KR101620063B1 - Distribution box of earthquake-proof type having up and down and refraction buffer - Google Patents

Abstract

The double seam type power distribution box 100 having the vertical refraction buffering means according to the present invention,
A case 110 and an electric distribution board 120 housed in the case 110. The case 110 is interposed between a lower surface 115 of the case 110 and the ground G, And the upper and lower refractive damping means 130 interposed between the lower surface 115 of the case 110 and the ground G and the case 110 and the upper and lower refractive damping means 130, A lower surface 115 of the case 110 is connected to the ground G and a case where the upper plate 131 is attached to the case 110 and the switchboard 120, A compression spring 132 for connecting the upper plate 131 and the lower plate 134 to each other so that the upper plate 131 and the lower plate 134 are disposed around the compression spring 132, A tension spring 133 which is connected to the upper plate 131 and the lower plate 134 so as to be rotatable and which is received in the compression spring 132, It comprises 135.
The vibration transmitted to the case 110 is firstly attenuated by the upper and lower refractive damping means 130 interposed between the bottom of the case 110 and the ground G, And the upper and lower refractive damping means 130 interposed between the case 110 and the switchboard 120 between the bracket 113 and the bracket 113. [

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a double earthquake-

More particularly, the present invention relates to a double damper type distribution box having an upper and lower refraction buffering means, and more particularly, to a double damper type distribution box having an upper and lower refraction buffering means. More specifically, The present invention relates to a double shock resistant power distribution box having an upper and lower refractive cushioning means.

FIG. 1 is a cross-sectional view illustrating a seismic resistant power distribution box according to the background art. The structure and problems of the background art will be described below.

Generally, the earthquake-resistant power distribution box 1 accommodates the switchboard 20 and is constructed such that the buffer means 30 is mounted on the floor surface so as to be able to cope with an earthquake. The seismic resistant power distribution box 1 is structured such that the bracket 10 is fixed to the inner side thereof to support the power distribution board 20. Further, a cable (40) led into the seismic distribution cabinet (1) is connected to the switchboard (20). The switchboard 20 is a device for controlling power such as distributing and supplying the applied electric power or transforming the voltage, and may be a board type or a box type.

When the ground vibrates vertically and horizontally due to an earthquake, the shock resistant power distribution box 1 serves to prevent vibration of the shock absorber 30.

However, in the background art, since the buffering function is not provided at the connection portion between the power distribution board 20 and the bracket 10, when an earthquake occurs, stress is repeatedly applied to the connecting portion between the power distribution board 20 and the bracket 10 The distribution board 20 is separated from the bracket 10 and is severely swung vertically and horizontally within the seismic distribution cabinet 1 or collides with the interior of the seismic distribution cabinet 1. [

As a result, there is a problem that the cable 40 is disconnected or short-circuited, resulting in power disconnection. In particular, there is a problem that a fire occurs due to a spark generated when the cable 40 is short-circuited.

The buffering means 30 is a general compression spring, and when a load equal to or higher than a predetermined limit is applied to the upper or lower side, the buffering means 30 is broken and the vibration-proof cabinet 1 is detached from the floor, Causing a secondary damage.

Korean Patent Registration No. 10-1254091 (Registered on April 8, 2013)

The double damper type distribution box having the vertical inflection buffering means according to the present invention not only attenuates vibrations transmitted from the ground when an earthquake occurs but also attenuates vibrations transmitted to the inside of the switchboard, . It is an object of the present invention to prevent the occurrence of a fire due to a spark that occurs when a cable is short-circuited, cut off, or short-circuited because the inside of the switchboard is detached and swung.

In addition, when the load above the predetermined limit is applied to the upper side or the side side due to the earthquake, the buffering means is cut off, so that the earthquake-resistant power distribution box is detached from the ground to damage the surrounding building or vehicle, And the like.

The double damper type distribution box having the upper and lower refractive dampening means according to the present invention,

And an upper and lower refractive damper means interposed between the lower surface of the case and the ground and between the case and the switchboard,

Wherein the upper and lower refractive-

A lower plate attached to a lower surface of the case, a lower surface of the case and a counterpart to which the upper plate is not attached in the case and the switchboard, and a lower plate attached to the upper plate and the lower plate, A tension spring for connecting the upper plate and the lower plate so as to be disposed around the compression spring, and a pivot shaft accommodated in the compression spring and having both side ends rotatably connected to the upper plate and the lower plate .

The above-

A compression spring connected to a lower portion of the upper shaft and a lower shaft connected to a lower portion of the compression spring and connected to rotate on an upper surface of the lower plate.

The upper and lower shafts are connected to the upper and lower plates, respectively. The upper and lower shafts are formed on the lower surface of the upper plate. The upper and lower grooves are formed in the upper surface of the lower plate to correspond to the upper groove. An upper bearing which is connected to the upper end of the upper shaft and is accommodated in the upper groove and whose upper surface is in close contact with the upper groove and which is connected to the lower end of the lower shaft, And includes a lower bearing which is a spherical surface that is brought into close contact with the lower groove.

And a lower cap attached to the lower plate and supporting the lower bearing. The upper cap is attached to the upper plate and supports the upper bearing. do.

And an elastic tube accommodated in the compression spring, the elastic tube having an upper end and a lower end closely fitted to the upper and lower caps, respectively.

The safety spindle is disposed around the compression spring. The safety spindle is fixed to the lower plate and passes through the upper plate. The through hole is formed in the upper plate so that the safety shaft passes through the safety spindle. And a head connected to the through hole.

The double damper-type power distribution box having the upper and lower refractive damper means according to the present invention has the following effects.

The vibration transmitted to the case at the time of occurrence of an earthquake is primarily attenuated by the upper and lower refractive damping means interposed between the bottom and the ground of the case and is further reduced by the upper and lower refractive damping means interposed between the cabinet and the bracket, There is an effect of being attenuated secondarily.

In addition, the upper and lower refractive buffering means is effective in preventing the compression spring and the tension spring from being separated by the ultimate strength by the safety shaft as the upper plate and the lower plate to separate the upper plate and the lower plate from each other.

Therefore, it is possible to prevent a phenomenon in which the switchboard is detached from the bracket or collide with the inner side surface of the case, and that the cable is detached from the switchboard and strikes against the inner side surface of the switchboard or the case, And it is possible to prevent the occurrence of a fire due to a spark that occurs during a short circuit.

Further, there is an effect that it is possible to prevent the secondary damage from occurring because the case is detached from the ground and the surrounding buildings, vehicles, and the like are damaged.

1 is a perspective view showing a seismic distribution box according to the background art;
2 is a perspective view showing a double shock resistant distribution box having upper and lower refractive shock buffering means according to the present invention.
3 is an exploded perspective view showing a vertical refraction buffering means constructed in a double ridge-type distribution box having upper and lower refractive buffering means according to the present invention.
Fig. 4 is a cross-sectional view of a vertical refraction buffering means constituted in a double ridge-type distributing box having a vertical refraction buffering means according to the present invention, in which a tension spring is represented.
FIG. 5 is a cross-sectional view of a vertical refraction buffering means constituted in a double ridge-type distribution box having an upper and lower refractive buffer according to the present invention, in which a safety bolt is represented.
6 is a sectional view showing a state in which a load is applied sideways, as an upper and lower refractive dampening means constituted in a double rimmed type distribution cabinet having an upper and lower refractive damping means according to the present invention.
Fig. 7 is a sectional view showing a state in which a load is applied in a rotating direction in the vertical refraction buffering means constituted in the double ridge type distribution box having the vertical refraction buffering means according to the present invention. Fig.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention.

FIG. 2 is a perspective view showing a double shock resistant distribution box having upper and lower refractive shock buffering means according to the present invention, FIG. 3 is an exploded perspective view showing a vertical refraction buffering means constructed in a double shock resistant distribution box having upper and lower refractive shock buffering means according to the present invention, And FIG. 4 is a cross-sectional view of the upper and lower refractive damping cushioning means constituted in the double damper-type power distribution box having the upper and lower refractive damping means according to the present invention, FIG. 6 is a sectional view of a vertical refraction buffering means constituted in a seismic resistant cabinet, in which a safety bolt is expressed; FIG. 6 is a vertical refraction buffering means constituted in a double ridge- Fig. 7 is a sectional view showing a state in which a double shock resistant distribution As the upper and lower refractive buffer means is configured to, as will be described with a cross-sectional view showing a state in which the load is applied to the turning direction.

The present invention relates to a general distribution cabinet, which further comprises a vertical refraction buffering means (130) on the outside and inside of the cabin, so that it can be doubly buffered when an earthquake occurs, Is prevented.

To this end, the double damper type power distribution box 100 having the upper and lower refractive damping means according to the present invention is constructed as follows.

A box-shaped case 110 is formed, and an electric panel 120 for controlling electric power is accommodated in the case 110. The switchboard 120 is formed in a plate or box shape and is configured to be supported by a bracket 113 whose lower end is fixed to the inner side surface of the case 110. Further, a cable C connected to the switchboard 120 is formed so as to enter the upper portion of the case 110 to supply electric power.

The upper and lower refraction buffering means 130 is further provided on the lower surface 115 of the case 110 and supported on the ground G so as to be interposed between the case 110 and the switchboard 120. In order for the upper and lower refractive dampening means 130 to be interposed between the case 110 and the switchboard 120, the vertical inflation damping means 130 is interposed between the bracket 113 and the switchboard 120, And the upper and lower refractive damping means 130 are interposed on the inner side surface of the case 110.

3 and 4, the upper and lower refractive dampening means 130 includes a lower surface 115 of the case 110, a ground G, and a top plate 120 attached to one side of the case 110 and the switchboard 120, And a lower plate 134 attached to the opposite side to which the upper plate 131 is not attached on the lower surface 115 of the case 110 and the ground G and the case 110 and the distribution board 120 .

A compression spring 132 for connecting the upper plate 131 and the lower plate 134 and a tension spring 134 for connecting the upper plate 131 and the lower plate 134 are disposed around the compression spring 132 And a rotary shaft 135 which is accommodated in the compression spring 132 and is connected to the lower plate 131 and the lower plate 134 at both ends so as to be rotatable is formed.

The rotary shaft 135 is constituted by an upper shaft 1351 connected to the lower surface 1315 of the upper plate 131 so as to rotate and a compression spring 1356 connected to the lower portion of the upper shaft 1351 is constituted, And a lower shaft 1357 connected to the lower portion of the spring 1356 and connected to rotate on the upper surface 1345 of the lower plate 134 is formed. Therefore, the upper and lower ends of the rotary shaft 135 are not only rotated but also can be bent by the compression spring 1356, so that it is possible to cope with seismic loads in various directions.

The upper and lower shafts 1351 and 1357 are connected to the upper plate 131 and the lower plate 134 so that the upper and lower shafts 1351 and 1357 are rotated. An upper groove 1311 which is a spherical surface is formed. An upper bearing 1353 connected to the upper end of the upper shaft 1351 and received in the upper groove 1311 constitutes a spherical surface in which the upper surface 1355 is in close contact with the upper groove 1311. At this time, the upper bearing 1353 is configured to be easily supported on the plate-shaped upper cap 137 described below because the lower surface E is flat. If the lower surface (E) is spherical, it is preferable to form the upper cap 137 flat because it is difficult to form the upper cap 137 in conformity with the lower surface (E). A male thread S is formed on the upper shaft 1351 and a tapped hole T is formed on a lower surface E of the upper bearing 1353 so that the male thread S is fastened to the male thread S. .

The lower bearing 1358 is connected to the lower end of the lower shaft 1357 and is accommodated in the lower groove 1341 and is a spherical surface in which the lower surface 1359 is in close contact with the lower groove 1341. The lower bearing 1358 is configured such that the upper surface M is flat and can be easily supported on a plate-shaped lower cap 138 described later. If the upper surface M is spherical, for example, it is difficult to form the lower cap 138, which will be described later, to conform to the upper surface M. Therefore, it is preferable that the lower surface 138 is formed flat. A male thread U is formed on the lower shaft 1357 and a tapped hole V is formed on the upper surface M of the lower bearing 1358 to be coupled to the male thread U, .

An upper cap 137 is attached to the upper plate 131 to support the upper bearing 1353 as a plate-like plate through which the upper shaft 1351 passes. The upper cap 137 has a groove 1375 opened upward and a through hole 1373 through which the upper shaft 1351 passes is formed in the groove 1375.

The lower surface 1315 of the upper plate 131 is formed with a protrusion 1318 inserted in the groove 1375 and configured with the upper groove 1311. The protrusion 1318 is fixed to the groove 1375 by welding or an adhesive. A gap W is formed in the upper cap 137 and the protrusion 1318 and a gap X is formed between the through hole 1373 and the upper shaft 1351 so that the upper shaft 1351 and the upper The bearing 1353 is configured to be rotatable.

Further, a lower cap 138 is attached to the lower plate 134 to support the lower bearing 1358 as a plate-like plate through which the lower shaft 1357 passes. The lower cap 138 has a groove 1387 opened downward and a through hole 1385 through which the lower shaft 1357 passes is formed in the groove 1387.

A protrusion 1348 is formed in the upper surface 1345 of the lower plate 134 so as to be inserted into the groove 1387 and configured by the lower groove 1341. The projecting portion 1348 is fixed to the groove 1387 by welding or an adhesive. A gap B is formed in the lower cap 138 and the protrusion 1348 and a gap I is formed between the through hole 1385 and the lower shaft 1357 to form a lower shaft 1357, And the lower bearing 1358 is configured to be rotatable.

An elastic tube 139 accommodated in the compression spring 132 and having an upper end and a lower end closely fitted to the upper and lower caps 137 and 138 The compression spring 135 and the compression spring 1356 of the rotary shaft 135 are complemented. The elastic tube 139 may be formed of, for example, a rubber material, urethane, or other synthetic resin.

5, a safety shaft 136 is disposed around the compression spring 132 and fixed to the lower plate 134 to penetrate the upper plate 131. The safety shaft 136 is passed through the upper plate 131 A gap Y is formed between the safety axis 136 and the through hole 1313 so that the upper plate 131 or the lower plate 134 can easily rotate . The head 1361 is disposed at an upper portion of the through hole 1313 and is connected to the safety axis 136 to be engaged with the through hole 1313. For example, the safety shaft 136 may be a bolt, and the head 1361 may be a nut fastened to the safety shaft 136. At this time, the case 110 is formed with a hole through which the safety shaft 136 and the head 1361 pass.

The tension spring 132 is connected to a pin 137 fixed to the upper plate 131 and the lower plate 134 and is configured to be caught by a latch 138 passing through the pin 137. Since the stopper 138 is formed to be larger than the diameter of the pin 137, the upper plate 131 can be reciprocated up and down.

A process in which the double damper-type power distribution box 100 having the up-and-down refractive damping means according to the present invention corresponds to an earthquake will now be described.

First, when vibrations occur in the upper and lower chambers due to an earthquake, the upper plate 131 of the upper and lower refractive dampers 130 is raised and lowered as shown in FIG. At this time, the lifting spring 133 is raised and lowered by the clearance of the locking spring 138 formed on the tension spring 133 and the pin 137. Further, the compression springs 132 and 1356 and the elastic tube 139 are buffered against the descending external force, and the tension spring 133 is buffered when the compression springs 132 and 1356 and the elastic tube 139 are lifted.

When the upper plate 131 is lifted up, the head 1361 of the safety shaft 136 is caught by the through hole 1313 so that the compression springs 132 and 1356 and the tension spring 133 are subjected to an ultimate load So that the phenomenon of being separated from the lower plate 134 is prevented.

Particularly, since the rotation shaft 135 is easily expanded and contracted by the compression spring 1356 with respect to a tensile force or a compressive force, it can cope with an external force without breaking.

6, the upper plate 131 and the lower plate 134 are laterally displaced when an external force acts laterally due to an earthquake. The compression springs 132 and 1356, the elastic tube 139, and the tension spring 133 ) Function as a buffer. At this time, the upper bearing 1353 and the lower bearing 1358 are rotated in a state of being in close contact with the upper groove 1311 and the lower groove 1341, respectively, The upper bearing 1353 and the lower bearing 1358 are engaged with each other.

7, when the upper plate 131 or the lower plate 134 is rotated due to an earthquake, the upper bearing 1353 and the lower bearing 1358 are respectively engaged with the upper groove 1311 and the lower groove 1341 So that the compression springs 132 and 1357 and the tension springs 133 can be compressed or expanded while being buffered.

Particularly, since the pivoting shaft 135 is bent by the compression spring 1357 with respect to the lateral external force and the turning external force, the shock absorbing function can be performed without breaking.

The upper and lower refractive damping means 130 is configured such that vibration transmitted to the case 110 at the time of an earthquake is transmitted to the upper and lower refractive damping means 130 interposed between the bottom of the case 110 and the ground G, And is secondarily attenuated by the upper and lower refractive damping means 130 interposed between the cabinet 110 and the cabinet 120 between the cabinet 120 and the bracket 113 .

The compression springs 132 and 1356 and the tension spring 133 are cut off by the safety shaft 136 due to the ultimate strength of the upper plate 131 and the lower plate 134 so that the upper plate 131 and the lower plate 134, The separation phenomenon can be prevented.

Therefore, it is possible to prevent a phenomenon in which the switchboard 120 is detached from the bracket 113 or collides with the inner side surface of the case 110. [ There is an effect that the state in which the switchboard 120 is supported by the bracket 113 can be maintained at all times. Therefore, it is possible to prevent the cable C from being short-circuited when the cable C is released from the switchboard 120 and hit the inner side surface of the cabinet 120 or the case 110, thereby preventing a short circuit accident, There is an effect that the occurrence phenomenon can be prevented. In addition, the case 110 is separated from the ground G to damage the surrounding buildings, vehicles, and the like, thereby preventing secondary damage.

The embodiments and the accompanying drawings described in the present specification are merely illustrative of some of the technical ideas included in the present invention. Therefore, it is to be understood that the embodiments disclosed herein are not for purposes of limiting the technical idea of the present invention, but are intended to be illustrative, and therefore, the scope of the technical idea of the present invention is not limited by these embodiments. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

100: Double shock resistant distribution box with vertical refraction buffering means
110: Case 113: Bracket 115: Lower surface 120: Distribution board 130: Upper and lower refractive buffering means 131:
1311: Upper groove 1312: Inner side
1313: through hole 1315:
1318: protrusion 132: compression spring
133: Tension spring 137: Pin
138: stopper 134: bottom plate
1341: lower groove 1343: inner side
1345: upper surface 1348:
135: Pivot shaft 1351: Pivot shaft
1353: Upper bearing 1356: Compression spring
1357: Lower shaft 1358: Lower bearing
136: Safety axis 1361: Head
137: upper cap 1373: through hole
138: Lower cap 1385:
139: Elastic tube

Claims (6)

A box-shaped case 110,
An electric distribution board 120 accommodated in the case 110,
And upper and lower refractive damper means 130 interposed between the lower surface 115 of the case 110 and the ground G and interposed between the case 110 and the switchboard 120,
The switchboard 120 has a lower end supported by a bracket 113 fixed to an inner side surface of the case 110,
The upper and lower refractive damping means 130 is interposed between the bracket 113 and the switchboard 120 and the vertical damping buffer means 130 is interposed between the side surface of the switchboard 120 and the inner side surface of the case 110 Respectively,
The up-and-down refractive buffering means (130)
A lower surface 115 of the case 110 and a ground G and an upper plate 131 attached to either one of the case 110 and the switchboard 120,
A lower plate 134 attached to a lower surface 115 of the case 110 and a ground G and a counterpart to which the upper plate 131 is not attached in the case 110 and the switchboard 120;
A compression spring 132 for connecting the upper plate 131 and the lower plate 134,
A tension spring 133 connecting the upper plate 131 and the lower plate 134 to be disposed around the compression spring 132,
And a pivot shaft 135 which is accommodated in the compression spring 132 and has opposite ends connected to the upper plate 131 and the lower plate 134 so as to be rotatable. Distribution box. The method according to claim 1,
The pivot shaft 135,
An upper shaft 1351 rotatably connected to a lower surface 1315 of the upper plate 131,
A compression spring 1356 connected to the lower portion of the upper shaft 1351,
And a lower shaft (1357) connected to a lower portion of the compression spring (1356) and connected to the upper surface (1345) of the lower plate (134) so as to pivot. 3. The method of claim 2,
In order that the upper shaft 1351 and the lower shaft 1357 are connected to the upper plate 131 and the lower plate 134 so as to rotate,
An upper groove 1311 formed on the lower surface 1315 of the upper plate 131 and having an inner side surface 1312 as a spherical surface,
A lower groove 1341 formed on an upper surface 1345 of the lower plate 134 so as to correspond to the upper groove 1311 and having an inner side surface 1343 as a spherical surface,
An upper bearing 1353 connected to the upper end of the upper shaft 1351 and received in the upper groove 1311 and having a top surface 1355 in close contact with the upper groove 1311,
And a lower bearing 1358 connected to a lower end of the lower shaft 1357 and received in the lower groove 1341, the lower bearing 1358 being a spherical surface in which the lower surface 1359 is in close contact with the lower groove 1341. [ Double damper type distribution box with refraction buffering means. The method of claim 3,
An upper cap 137 attached to the upper plate 131 to support the upper bearing 1353, a plate-like plate passing through the upper shaft 1351,
And a lower cap (138) attached to the lower plate (134) to support the lower bearing (1358) in a plate shape passing through the lower shaft (1357) Distribution box. 5. The method of claim 4,
And an elastic tube 139 accommodated in the compression spring 132 and having an upper end and a lower end closely fitted to the upper and lower caps 137 and 138, respectively, Wherein the upper and lower refraction buffering means is a double damper type distribution box. 6. The method according to any one of claims 1 to 5,
A safety shaft 136 fixed to the lower plate 134 and passing through the upper plate 131,
A through hole 1313 formed in the upper plate 131 to allow the safety shaft 136 to pass therethrough,
And a head (1361) disposed at an upper portion of the through hole (1313) and connected to the safety axis (136) to be engaged with the through hole (1313).

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