KR101752841B1 - Remote control board having earthquake-proofing function - Google Patents

Abstract

A remote control panel having an earthquake-proof function includes a remote control panel enclosure; A concave flat spring that elastically supports the remote control box enclosure to buffer the impact force acting on the remote control panel enclosure through the ground; A lower bracket disposed below the concave flat spring; And an earthquake-resistant structure installed between the bottom portion of the concave flat spring and the lower bracket to buffer the impact force acting on the remote control panel enclosure. The concave flat spring includes a first concave plate formed so that four concave portions formed by gradually bending toward the bottom from the reference plane define a rectangular shape; And a second concave plate that is formed on the first concave plate with a size smaller than that of the first concave plate and is formed so that four concave portions formed by gradually bending toward the bottom from the reference surface define a rectangular shape. Accordingly, even if a shock wave such as a seismic wave is generated, vibration can be reduced primarily through the earthquake-proof structure, and secondarily, vibration can be reduced through the concave flat spring, thereby minimizing the influence of the seismic wave on the remote control panel enclosure.

Description

{REMOTE CONTROL BOARD HAVING EARTHQUAKE-PROOFING FUNCTION}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a remote control panel having an earthquake-proof function, and more particularly, to a remote control panel having an earthquake-resistant function configured to reduce shock waves and vibrations transmitted from the outside using a flat spring and an earthquake-resistant structure.

In order to monitor and control the control center at remote sites, various field devices (eg, lighting equipment, power equipment, air conditioning equipment, disaster prevention equipment, air conditioning equipment and the like) A remote control panel for connecting the field device and the control center is provided.

The remote control panel is installed in the field and collects (ie, monitors) the information of the on-site devices, controls the operation, communicates with the control center, and transmits information of the collected on-site devices to the control center. And controls the operation / stop of the field device.

The remote control panel includes an enclosure for monitoring and controlling the on-site equipment, a controller for communicating with the control center, and an enclosure for enclosing and controlling the controller.

If vibration or shock due to mechanical vibration or earthquake occurs in such a remote control panel, the equipment such as the controller inside the remote control panel and the wiring connecting the power equipment to each other are easily damaged or damaged. The remote control operation may be interrupted and a fire may be caused.

In recent years, large and small earthquakes in many parts of the world have resulted in numerous human and national damages. Also in Korea, which has been classified as a relatively safe zone, there is a need for seismic design for remote control panels.

Korean Registered Patent No. 10-1608689 (Announcement of Apr. 26, 2014) (Earthquake Resistant Structure) Korean Registered Patent No. 10-1183474 (2012. 09. 17. Announcement) (Earthquake-resistant power distribution device using leaf spring) Korean Registered Patent No. 10-1274982 (2013. 06. 10.) (Rotary type vibration absorbing device for seismic function of high and low voltage switchgear, motor control panel, and distribution board) Korean Registered Patent No. 10-1561039 (Oct. 12, 2015) (Switchgear with dustproof and seismic performance)

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a remote control panel having an earthquake-resistant function configured to reduce shock waves and vibration transmitted from the outside using a concave flat spring and an earthquake-resistant structure .

In order to achieve the object of the present invention, a remote control panel having an earthquake-proof function according to an embodiment includes a remote control panel enclosure equipped with a remote control panel facility; A concave flat spring for elastically supporting the remote control enclosure under the remote control enclosure and buffering an impact force acting on the remote control enclosure through the ground; A lower bracket disposed below the concave flat spring; And an earthquake-resistant structure installed between the bottom portion of the concave flat spring and the lower bracket to buffer an impact force acting on the remote control enclosure, wherein the concave flat spring covers the bottom portion of the remote control enclosure A first concave plate having four concave portions formed so as to be gradually bent from the reference surface toward the bottom portion to define a rectangular shape; And a second concave plate having a smaller size than the first concave plate and disposed on the first concave plate and having four concave portions formed by gradually bending toward the bottom from the reference surface to define a rectangular shape.

In one embodiment, the concave flat spring has a smaller size than the second concave plate, is disposed on the second concave plate, and the four concave portions formed by gradually bending from the reference plane toward the bottom define a rectangular shape And a third concave plate formed so as to be capable of being rotated.

In one embodiment, the concave flat spring has a smaller size than the third concave plate, is disposed on the third concave plate, and the four concave portions formed by gradually bending toward the bottom from the reference plane define a rectangular shape And a fourth concave plate formed so as to be able to be rotated.

In one embodiment, the center of each of the concave portions formed in the first concave plate and the center of each of the concave portions formed in the second concave plate may be arranged on the same line.

In one embodiment, each of the recesses formed in the first concave plate and the second concave plate may be circular or rectangular when viewed in a plan view.

According to the remote control panel having such an earthquake-proof function, the recessed flat spring is recessed to elastically support the bottom portion of the remote control panel enclosure, and the earthquake-resistant structural member, which penetrates the recess of the recessed flat spring and is fastened to the bottom portion of the remote control panel enclosure It is possible to minimize the influence of the seismic waves on the remote control panel enclosure by first reducing the vibration through the earthquake-proof structure and secondarily reducing the vibration through the concave flat spring even if shock waves such as seismic waves are generated .

1 is an exploded perspective view schematically illustrating a remote control panel having an earthquake-proof function according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view schematically showing the coupled state of the concave flat spring, the earthquake-proof structure, the remote control enclosure and the floor shown in FIG.
FIG. 3A is a perspective view schematically illustrating the earthquake-resistant structure shown in FIG. 1. FIG. 3B is a cross-sectional view taken along line I-I 'of the earthquake-resistant structural body shown in FIG. 3A. 3C is an exploded perspective view schematically illustrating the earthquake-resistant structure shown in FIG. 3A.
4 is an exploded perspective view schematically illustrating a remote control panel having an earthquake-proof function according to another embodiment of the present invention.
5 is a cross-sectional view schematically showing the engagement state of the first concave flat spring, the second concave flat spring, the seismic resistant structure, the remote control enclosure and the floor shown in Fig.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described in more detail with reference to the accompanying drawings. The present invention is capable of various modifications and various forms, and specific embodiments are illustrated in the drawings and described in detail in the text. It should be understood, however, that the invention is not intended to be limited to the particular forms disclosed, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

Like reference numerals are used for like elements in describing each drawing. In the accompanying drawings, the dimensions of the structures are enlarged to illustrate the present invention in order to clarify the present invention.

The terms first, second, etc. may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, the first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component. The singular expressions include plural expressions unless the context clearly dictates otherwise.

In this application, the terms "comprises", "having", and the like are used to specify that a feature, a number, a step, an operation, an element, a part or a combination thereof is described in the specification, But do not preclude the presence or addition of one or more other features, integers, steps, operations, components, parts, or combinations thereof.

Also, unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the contextual meaning of the related art and are to be interpreted as either ideal or overly formal in the sense of the present application Do not.

1 is an exploded perspective view schematically illustrating a remote control panel having an earthquake-proof function according to an embodiment of the present invention. Fig. 2 is a cross-sectional view schematically showing the coupled state of the concave flat spring 300 shown in Fig. 1, the earthquake-proof structure 100, the remote control enclosure and the floor.

1 and 2, a remote control panel having an earthquake-proof function according to an embodiment of the present invention includes a remote control panel enclosure 200, a concave flat spring 300, a lower bracket 400, .

Remote control panel enclosure 200 is equipped with a remote control panel facility. The above-mentioned remote control equipment collects (ie, monitors) the information of the on-site devices, controls the operation, communicates with the control center to transmit information of the collected on-site devices to the control center, And controls the operation of the device. The remote control panel facility includes a housing for monitoring and controlling the on-site equipment, a controller for communicating with the control center, and an enclosure for enclosing and protecting devices such as a controller.

The concave flat spring 300 elastically supports the remote control panel enclosure 200 at the lower portion of the remote control enclosure 200 to buffer the impact force acting on the remote control panel enclosure 200 through the ground. In this embodiment, the concave flat spring 300 has a wide size and a generally rectangular shape so as to cover the bottom surface of the remote control panel enclosure 200. In this embodiment, since the concave flat spring 300 has a planar shape, the shock absorbing effect of the impact force can be enhanced even if the shock wave is transmitted in any direction of the remote control panel enclosure 200.

The lower bracket 400 is disposed below the concave flat spring 300. In this embodiment, it is shown that the lower brackets 400 are arranged in pairs.

The earthquake-proof structure 100 is installed between the bottom portion of the concave flat spring 300 and the lower bracket 400 to buffer the impact force acting on the remote control panel enclosure 200. In this embodiment, four earthquake-proof structures 100 are shown. The two seismic resistant structures 100 are disposed in one lower bracket 400 and the remaining two seismic resistant structures 100 are disposed in the other lower bracket 400. [

The concave flat spring 300 includes a first concave plate 310, a second concave plate 320, a third concave plate 330, and a fourth concave plate 340. In the present embodiment, the concave flat spring 300 is described as being composed of four concave plates, but it may be composed of two concave plates, or may be composed of three concave plates, Plates.

The first concave plate 310 has a size capable of covering the bottom portion of the remote control panel enclosure 200. In the first concave plate 310, four concave portions formed by bending gradually from the reference plane toward the bottom portion are formed to define a rectangular shape.

The second concave plate 320 is disposed on the first concave plate 310 with a smaller size than the first concave plate 310. In the second concave plate 320, four concave portions formed by bending gradually from the reference plane toward the bottom portion are formed to define a rectangular shape. In this embodiment, the centers of the concave portions formed on the first concave plate 310 and the centers of the concave portions formed on the second concave plate 320 are arranged on the same line.

The third concave plate 330 is disposed on the second concave plate 320 with a smaller size than the second concave plate 320. In the third concave plate 330, four concave portions formed by bending gradually from the reference surface toward the bottom portion are formed to define a rectangular shape. In this embodiment, the centers of the concave portions formed in the second concave plate 320 and the centers of the concave portions formed in the third concave plate 330 are arranged on the same line.

The fourth concave plate 340 is disposed on the third concave plate 330 with a smaller size than the third concave plate 330. [ In the fourth concave plate 340, four recesses formed by gradually bending toward the bottom from the reference plane are formed to define a rectangular shape. In this embodiment, the centers of the concave portions formed on the third concave plate 330 and the centers of the concave portions formed on the fourth concave plate 340 are arranged on the same line.

Although each of the concave portions formed in the first concave plate 310, the second concave plate 320, the third concave plate 330, and the fourth concave plate 340 is circular in FIG. 1, For example, triangular, rectangular, pentagonal, hexagonal, or the like.

Although not shown in FIG. 1, between the first concave plate 320 and the third concave plate 330, and between the first concave plate 310 and the second concave plate 320, and between the third concave plate 330 And the fourth concave plate 340, respectively. The anti-vibration pad functions to reduce the transmission of impact waves such as seismic waves from the lower part to the upper part. The material of the anti-vibration pad may include ethylene rubber.

In this embodiment, a planar concave flat spring is formed as a whole to cover the lower portion of the remote control enclosure. However, a helical spring may be disposed locally corresponding to, for example, a portion where the earthquake-proof structure is disposed. The helical spring may have a concave shape when observing the lower part from the upper part.

As described above, according to an embodiment of the present invention, the concave flat spring 300 having a concave shape is disposed to elastically support the bottom portion of the remote control panel enclosure 200, and the concave flat spring 300 Even if a shock wave such as a seismic wave is generated by disposing the earthquake-resistant structural body 100 fastened to the bottom of the remote control panel enclosure 200 through the recess, the vibration is primarily reduced through the earthquake-proof structural body 100, Shaped planar spring 300 to minimize the effect of the seismic waves on the remote control enclosure 200. [

Although the concave flat spring 300, the lower bracket 400 and the earthquake-proofing structure 100 described above are employed in a remote control panel to overcome the impact force or vibration caused by a seismic wave transmitted from the ground to a remote control panel, It can be used variously to shock power or vibration caused by seismic waves transmitted from the ground to the transmission / reception system, and to be used for impact force or vibration mitigation due to seismic waves such as piers or buildings requiring seismic design.

FIG. 3A is a perspective view schematically illustrating the earthquake-resistant structure 100 shown in FIG. 3B is a cross-sectional view of the earthquake-resistant structural body 100 shown in FIG. 3A taken along the line I-I '. 3C is an exploded perspective view schematically illustrating the earthquake-resistant structure 100 shown in FIG. 3A.

3A to 3C, the earthquake-resistant structure 100 is installed between the bottom of the concave flat spring 300 and the lower bracket 400, and is provided with a damper body 400 for cushioning impact force or vibration acting on the remote control panel. A lower damper washer 120, a damper piston 130, an upper damper washer 140, and a damper cover 150.

The damper body 110 includes a cylindrical portion 112 having a circular hollow portion, a first wing portion 114 formed on one side of the cylinder portion 112 and a second wing portion 116 formed on the other side of the cylinder portion 112 ). The cylinder portion 112 may have a cylindrical shape and a hollow is formed therein. The bottom portion of the cylinder portion 112 is formed with a hollow hole having a size smaller than the hollow diameter formed therein. The first body fastening hole 112a, the second body fastening hole 112b, the third body fastening hole 112c and the fourth body fastening hole 112d are formed on the top of the cylinder part 112.

The lower damper washer portion 120 has a donut shape and is disposed in the hollow portion of the cylinder portion 112. The lower damper washer portion 120 includes a first damper washer 122 having a donut shape and disposed in the hollow of the cylinder portion 112 and a second damper washer 122 having a donut shape and disposed on the first damper washer 122. [ (Not shown).

In this embodiment, the diameter of the inner hole of the first damper washer 122 may be different from the diameter of the inner hole of the second damper washer 124. That is, the diameter of the inner hole of the first damper washer 122 may be larger than the diameter of the inner hole of the second damper washer 124. On the other hand, the diameter of the inner hole of the first damper washer 122 may be smaller than the diameter of the inner hole of the second damper washer 124. Accordingly, when the first damper washer 122 and the second damper washer 124 are disposed in the hollow of the damper body 110, a certain space can be formed. The formed space can serve to buffer shock or vibration. For example, the impact force or vibration transmitted from below is vertically absorbed by each of the first damper washer 122 and the second damper washer 124, and horizontally absorbed by the certain space. Accordingly, even if a cushioning material such as oil is not injected into the inside of the cylinder, air in a certain space formed serves as a cushioning material. Therefore, the oil does not leak.

The damper piston 130 has a shaft member 132 having a predetermined length formed therein and a step member 134 formed between the lower end of the shaft member 132 and the intermediate portion of the shaft member 132, 112 and penetrates the lower damper washer portion 120 and is exposed to holes formed in the bottom portion of the damper body portion 110. [

The upper damper washer portion 140 has a donut shape and is inserted into the hollow of the cylinder portion 112 and disposed on the step member 134 of the damper piston 130. The upper damper washer 140 includes a third damper washer 142 having a donut shape and inserted into the hollow of the cylinder portion 112 and disposed on the step member 134 of the damper piston 130, And a fourth damper washer 144 inserted into the hollow of the cylinder portion 112 and fitted in the shaft member 132 of the damper piston 130 and disposed on the third damper washer 142.

In this embodiment, the diameter of the third damper washer 142 may be smaller than the diameter of the fourth damper washer 144. Therefore, when the third damper washer 142 and the fourth damper washer 144 are disposed in the hollow of the damper body 110, a certain space can be formed. The formed space can serve to buffer shock or vibration. For example, the impact force or vibration transmitted from below is vertically absorbed by each of the third damper washer 142 and the fourth damper washer 144, and horizontally absorbed by the certain space. Accordingly, even if a cushioning material such as oil is not injected into the inside of the cylinder, air in a certain space formed serves as a cushioning material. Therefore, the oil does not leak.

In the present embodiment, the hollow depth of the cylinder portion 112 is determined by the thickness of the first damper washer 122, the thickness of the second damper washer 124, the thickness of the step member 134 of the damper piston 130, The thickness of the third damper washer 142 and the thickness of the fourth damper washer 144 may be the same.

The damper cover part 150 is disposed on the damper body part 110 and joins the upper damper washer part 140 and exposes the shaft member 132 of the damper piston 130 through the hole formed in the center part to a predetermined height . The first cover hole 154a, the second cover hole 154b, the third cover hole 154c and the fourth cover hole 154d are formed at the edge of the damper cover portion 150. [ The first cover hole 154a, the second cover hole 154b, the third cover hole 154c and the fourth cover hole 154d are respectively formed with a first body fastening hole 112a formed in a top portion of the cylinder portion 112, The second body fastening hole 112b, the third body fastening hole 112c, and the fourth body fastening hole 112d.

The earthquake-resistant structural body 100 further includes a coupling part 160 for coupling the damper body part 110 and the damper cover part 150 with each other. The fastening portion 160 includes a first screw 162 which penetrates through the first cover hole 154a and is fastened to the first body fastening hole 112a of the damper body portion 110, The damper body 110 penetrates through the second screw 164 and the third cover hole 154c that pass through the hole 154b and are fastened to the second body fastening hole 112b of the damper body 110, Which is fastened to the fourth body fastening hole 112d of the damper body 110 through the third screw 166 and the fourth cover hole 154d fastened to the third body fastening hole 112c of the damper body 110, Screw (168).

In this embodiment, the material of each of the first damper washer 122, the second damper washer 124, the third damper washer 142, and the fourth damper washer 144 may include ethylene rubber.

The material of each of the first damper washer 122, the second damper washer 124 and the fourth damper washer 144 includes ethylene rubber and the material of the third damper washer 142 may include carbon steel. have.

In this embodiment, the shaft member 132 of the damper piston 130 may be exposed to the outside through a hole formed in the damper body portion 110.

As described above, the piston is implemented by disposing the damper washers of different diameters on and above the step members of the damper piston so as to control the internal air flow, and the piston- It is possible to secure the safety of the remote control panel by uniformly reducing the shock and vibration transmitted from the outside. In addition, since there is no fluid such as silicone oil in the inside of the earthquake-proof structure, the silicone oil does not leak to the outside when installed and operated in the field.

4 is an exploded perspective view schematically illustrating a remote control panel having an earthquake-proof function according to another embodiment of the present invention. 5 is a cross-sectional view schematically showing the coupled state of the concave flat spring 300, the convex planar spring 500, the earthquake-proof structure 100, the remote control enclosure and the floor shown in Fig.

4 and 5, a remote control panel having an earthquake-proof function according to another embodiment of the present invention includes a remote control panel enclosure 200, a concave flat spring 300, a convex planar spring 500, ).

Remote control panel enclosure 200 is equipped with a remote control panel facility. The above-mentioned remote control equipment collects (ie, monitors) the information of the on-site devices, controls the operation, communicates with the control center to transmit information of the collected on-site devices to the control center, And controls the operation of the device. The remote control panel facility includes a housing for monitoring and controlling the on-site equipment, a controller for communicating with the control center, and an enclosure for enclosing and protecting devices such as a controller.

The concave flat spring 300 elastically supports the remote control enclosure 200 at the lower portion of the remote control enclosure 200 to buffer the impact force acting on the remote control enclosure 200 through the lower portion. In this embodiment, the concave flat spring 300 has a wide size and a generally rectangular shape so as to cover the bottom surface of the remote control panel enclosure 200. In this embodiment, since the concave flat spring 300 has a planar shape, the shock absorbing effect of the impact force can be enhanced even if the shock wave is transmitted in any direction of the remote control panel enclosure 200.

The convex planar spring 500 elastically supports the concave flat spring 300 at the lower portion of the concave flat spring 300 to buffer the impact force acting on the concave flat spring 300 through the lower portion. In this embodiment, the convex planar spring 500 has a wide size and a generally rectangular shape so as to cover the bottom surface of the remote control panel enclosure 200. In this embodiment, since the convex planar spring 500 has a planar shape, the effect of buffering the impact force can be enhanced even if the shock wave is transmitted in any direction of the remote control panel enclosure 200.

The earthquake-proof structure 100 is installed between the concave flat spring 300 and the convex planar spring 500 to buffer the impact force acting on the remote control panel enclosure 200. In this embodiment, four earthquake-proof structures 100 are shown. The two earthquake-resistant structures 100 are disposed on one lower bracket, and the remaining two earthquake-resistant structures 100 are disposed on the other lower bracket.

The concave flat spring 300 includes a first concave plate 310, a second concave plate 320, a third concave plate 330, and a fourth concave plate 340. In the present embodiment, the concave flat spring 300 is described as being composed of four concave plates, but it may be composed of two concave plates, or may be composed of three concave plates, Plates.

The first concave plate 310 has a size capable of covering the bottom portion of the remote control panel enclosure 200. In the first concave plate 310, four concave portions formed by bending gradually from the reference plane toward the bottom portion are formed to define a rectangular shape.

The second concave plate 320 is disposed on the first concave plate 310 with a smaller size than the first concave plate 310. In the second concave plate 320, four concave portions formed by bending gradually from the reference plane toward the bottom portion are formed to define a rectangular shape. In this embodiment, the centers of the concave portions formed on the first concave plate 310 and the centers of the concave portions formed on the second concave plate 320 are arranged on the same line.

The third concave plate 330 is disposed on the second concave plate 320 with a smaller size than the second concave plate 320. In the third concave plate 330, four concave portions formed by bending gradually from the reference surface toward the bottom portion are formed to define a rectangular shape. In this embodiment, the centers of the concave portions formed in the second concave plate 320 and the centers of the concave portions formed in the third concave plate 330 are arranged on the same line.

The fourth concave plate 340 is disposed on the third concave plate 330 with a smaller size than the third concave plate 330. [ In the fourth concave plate 340, four recesses formed by gradually bending toward the bottom from the reference plane are formed to define a rectangular shape. In this embodiment, the centers of the concave portions formed on the third concave plate 330 and the centers of the concave portions formed on the fourth concave plate 340 are arranged on the same line.

4, each of the recesses formed in each of the first concave plate 310, the second concave plate 320, the third concave plate 330, and the fourth concave plate 340 has a circular shape, For example, triangular, rectangular, pentagonal, hexagonal, or the like.

4, between the first concave plate 320 and the third concave plate 330 and between the first concave plate 310 and the second concave plate 320 and between the third concave plate 330 and the third concave plate 330, And the fourth concave plate 340, respectively. The anti-vibration pad functions to reduce the transmission of impact waves such as seismic waves from the lower part to the upper part. The material of the anti-vibration pad may include ethylene rubber.

In this embodiment, a planar concave flat spring is formed as a whole to cover the lower portion of the remote control enclosure. However, a helical spring may be disposed locally corresponding to, for example, a portion where the earthquake-proof structure is disposed. The helical spring may have a concave shape when observing the lower part from the upper part.

The convex planar spring 500 includes a first convex plate 510, a second convex plate 520, a third convex plate 530 and a fourth convex plate 540. In the present embodiment, the convex planar spring 500 is described as being composed of four convex plates, but it may be composed of two convex plates, or may be composed of three convex plates, As shown in FIG.

The first convex plate 510 is sized to cover the bottom of the remote control enclosure 200. The first convex plate 510 is formed with four convex portions formed by bending gradually from the reference plane toward the bottom portion to define a rectangular shape.

The second convex plate 520 is disposed below the first convex plate 510 with a smaller size than the first convex plate 510. Four convex portions formed by bending gradually from the reference plane toward the bottom portion are formed in the second convex plate 520 to define a rectangular shape. In this embodiment, the centers of the convex portions formed on the first convex plate 510 and the centers of the convex portions formed on the second convex plate 520 are arranged on the same line.

The third convex plate 530 is disposed below the second convex plate 520 with a smaller size than the second convex plate 520. [ Four convex portions formed by bending gradually from the reference plane toward the bottom portion are formed in the third convex plate 530 to define a rectangular shape. In this embodiment, the centers of the convex portions formed on the second convex plate 520 and the centers of the convex portions formed on the third convex plate 530 are arranged on the same line.

The fourth convex plate 540 is disposed below the third convex plate 530 with a smaller size than the third convex plate 530. Four convex portions formed by bending gradually from the reference plane toward the bottom portion are formed in the fourth convex plate 540 to define a rectangular shape. In this embodiment, the centers of the convex portions formed on the third convex plate 530 and the centers of the convex portions formed on the fourth convex plate 540 are arranged on the same line.

4, each convex portion formed on each of the first convex plate 510, the second convex plate 520, the third convex plate 530, and the fourth convex plate 540 is shown in a circular shape, For example, triangular, rectangular, pentagonal, hexagonal, or the like.

Although not shown in FIG. 4, between the first convex plate 510 and the second convex plate 520, between the second convex plate 520 and the third convex plate 530, and between the third convex plate 530 And the fourth convex plate 540, respectively. The anti-vibration pad functions to reduce the transmission of impact waves such as seismic waves from the lower part to the upper part. The material of the anti-vibration pad may include ethylene rubber.

In the present embodiment, a planar convex flat spring is formed to cover the lower portion of the remote control enclosure as a whole, but a helical spring may be disposed locally, for example, in correspondence with a portion where the earthquake-proof structure is disposed. The helical spring may have a convex shape when observing the lower part from the upper part.

As described above, according to another embodiment of the present invention, a concave flat spring 300 having a concave shape is disposed to resiliently support the bottom portion of the remote control panel enclosure 200, and a concave flat spring 300 A convex planar spring 500 having a convex shape is disposed so as to be resiliently supported and an earthquake-resistant structural body 100 fastened to the bottom of the remote control panel enclosure 200 through the concave portion of the concave flat spring 300 is disposed, Even if a shock wave such as a shock wave is generated, the vibration is reduced through the convex planar spring 500, the vibration is reduced secondarily through the earthquake-proof structural body 100, and the vibration is thirdarily transmitted through the concave flat spring 300 Thereby minimizing the impact of the seismic waves on the remote control enclosure 200. [

Although the concave flat spring 300, the convex planar spring 500 and the earthquake-proofing structure 100 described above are employed in the remote control panel and described above to cushion the impact force or vibration caused by the earthquake waves transmitted from the ground to the remote control panel, It can be used variously to shock power and vibration caused by earthquake waves such as piers or buildings that require seismic design.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. You will understand.

100: earthquake-resistant structural body 110: damper body part
112: cylinder part 114: first wing part
116: second wing 120: lower damper washer
122: first damper washer 124: second damper washer
130: damper piston 132: shaft member
134: step member 140: upper damper washer
142: third damper washer 144: fourth damper washer
150: Damper cover part 200: Remote control panel enclosure
300: concave flat spring 310: first concave plate
320: second concave plate 330: third concave plate
340: fourth concave plate 400: lower bracket
500: convex planar spring 510: first convex plate
520: second convex plate 530: third convex plate
540: fourth convex plate

Claims (5)

Remote control panel enclosure with remote control panel facility;
The remote control unit includes a remote control unit enclosure having a size capable of covering the bottom surface of the remote control unit enclosure and having a rectangular shape as a whole to elastically support the remote control unit enclosure at a lower portion of the remote control unit enclosure to cushion the impact force acting on the remote control unit enclosure through the ground. Flat spring;
A lower bracket disposed below the concave flat spring; And
And an earthquake-resistant structure installed between the bottom portion of the concave flat spring and the lower bracket to buffer an impact force acting on the remote control panel enclosure,
The concave flat spring
A first concave plate having a size capable of covering a bottom portion of the remote control box enclosure and formed so as to define a quadrangular shape in which four concave portions formed by gradually bending toward the bottom portion from a reference plane are defined; And
A second concave plate having a size smaller than the first concave plate and disposed on the first concave plate and having four concave portions formed by gradually bending toward the bottom from the reference plane to define a rectangular shape,
Wherein each of the recesses formed in the first concave plate and the second concave plate is one of a circular shape and a polygonal shape when observed on a plane. The flat plate spring according to claim 1, wherein the concave flat spring has a smaller size than the second concave plate and is disposed on the second concave plate, and the four concave portions formed by bending gradually from the reference plane toward the bottom portion have a rectangular shape Further comprising: a third concave plate formed to define the first concave plate. The flat plate spring according to claim 2, wherein the concave flat spring has a smaller size than the third concave plate and is disposed on the third concave plate, and the four concave portions formed by bending gradually from the reference plane toward the bottom portion have a rectangular shape Further comprising: a fourth concave plate formed to define the first concave plate. The remote control panel according to claim 1, wherein centers of the concave portions formed on the first concave plate and centers of the concave portions formed on the second concave plate are arranged on the same line. delete

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