KR102144552B1 - Distributing board with vibration isolation - Google Patents

Abstract

The present invention relates to a switchboard having a vibration isolating function, which can protect a switchboard by offsetting a force caused by an earthquake or an external vibration. The switchboard having a vibration isolating function comprises a plurality of first vibration-proof units installed at a lower edge of a distribution box, wherein the first vibration-proof units include: a first lower main body installed in a support surface on which the distribution box is supported; an elevating support unit formed in the first lower main body and having a vertically extending elevating groove formed to be downwardly recessed by a predetermined depth from an upper surface; a first upper main body supported on a lower surface of the distribution box; an elevating member formed in the first upper main body, extending downwardly, and having a lower end formed to correspond to the shape and diameter of the elevating groove to be inserted into the elevating groove of the elevating support unit; and an elastic support member including a base unit supported by the first lower main body and an inclined support unit extending to be inclined toward the elevating member while upwardly extending from the base unit, and elastically supporting the elevating member upwardly by having an end of the inclined support unit supported by the elevating member.

Description

Switchboard with base isolation function {DISTRIBUTING BOARD WITH VIBRATION ISOLATION}

The present invention relates to a switchboard having a seismic isolation function, and more particularly, to a switchboard having a seismic isolation function capable of protecting the switchboard by offsetting the force caused by an earthquake or external vibration.

In general, a switchboard is an electrical facility that safely supplies industrial power to users, and is a device used for monitoring, control, and protection of the electrical system when the power sent from a power plant or substation is received and distributed to customers.

Such a switchboard is composed of a structure that attaches and supports unit devices such as circuit breakers or protection relays, and an assembly of conductors that connects and connects the unit devices, and is a product in which these various electrical devices are safely insulated and stored in a rectangular steel enclosure. .

However, since the switchgear is fixed to the ground, there is a problem that the housing provided in the switchgear may be deformed due to the vibration of the seismic wave when an earthquake occurs, or various electric devices installed inside the switchgear may be damaged, and in severe cases, the switchboard may fall. there was.

In this case, there is a problem that it is impossible to stably supply power to a place where power is needed, and an electric shock accident may occur due to a short circuit.

Accordingly, even if vibration is applied to the switchboard due to an earthquake, etc., the switchboard housing is not deformed and the internal electrical equipment is not damaged, and the switchboard is prevented from overturning, thereby preventing safety accidents such as power failure, short circuit or fire. A switchgear with performance is desperately in demand.

In addition, when an earthquake occurs, the vibration shock applied to the switchboard is relieved by the elastic support under the switchboard, but it is not completely alleviated, and some of the shocks are transmitted to the devices in the switchboard. Four to six vibration and seismic devices were required.

Korea Patent Registration No. 10-1042577: Seismic function type switchboard Korean Patent Registration No. 10-1480853: Switchboard having seismic and vibration prevention functions

The present invention has been created to solve the above problems, and an object of the present invention is to provide a switchboard having a seismic isolation function capable of maintaining stability even in an earthquake situation by attenuating vibrations caused by earthquakes or external forces applied from the outside.

The present invention is a switchboard having a seismic isolating function including a plurality of first vibration isolating units installed at a lower edge of the distribution box, wherein the first vibration isolating unit includes a first lower body installed on a support surface on which the distribution box is supported, and the A lifting support part formed in the first lower body and formed so that the lifting groove extending vertically is inserted downward from the upper surface to a predetermined depth, a first upper body supported on the lower surface of the distribution box, and formed on the first upper body and downwardly The elevating member extending and formed to correspond to the shape and diameter of the elevating groove so that the lower end can be inserted into the elevating groove of the elevating support unit, the base portion supported by the first lower body, and the more extending upward from the base portion It includes an inclined support portion extending obliquely toward the elevating member, and an end portion of the inclined support portion is supported by the elevating member and an elastic support member for elastically supporting the elevating member upward.

The inclined support portion of the elastic support member extends from the end of the base portion toward the elevating member at a first inclined angle, and a first inclined support portion extending toward the elevating member at an angle smaller than the first inclined angle. It includes at least one second inclined support portion, and when two or more of the second inclined support portions are formed, each of the second inclined support portions has different inclination angles.

The elastic support member is from one side inclined support portion extending toward the elevating member from both ends facing each other on one side of the base portion, and from both ends of the other side extending along a direction crossing the one direction from the base portion. It is preferable to include the other side inclined support portion extending toward each of the elevating member.

The one side inclined support part and the other side inclined support part each include two or more inclined plates, the inclined plates of the one inclined support part are formed with different inclination angles with the base part, and the inclined plates of the other inclined support part are also inclined angles made with the base part. It is preferable that they are formed to be different from each other.

In order to counteract the left-right vibration applied to the distribution box, the lower end of the lifting support part is formed in a curved shape, and the lower end support part of the first lower body supporting the lower end of the lifting support part corresponds to the lower curved surface of the lifting support part. It is formed, and it is preferable that a bearing is formed at a contact portion in contact with the lower curved surface of the lifting support part so that the lower part of the lifting support part can roll along the lower curved surface in response to an external force.

The first lower body has a through hole formed on the upper surface so that the upper part of the lifting support part is exposed upward, and the upper end of the lifting support part is formed so that the upper end of the lifting support part may protrude further upward by a predetermined length than the upper surface of the first lower body. And, it is preferable that the diameter of the through hole is larger than the upper outer diameter of the elevation support portion passing through the through hole so that the upper end of the elevation support portion can be inclined.

The second lower body is installed in the lower center of the distribution box and further includes a second vibration isolating unit for canceling horizontal vibration applied to the distribution box, and the second vibration isolating unit is installed on a support surface on which the distribution box is supported. And, the second upper body provided on the upper side of the second lower body and supported on the lower surface of the distribution box, and the second lower body by a fastener having a lower end supported on the upper surface of the second lower body and penetrating the upper and lower surfaces. And an auxiliary elastic support body fixed to and supported by the second upper body at both side ends, wherein the auxiliary elastic support body is formed to have a hexagonal honeycomb pattern, and the second upper body is in a horizontal direction with respect to the second lower body. It is formed to elastically support it so as to return to the initial position after moving a predetermined distance when receiving an external force advancing along.

The switchboard having a seismic isolation function according to the present invention has the advantage of reducing vibrations caused by earthquakes or external forces to minimize damage to the distribution box caused by such external vibrations.

1 is a perspective view of an embodiment of a switchboard having a base isolation function according to the present invention,
2 is a perspective view showing a vibration isolation unit of the switchboard having a seismic isolation function of Figure 1;
3 is an exploded perspective view of a first vibration isolating unit installed at four corners of a distribution box among the vibration isolating units of FIG. 2;
4 and 5 are cross-sectional views of the first vibration isolating unit of FIG. 3;
6 is a cross-sectional view showing a state in which the first vibration isolating unit of FIG. 3 is rotated in the left-right direction;
7 is a perspective view showing another embodiment of an elastic support member,
8 is a cross-sectional view of a second vibration isolating unit installed in the lower center of the distribution box among the vibration isolating units of FIG. 2.

Hereinafter, a switchboard having a seismic isolation function according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. In the present invention, various modifications may be made and various forms may be applied, and specific embodiments will be illustrated in the drawings and described in detail in the text. However, this is not intended to limit the present invention to a specific form of disclosure, it should be understood to include all changes, equivalents, and substitutes included in the spirit and scope of the present invention. In describing each drawing, similar reference numerals have been used for similar elements. In the accompanying drawings, the dimensions of the structures are shown to be enlarged than the actual size for clarity of the present invention.

Terms such as first and second may be used to describe various elements, but the elements should not be limited by the terms. These terms are only used for the purpose of distinguishing one component from another component. For example, without departing from the scope of the present invention, a first component may be referred to as a second component, and similarly, a second component may be referred to as a first component.

The terms used in the present application are used only to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In the present application, terms such as "comprise" or "have" are intended to designate the presence of features, numbers, steps, actions, elements, parts, or combinations thereof described in the specification, but one or more other features. It is to be understood that the presence or addition of elements or numbers, steps, actions, components, parts, or combinations thereof, does not preclude in advance the possibility.

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 the present invention belongs. Terms as defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related technology, and should not be interpreted as an ideal or excessively formal meaning unless explicitly defined in this application. Does not.

As shown in Figs. 1 and 2, the switchboard 10 having the seismic isolation function of the present invention is installed under the switchboard 20 and applied from the outside, especially in the vertical direction and horizontally applied by an external force such as an earthquake. It includes a first vibration isolating unit 100 and a second vibration isolating unit 200 formed to cancel external force against vibration in the direction.

The first vibration isolating unit 100 is formed at each of the four corners of the distribution box 20, and the second vibration isolating unit 200 is formed to support the lower center of the distribution box 20.

The first anti-vibration unit 100 includes a first lower body 110 installed on a support surface supporting the distribution box 20, an elevation support 120 formed on the first lower body 110, and the first The first upper body 140 fixed to the edge of the power distribution box 20 so as to be positioned above the lower body 110, the lifting member 150 formed on the first upper body 140, and the first It includes an elastic support member 160 for elastically supporting the upper body 140 upwardly with respect to the first lower body 110.

The first lower body 110 has a lower end fixed to the support surface as described above, and for this purpose, a flange covering the upper part of the support surface may be formed on the lower surface of the first lower body 110, and an anchor to the flange Can be fixed by installing.

The first lower body 110 has a hexahedral shape with an empty inside, and the upper plate is blocked on the upper surface, but the through hole 111 is formed so that the upper end of the lifting support unit 120 to be described later protrudes upward for a predetermined length. .

The lifting support part 120 is a cylindrical member formed to extend vertically in the inside of the first lower body 110, and has a lifting groove 121 that is inserted to a predetermined depth downward from an upper end.

The lifting support part 120 has an outer diameter smaller than the diameter of the through hole 111 so that the upper end of the lifting support part 120 protrudes upward from the first upper body 140 through the through hole 111, and in particular, the lifting support part 120 It is preferable that the inner surface of the through hole 111 and the outer circumferential surface of the lifting support unit 120 are formed to be spaced apart by a predetermined distance so that the lower end portion can be rotated at a predetermined angle.

The elevating support portion 120 also has a bottom curved portion 122 formed in a curved bottom portion.

The lower curved portion 122 is formed in a hemispherical shape that is convex downward, and the bearing housing 130 formed at the inner lower end of the first lower body 110 is lower in response to the shape of the lower curved portion 122 The ball bearing 131 is formed on a contact surface in contact with the lower curved portion 122 and is formed to be concavely inserted.

Therefore, the lower curved portion 122 is provided with a ball bearing 131 on a contact surface with the bearing housing 130, and is formed in a curved shape, so that a predetermined angle can be rotated, and the rotating angle is the lifting support unit ( The upper end of 120) is limited by contacting the inner peripheral surface of the through hole 111 of the first body.

The first upper body 140 is coupled to the lower end of the corner of the distribution box 20 as described above, and the first upper body 140 has a hexahedral shape opened downward. The first upper body 140 has an inner width greater than the outer circumferential width of the first lower body 110 so that when the first lower body 110 moves up and down, the first lower body 110 is inside the first upper body 140 When the lift support unit 120 is rotated around the lower curved portion 122, it is preferably formed so as not to cause interference.

An elevating member 150 is installed inside the first upper body 140.

The lifting member 150 is formed to be fixed to the first upper body 140 by a fastening member inserted through the lower surface and the upper body of the distribution box 20, and reference numeral 152 denotes the lifting member 150. It is a steel bracket provided to be fastened to the first upper body 140.

The elevating member 150 is formed in a cylindrical shape and is formed so that the lower portion can be inserted into the elevating groove 121 of the elevating support portion 120.

The upper part of the lifting member 150 is formed with a locking protrusion 151 that extends and protrudes outward to support the elastic support member 160 to be described later, and the lower part is inserted into the lifting groove 121 as described above. , The length of the lifting member 150 is so that the lifting member 150 in a state supported by the elastic support member 160 does not touch the bottom of the lifting groove 121, that is, the lower end of the lifting member 150 The bottom of the lifting groove 121 of the lifting support part 120 is formed to be spaced apart a predetermined distance.

The elastic support member 160 is installed on the first lower body 110 to support the elevating member 150 upwardly.

The elastic support member 160 includes a base portion 161 installed on the upper surface of the first lower body 110 and an inclined support portion 162 extending obliquely toward the elevating member 150 at both ends of the base portion 161 Includes.

The base portion 161 is preferably formed such that a hole corresponding to the through hole 111 is provided so that the elevating support portion 120 and the elevating member 150 can penetrate, and the amount of the facing base portion 161 The inclined support part 162 is formed at the end, and the inclined support part 162 is inclined so as to be closer to the elevating member 150 as it extends upward from the end of the base part 161. Has the shape of a triangle as a whole.

In particular, the inclined support part 162 includes a first inclined support part 163 extending at a first inclination angle with the base part 161, and a second inclined support part extending toward the elevating member 150 at an angle smaller than the first inclination angle 164).

The second inclined support part 164 is formed to be spaced apart from the first inclined support part 163 when no external force is applied. In this embodiment, the inclined support part 162 is 2 The inclined support portion 164 is included, that is, it is shown to include two inclined plates, but the inclined support portion 162 may be formed to have different inclination angles so that three or more inclined plates can be spaced apart from each other.

The elastic support member 160 elastically supports the first upper body 140 connected to the distribution box 20 with respect to the first lower body 110 as described above. If the vertical vibration is applied to the distribution box 20, the inclined support part 162 is deformed so that the inclination angle formed with the base part 161 is reduced, and when the external force is removed, the inclined support part 162 returns to the initial position. It moves upward by elastic force and returns to the initial position.

In particular, in the case of the present invention, since the inclined support part 162 is composed of the first inclined support part 163 and the second inclined support part 164 having different inclination angles, it is expected that the elastic force according to the magnitude of the external force is actively adjusted. I can. That is, when a small external force is applied, only the first inclined support part 163 is connected to the lifting member 150 to support the lifting member 150 upwardly.

However, if the magnitude of the external force applied to the distribution box 20 is large, the first inclined support part 163 descends and comes into contact with the second inclined support part 164, and after contacting the second inclined support part 164, the first inclined support part Since the elevating member 150 and the first upper body 140 are supported in a state in which the elastic force of the 163 and the second inclined support part 164 are combined, it is possible to respond to a larger external force.

In this case, when the inclined support part 162 is formed of a plurality, since it is possible to actively respond to a force of various magnitudes than when there is only one inclined support part 162, it is possible to respond to both vibration of a small magnitude to a large external force.

As shown in FIG. 7, the elastic support member 170 has one side extending toward the elevating member 150 from both ends of the inclined support part 172 crossing each other in the base part 171 and the other direction. It may be formed to include the inclined support 173 and the other inclined support 174.

In this case, since the number of the inclined support portions 172 is twice as large as in the previous embodiment, the distribution box 20 having a higher weight can be supported. The elastic support member 170 of the present embodiment may also be formed so that the one side inclined support part 173 and the other side inclined support part 174 are not formed of only one inclined plate, but include two or more inclined plates.

The second anti-vibration unit 200 installed at the lower center of the distribution box 20 is for canceling an external force in the horizontal direction applied to the distribution box 20.

The second anti-vibration unit 200 includes a second lower body 210 installed on a support surface, a second upper body 220 provided above the second lower body 210, and a second upper body 220 It includes an auxiliary support support installed between the and the second lower body 210.

The auxiliary elastic support 240 is fixed to the upper surface of the second lower body 210 through a fastener 230, and the edge is formed to contact the skirt surface of the second upper body 220.

The auxiliary elastic support 240 is an elastic support having a honeycomb-shaped inner pattern, and when external force is applied in the horizontal direction, the auxiliary elastic support 240 in the direction in which the external force is applied is compressed to cancel the external force. And in this way, when the distribution box 20 and the second upper body 220 move along the application direction of the external force at a predetermined distance with respect to the second lower body 210, in the case of the first vibration isolating unit 100, the lifting support unit ( As the lower end of 120) rotates, the first upper body 140 supports the second upper body 220 to move a predetermined distance to one side, so the distribution box 20 moves along the direction in which the external force is applied. It cancels the external force, and can return to the initial position through the restoring force of the auxiliary elastic support 240.

The switchboard 10 having the seismic isolation function of the present invention described above absorbs the vibration applied by the first vibration isolating unit 100 in the vertical direction, and the second vibration isolating unit 200 absorbs the external force applied along the horizontal direction. By absorbing and offsetting, the distribution box 20 can be safely supported against external force.

The description of the presented embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be apparent to those of ordinary skill in the art, and the general principles defined herein may be applied to other embodiments without departing from the scope of the present invention. Thus, the present invention is not to be limited to the embodiments presented herein, but is to be interpreted in the widest scope consistent with the principles and novel features presented herein.

10: switchboard with base isolation function
20: distribution box
100: first vibration isolation unit
110: first lower body 111: through hole
120: elevating support unit 121: elevating groove
122: lower curved portion 130: bearing housing
131: ball bearing 140: first upper body
150: lifting member 151: locking jaw
160: elastic support member 161: base portion
162: inclined support 163: first inclined support
164: second inclined support 170: elastic support member
171: base portion 172: inclined support portion
173: one side inclined support 174: the other side inclined support
200: second vibration isolation unit
210: second lower body 220: second upper body
230: fastener 240: auxiliary elastic support

Claims (8)

In the switchboard having a seismic isolating function including a plurality of first vibration isolating units installed at a lower edge of the distribution box,
The first anti-vibration unit includes a first lower body installed on a support surface on which the distribution box is supported;
An elevating support portion formed in the first lower body and formed such that an elevating groove extending vertically is drawn downward from an upper surface to a predetermined depth;
A first upper body supported on a lower surface of the distribution box;
An elevating member formed on the first upper body and extending downwardly to correspond to the shape and diameter of the elevating groove so that a lower end thereof can be inserted into the elevating groove of the elevating support unit;
And a base portion supported by the first lower body, and an inclined support portion extending obliquely toward the elevating member as it extends upward from the base portion, and an end portion of the inclined support portion is supported by the elevating member to support the elevating member. It includes an elastic support member that elastically supports upward,
The inclined support portion of the elastic support member includes a first inclined support portion extending from the end of the base portion toward the elevating member at a first inclined angle,
At least one second inclined support portion extending toward the elevating member from the end of the base portion to form an angle smaller than the first inclined angle,
A switchboard having a seismic isolation function, wherein when two or more second inclined support portions are formed, each of the second inclined support portions has different inclination angles.
delete In the switchboard having a seismic isolating function including a plurality of first vibration isolating units installed at a lower edge of the distribution box,
The first anti-vibration unit includes a first lower body installed on a support surface on which the distribution box is supported;
An elevating support portion formed in the first lower body and formed such that an elevating groove extending vertically is drawn downward from an upper surface to a predetermined depth;
A first upper body supported on a lower surface of the distribution box;
An elevating member formed on the first upper body and extending downwardly to correspond to the shape and diameter of the elevating groove so that a lower end thereof can be inserted into the elevating groove of the elevating support unit;
And a base portion supported by the first lower body, and an inclined support portion extending obliquely toward the elevating member as it extends upward from the base portion, and an end portion of the inclined support portion is supported by the elevating member to support the elevating member. It includes an elastic support member that elastically supports upward,
The elastic support member includes one side inclined support portion extending toward the elevating member from both ends facing each other on one side of the base portion,
A switchboard having a seismic isolation function, comprising: from both ends of the base portion in the other direction extending along a direction crossing the one direction, the other side inclined support portions respectively extending toward the elevating member.
The method of claim 3,
The one side inclined support portion and the other side inclined support portion each include two or more inclined plates, and the inclined plates of the one side inclined support portion are formed at different angles of inclination with the base portion,
The switchboard having a seismic isolation function, characterized in that the inclined plates of the other side inclined support part are formed to have different inclination angles with the base part.
The method according to any one of claims 1 or 3,
In order to offset the left-right vibration applied to the distribution box, the lower end of the lifting support part is formed in a curved shape, and the lower end support part of the first lower body supporting the lower end of the lifting support part corresponds to the lower curved surface of the lifting support part. Is formed,
A switchboard having a seismic isolation function, wherein a bearing is formed at a contact portion contacting the lower curved surface of the lifting support part so that the lower part of the lifting support part rolls along the lower curved surface in response to an external force.
The method of claim 5,
The first lower body has a through hole formed on the upper surface so that the upper part of the lifting support part is exposed upward, and the upper end of the lifting support part is formed to protrude further upward by a predetermined length than the upper surface of the first lower body. Become,
A switchboard having a seismic isolation function, wherein a diameter of the through hole is formed larger than an outer diameter of an upper portion of the elevation support portion passing through the through hole so that the upper end of the elevation support portion is inclined.
The method according to any one of claims 1 or 3,
A switchboard having a seismic isolating function, further comprising a second vibration isolating unit installed in the lower center of the distribution box to cancel horizontal vibration applied to the distribution box.
The method of claim 7,
The second anti-vibration unit includes a second lower body installed on a support surface on which the distribution box is supported;
A second upper body provided on an upper portion of the second lower body and supported on a lower surface of the distribution box;
A lower end is supported on the upper surface of the second lower body and fixed to the second lower body by fasteners penetrating the upper and lower surfaces, and both side ends are provided with an auxiliary elastic support body supported by the second upper body,
The auxiliary elastic support is formed to have a hexagonal honeycomb pattern, and when the second upper body receives an external force traveling along the horizontal direction with respect to the second lower body, it elastically supports to return to the initial position after moving a predetermined distance. A switchboard having a base isolation function, characterized in that.

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