KR101080646B1 - Vertical System for Seismic Retrofit of Electric/Electronic Control Equipment - Google Patents

Abstract

The present invention prevents the control cabinet installed in the control room of a nuclear power plant or thermal power plant and the switchboard installed in the central monitoring room of a substation from being conducted by horizontal seismic forces so that the equipment is not damaged. It relates to a seismic reinforcement system.

Control cabinet, switchboard, hydraulic damper, seismic force, seismic reinforcement

Description

Seismic retrofit system on top of electric / electronic control equipment {Vertical System for Seismic Retrofit of Electric / Electronic Control Equipment}

The present invention prevents the control cabinet installed in the control room of a nuclear power plant or thermal power plant and the switchboard installed in the central monitoring room of a substation from being conducted by horizontal seismic forces so that the equipment is not damaged. It relates to a seismic reinforcement system.

In general, the control cabinet installed in the control room of a nuclear power plant or thermal power plant and the switchboard installed in the central monitoring room of a substation are important facilities that perform operation control functions of a power plant or substation.

The control cabinet of the nuclear power plant or thermal power plant and the substation of the substation are installed at the upper part of the access floor installed on the slab of the structure. It is constructed in the installed form and serves as a passage for control cabinet and switchboard cable when the inside is empty.

The control cabinet and switchboard equipment installed in the upper part of the access floor may be anchored to the structural slab, but the operation part of the control cabinet and the switchboard is placed on the upper part of the access floor without the seismic reinforcement. Most of the time.

Therefore, the control cabinet and switchboard installed in the conventional nuclear power plant or thermal power plant without seismic reinforcement have high risk of conduction when horizontal earthquake motion is applied, and the cable connected to the control cabinet switchboard during cutting There was a problem that the normal operation does not work due to component damage.

In addition, in the case of control cabinets and switchboards with seismic reinforcement, domestic seismic technical standards have been gradually strengthened, so the need for additional equipment seismic reinforcement is increasing. In the case of additional seismic reinforcement or additional seismic reinforcement, a method commonly used is to fix an electronic device by anchoring or welding a joint to a structure slab under the access floor, thereby causing damage to a cable or damage to internal parts of a controller. This often occurred.

Recently, a method of installing a costly seismic isolation device has also been examined.

However, the expected difficulty when installing the seismic isolator in the operation of the control equipment is also difficult to install because numerous cables are connected to the base of the control cabinet and switchboard equipment, and the risk of cable short-circuit exists when earthquake-resistant reinforcement is installed in electronic equipment. However, there was a problem that the normal operation of the control unit cannot be completely guaranteed.

The present invention has been made to solve the conventional problems as described above, the object of the present invention is to seize the seismic reinforcement method without a cable and easy to reinforcement work to overcome the limitations of the existing seismic reinforcement method separate seismic in the upper part By installing a reinforcement system and fixing it to the upper ceiling slab, the control cabinet and switchboard are prevented from falling in the horizontal direction in case of horizontal earthquake movement or vertical earthquake movement, thereby preventing the cable breakage of the controller or the internal parts of the controller. The purpose is to provide a seismic reinforcement system on the top of the electrical and electronic control equipment.

The objects and advantages of the present invention will be described in more detail below, and will be further embodied by the examples. Further objects and advantages of the invention may be realized by the means indicated in the claims and combinations thereof.

In order to achieve the above object, the present invention is made of a cylindrical shape, the upper rod formed in a plate shape so that one end is fixedly coupled to the ceiling slab of the building, and rotatably coupled to the end of the upper rod, cylindrical Comprising a phase, the hydraulic damper is provided with an oil and a spring therein, one end is coupled to the electronic device, the other end is located inside the hydraulic damper, and includes a lower rod coupled to be elastically supported by the oil and the spring To provide a seismic reinforcement system on top of the electrical / electronic control equipment.

In addition, in the present invention, the end of the upper rod is formed to be curved in a hemispherical shape, the hydraulic damper coupled thereto is characterized in that the upper inner peripheral surface is made of a curved surface corresponding to the curved surface formed at the end of the upper rod.

In addition, in the present invention, the lower rod is screwed to form a screw thread of the shape corresponding to the plate portion and the rod portion is formed, the plate portion is formed in a plate shape, one side is provided with a column made of a hollow shape of the pillar The nut is configured to be rotatably installed on the upper portion, and the rod part is inserted or drawn out into a hollow formed in the pillar according to the rotation of the nut to adjust the height.

In addition, in the present invention, a support plate may be further included between the ceiling slab coupled to the upper rod and the electronic device coupled to the lower rod.

In addition, in the present invention, it is characterized in that it further comprises a horizontal support for connecting each electronic device in the horizontal direction when two or more electronic devices.

Therefore, the upper earthquake reinforcement system of the electric / electronic control facility according to the present invention is easy to construct for seismic reinforcement because there is no other facility in the control cabinet and switchboard in operation. This has the advantage of preventing the conduction of electronic devices such as control cabinets and switchboards.

Hereinafter, the configuration and operation effects of the electric / electronic control equipment upper seismic reinforcing system according to the present invention will be described in more detail with reference to the preferred embodiments and the accompanying drawings.

1 is a view schematically showing a seismic reinforcement system of an electric / electronic control facility according to the present invention, FIG. 2 is a partially enlarged view of FIG. 1, and FIG. 3 is a schematic view of seismic reinforcement of a plurality of electronic devices. 4 is an enlarged view of FIG. 3, and FIG. 5 is a plan view of FIG. 3.

As shown in FIGS. 1 and 2, the seismic reinforcement system of the upper part of the electric / electronic control facility according to the present invention enables the seismic reinforcement system to be installed on the upper portion of the electronic device 30, thereby generating horizontal seismic motion and vertical seismic motion. While preventing the electronic device 30 such as the control cabinet and the switchboard from being conducted, the greatest feature is that the ease of installation is improved. The upper rod 110, the hydraulic damper 120, and And a lower rod 130.

The upper rod 110 is fixed to the ceiling slab 10, as shown in Figure 2, one end is formed in a plate shape to be coupled through the ceiling slab 10 and the anchor 20, A screw hole is formed along the edge of the plate to allow the anchor 10 to be inserted. In addition, the other end is coupled to the hydraulic damper 120 to be described later, when the horizontal earthquake movement occurs, the hydraulic damper 120 is curved in a semi-spherical shape so that it can be restored to its original position even if the hydraulic damper 120 is deformed, such as tilting in a horizontal direction to be described later ( Preferably, 120 can be rotated through the curved surface.

Hydraulic damper 120 is one end is rotatably coupled to the upper rod 110, is formed in a cylindrical shape, the upper inner peripheral surface is formed to form a curved surface corresponding to the curved surface of the upper rod 110, the inside The oil 122 and the spring 124 is provided to reduce the seismic force when the earthquake movement occurs.

One end of the lower rod 130 is coupled to the hydraulic damper 120, and the other end is fixed to the electronic device 30 such as a control cabinet and a switchboard. Like the upper rod 110, one end is plate-shaped. Is formed to be fixed to the electronic device 30 by an anchor, the other end is formed to form a curved surface.

At this time, the lower rod 130 formed to form the curved surface is located inside the hydraulic damper 120, is coupled to be elastically supported by a spring 124 provided in the hydraulic damper 120 is the electronic device 30 When the vertical earthquake motion is applied to the oil 122 and the spring 124 in the hydraulic damper 120 serves to reduce the seismic force.

That is, along the curved surface formed at the end of the upper rod 110, the hydraulic damper 120 is rotated to a certain portion, so that when the horizontal earthquake movement occurs a certain portion in the horizontal direction, such as the electronic device 30 is tilted to restore the original position In order to reduce the seismic force in the vertical earthquake movement by the oil 122 and the spring 124 provided in the hydraulic damper 120.

In addition, the lower rod 130, as shown in Figure 4, the plate portion 132 and the rod portion 134 is a screw thread formed by the shape corresponding to each other is screwed, the plate portion 132 has a bottom surface It is formed in a plate shape so as to be coupled to the electronic device 30, a hollow pillar 132a is provided at the center of the upper surface and a nut 132b is rotatably installed on the pillar 132a. When the plate portion 132 and the rod portion 134 is coupled to rotate the nut 132b, the rod portion 134 is inserted into or withdrawn in a hollow formed in the pillar 132a of the seismic reinforcement system of the You can also adjust the height of the installation.

In addition, when the upper rod 110 and the ceiling slab 10 or the lower rod 130 and the electronic device 30 is coupled to protect the ceiling slab 10 or the electronic device 30, the upper rod 110 ) And the support plate 140 may be further combined to facilitate coupling of the lower rod 130.

In addition, as shown in FIG. 3, when the seismic reinforcement work is to be performed on two or more electronic devices 30, each electronic device 30 is connected in a horizontal direction so that a more firm support can be achieved. It may be configured to further include a support (150).

That is, in general, the electronic devices 30, such as control cabinets or switchboards of nuclear power plants and hydroelectric power plants, amount to 700-800 kg per piece, and these electronic devices 30 are usually provided with four or more. Thus, as shown in Figures 3 to 5, when performing the seismic reinforcement for two or more electronic devices 30, the horizontal support 150 that can connect each electronic device 30 to each other in the horizontal direction And the horizontal support 150 is connected to the upper part of the electronic device 30 and the lower part of the ceiling slab 10 through the anchor 20, so that the horizontal support 150 can be more firmly supported when subjected to the seismic force in the horizontal direction. The seismic reinforcement effect can be maximized.

So far, the present invention has been described in detail with reference to embodiments of the present invention, but the scope of the present invention is not limited thereto, and it will be included to substantially equivalent ranges with the embodiments of the present invention.

In addition, as shown in the above description, the technology of the electric / electronic control equipment upper seismic reinforcing system according to the present invention is very simple, but the technical advantages of the present invention will be very clear in that the technical effect is very large. .

1 is a schematic illustration of an electric / electronic control facility upper seismic reinforcement system according to the present invention;

2 is an enlarged partial view of FIG. 1;

3 is a schematic view showing a seismic reinforcement of a plurality of electronic devices;

4 is an enlarged view of FIG. 3;

5 is a plan view of FIG. 3.

<Code Description of Main Parts of Drawing>

110: upper rod 120: hydraulic damper

122: oil 124: spring

130: lower rod 132: plate

132a: pillar 132b: nut

134: rod portion 140: support plate

150: horizontal support

Claims (5)

An upper rod formed in a cylindrical shape and formed in a plate shape so that one end can be fixedly coupled to the ceiling slab of the building; A hydraulic damper rotatably coupled to an end of the upper rod, having a cylindrical shape, and having an oil and a spring provided therein; And one end coupled to the electronic device, and the other end positioned inside the hydraulic damper, the lower rod being coupled to be elastically supported by the oil and the spring. The electric / electronic device according to claim 1, wherein an end of the upper rod is formed to be curved in a hemispherical shape, and the hydraulic damper coupled to the upper rod is formed of a curved surface corresponding to a curved surface formed at an end of the upper rod. Seismic reinforcement system on the top of control equipment. The method according to claim 1, The lower rod is screwed to form a screw thread having a shape corresponding to the plate portion and the rod portion, The plate portion is formed in a plate shape, a hollow column is provided on one side and the nut is rotatably installed on the top of the pillar is inserted or withdrawn in the hollow formed in the rod portion in accordance with the rotation of the nut The seismic reinforcement system of the upper part of the electric / electronic control equipment, characterized in that the height can be adjusted. The electric shockproof reinforcement system of claim 1, further comprising a support plate between the ceiling slab coupled to the upper rod and the electronic device coupled to the lower rod. The system of claim 1, further comprising a horizontal support for connecting each electronic device in a horizontal direction when two or more electronic devices are present.

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