KR101171725B1 - Switchgear and automatic control panel comprising earthquake-proof apparatus - Google Patents

Abstract

PURPOSE: A switchgear and an automatic control board including an earthquake-proof device are provided to rapidly deal with vibration or impact by remotely monitoring vibration width information of the switchgear and the automatic control board. CONSTITUTION: A top case(10) includes a bolt unit, a first intermediate unit, and a screw thread. A compression spring absorbs vibration and impact applied to the switchgear and the automatic control board. A bottom case(40) is screwed with the top case using the screw thread of the top case. A buffer unit is formed in the inner lower side of the bottom case. A stage(60) includes a groove(61), a sawtooth part(63), and a second hole(65).

Description

Switchgear and automatic control panel including seismic monitoring device for seismic information monitoring {SWITCHGEAR AND AUTOMATIC CONTROL PANEL COMPRISING EARTHQUAKE-PROOF APPARATUS}

The present invention relates to a switchgear and an automatic control panel, and more particularly to a switchgear and an automatic control panel including a seismic device capable of monitoring seismic information.

In general, since electric power demand is high in private electric facilities such as buildings or factories, it is impossible to receive electricity that can be used as it is from a power company, such as a general electric equipment having a low voltage of 110V or 220V.

Therefore, in general private electric installations, high voltages of 3,300V or 6,600V are received from the distribution lines of substations and converted to commercial voltages.In particular, private electric installations of large buildings receive 22.9kV of special high voltages and do not convert them to commercial voltages again. There is a switchgear that makes this possible. The switchgear includes a distribution panel, an MCC panel (Motor Control Center Panel), a low panel, a high panel, a transformer panel, and a special high panel.

Such a switchgear is a power supply facility for receiving high voltage and special high pressure supplied from a substation, a substation facility for stepping down high voltage and special high voltage received from a substation to a commercial voltage, and converts the stepped electricity into an electric device or a light in each part of the building. It is formed as a power distribution facility for supplying electricity to the building safely and efficiently.

The enclosure of such a switchgear panel has a panel bottom by attaching anchor bolts to concrete floors inside or outside buildings, assembling floor angles, assembling column angles to the floor angles, and assembling the enclosures to the assembled column angles. There is no seismic design, but the assembly is assembled by tightening bolts at an angle.

Therefore, in the conventional switchgear, the vibration state is transmitted to the panel itself with respect to mechanical vibration or earthquake caused by the vibration of the floor or the energization of a large power, and various devices mounted therein are damaged by an earthquake. It is often happening. That is, there is a problem that various components installed inside the enclosure flow, causing damage such as power failure and fire.

As a conventional technique for solving such a problem, a "switchboard having a seismic function" of Korean Patent No. 0939475 is known, and a representative drawing of this patent is shown in Figs. 1A to 1C. Figure 1a is an exploded perspective view of the seismic means of the switchgear according to the prior art, Figure 1b and Figure 1c is a cross-sectional view showing a state in which the impact force applied in the vertical or horizontal direction in the seismic means. (The reference numerals shown in Figs. 1A to 1C are not related to the reference numerals of the drawings according to the present embodiment described below and refer only to the prior art parts.)

1A to 1C, when vibration or shock is applied to the switchgear, the seismic means in the dotted lines shown in FIGS. 1B and 1C mitigate the impact. However, since the seismic means is coupled so that only a part of the seismic means overlaps the bottom angle 31 and the support angle 32 at a predetermined interval, when the shock is applied to the seismic means, the support angle 32 is the bottom angle 31. A problem arises that deviates from.

And when the impact in the horizontal direction is applied, as shown in Figure 1c, the support bolts 72 are moved at a predetermined angle in the bearing support case 71, worn or worn while hitting each other, eventually supporting bolts 72 A problem arises that is separated from the bearing support case (71). And there is a problem that the noise is generated while the support bolt 72 hit the bearing support case 71.

If vibrations or shocks are applied to the switchgear, there is no data on the degree of preparation or management guidelines. Therefore, when the vibration or shock is applied again, it is cumbersome to prepare a countermeasure or establish a management guide for each time.

The present invention has been proposed to solve the above problems, and an object thereof is to provide a switchgear and an automatic control panel including an earthquake-resistant device capable of earthquake-proof by the shock-absorbing action of the earthquake-resistant device to the external vibration or shock.

Another object of the present invention is to provide a switchgear and an automatic control panel including an earthquake-resistant device capable of monitoring seismic information that can remotely monitor the information according to vibration or shock.

Still another object of the present invention is to provide a switchgear and an automatic control panel including a seismic device capable of monitoring seismic information that can be quickly coped with when vibration or shock is applied by setting management guidelines according to the vibration width information of the switchgear and the automatic control panel. It is.

The switchgear and automatic control panel including a seismic control device capable of monitoring the seismic information according to the present invention for achieving the above object, the bolt portion formed to be installed through the nut in the enclosure of the switchgear and automatic control panel, the lower part of the bolt portion An upper case including a lid-shaped first middle portion formed in the lower portion of the first intermediate portion and a thread formed on an outer wall under the first intermediate portion; A compression spring provided inside the upper case and absorbing vibrations and shocks applied from the outside; A second intermediate part corresponding to a circumference of the compression spring at a lower portion of the compression spring, and having an upper protrusion fitted to an inner hole of the compression spring, and below the upper protrusion at a lower portion of the compression spring. A support including an elongated lower protrusion; A lower case screwed through a thread of the upper case so that the compression spring and the support are provided therein, and a first hole formed at a lower portion thereof to protrude the lower protrusion of the support into the first hole; A cushioning portion made of urethane material provided at an inner lower portion of the lower case to be in contact with a lower protrusion of the support; And grooves formed on the upper surface of the switchboard and the automatic control panel, the grooves formed on the upper side of the support to be movable at various angles by inserting the lower protrusions of the support, and both sides face in opposite directions in order to improve friction with the bottom surface. And a scaffold formed at a lower portion thereof, and a scaffold including a plurality of second holes for coupling with a bottom surface thereof.

And a switchgear and automatic control panel comprising a seismic device capable of monitoring the seismic information according to the present invention, the measurement unit for installing the switchgear and automatic control panel for measuring the vibration width information of the switchgear and automatic control panel according to vibration information and vibration, and A control unit installed on the front of the distribution panel and the automatic control panel and including a display unit which displays the measured information, and a transmission unit which transmits the measured information; And a seismic information monitoring unit including a computer for monitoring the information transmitted through the transmission unit of the control unit and setting a management guideline according to the information.

The present invention has the effect that the earthquake-resistant is possible by the shock-absorbing action of the earthquake resistance device to the external vibration or shock. That is, there is an effect capable of double buffering action by the compression spring and the buffer portion. As a result, the switchgear and the automatic control panel itself can be prevented from falling or shaking, such as shaking, and can also prevent damage such as power failure and fire, which can occur due to the flow of various components inside the enclosure. There is also an effect.

And there is an effect that can remotely monitor the information according to the vibration or shock, for example the vibration width information of the switchboard and automatic control panel according to the vibration information and the magnitude. As a result, by remotely monitoring the switchgear and automatic control panel, there is an effect that can quickly respond to vibration or shock.

In addition, by setting the management guidelines according to the vibration width information of the switchgear and automatic control panel, there is also an effect that can quickly respond to vibration or shock.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

1A to 1C are exploded perspective and sectional views of the seismic means of the switchgear according to the prior art.
2 is a front view showing a switchgear and an automatic control panel including a seismic device capable of monitoring seismic information according to the present invention.
Figure 3a and Figure 3b is an exploded perspective view and a perspective view showing a part of the earthquake-resistant device of the switchgear and automatic control panel including a seismic device capable of monitoring seismic information according to the present invention.
4A and 4B are a perspective view and a cross-sectional view of an earthquake-proof device of a switchgear and an automatic control panel including an earthquake-resistant device capable of monitoring seismic information according to the present invention.
5A and 5B are a plan view showing a front view showing a buffering action according to the earthquake-resistant device of the switchgear and automatic control panel including a seismic device capable of monitoring seismic information according to the present invention.

Hereinafter, a switchgear and an automatic control panel including a seismic device capable of monitoring seismic information according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

2 is a front view showing a switchgear and an automatic control panel including a seismic device capable of monitoring seismic information according to the present invention. 3A and 3B are separate perspective views and perspective views showing a part of a seismic device of a switchgear and an automatic control panel including a seismic device capable of monitoring seismic information according to the present invention, and FIGS. 4A and 4B are seismic information according to the present invention. A perspective view and a cross-sectional view showing a seismic device of a switchgear and an automatic control panel including a seismic device that can be monitored.

First, referring to FIG. 2, the switchgear and the automatic control panel 200 are made of a steel plate to incorporate a control unit and other necessary electrical components. The display unit 70 is provided on the front of the switchboard and the automatic control panel 200. The display unit 70 displays the vibration width information of the switchboard and the automatic control panel 200 along with the vibration information when vibration or shock is applied to the switchboard and the automatic control panel 200. The management guide information can be displayed accordingly.

3A and 3B, and FIGS. 4A and 4B, the seismic device 100 included in the switchboard and the automatic control panel 200 according to the present embodiment includes an upper case 10, a compression spring 20, and a support ( 30), a lower case 40, a buffer 50, and a footrest 60.

The upper case 10 includes a bolt portion 11, a first intermediate portion 13, and a thread 15. The bolt portion 11 is formed to be installed through the nut 210 in the lower part of the enclosure of the switchgear and automatic control panel 200. That is, as shown in Figure 4b, the bolt portion 11 of the upper case 10 is coupled through the nut 210 to the lower switchboard and the automatic control panel 200.

The first intermediate portion 13 is formed below the bolt portion 11. The first intermediate portion 13 may have a lid shape, and may include a compression spring 20 and a support 30 formed therein in combination with the lower case 40 to be described below.

The thread 15 is formed on the outer wall below the first intermediate portion 13. By the thread 15, the upper case 10 and the lower case 40 to be described below can be screwed.

The compression spring 20 is provided inside the upper case 10. The compression spring 20 absorbs vibrations and shocks applied to the switchboard and the automatic control panel 200 from the outside.

The support 30 includes an upper protrusion 31, a second intermediate portion 33, and a lower protrusion 35. The support 30 is provided inside the upper case 10 and the lower case 40 so that the lower protrusion 35 protrudes, and is provided below the compression spring 20 therein. At this time, the support 30 is provided so that the upper protrusion 31 is fitted into the inner hole of the compression spring (20). That is, as shown in FIG. 4B, the upper protrusion 31 is fitted into the inner hole of the compression spring 20.

The second intermediate portion 33 is provided below the upper protrusion 31. The second intermediate portion 33 is a size corresponding to the circumference of the compression spring 20, and because of the second intermediate portion 33, the upper protrusion 31 of the support 30 is formed in the inner hole of the compression spring 20. Can be fitted to.

The lower protrusion 35 is provided below the second intermediate portion 33. The lower protrusion 35 is longer than the upper protrusion 31 and protrudes through the first hole 45 of the lower case 40.

The lower case 40 is screwed through the thread 15 of the upper case 10 so that the compression spring and the support are provided therein. The lower case 40 includes a first hole 45 formed below. The lower protrusion 35 of the support 30 protrudes through the first hole 45.

The shock absorbing portion 50 is provided at the inner lower portion of the lower case 40 and abuts against the lower protrusion 35 of the support 30. The buffer unit 50 may be a urethane material, but is not limited thereto.

Scaffold 60 is installed on the bottom surface on which the switchboard and the automatic control panel 200 is installed. The footrest 60 includes a groove 61, a toothed portion 63, and a second hole 65. The groove 61 is formed on the top of the scaffold 60. The groove 61 allows the lower protrusion 35 of the support 30 to be fitted to move at various angles.

The tooth portion 63 is formed on the lower surface of the scaffold 60. The teeth 63 are formed so that both sides face in opposite directions to improve friction with the bottom surface. Although the tooth part 63 is shown in the opposite direction to face outward in the drawing, it is not limited to this form, but may be formed in the opposite direction to face inward.

A plurality of second holes 65 are formed to be coupled to the bottom surface. The seismic device 100 according to the present embodiment may be coupled to the bottom surface through the second hole 65. For example, a screw may be coupled to the second hole 65.

The seismic device 100 according to the present embodiment may further include a seismic information monitoring unit (not shown). The seismic information monitoring unit includes a control unit and a computer.

The control unit includes a measurement unit, a display unit 70, and a transmission unit. The measurement unit is installed in the switchboard and the automatic control panel 200, and measures the vibration information according to the vibration or shock applied to the switchboard and the automatic control panel 200. And the vibration width information of the switchgear and automatic control panel 200 according to the vibration is measured.

The display unit 70 is installed on the front of the distribution panel and the automatic control panel 200, and displays information measured by the measuring unit. The transmission unit transmits the information measured by the measurement unit, for example, to a computer spaced a predetermined distance apart. Information sent to the computer can be monitored by the user in real time.

The computer receives and monitors the information transmitted through the transmission unit of the control unit. The computer can set management instructions according to the transmitted information. The management instruction set in the computer may be displayed through the display unit 70 described above. The computer may be a computerized system located in a central control room. Through such a computer, the integrated management of the switchgear and the automatic control panel 200 is possible.

Meanwhile, the switchgear and the automatic control panel including the seismic device capable of monitoring the seismic information according to the present embodiment are not limited to the above-described form and may be variously modified within a range not departing from the technical spirit of the present invention. It will be readily apparent to those skilled in the art to which the present invention pertains.

100; Seismic device
200; Switchgear and Automatic Control Panel
210; nut
10; Upper case
11; Bolt part
13, 33; Middle section
15; Thread
20; Compression spring
30; support fixture
31, 35; projection part
40; Lower case
45, 65; hall
50; Buffer
60; Scaffolding
61; home
63; Tooth
70; Display

Claims (2)

An upper part including a bolt part formed to be installed through a nut at the lower part of the enclosure of the switchboard and the automatic control panel, a first intermediate part of a lid shape formed under the bolt part, and a thread formed on an outer wall under the first intermediate part. A case;
A compression spring provided inside the upper case and absorbing vibrations and shocks applied from the outside;
A second intermediate part corresponding to a circumference of the compression spring at a lower portion of the compression spring, and having an upper protrusion fitted to an inner hole of the compression spring, and below the upper protrusion at a lower portion of the compression spring. A support including an elongated lower protrusion;
A lower case screwed through a thread of the upper case so that the compression spring and the support are provided therein, and a first hole formed at a lower portion thereof to protrude the lower protrusion of the support into the first hole;
A cushioning portion made of urethane material provided at an inner lower portion of the lower case to be in contact with a lower protrusion of the support; And
It is installed on the bottom surface of the switchboard and the automatic control panel, the lower protrusion of the support is inserted into the groove formed on the top to enable movement at various angles, so that both sides face in the opposite direction to improve the friction between the bottom surface Switchgear and automatic control panel comprising a seismic device comprising; a toothed portion formed in the lower portion, and a scaffold comprising a plurality of second holes for coupling with the bottom surface. The method according to claim 1,
A measurement unit installed in the switchboard and the automatic control panel to measure vibration information and vibration width information of the switchboard and the automatic control panel according to vibration, a display unit installed on the front of the switchboard and the automatic control panel to display the measured information, and the measurement A control unit including a transmission unit for transmitting the received information;
A switchgear and automatic control panel further comprising a seismic information monitoring unit comprising; computer for monitoring the information transmitted through the transmission unit of the control unit, and setting the management instructions according to the information.

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