KR200485852Y1 - Device for protection of vibration - Google Patents

Abstract

The present invention relates to an anti-seismic and anti-shake brace for minimizing shaking of a pipeline from an impact of a seismic wave to prevent breakage and deformation of the pipeline. A lower clamp positioned at a predetermined distance from the upper clamp and fixing one side of the lower outer surface of the pipe; A first rotating means rotatably installed on one side of the upper surface of the upper clamp and rotated by a seismic wave; A second rotating means rotatably mounted on the ceiling surface at a predetermined distance from the first rotating means and rotated by a seismic wave; And a thread bar provided between the first rotating means and the second rotating means and rotated by rotation of the first and second rotating means to absorb the impact of the seismic wave.

Description

{DEVICE FOR PROTECTION OF VIBRATION}

More particularly, the present invention relates to an anti-seismic anti-shake brace for minimizing shaking of a pipeline from an impact of a seismic wave to prevent breakage and deformation of the pipeline.

In general, fluids essential to human life such as water and sewage, oil and gas are transported mechanically through piping from the production site to the final destination. For example, various pipelines such as water and sewage pipes and gas pipelines are buried under the residential area.

If cracks occur in the piping due to the aging or external impact of the piping, the replacement of the piping, replacement and maintenance are required.

For example, when the water pipe at a certain point is old, the old main pipe is shut off to replace the old pipe. Therefore, the entire wide area connected to the main valve must be separated for a long time There is a problem that the loss cost of the local residents is very large.

To solve this problem, U.S. Patent Nos. 4,458,721 (Yie et al) and 5,462,077 (Cohen et al.) Disclose devices for temporarily interrupting fluid flowing into a pipe using an inflatable device, such as an airbag, .

However, the devices disclosed in U.S. Patent Nos. 4,458,721 and 5,462,077 are low in durability of the airbag, so that the airbag can be ruptured and there is a limit to block the high-pressure fluid. Accordingly, the pressure of the fluid is limitedly used for small-diameter piping.

In order to solve such a problem, the present applicant proposes an apparatus and a method for radially expanding a rolled plate of steel through Korean Utility Model Patent Publication No. 2007-0034919 and Korean Patent No. 0728766 to block the flow of fluid in the piping Respectively.

However, the pressure of the fluid applied to the expansion plate is very high, about 3 to 20 kg / cm < 3 >

In such a case, the expansion plate instantaneously expands due to the high pressure, and a large impact is generated on the inner surface of the pipe, so that the pipe may be ruptured.

In addition, when the inside of the pipe is momentarily blocked by the expansion plate, a strong eddy is generated in the inside of the pipe, thereby damaging the inside of the pipe.

However, in order to solve the above-mentioned conventional problems, Application No. 10-2009-0097105 (name of design: piping departure prevention device) of October 13, 2009 is filed, A pair of piping fixing means which are formed in such a manner that arms are formed on both sides and the inner side is in contact with the outer surface of the piping so as to surround the piping and are opposed to each other; A vertical support which is installed at both ends of the arm and which is installed in a direction perpendicular to the bottom surface to support the pipe fixing means and a pair of pipe fixing means facing each other, And a pair of horizontal supports installed at both ends.

However, the conventional piping departure prevention apparatus has a problem that piping is damaged from seismic waves due to breakage and deformation due to vibration generated by a shock of a seismic wave.

The object of the present invention is to provide an anti-seismic and anti-shaking device for preventing piping breakage and deformation by minimizing the shaking of the piping from the impact of a seismic wave, It is in providing a brace.

However, the object of the present invention is not limited to the above-mentioned objects, and other objects not mentioned can be clearly understood by those skilled in the art from the following description.

According to an aspect of the present invention, there is provided an anti-

An upper clamp for fixing one side of the upper outer surface of the pipe;

A lower clamp positioned at a predetermined distance from the upper clamp and fixing one side of the lower outer surface of the pipe;

A first rotating means rotatably installed on one side of the upper surface of the upper clamp and rotated by a seismic wave;

A second rotating means rotatably mounted on the ceiling surface at a predetermined distance from the first rotating means and rotated by a seismic wave;

And a thread bar provided between the first rotating means and the second rotating means and rotated by rotation of the first and second rotating means to absorb the impact of the seismic wave.

As described above, the seismic shake prevention brace according to the present invention has the effect of preventing breakage and deformation of the pipe by minimizing the shaking of the pipe from the impact of the seismic wave.

1 is a view showing an anti-vibration shake prevention brace according to the present invention,
Fig. 2 is an exploded view of the main part of Fig. 1,
FIGS. 3 to 4 are views showing the use state of FIG. 1,
FIG. 5 is a view showing a state in which a pipe is installed on an anti-vibration / anti-shake brace according to the present invention;
6 is a view showing another embodiment of an anti-vibration / anti-shake brace according to the present invention,
7 is a view showing still another embodiment of an anti-vibration shake brace according to the present invention,
8 is a view showing a state in which a pipe is installed on the anti-vibration / anti-shake brace of FIG.

Hereinafter, a preferred embodiment of a chain system for anti-seismic anti-vibration bracing according to the present invention will be described.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention unnecessarily obscure.

FIG. 1 is a view showing an anti-seismic shake prevention brace according to the present invention, FIG. 2 is an exploded view of FIG. 1, and FIGS. 3 to 4 are views showing a use state of FIG.

1 to 4, the anti-vibration / anti-shake brace 100 according to the present invention includes:

An upper clamp 102 for fixing one side of the upper outer surface of the pipe;

A lower clamp 104 positioned at a predetermined distance from the upper clamp 102 to fix one side of the lower outer surface of the pipe;

A screw pipe 106 protruding from the upper center of the upper clamp 102;

A fastening portion 108 screwed to the screw pipe 106;

A vertical pipe 110 screwed to the coupling part 108 to minimize shaking of the piping from a shock of a seismic wave;

An insert plate 112 screwed to the upper portion of the vertical pipe 110 and embedded in the ceiling surface;

A first connection part (114) located at one side of the upper surface of the upper clamp (102) at a predetermined interval from the screw pipe (106);

A first fixing means 116 for fixing the first connection portion 114, the upper clamp 102 and the lower clamp 104;

A second connection part 118 positioned on one side of the upper surface of the upper clamp 102 at a predetermined interval from the first connection part 114;

A second fixing means 120 for fixing the second connection portion 118, the upper clamp 102 and the lower clamp 104;

Third fixing means 122 coupled to the upper portion of the first connection portion 114;

A third connection portion (124) rotatably coupled to the third fixing means (122);

A fourth connection part 126 coupled to one side of the third fixing device 122 at a predetermined interval from the third connection part 124;

A fourth fixing means 128 coupled to an upper portion of the fourth connection portion 126;

A fifth connection part 130 rotatably coupled to the fourth fixing device 128;

A fifth fixing means 132 coupled to an upper portion of the second connection portion 118;

A sixth connection part (134) rotatably coupled to the fifth fixing device (132);

A seventh connecting portion 136 coupled to one side of the fifth fixing means 132 at a predetermined interval from the sixth connecting portion 134;

A sixth fixing means 138 coupled to an upper portion of the seventh connecting portion 136;

An eighth connection portion (140) rotatably coupled to the sixth fixing means (138);

A first screw rod 142 installed at the fifth connection part 130;

A ninth connection 144 coupled to the first screw rod 142;

A seventh fixing means 146 coupled to an upper portion of the ninth connecting portion 144;

A tenth connection portion (148) rotatably coupled to the seventh fixing means (146);

A second screw rod 150 installed at the third connection part 124;

An eleventh connection part 152 coupled to the second threaded rod 150;

An eighth fixing means 154 coupled to an upper portion of the eleventh connection portion 152;

A twelfth connection portion (156) rotatably coupled to the eighth fixing means (154);

A third threaded rod 158 installed at the sixth connection part 134;

A thirteenth connection part 160 coupled to the third threaded rod 158;

A ninth fixing means 162 coupled to an upper portion of the thirteenth connection portion 160;

A fourteenth connection portion (164) rotatably coupled to the ninth fixing means (162);

A fourth screw rod 166 installed at the eighth connection part 140;

A fifteenth coupling portion 168 coupled to the fourth threaded rod 166;

A tenth fixing means 170 coupled to an upper portion of the fifteenth connection portion 168;

And a sixteenth connection portion 172 rotatably coupled to the tenth fixing means 170.

The assembling process and the use state of the anti-vibration / anti-shake brace 100 according to the present invention will be described as follows.

Here, the assembling process of the vibration-proof anti-shake brace according to the present invention may be changed in any order depending on the assembler.

First, the upper clamp 102 having the screw pipe 106 and fixing one side of the upper outer surface of the pipe is positioned, and the lower side of the lower outer surface of the pipe is fixed by being spaced apart from the upper clamp 102 The lower clamp 104 is positioned.

After the fastening portion 108 is screwed to the screw pipe 106, the vertical pipe 110 is screwed to the fastening portion 108 to minimize the shaking of the pipe from a shock of a seismic wave.

Then, the insert plate 112 is screwed on the upper portion of the vertical pipe 110.

The first connection portion 114 is positioned at one side of the upper surface of the upper clamp 102 at a predetermined interval from the screw pipe 106.

Then, the first connection unit 114, the upper clamp 102, and the lower clamp 104 are fixed by the first fixing unit 116.

The second connection part 118 is positioned at one side of the upper surface of the upper clamp 102 at a predetermined distance from the first connection part 114.

Then, the second connection unit 118, the upper clamp 102, and the lower clamp 104 are fixed by the second fixing unit 120.

After the third fixing means 122 is coupled to the upper portion of the first connecting portion 114, the third connecting portion 124 is rotatably coupled to the third fixing means 122.

The fourth connecting portion 126 is coupled to one side of the third fixing means 122 at a predetermined interval from the third connecting portion 124.

After the fourth fixing unit 128 is coupled to the upper portion of the fourth connecting unit 126, the fifth connecting unit 130 is rotatably coupled to the fourth fixing unit 128.

After the fifth fixing means 132 is coupled to the upper portion of the second connecting portion 118, the sixth connecting portion 134 is rotatably coupled to the fifth fixing means 132.

A seventh connecting portion 136 is coupled to one side of the fifth fixing means 132 at a predetermined interval from the sixth connecting portion 134 and then a sixth fixing means 138 ).

After the eighth connection unit 140 is rotatably coupled to the sixth fixing unit 138, a first screw rod 142 is installed on the fifth connection unit 130.

The seventh fixing unit 146 is coupled to the upper portion of the ninth connecting unit 144 after the ninth connecting unit 144 is coupled to the first screw thread 142. [

Then, the seventh fixing means 146 is rotatably coupled to the tenth connecting portion 148.

After the second threaded rod 150 is installed on the third connecting part 124, the eleventh connecting part 152 is coupled to the second threaded rod 150.

The eighth fixing unit 154 is coupled to the eleventh connecting unit 152 and then the twelfth connecting unit 156 is rotatably coupled to the eighth fixing unit 154.

After the third threaded rod 158 is installed on the sixth connecting part 134, the thirteenth connecting part 160 is coupled to the third threaded rod 158.

After the ninth fixing means 162 is coupled to the upper portion of the thirteenth connecting portion 160, the seventeenth connecting portion 164 is rotatably coupled to the ninth fixing means 162.

A fourth threaded rod 166 is installed on the eighth connecting part 140 and a fifteenth connecting part 168 is coupled to the fourth threaded rod 166.

After the tenth fixing unit 170 is coupled to the top of the fifteenth connecting unit 168, the sixteenth connecting unit 172 is rotatably coupled to the tenth fixing unit 170.

As described above, when the assembling of the anti-vibration / anti-shake brace 100 according to the present invention is completed,

The insert plate 112 is installed on the ceiling.

As shown in FIG. 5, a pipe 200 is installed between the upper clamp 102 and the lower clamp 104.

When the pipe 200 is installed between the upper clamp 102 and the lower clamp 104 and an impact (i.e., vibration) occurs in the structure due to a seismic wave,

The vertical pipe 110 supports the pipeline so as not to shake the pipeline from a shock of a seismic wave.

The tenth connection unit 148 is rotatably coupled to the seventh fixing unit 146 and the fifth connection unit 130 is rotatably coupled to the fourth fixing unit 128,

The first threaded rod 142 installed between the tenth connection part 148 and the fifth connection part 130 absorbs a shock of a seismic wave while moving according to the movement of the tenth connection part 148 and the fifth connection part 130. [ do.

The twelfth connecting portion 156 is rotatably coupled to the eighth fixing means 154 and the third connecting portion 124 is rotatably coupled to the third fixing means 122,

The second threaded rod 150 installed between the twelfth connection part 156 and the third connection part 124 absorbs the impact of the seismic wave while moving according to the movement of the twelfth connection part 156 and the third connection part 124. [ do.

The seventeenth connecting portion 164 is rotatably coupled to the ninth fixing means 162 and the sixth connecting portion 134 is rotatably coupled to the fifth fixing means 132,

The third threaded rod 158 installed between the fourteenth connection part 164 and the sixth connection part 134 absorbs the impact of the seismic wave while moving according to the movement of the fourteenth connection part 164 and the sixth connection part 134. [ do.

The sixteenth connection unit 172 is rotatably coupled to the tenth fixing unit 172 and the eighth connection unit 140 is rotatably coupled to the sixth fixing unit 138,

The fourth screw rod 166 installed between the sixteenth connection part 172 and the eighth connection part 140 absorbs the impact of the seismic wave while moving according to the movement of the sixteenth connection part 172 and the eighth connection part 140. [ do.

6 is a view showing another embodiment of an anti-vibration shake prevention brace according to the present invention,

And the second threaded rod and the third threaded rod are removed from the anti-vibration shake-proof brace according to the present invention.

FIG. 7 is a view showing another embodiment of an anti-seismic shake prevention brace according to the present invention, and FIG. 8 is a view showing a state where a pipeline is installed on the anti-seismic shake prevention braces of FIG.

As shown in FIGS. 7 to 8, the anti-vibration / anti-vibration brace 100 of another embodiment includes:

An upper clamp 102 for fixing one side of the upper outer surface of the pipe;

A lower clamp 104 positioned at a predetermined distance from the upper clamp 102 to fix one side of the lower outer surface of the pipe;

A screw pipe 106 protruding from the center of the upper clamp 102 and the lower clamp 104;

A fastening portion 108 screwed to the screw pipe 106;

A vertical pipe 110 screwed to the coupling part 108 to minimize shaking of the piping from a shock of a seismic wave;

An insert plate 112 screwed on the upper portion of the vertical pipe 110;

First fixing means (116) for fixing the upper clamp (102) and the lower clamp (104);

A second fixing means 120 for fixing the upper clamp 102 and the lower clamp 104 at a predetermined interval from the first fixing means 116;

A first rotation part 300 rotatably coupled to the first fixing part 116;

A first shaft 302 coupled to the first rotation part 300 and rotated;

A first support plate 304 threadedly engaged with the upper portion of the first shaft 302;

A second rotation part (306) rotatably coupled to the second fixing part (120);

A second shaft 308 coupled to the second rotation part 306 and rotated;

And a second support plate 310 screwed on the upper portion of the second shaft 308.

[0033] The operation of the anti-vibration / anti-shake brace 100 according to another embodiment having the above-

The insert plate 112 is installed on the floor and ceiling.

As shown in FIG. 8, a pipe 200 is installed between the upper clamp 102 and the lower clamp 104.

When the pipe 200 is installed between the upper clamp 102 and the lower clamp 104 and an impact (i.e., vibration) occurs in the structure due to a seismic wave,

The vertical pipe 110 supports the pipeline so as not to shake the pipeline from a shock of a seismic wave.

The first rotation part 300 is rotatably coupled to the first fixing part 116,

The first shaft 302 installed in the first rotation part 300 moves according to the movement of the first rotation part 300 and absorbs the shock of a seismic wave.

The second rotation unit 306 is rotatably coupled to the second fixing unit 120,

The second shaft 308 installed on the second rotation part 306 moves according to the movement of the second rotation part 306 to absorb the impact of the seismic wave.

The detailed description of the design is merely exemplary in nature and is used merely for the purpose of describing the present invention and not for limiting the scope of the design described in the claims or the claims. Therefore, those skilled in the art will appreciate that various modifications and equivalent embodiments are possible without departing from the scope of the present invention. Accordingly, the true scope of protection of the present invention should be determined by the technical idea of the appended claims.

100: Seismic shake prevention brace
102: upper clamp
104: Lower clamp
110: vertical pipe
112: insert plate
114: first connection portion
116: first fixing means
142: 1 st
150: The 2nd Nasa Bong
158: THIRD THREE
166: Fourth bar

Claims (3)

An upper clamp 102 for fixing one side of the upper outer surface of the pipe;
A lower clamp 104 positioned at a predetermined distance from the upper clamp 102 to fix one side of the lower outer surface of the pipe;
A screw pipe 106 protruding from the upper center of the upper clamp 102;
A fastening portion 108 screwed to the screw pipe 106;
A vertical pipe 110 screwed to the coupling part 108 to minimize shaking of the piping from a shock of a seismic wave;
An insert plate 112 screwed to the upper portion of the vertical pipe 110 and embedded in the ceiling surface;
A first connection part (114) located at one side of the upper surface of the upper clamp (102) at a predetermined interval from the screw pipe (106);
A first fixing means 116 for fixing the first connection portion 114, the upper clamp 102 and the lower clamp 104;
A second connection part 118 positioned on one side of the upper surface of the upper clamp 102 at a predetermined interval from the first connection part 114;
A second fixing means 120 for fixing the second connection portion 118, the upper clamp 102 and the lower clamp 104;
Third fixing means 122 coupled to the upper portion of the first connection portion 114;
A third connection portion (124) rotatably coupled to the third fixing means (122);
A fourth connection part 126 coupled to one side of the third fixing device 122 at a predetermined interval from the third connection part 124;
A fourth fixing means 128 coupled to an upper portion of the fourth connection portion 126;
A fifth connection part 130 rotatably coupled to the fourth fixing device 128;
A fifth fixing means 132 coupled to an upper portion of the second connection portion 118;
A sixth connection part (134) rotatably coupled to the fifth fixing device (132);
A seventh connecting portion 136 coupled to one side of the fifth fixing means 132 at a predetermined interval from the sixth connecting portion 134;
A sixth fixing means 138 coupled to an upper portion of the seventh connecting portion 136;
An eighth connection portion (140) rotatably coupled to the sixth fixing means (138);
A first screw rod 142 installed at the fifth connection part 130;
A ninth connection 144 coupled to the first screw rod 142;
A seventh fixing means 146 coupled to an upper portion of the ninth connecting portion 144;
A tenth connection portion (148) rotatably coupled to the seventh fixing means (146);
A second screw rod 150 installed at the third connection part 124;
An eleventh connection part 152 coupled to the second threaded rod 150;
An eighth fixing means 154 coupled to an upper portion of the eleventh connection portion 152;
A twelfth connection portion (156) rotatably coupled to the eighth fixing means (154);
A third threaded rod 158 installed at the sixth connection part 134;
A thirteenth connection part 160 coupled to the third threaded rod 158;
A ninth fixing means 162 coupled to an upper portion of the thirteenth connection portion 160;
A fourteenth connection portion (164) rotatably coupled to the ninth fixing means (162);
A fourth screw rod 166 installed at the eighth connection part 140;
A fifteenth coupling portion 168 coupled to the fourth threaded rod 166;
A tenth fixing means 170 coupled to an upper portion of the fifteenth connection portion 168;
And a sixteenth connection portion (172) rotatably coupled to the tenth fixing means (170). delete delete

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