KR200486262Y1 - Safety chain channel device - Google Patents

Abstract

The present invention relates to an anti-dust chanel apparatus for rapidly restoring a chan- nel to its original state during an impact of a seismic wave, thereby minimizing the impact of piping from a seismic wave. A first vertical channel (104) positioned at a predetermined distance from the first insert plate (102) and absorbing a shock of a seismic wave; A first connection part 106 provided between the first insert plate 102 and the first vertical channel 104; A second insert plate 108 positioned at a predetermined distance from the first insert plate 102; A second vertical channel 112 positioned at a predetermined distance from the second insert plate 108 to absorb a shock of a seismic wave; A second connection part 114 installed between the second insert plate 108 and the second vertical channel 112; A horizontal channel 116 installed between the lower end of the first vertical channel 104 and the lower end of the second vertical channel 112 to absorb a shock of a seismic wave; And a third connection part 118 provided under the first vertical channel 104.

Description

Safety chain channel device

The present invention relates to a chanel device, and more particularly, to an anti-chanel device for rapidly restoring a chan- nel to its original state at the time of a shock of a seismic wave, thereby minimizing the impact of the pipe from a seismic wave.

Generally, the conventional piping construction method is to cut a section steel such as "A" type, "C" type, "I" type, "H" type which is general section steel by oxygen cutting or a speed cutter After welding, it was used as a pipe support.

However, in such an application method, it is necessary to carry out the multi-step process from the existing shape steel pipe to the field by performing the green film coating and to the completion step of the heat insulation work, so that the worker can easily grasp the pipe support member The assembly time is increased and assemblability is poor.

In addition, the conventional welding method has a fear of environmental pollution as well as an electric shock, and there are a lot of construction processes, and there is a fear of occurrence of a fire along with a work avoidance phenomenon, and air delay, material consumption on the site, , Causing a rise in cost.

Accordingly, a pipe support base for fixing the frame to the ceiling front surface is formed by connecting the frame with the bolt and the nut.

An example of such a piping supporting stand is disclosed in Patent Registration No. 10-0780079, in which an upper ceiling piping support is provided, which includes a channel which is connected to the ceiling of the building by an upper plate and a bracket, The pipe is composed of a horizontal part supported by a pipe and a vertical part bent upwardly integrally from both sides of the horizontal part and bound to the ceiling.

As another example, a ceiling pipe mount is shown in Patent Registration No. 10-0807826, which includes a pair of vertical channels, the upper end of which is bound to the ceiling of the building by means of an insert plate and a bracket, And a clamp shoe installed on the horizontal chan- nel for supporting the piping, wherein the vertical chan- nel and the horizontal chan- nel form a concave or convex embossed portion on a part or entire surface thereof; Wherein the joint is formed by welding a horizontal element supporting the horizontal channel and a vertical element supporting the vertical channel, the horizontal element and the vertical element being partially or entirely formed with concave or convex embossed portions, And a spacer which is inserted into the opening of the vertical channel in the element to maintain the interval of the opening, and a concave or convex embossed portion is formed on a part or the whole surface of the bracket.

However, in the related arts, work efficiency can be expected by assembling the horizontal frame and the vertical frame by using bolts and nuts, while the connection bracket connecting the insert plate and the vertical frame installed on the ceiling front face each other, Since the respective components are separated so as to be coupled by the nut and the nut, there is a problem that storage and transportability are deteriorated.

In addition, in the process of assembling the connection bracket to the insert plate embedded in the ceiling surface in the field by assembling the connection bracket with bolts and nuts, the insert plate installed with a high height causes a delay in the operation time and greatly deteriorates the workability.

In addition, in the related art, two vertical frames are provided so as to correspond to each other to support the horizontal frame and are connected to and supported by the insert plate by the connection bracket. In the case of the conventional connection bracket, There is a problem that the position of the insert plate installed on the ceiling surface needs to be changed and reinstalled when the interval of the two vertical frames is to be changed according to the working conditions.

It is difficult to reinstall the insert plate in which the upper side is embedded in the concrete placed to form the ceiling front face substantially. Therefore, the insert plate buried in the ceiling front face is left as it is and a new insert plate is installed on the ceiling face with anchor bolts or the like There is a problem in that the work efficiency is greatly reduced along with the delay of the work time.

[0003] However, in order to solve the above-mentioned problems of the conventional piping support bracket, Japanese Patent Application No. 20-2009-0015060 (entitled: Improved Pipe Supporting Bracket), filed on November 20, 2009, An insert plate 10 embedded in the ceiling face 11 formed by the insert plate 10 and a connection bracket 20 located on the lower side of the insert plate 10 and an upper portion inserted into the connection bracket 20 Two vertical frames 30 and 30 connected by bolts B and N and connected to both sides of the lower sides of the two vertical frames 30 and 30, And a horizontal frame 40 fastened by a nut N. The connection bracket 20 is attached to the lower surface of the insert plate 10 so that the upper portion of the connection bracket 20 is in close contact with the insert plate 10, And the insert plate 10 and the heat- (22) (23) is formed such that the vertical frame (30) can be positioned at a variable position when the upper portion of the vertical frame (30) is drawn inward and fastened, and the two fastening surfaces And the fastening holes 24 and 25 corresponding to the fastening holes 31 of the vertical frame 30 are formed in the fastening holes 22 and 23, respectively.

However, the conventional improved piping supporting stand can not be restored to its original state when a shock of a seismic wave is applied to the piping, thereby damaging the piping from a seismic wave.

Accordingly, the present invention has been made to solve the above-mentioned problems of the prior art, and it is an object of the present invention to provide a method and apparatus for rapidly recovering a chan- nel to its original state upon impact of a seismic wave, Thereby providing a channel device.

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.

In order to achieve the above object, according to the present invention,

A first insert plate 102;

A first vertical channel (104) positioned at a predetermined distance from the first insert plate (102) and absorbing a shock of a seismic wave;

A first connection part 106 provided between the first insert plate 102 and the first vertical channel 104;

A second insert plate 108 positioned at a predetermined distance from the first insert plate 102;

A second vertical channel 112 positioned at a predetermined distance from the second insert plate 108 to absorb a shock of a seismic wave;

A second connection part 114 installed between the second insert plate 108 and the second vertical channel 112;

A horizontal channel 116 installed between the lower end of the first vertical channel 104 and the lower end of the second vertical channel 112 to absorb a shock of a seismic wave;

A thirteenth connection portion 168 installed at a central portion of the first vertical channel 104;

A ninth hinge part 170 rotatably installed on one side of the thirteenth connection part 168;

A seventeenth connecting portion 172 provided on the ninth hinge portion 170;

A seventh insert plate 174 positioned at a predetermined distance from the fourteenth connection portion 172;

A fifteenth connecting portion 176 installed at a lower end of the seventh insert plate 174;

A tenth hinge portion 178 rotatably installed on one side of the fifteenth connection portion 176;

A seventh vertical channel 180 installed between the fourteenth connection unit 172 and the tenth hinge unit 178 to absorb a shock of a seismic wave;

A sixteenth connection portion 182 installed at a central portion of the second vertical channel 112;

An eleventh hinge portion 184 rotatably installed on one side of the sixteenth connection portion 182;

A seventeenth connecting portion 186 provided on the eleventh hinge portion 184;

An eighth insert plate 188 positioned at a predetermined distance from the seventeenth connecting portion 186;

An eighteenth connecting portion 190 installed at a lower end of the eighth insert plate 188;

A twelfth hinge portion 192 rotatably installed on one side of the eighteenth connecting portion 190;

And an eighth vertical channel 194 disposed between the seventeenth connection unit 186 and the twelfth hinge unit 192 to absorb a shock of a seismic wave.

As described above, according to the present invention, an anti-vibration chanel device can quickly restore the channel to its original state upon impact of a seismic wave, thereby minimizing the impact of piping from a seismic wave.

1 is a view showing an anti-dust chanel device according to the present invention,
Fig. 2 is a schematic view showing a main part of the anti-dust chanel device of Fig. 1,
3 is an exploded view of the main part of Fig. 1,
4 is a view showing another embodiment of an anti-dust chanel device according to the present invention,
5 is a view showing another embodiment of an anti-dust chanel device according to the present invention,
6 is a view showing another embodiment of an anti-dust chanel device according to the present invention,
7 is a view showing another embodiment of an anti-dust chanel device according to the present invention,
8 is a view showing another embodiment of an anti-dust chanel device according to the present invention.

Hereinafter, a preferred embodiment of the vibration-resistant channel device 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-dust chanel device according to the present invention, FIG. 2 is a schematic view of the main part of the anti-dust chanel device of FIG. 1, and FIG. 3 is an exploded view of the main part of FIG.

As shown in Figs. 1 to 3, the vibration-damping channel device 100 according to the present invention includes:

A first insert plate 102;

A first vertical channel (104) positioned at a predetermined distance from the first insert plate (102) and absorbing a shock of a seismic wave;

A first connection part 106 provided between the first insert plate 102 and the first vertical channel 104;

A second insert plate 108 positioned at a predetermined distance from the first insert plate 102;

A second vertical channel 112 positioned at a predetermined distance from the second insert plate 108 to absorb a shock of a seismic wave;

A second connection part 114 installed between the second insert plate 108 and the second vertical channel 112;

A horizontal channel 116 installed between the lower end of the first vertical channel 104 and the lower end of the second vertical channel 112 to absorb a shock of a seismic wave;

A third connection part 118 provided under the first vertical channel 104;

A first hinge part (not shown) rotatably installed on one side of the third connection part 118;

A fourth connection part 122 installed at the first hinge part;

A third insert plate 124 positioned at a predetermined distance from the fourth connection portion 122;

A fifth connection part 126 installed at a lower end of the third insert plate 124;

A second hinge part 128 rotatably installed on one side of the fifth connection part 126;

A third vertical channel 130 installed between the fourth connection part 122 and the second hinge part 128 to absorb a shock of a seismic wave;

A third hinge portion (not shown) rotatably installed on one side of the third connection portion 118 so as to face the first hinge portion at a predetermined interval;

A sixth connection part 134 provided at the third hinge part;

A fourth insert plate 136 positioned at a certain distance from the sixth connection part 134;

A seventh connecting portion 138 provided at the lower end of the fourth insert plate 136;

A fourth hinge part 140 rotatably installed on one side of the seventh connecting part 138;

A fourth vertical channel 142 installed between the sixth connection part 134 and the fourth hinge part 140 to absorb a shock of a seismic wave;

An eighth connection part 144 installed below the fourth vertical channel 142;

A fifth hinge part (not shown) rotatably installed on one side of the eighth connection part 144;

A ninth connecting part (148) provided on the fifth hinge part;

A fifth insert plate 150 positioned at a predetermined distance from the ninth connection portion 148;

A tenth connection part 152 installed at a lower end of the fifth insert plate 150;

A sixth hinge unit 154 rotatably installed on one side of the tenth connection unit 152;

A fifth vertical channel 156 installed between the ninth connecting part 148 and the sixth hinge part 154 to absorb a shock of a seismic wave;

A seventh hinge portion (not shown) rotatably installed on one side of the eighth connecting portion 144 so as to face the fifth hinge portion at a predetermined interval;

An eleventh connection part 158 provided at the seventh hinge part;

A sixth insert plate 160 positioned at a predetermined distance from the eleventh connection unit 158;

A twelfth connection part 162 installed at the lower end of the sixth insert plate 160;

An eighth hinge part (164) rotatably installed on one side of the twelfth connection part (162);

A sixth vertical channel 166 installed between the eleventh connection part 158 and the eighth hinge part 164 to absorb a shock of a seismic wave;

A thirteenth connection portion 168 installed at a central portion of the first vertical channel 104;

A ninth hinge part 170 rotatably installed on one side of the thirteenth connection part 168;

A seventeenth connecting portion 172 provided on the ninth hinge portion 170;

A seventh insert plate 174 positioned at a predetermined distance from the fourteenth connection portion 172;

A fifteenth connecting portion 176 installed at a lower end of the seventh insert plate 174;

A tenth hinge portion 178 rotatably installed on one side of the fifteenth connection portion 176;

A seventh vertical channel 180 installed between the fourteenth connection unit 172 and the tenth hinge unit 178 to absorb a shock of a seismic wave;

A sixteenth connection portion 182 installed at a central portion of the second vertical channel 112;

An eleventh hinge portion 184 rotatably installed on one side of the sixteenth connection portion 182;

A seventeenth connecting portion 186 provided on the eleventh hinge portion 184;

An eighth insert plate 188 positioned at a predetermined distance from the seventeenth connecting portion 186;

An eighteenth connecting portion 190 installed at a lower end of the eighth insert plate 188;

A twelfth hinge portion 192 rotatably installed on one side of the eighteenth connecting portion 190;

And an eighth vertical channel 194 disposed between the seventeenth connection unit 186 and the twelfth hinge unit 192 to absorb a shock of a seismic wave.

The assembling process and the use state of the dust-proof chanel device 100 according to the present invention will be described as follows.

Here, the assembling process of the dust-proof chanel device according to the present invention can be changed in any order depending on the assembler.

First, after positioning the first insert plate 102, the first vertical channel 104, which absorbs the shock of a seismic wave, is positioned at a predetermined interval from the first insert plate 102.

A first connection part 106 is provided between the first insert plate 102 and the first vertical channel 104.

Then, the second insert plate 108 is positioned so as to face the first insert plate 102 at regular intervals.

The second vertical channel 112, which absorbs the impact of the seismic wave, is positioned at a predetermined interval from the second insert plate 108.

A second connection part 114 is provided between the second insert plate 108 and the second vertical channel 112.

A horizontal channel 116 for absorbing a shock of a seismic wave is installed between a lower end of the first vertical channel 104 and a lower end of the second vertical channel 112.

A third connection part 118 is installed below the first vertical channel 104.

A first hinge portion (not shown) is rotatably installed on one side of the third connection portion 118, and a fourth connection portion 122 is provided on the first hinge portion.

After the third insert plate 124 is positioned at a predetermined distance from the fourth connection part 122, a fifth connection part 126 is installed at the lower end of the third insert plate 124.

After the second hinge part 128 is rotatably installed on one side of the fifth connection part 126, a shock of a seismic wave is absorbed between the fourth connection part 122 and the second hinge part 128 The third vertical channel 130 is installed.

A third hinge portion (not shown) is rotatably installed on one side of the third connection portion 118 so as to face the first hinge portion at a predetermined distance.

After the sixth connecting portion 134 is installed on the third hinge portion, the fourth insert plate 136 is positioned at a predetermined distance from the sixth connecting portion 134.

A seventh connecting portion 138 is installed at the lower end of the fourth insert plate 136 and a fourth hinge portion 140 is rotatably installed at one side of the seventh connecting portion 138.

A fourth vertical channel 142 for absorbing a shock of a seismic wave is installed between the sixth connection part 134 and the fourth hinge part 140. An eighth connection part 142 is provided below the fourth vertical channel 142, (144).

A fifth hinge portion (not shown) is rotatably installed on one side of the eighth connecting portion 144, and a ninth connecting portion 148 is provided on the fifth hinge portion.

After the fifth insert plate 150 is positioned at a predetermined interval from the ninth connecting portion 148, a tenth connecting portion 152 is installed at the lower end of the fifth insert plate 150.

A sixth hinge part 154 is rotatably installed on one side of the tenth connecting part 152 and a shock absorber for absorbing a shock of a seismic wave is provided between the ninth connecting part 148 and the sixth hinge part 154. [ 5 Install the vertical channel (156).

A seventh hinge portion (not shown) is rotatably installed on one side of the eighth connecting portion 144 after the eighth connecting portion 144 is disposed to face the fifth hinge portion at a predetermined interval .

After the eleventh connection part 158 is installed on the seventh hinge part, the sixth insert plate 160 is positioned at a predetermined interval from the eleventh connection part 158. [

A twelfth connecting portion (162) is installed at the lower end of the sixth insert plate (160).

An eighth hinge portion 164 is rotatably installed on one side of the twelfth connecting portion 162 and then an eighth hinge portion 164 is provided between the eleventh connecting portion 158 and the eighth hinge portion 164 to absorb a shock of a seismic wave. 6 Install the vertical channel (166).

A thirteenth connecting portion 168 is installed at the center of the first vertical channel 104 and then a ninth hinge portion 170 is installed at one side of the thirteenth connecting portion 168 to be rotatable.

The seventh insert part 174 is positioned at a predetermined distance from the fourteenth connecting part 172 after the fourteenth connecting part 172 is installed on the ninth hinge part 170. [

A seventeenth connecting portion 176 is installed at the lower end of the seventh insert plate 174 and a tenth hinge portion 178 is rotatably installed at one side of the fifteenth connecting portion 176.

A seventh vertical channel 180 for absorbing a shock of a seismic wave is installed between the fourteenth connection portion 172 and the tenth hinge portion 178.

After the sixteenth connection portion 182 is installed in the middle of the second vertical channel 112, an eleventh hinge portion 184 is rotatably installed on one side of the sixteenth connection portion 182.

After the seventeenth connecting portion 186 is installed on the eleventh hinge portion 184, the eighth insert plate 188 is positioned at a predetermined distance from the seventeenth connecting portion 186.

An eighteenth connecting portion 190 is installed at the lower end of the eighth insert plate 188 and a twelfth hinge portion 192 is rotatably installed at one side of the eighteenth connecting portion 190.

An eighth vertical channel 194 for absorbing a shock of a seismic wave is installed between the seventeenth connecting portion 186 and the twelfth hinge portion 192.

As described above, when the dust-proof chanel device 100 according to the present invention is assembled,

The first insert plate 102, the second insert plate 108, the third insert plate 124, the fourth insert plate 136, the fifth insert plate 150, the sixth insert plate 160, The insert plate 174 and the eighth insert plate 188 are buried in the ceiling.

After a clamp (not shown) is provided on the upper surface of the horizontal channel 116, a pipe (not shown) is installed in the clamp.

After the piping is installed in the clamp as described above, if a shock (i.e., vibration) occurs in the structure due to the seismic wave,

The first vertical channel 104 and the second vertical channel 112 support the pipeline so as not to be shaken from a shock of a seismic wave.

The third vertical channel 130 is installed between the fourth connection part 122 and the second hinge part 128,

The third vertical channel 130 moves according to the rotation of the fourth connection part 122 and the second hinge part 128 to absorb a shock of a seismic wave.

Therefore, the third vertical channel 130 supports the pipeline so as not to shake the pipeline from the impact of the seismic wave.

The fourth vertical channel 142 is installed between the sixth connection part 134 and the fourth hinge part 140,

The fourth vertical channel 142 moves according to the rotation of the sixth connection part 134 and the fourth hinge part 140 to absorb a shock of a seismic wave.

Accordingly, the fourth vertical channel 142 supports the pipeline so as not to be shaken from a shock of a seismic wave.

The fifth vertical channel 156 is installed between the ninth connecting portion 148 and the sixth hinge portion 154,

The fifth vertical channel 156 moves according to the rotation of the ninth connecting portion 148 and the sixth hinge portion 154 to absorb the impact of the seismic wave.

Therefore, the fifth vertical channel 156 supports the pipeline so as not to shake the pipeline from a shock of a seismic wave.

The sixth vertical channel 166 is installed between the eleventh connection part 158 and the eighth hinge part 164,

The sixth vertical channel 166 moves according to the rotation of the eleventh connection part 158 and the eighth hinge part 164 to absorb a shock of a seismic wave.

Therefore, the sixth vertical channel 166 supports the pipeline so as not to be shaken from a shock of a seismic wave.

The seventh vertical channel 180 is installed between the fourteenth connection part 172 and the tenth hinge part 178,

The seventh vertical channel 180 moves along the rotation of the fourteenth connection part 172 and the tenth hinge part 178 to absorb the impact of the seismic waves.

Therefore, the seventh vertical channel 180 supports the pipeline so as not to be shaken from a shock of a seismic wave.

The eighth vertical channel 194 is provided between the seventeenth connecting portion 186 and the twelfth hinge portion 192,

The eighth vertical channel 194 moves according to the rotation of the seventeenth connecting portion 186 and the twelfth hinge portion 192 to absorb a shock of a seismic wave.

Therefore, the eighth vertical channel 194 supports the pipeline so as not to shake the pipeline from a shock of a seismic wave.

Therefore, the dust-proof chanel system of the present invention minimizes the shaking of the piping from the impact of the seismic wave, thereby preventing breakage and deformation of the piping.

4 is a view showing another embodiment of an anti-dust chanel device according to the present invention,

A first insert plate 102;

A first vertical channel (104) positioned at a predetermined distance from the first insert plate (102) and absorbing a shock of a seismic wave;

A first connection part 106 provided between the first insert plate 102 and the first vertical channel 104;

A second insert plate 108 positioned at a predetermined distance from the first insert plate 102;

A second vertical channel 112 positioned at a predetermined distance from the second insert plate 108 to absorb a shock of a seismic wave;

A second connection part 114 installed between the second insert plate 108 and the second vertical channel 112;

A horizontal channel 116 installed between the lower end of the first vertical channel 104 and the lower end of the second vertical channel 112 to absorb a shock of a seismic wave;

A third connection part 118 provided under the first vertical channel 104;

A first hinge part (not shown) rotatably installed on one side of the third connection part 118;

A fourth connection part 122 installed at the first hinge part;

A third insert plate 124 positioned at a predetermined distance from the fourth connection portion 122;

A fifth connection part 126 installed at a lower end of the third insert plate 124;

A second hinge part 128 rotatably installed on one side of the fifth connection part 126;

A third vertical channel 130 installed between the fourth connection part 122 and the second hinge part 128 to absorb a shock of a seismic wave;

A third hinge portion (not shown) rotatably installed on one side of the third connection portion 118 so as to face the first hinge portion at a predetermined interval;

A sixth connection part 134 provided at the third hinge part;

A fourth insert plate 136 positioned at a certain distance from the sixth connection part 134;

A seventh connecting portion 138 provided at the lower end of the fourth insert plate 136;

A fourth hinge part 140 rotatably installed on one side of the seventh connecting part 138;

A fourth vertical channel 142 installed between the sixth connection part 134 and the fourth hinge part 140 to absorb a shock of a seismic wave;

An eighth connection part 144 installed below the fourth vertical channel 142;

A fifth hinge part (not shown) rotatably installed on one side of the eighth connection part 144;

A ninth connecting part (148) provided on the fifth hinge part;

A fifth insert plate 150 positioned at a predetermined distance from the ninth connection portion 148;

A tenth connection part 152 installed at a lower end of the fifth insert plate 150;

A sixth hinge unit 154 rotatably installed on one side of the tenth connection unit 152;

A fifth vertical channel 156 installed between the ninth connecting part 148 and the sixth hinge part 154 to absorb a shock of a seismic wave;

A seventh hinge portion (not shown) rotatably installed on one side of the eighth connecting portion 144 so as to face the fifth hinge portion at a predetermined interval;

An eleventh connection part 158 provided at the seventh hinge part;

A sixth insert plate 160 positioned at a predetermined distance from the eleventh connection unit 158;

A twelfth connection part 162 installed at the lower end of the sixth insert plate 160;

An eighth hinge part (164) rotatably installed on one side of the twelfth connection part (162);

And a sixth vertical channel 166 installed between the eleventh connection part 158 and the eighth hinge part 164 to absorb a shock of a seismic wave.

The operation of the vibration-damping channel apparatus 100 according to another embodiment shown in Fig.

It is omitted because it is the same as or similar to the operation of FIG.

5 is a view showing another embodiment of an anti-dust chanel device according to the present invention,

A first insert plate 102;

A first vertical channel (104) positioned at a predetermined distance from the first insert plate (102) and absorbing a shock of a seismic wave;

A first connection part 106 provided between the first insert plate 102 and the first vertical channel 104;

A second insert plate 108 positioned at a predetermined distance from the first insert plate 102;

A second vertical channel 112 positioned at a predetermined distance from the second insert plate 108 to absorb a shock of a seismic wave;

A second connection part 114 installed between the second insert plate 108 and the second vertical channel 112;

A horizontal channel 116 installed between the lower end of the first vertical channel 104 and the lower end of the second vertical channel 112 to absorb a shock of a seismic wave;

A thirteenth connection portion 168 installed at a central portion of the first vertical channel 104;

A ninth hinge part 170 rotatably installed on one side of the thirteenth connection part 168;

A seventeenth connecting portion 172 provided on the ninth hinge portion 170;

A seventh insert plate 174 positioned at a predetermined distance from the fourteenth connection portion 172;

A fifteenth connecting portion 176 installed at a lower end of the seventh insert plate 174;

A tenth hinge portion 178 rotatably installed on one side of the fifteenth connection portion 176;

A seventh vertical channel 180 installed between the fourteenth connection unit 172 and the tenth hinge unit 178 to absorb a shock of a seismic wave;

A sixteenth connection portion 182 installed at a central portion of the second vertical channel 112;

An eleventh hinge portion 184 rotatably installed on one side of the sixteenth connection portion 182;

A seventeenth connecting portion 186 provided on the eleventh hinge portion 184;

An eighth insert plate 188 positioned at a predetermined distance from the seventeenth connecting portion 186;

An eighteenth connecting portion 190 installed at a lower end of the eighth insert plate 188;

A twelfth hinge portion 192 rotatably installed on one side of the eighteenth connecting portion 190;

And an eighth vertical channel 194 disposed between the seventeenth connection unit 186 and the twelfth hinge unit 192 to absorb a shock of a seismic wave.

The operation of the vibration-damping channel device 100 according to still another embodiment shown in Fig.

It is omitted because it is the same as or similar to the operation of FIG.

6 is a view showing another embodiment of an anti-dust chanel device according to the present invention,

A first insert plate 102;

A first vertical channel (104) positioned at a predetermined distance from the first insert plate (102) and absorbing a shock of a seismic wave;

A first connection part 106 provided between the first insert plate 102 and the first vertical channel 104;

A second insert plate 108 positioned at a predetermined distance from the first insert plate 102;

A second vertical channel 112 positioned at a predetermined distance from the second insert plate 108 to absorb a shock of a seismic wave;

A second connection part 114 installed between the second insert plate 108 and the second vertical channel 112;

A horizontal channel 116 positioned between the lower end of the first vertical channel 104 and the lower end of the second vertical channel 112 to absorb a shock of a seismic wave;

A first coupling part 200 for coupling the lower end of the first vertical channel 104 and one end of the horizontal channel 116;

A second fastening part 202 for fastening the lower end of the second vertical channel 112 and the other end of the horizontal channel 116 at a predetermined interval from the first fastening part 200;

A third connection part 118 provided under the first vertical channel 104;

A first hinge part (not shown) rotatably installed on one side of the third connection part 118;

A fourth connection part 122 installed at the first hinge part;

A third insert plate 124 positioned at a predetermined distance from the fourth connection portion 122;

A fifth connection part 126 installed at a lower end of the third insert plate 124;

A second hinge part 128 rotatably installed on one side of the fifth connection part 126;

A third vertical channel 130 installed between the fourth connection part 122 and the second hinge part 128 to absorb a shock of a seismic wave;

A third hinge portion (not shown) rotatably installed on one side of the third connection portion 118 so as to face the first hinge portion at a predetermined interval;

A sixth connection part 134 provided at the third hinge part;

A fourth insert plate 136 positioned at a certain distance from the sixth connection part 134;

A seventh connecting portion 138 provided at the lower end of the fourth insert plate 136;

A fourth hinge part 140 rotatably installed on one side of the seventh connecting part 138;

A fourth vertical channel 142 installed between the sixth connection part 134 and the fourth hinge part 140 to absorb a shock of a seismic wave;

An eighth connection part 144 installed below the fourth vertical channel 142;

A fifth hinge part (not shown) rotatably installed on one side of the eighth connection part 144;

A ninth connecting part (148) provided on the fifth hinge part;

A fifth insert plate 150 positioned at a predetermined distance from the ninth connection portion 148;

A tenth connection part 152 installed at a lower end of the fifth insert plate 150;

A sixth hinge unit 154 rotatably installed on one side of the tenth connection unit 152;

A fifth vertical channel 156 installed between the ninth connecting part 148 and the sixth hinge part 154 to absorb a shock of a seismic wave;

A seventh hinge portion (not shown) rotatably installed on one side of the eighth connecting portion 144 so as to face the fifth hinge portion at a predetermined interval;

An eleventh connection part 158 provided at the seventh hinge part;

A sixth insert plate 160 positioned at a predetermined distance from the eleventh connection unit 158;

A twelfth connection part 162 installed at the lower end of the sixth insert plate 160;

An eighth hinge part (164) rotatably installed on one side of the twelfth connection part (162);

A sixth vertical channel 166 installed between the eleventh connection part 158 and the eighth hinge part 164 to absorb a shock of a seismic wave;

A thirteenth connection portion 168 installed at a central portion of the first vertical channel 104;

A ninth hinge part 170 rotatably installed on one side of the thirteenth connection part 168;

A seventeenth connecting portion 172 provided on the ninth hinge portion 170;

A seventh insert plate 174 positioned at a predetermined distance from the fourteenth connection portion 172;

A fifteenth connecting portion 176 installed at a lower end of the seventh insert plate 174;

A tenth hinge portion 178 rotatably installed on one side of the fifteenth connection portion 176;

A seventh vertical channel 180 installed between the fourteenth connection unit 172 and the tenth hinge unit 178 to absorb a shock of a seismic wave;

A sixteenth connection portion 182 installed at a central portion of the second vertical channel 112;

An eleventh hinge portion 184 rotatably installed on one side of the sixteenth connection portion 182;

A seventeenth connecting portion 186 provided on the eleventh hinge portion 184;

An eighth insert plate 188 positioned at a predetermined distance from the seventeenth connecting portion 186;

An eighteenth connecting portion 190 installed at a lower end of the eighth insert plate 188;

A twelfth hinge portion 192 rotatably installed on one side of the eighteenth connecting portion 190;

And an eighth vertical channel 194 disposed between the seventeenth connection unit 186 and the twelfth hinge unit 192 to absorb a shock of a seismic wave.

The operation of the vibration-damping channel device 100 of the other embodiment shown in Fig.

It is omitted because it is the same as or similar to the operation of FIG.

7 is a view showing another embodiment of an anti-dust chanel device according to the present invention,

A first insert plate 102;

A first vertical channel (104) positioned at a predetermined distance from the first insert plate (102) and absorbing a shock of a seismic wave;

A first connection part 106 provided between the first insert plate 102 and the first vertical channel 104;

A second insert plate 108 positioned at a predetermined distance from the first insert plate 102;

A second vertical channel 112 positioned at a predetermined distance from the second insert plate 108 to absorb a shock of a seismic wave;

A second connection part 114 installed between the second insert plate 108 and the second vertical channel 112;

A horizontal channel 116 positioned between the lower end of the first vertical channel 104 and the lower end of the second vertical channel 112 to absorb a shock of a seismic wave;

A first coupling part 200 for coupling the lower end of the first vertical channel 104 and one end of the horizontal channel 116;

A second fastening part 202 for fastening the lower end of the second vertical channel 112 and the other end of the horizontal channel 116 at a predetermined interval from the first fastening part 200;

A third connection part 118 provided under the first vertical channel 104;

A first hinge part (not shown) rotatably installed on one side of the third connection part 118;

A fourth connection part 122 installed at the first hinge part;

A third insert plate 124 positioned at a predetermined distance from the fourth connection portion 122;

A fifth connection part 126 installed at a lower end of the third insert plate 124;

A second hinge part 128 rotatably installed on one side of the fifth connection part 126;

A third vertical channel 130 installed between the fourth connection part 122 and the second hinge part 128 to absorb a shock of a seismic wave;

A third hinge portion (not shown) rotatably installed on one side of the third connection portion 118 so as to face the first hinge portion at a predetermined interval;

A sixth connection part 134 provided at the third hinge part;

A fourth insert plate 136 positioned at a certain distance from the sixth connection part 134;

A seventh connecting portion 138 provided at the lower end of the fourth insert plate 136;

A fourth hinge part 140 rotatably installed on one side of the seventh connecting part 138;

A fourth vertical channel 142 installed between the sixth connection part 134 and the fourth hinge part 140 to absorb a shock of a seismic wave;

An eighth connection part 144 installed below the fourth vertical channel 142;

A fifth hinge part (not shown) rotatably installed on one side of the eighth connection part 144;

A ninth connecting part (148) provided on the fifth hinge part;

A fifth insert plate 150 positioned at a predetermined distance from the ninth connection portion 148;

A tenth connection part 152 installed at a lower end of the fifth insert plate 150;

A sixth hinge unit 154 rotatably installed on one side of the tenth connection unit 152;

A fifth vertical channel 156 installed between the ninth connecting part 148 and the sixth hinge part 154 to absorb a shock of a seismic wave;

A seventh hinge portion (not shown) rotatably installed on one side of the eighth connecting portion 144 so as to face the fifth hinge portion at a predetermined interval;

An eleventh connection part 158 provided at the seventh hinge part;

A sixth insert plate 160 positioned at a predetermined distance from the eleventh connection unit 158;

A twelfth connection part 162 installed at the lower end of the sixth insert plate 160;

An eighth hinge part (164) rotatably installed on one side of the twelfth connection part (162);

And a sixth vertical channel 166 installed between the eleventh connection part 158 and the eighth hinge part 164 to absorb a shock of a seismic wave.

The operation of the vibration-damping channel device 100 of the other embodiment shown in Fig.

It is omitted because it is the same as or similar to the operation of FIG.

8 is a view showing another embodiment of an anti-dust chanel device according to the present invention,

A first insert plate 102;

A first vertical channel (104) positioned at a predetermined distance from the first insert plate (102) and absorbing a shock of a seismic wave;

A first connection part 106 provided between the first insert plate 102 and the first vertical channel 104;

A second insert plate 108 positioned at a predetermined distance from the first insert plate 102;

A second vertical channel 112 positioned at a predetermined distance from the second insert plate 108 to absorb a shock of a seismic wave;

A second connection part 114 installed between the second insert plate 108 and the second vertical channel 112;

A horizontal channel 116 positioned between the lower end of the first vertical channel 104 and the lower end of the second vertical channel 112 to absorb a shock of a seismic wave;

A first coupling part 200 for coupling the lower end of the first vertical channel 104 and one end of the horizontal channel 116;

A second fastening part 202 for fastening the lower end of the second vertical channel 112 and the other end of the horizontal channel 116 at a predetermined interval from the first fastening part 200;

A thirteenth connection portion 168 installed at a central portion of the first vertical channel 104;

A ninth hinge part 170 rotatably installed on one side of the thirteenth connection part 168;

A seventeenth connecting portion 172 provided on the ninth hinge portion 170;

A seventh insert plate 174 positioned at a predetermined distance from the fourteenth connection portion 172;

A fifteenth connecting portion 176 installed at a lower end of the seventh insert plate 174;

A tenth hinge portion 178 rotatably installed on one side of the fifteenth connection portion 176;

A seventh vertical channel 180 installed between the fourteenth connection unit 172 and the tenth hinge unit 178 to absorb a shock of a seismic wave;

A sixteenth connection portion 182 installed at a central portion of the second vertical channel 112;

An eleventh hinge portion 184 rotatably installed on one side of the sixteenth connection portion 182;

A seventeenth connecting portion 186 provided on the eleventh hinge portion 184;

An eighth insert plate 188 positioned at a predetermined distance from the seventeenth connecting portion 186;

An eighteenth connecting portion 190 installed at a lower end of the eighth insert plate 188;

A twelfth hinge portion 192 rotatably installed on one side of the eighteenth connecting portion 190;

And an eighth vertical channel 194 disposed between the seventeenth connection unit 186 and the twelfth hinge unit 192 to absorb a shock of a seismic wave.

The operation of the vibration-damping channel device 100 according to another embodiment shown in Fig.

It is omitted because it is the same as or similar to the operation of FIG.

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 present invention as set forth in the appended claims or the appended 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. Therefore, the true scope of technical protection of this invention should be determined by the technical idea of the appended utility model registration claim.

100: Inner chanel device
102: first insert plate
104: 1st vertical channel
108: second insert plate
112: Second vertical channel
116: horizontal channel
124: third insert plate
130: Third vertical channel
136: fourth insert plate
142: fourth vertical channel

Claims (3)

A first insert plate 102;
A first vertical channel (104) positioned at a predetermined distance from the first insert plate (102) and absorbing a shock of a seismic wave;
A first connection part 106 provided between the first insert plate 102 and the first vertical channel 104;
A second insert plate 108 positioned at a predetermined distance from the first insert plate 102;
A second vertical channel 112 positioned at a predetermined distance from the second insert plate 108 to absorb a shock of a seismic wave;
A second connection part 114 installed between the second insert plate 108 and the second vertical channel 112;
A horizontal channel 116 installed between the lower end of the first vertical channel 104 and the lower end of the second vertical channel 112 to absorb a shock of a seismic wave;
A third connection part 118 provided under the first vertical channel 104;
A first hinge portion rotatably installed on one side of the third connection portion 118;
A fourth connection part 122 installed at the first hinge part;
A third insert plate 124 positioned at a predetermined distance from the fourth connection portion 122;
A fifth connection part 126 installed at a lower end of the third insert plate 124;
A second hinge part 128 rotatably installed on one side of the fifth connection part 126;
A third vertical channel 130 installed between the fourth connection part 122 and the second hinge part 128 to absorb a shock of a seismic wave;
A third hinge portion rotatably installed on one side of the third connection portion 118 so as to face the first hinge portion at a predetermined interval;
A sixth connection part 134 provided at the third hinge part;
A fourth insert plate 136 positioned at a certain distance from the sixth connection part 134;
A seventh connecting portion 138 provided at the lower end of the fourth insert plate 136;
A fourth hinge part 140 rotatably installed on one side of the seventh connecting part 138;
A fourth vertical channel 142 installed between the sixth connection part 134 and the fourth hinge part 140 to absorb a shock of a seismic wave;
An eighth connection part 144 installed below the fourth vertical channel 142;
A fifth hinge portion rotatably installed on one side of the eighth connection portion 144;
A ninth connecting part (148) provided on the fifth hinge part;
A fifth insert plate 150 positioned at a predetermined distance from the ninth connection portion 148;
A tenth connection part 152 installed at a lower end of the fifth insert plate 150;
A sixth hinge unit 154 rotatably installed on one side of the tenth connection unit 152;
A fifth vertical channel 156 installed between the ninth connecting part 148 and the sixth hinge part 154 to absorb a shock of a seismic wave;
A seventh hinge portion rotatably installed on one side of the eighth connecting portion 144 so as to face the fifth hinge portion at a predetermined interval;
An eleventh connection part 158 provided at the seventh hinge part;
A sixth insert plate 160 positioned at a predetermined distance from the eleventh connection unit 158;
A twelfth connection part 162 installed at the lower end of the sixth insert plate 160;
An eighth hinge part (164) rotatably installed on one side of the twelfth connection part (162);
A sixth vertical channel 166 installed between the eleventh connection part 158 and the eighth hinge part 164 to absorb a shock of a seismic wave;
A thirteenth connection portion 168 installed at a central portion of the first vertical channel 104;
A ninth hinge part 170 rotatably installed on one side of the thirteenth connection part 168;
A seventeenth connecting portion 172 provided on the ninth hinge portion 170;
A seventh insert plate 174 positioned at a predetermined distance from the fourteenth connection portion 172;
A fifteenth connecting portion 176 installed at a lower end of the seventh insert plate 174;
A tenth hinge portion 178 rotatably installed on one side of the fifteenth connection portion 176;
A seventh vertical channel 180 installed between the fourteenth connection unit 172 and the tenth hinge unit 178 to absorb a shock of a seismic wave;
A sixteenth connection portion 182 installed at a central portion of the second vertical channel 112;
An eleventh hinge portion 184 rotatably installed on one side of the sixteenth connection portion 182;
A seventeenth connecting portion 186 provided on the eleventh hinge portion 184;
An eighth insert plate 188 positioned at a predetermined distance from the seventeenth connecting portion 186;
An eighteenth connecting portion 190 installed at a lower end of the eighth insert plate 188;
A twelfth hinge portion 192 rotatably installed on one side of the eighteenth connecting portion 190;
And an eighth vertical channel (194) installed between the seventeenth connection portion (186) and the twelfth hinge portion (192) to absorb a shock of a seismic wave. A first insert plate 102;
A first vertical channel (104) positioned at a predetermined distance from the first insert plate (102) and absorbing a shock of a seismic wave;
A first connection part 106 provided between the first insert plate 102 and the first vertical channel 104;
A second insert plate 108 positioned at a predetermined distance from the first insert plate 102;
A second vertical channel 112 positioned at a predetermined distance from the second insert plate 108 to absorb a shock of a seismic wave;
A second connection part 114 installed between the second insert plate 108 and the second vertical channel 112;
A horizontal channel 116 installed between the lower end of the first vertical channel 104 and the lower end of the second vertical channel 112 to absorb a shock of a seismic wave;
A third connection part 118 provided under the first vertical channel 104;
A first hinge portion rotatably installed on one side of the third connection portion 118;
A fourth connection part 122 installed at the first hinge part;
A third insert plate 124 positioned at a predetermined distance from the fourth connection portion 122;
A fifth connection part 126 installed at a lower end of the third insert plate 124;
A second hinge part 128 rotatably installed on one side of the fifth connection part 126;
A third vertical channel 130 installed between the fourth connection part 122 and the second hinge part 128 to absorb a shock of a seismic wave;
A third hinge portion rotatably installed on one side of the third connection portion 118 so as to face the first hinge portion at a predetermined interval;
A sixth connection part 134 provided at the third hinge part;
A fourth insert plate 136 positioned at a certain distance from the sixth connection part 134;
A seventh connecting portion 138 provided at the lower end of the fourth insert plate 136;
A fourth hinge part 140 rotatably installed on one side of the seventh connecting part 138;
A fourth vertical channel 142 installed between the sixth connection part 134 and the fourth hinge part 140 to absorb a shock of a seismic wave;
An eighth connection part 144 installed below the fourth vertical channel 142;
A fifth hinge portion rotatably installed on one side of the eighth connection portion 144;
A ninth connecting part (148) provided on the fifth hinge part;
A fifth insert plate 150 positioned at a predetermined distance from the ninth connection portion 148;
A tenth connection part 152 installed at a lower end of the fifth insert plate 150;
A sixth hinge unit 154 rotatably installed on one side of the tenth connection unit 152;
A fifth vertical channel 156 installed between the ninth connecting part 148 and the sixth hinge part 154 to absorb a shock of a seismic wave;
A seventh hinge portion rotatably installed on one side of the eighth connecting portion 144 so as to face the fifth hinge portion at a predetermined interval;
An eleventh connection part 158 provided at the seventh hinge part;
A sixth insert plate 160 positioned at a predetermined distance from the eleventh connection unit 158;
A twelfth connection part 162 installed at the lower end of the sixth insert plate 160;
An eighth hinge part (164) rotatably installed on one side of the twelfth connection part (162);
And a sixth vertical channel (166) installed between the eleventh connection part (158) and the eighth hinge part (164) to absorb a shock of a seismic wave. delete

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