not only in the left and right directions but also in the forward and backward directions is blocked from being transmitted to the crystal oscillator.

The present invention proposes a structure that reduces vibration in the vertical direction using a silicon pad, but is not limited to this. In other words, it is possible to propose a structure that reduces vibration in the upward direction by using an elastic member other than the silicon pad.

As an example, vertical vibration can be reduced using a spring. To explain further, vibration in the vertical direction can be reduced by using springs arranged in the height direction.

Figure 5 shows a crystal oscillator having an anti-vibration structure according to another embodiment of the present invention. Hereinafter, a crystal oscillator having an anti-vibration structure according to another embodiment of the present invention will be described in detail using FIG. 5.

According to Figure 5, the crystal oscillator proposes a method of reducing vibration in the vertical direction by using a spring instead of a silicon pad. That is, the present invention places the spring so that it can be compressed in the vertical direction to limit the transmission of vibration occurring in the vertical direction to the crystal oscillator.

Figure 6 shows a crystal oscillator having an anti-vibration structure according to another embodiment of the present invention. Hereinafter, we will look at the crystal vibrator structure according to another embodiment of the present invention in detail using FIG. 6.

According to Figure 6, a method of forming the spring fixing member into a flat type with a certain thickness is proposed. That is, a groove is formed inside a flat-type member with a certain thickness, and a portion of the spring is introduced into the formed groove. To explain further, the present invention proposes a method of using a flat plate member to function as a spring fixing member. By doing this, there is an advantage in that cost reduction, convenience of assembly, and thickness can be reduced by composing the two members including the flat member and the first spring fixing member into one flat member.

The present invention has been described with reference to an embodiment shown in the drawings, but this is merely illustrative, and those skilled in the art will understand that various modifications and other equivalent embodiments are possible therefrom. .

100: crystal oscillator 105: crystal oscillator
110: PCB 115: Storage case
120: silicone pad 125; Flat member
130: first spring fixing member 135: spring
140: second spring fixing member 145: first fastening member
150: second fastening member 155: bushing
160: Third fastening member 130a: 1-1 spring fastening member
130b: 1-2 spring fixing member
140a: 2-1 spring fixing member
140b: 2-2 spring fixing member

Claims (8)

A storage case in which a PCB on which a crystal oscillator is mounted is stored;
a first elastic member that is fastened by a fastening member in a state located at the bottom of the storage case and reduces vibration generated from a first direction;
a second elastic member located at the bottom of the first elastic member and reducing vibration generated in a second direction that is different from the first direction;
a third elastic member located at the bottom of the second elastic member and reducing vibration generated in a third direction that is different from the first or second direction;
a first flat member formed between the first elastic member and the second elastic member and blocking vibration in the first direction from being directly transmitted to the second elastic member;
It includes a second flat member formed between the second elastic member and the third elastic member and blocking vibration in the second direction from being directly transmitted to the third elastic member,
The first elastic member and the third elastic member are springs,
The second elastic member is a silicone pad,
The first elastic member and the third elastic member are composed of springs, and the spring arrangement direction of the first elastic member and the spring arrangement direction of the third elastic member are perpendicular to each other,
The first flat member is formed with a groove into which a lower portion of the first elastic member is inserted,
Vibration reduction device for a crystal vibrator, characterized in that the second flat member is formed with a groove into which a portion of the upper end of the third elastic member is inserted.
delete According to clause 1,
A first spring fixing member including a 1-1 spring fixing member into which the upper part of the spring, which is the first elastic member, is retracted, and a 1-2 spring fixing member into which the remaining upper part of the spring, which is the first elastic member, is retracted; and
A second spring fixing member including a 2-1 spring fixing member into which a lower part of the spring, which is the third elastic member, is retracted, and a 2-2 spring fixing member into which the remaining lower part of the spring, which is the third elastic member, is retracted. A vibration reduction device for a crystal oscillator, comprising:
The vibration reduction device of a crystal vibrator according to claim 3, comprising a third fastening member for fastening the 2-1 spring fixing member and the 2-2 spring fixing member to each other.
The silicone pad of claim 1,
A vibration reduction device for a crystal oscillator, characterized in that a hole is formed into which a bushing is inserted.
delete The vibration reduction device of a crystal oscillator according to claim 1, comprising a second fastening member for fastening the PCB and the storage case to each other.
The vibration reduction device of a crystal vibrator according to claim 7, comprising a first fastening member for fastening the PCB, a storage case, a silicon pad, a flat member, and a 1-1 spring fixing member.

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