KR20230045524A - Base isolation system for equipment - Google Patents

Abstract

According to one aspect of the present invention, a seismic isolation structure for a device facility fixated to a floor comprises: a pair of pressure ports respectively having a fastening unit inserted from an end part of a fastening slot of a device facility into the structure and having a support extended upward from the fastening unit to be respectively installed in both end parts of the fastening slot; a fastening means having a fastening bolt enabling a bolt body to penetrate the fastening slot and having a fastening nut fastened to the fastening bolt to fixate the device facility to a floor; and an elastic body, of which both ends are respectively supported by the pair of pressure ports, having a press-fitting groove where a bolt head of the fastening bolt or the fastening nut are press-fitted.

Description

Base isolation structure for equipment equipment {Base isolation system for equipment}

The present invention relates to a seismic isolation structure for equipment. More specifically, it relates to a seismic isolation structure for equipment and equipment capable of ensuring the safety of equipment and equipment against earthquakes by configuring the end of a fastening means for fixing the equipment and equipment to the floor to absorb vibration.

In Korea, which was considered an earthquake-safe zone, recent earthquakes that could cause safety concerns in Gyeongju and Pohang have raised awareness about earthquakes. In particular, when damage occurs to nuclear power plants, hydrothermal power plants, and plant facilities, significant economic damage Therefore, there is a demand for more strengthened structural safety and functional continuity against earthquakes.

Nuclear power plants, hydrothermal power plants, and plant facilities are equipped with many devices such as power control panels, switchboards, and measuring devices. These devices and facilities contain various parts necessary for safe operation of these facilities, so they are structurally stable even in the event of an earthquake. There is a need for a seismic isolation structure for equipment and equipment that can maintain its function.

Republic of Korea Patent Registration No. 10-2256820 (Announced on October 24, 2021)

An object of the present invention is to provide a seismic isolation structure for equipment and equipment capable of ensuring structural safety and functional continuity of equipment and equipment against earthquakes by configuring an end of a fastening means for fixing equipment and equipment to the floor to absorb vibration.

According to one aspect of the present invention, a seismic isolator structure for equipment fixed to a floor includes a binding part inserted inwardly from an end of a fastening slot of the equipment facility, and a support extending upward from the binding part. and a pair of acupressure tools installed at both ends of the fastening slot, respectively; a fastening means for fixing the equipment to the floor, including a fastening bolt through which the bolt body passes through the fastening slot, and a fastening nut fastened to the fastening bolt; A seismic isolation structure for equipment installation is provided, including an elastic body having a press-fitting groove into which the bolt head of the fastening bolt or the fastening nut is press-fitted, and both ends of which are respectively supported by the pair of acupressure tools.

The seismic isolation structure for equipment equipment may further include reinforcing caps each of which is press-fitted to the pair of supports, both ends of which face each other.

The reinforcing cap includes a pair of bent parts facing the outer surfaces of the pair of supports and a body part connecting upper ends of the pair of bent parts, in this case, the outer surfaces of the supports are turned inward. A first inclined surface may be formed, and a second inclined surface parallel to the first inclined surface may be formed on an inner surface of the bent portion.

The fastening slot is formed in the fixing plate of the equipment facility, and in this case, the seismic isolation structure for the equipment facility may further include an elastic plate interposed between the fixing plate and the floor.

The fastening slot may have a shape of a long hole elongated in one direction, and the long hole shape fastening slot may be formed in an expected propagation direction of a seismic wave.

The fastening bolt may be an anchor bolt whose bolt body extends from the bottom.

The bottom may be a steel plate on which another fastening slot opposite to the fastening slot is formed.

The fastening slot includes a first fastening slot long in one direction and a second fastening slot crossing the first fastening slot, and the pair of acupressure tools are respectively installed in the first fastening slot and the second fastening slot. It can be.

The support may have a half-ring shape so that the inside of the support of the pair of acupressure tools facing each other forms a circular shape.

In this case, the pair of supports may further include a circular reinforcing cap into which the support is fitted.

A fixing protrusion may be formed on one of the support and the circular reinforcing cap, and a fixing groove into which the fixing protrusion is inserted may be formed on the other one.

The bottom may be a steel plate in which another fastening slot crossing the fastening slot is formed.

The seismic isolation structure for equipment facilities according to an embodiment of the present invention is configured to absorb vibration at the end of a fastening means for fixing equipment equipment to the floor through a slot, thereby improving structural safety and functional continuity of equipment equipment against earthquakes. can be obtained.

1 is a simplified view of an equipment facility that can be installed in an earthquake-prone area according to an embodiment of the present invention.
2 is a view showing an acupressure tool having a seismic isolation structure for equipment according to an embodiment of the present invention.
3 is a view showing an elastic body of a seismic isolation structure for equipment facilities according to an embodiment of the present invention.
4 is a view showing a reinforcing cap of a seismic isolation structure for equipment facilities according to an embodiment of the present invention.
5 is a view showing an installation state of a seismic isolation structure for equipment facilities according to an embodiment of the present invention.
6 is a view showing a state in which an elastic body of a seismic isolation structure for equipment installation according to an embodiment of the present invention is installed.
7 is a modified example of an acupressure tool of a seismic isolation structure for equipment according to an embodiment of the present invention.
8 is a modified example of a reinforcing cap of a seismic isolation structure for equipment according to an embodiment of the present invention.
9 is a view showing an installation state according to a modified example of a seismic isolation structure for equipment facilities according to an embodiment of the present invention.
10 is a view showing a state in which an elastic body of a seismic isolation structure for equipment installation according to another embodiment of the present invention is installed.

Since the present invention can apply various transformations and have various embodiments, specific embodiments will be illustrated in the drawings and described in detail in the detailed description. However, it should be understood that this is not intended to limit the present invention to specific embodiments, and includes all transformations, equivalents, and substitutes included in the spirit and scope of the present invention. In describing the present invention, if it is determined that a detailed description of related known technologies may obscure the gist of the present invention, the detailed description will be omitted.

Hereinafter, an embodiment of a seismic isolation structure for equipment facilities according to the present invention will be described in detail with reference to the accompanying drawings. In the description with reference to the accompanying drawings, the same or corresponding components are given the same reference numerals and Redundant descriptions will be omitted.

1 is a diagram schematically illustrating equipment and facilities that can be installed in an earthquake-prone area according to an embodiment of the present invention. Further, FIG. 2 is a view showing an acupressure tool of a seismic isolation structure for equipment installations according to an embodiment of the present invention, and FIG. 3 is a view showing an elastic body of a seismic isolation structure for equipment installations according to an embodiment of the present invention. 4 is a view showing a reinforcing cap of a seismic isolation structure for equipment facilities according to an embodiment of the present invention. 5 is a view showing an installation state of a seismic isolation structure for equipment installations according to an embodiment of the present invention, and FIG. 6 shows a state in which elastic members of the seismic isolation structure for equipment installations according to an embodiment of the present invention are installed. it is a drawing

1 to 6, the device equipment 10, the floor 11, the fastening slots 12 and 30, the fixing plate 13, the fastening part 14, the support 16, the acupressure tool 18, the first Inclined surface (20), fastening bolt (22), bolt body (24), bolt head (26), fastening nut (28), press-fitting groove (32), elastic body (34), elastic plate (36), reinforcing cap (38) ), the bent portion 40, the body portion 42, and the second inclined surface 44 are shown.

The seismic isolation structure for equipment facilities according to the present embodiment is a seismic isolation structure for equipment equipment fixed to the floor 11, and the fastening part inserted inwardly from the end of the fastening slot 12 (slot) of the equipment equipment 10 ( 14) and a pair of acupressure tools 18 (支壓具) installed at both ends of the fastening slot 12, including the support 16 extending upward from the fastening portion 14; A fastening means for fixing the equipment 10 to the floor 11, including a fastening bolt 22 through which the bolt body 24 passes through the fastening slot, and a fastening nut 28 fastened to the fastening bolt 22, ; A press-fitting groove 32 into which the bolt head 26 or the fastening nut 28 of the fastening bolt 22 is press-fitted is formed, and both ends include elastic bodies 34 supported by a pair of acupressure tools 18, respectively.

1 shows an instrument installation 10 that can be installed in an earthquake-prone area. For operation or safety of nuclear power plants, hydrothermal power plants, plant facilities, etc., a number of equipment facilities 10 such as switchboards, power control panels, and measuring devices are installed inside these facilities.

Nuclear power plants, hydrothermal power plants, plant facilities, etc. require high structural safety and functional continuity, such as earthquakes, and the equipment 10 installed therein must also have structural safety and functional continuity so that its function is maintained in the event of an earthquake.

At the bottom of the equipment 10, a plurality of fastening slots 12 (slots) are formed to fix the equipment 10 to the floor 11 with a fastening means such as a bolt. A fastening slot 12 may be formed in the fixing plate 13 extending outward.

The fastening slot 12 may be formed in a long hole shape in one direction, and the long hole shaped fastening slot 12 may be formed in advance in an expected propagation direction of the seismic wave. Referring to FIG. 1 , it can be seen that the fastening slot 12 is formed along the propagation direction of the seismic wave assuming that the propagation direction of the seismic wave is in the direction of the double-headed arrow. As such, since the fastening slot 12 is formed along the propagation direction of the seismic wave, vibration caused by the earthquake can be absorbed by the relative movement of the fastening slot 12 with respect to the fastening means when an earthquake occurs.

The acupressure tool 18 (支壓具) includes a binding portion 14 inserted inwardly from the end of the fastening slot 12 of the device 10 and extending upward from the connecting portion 14. Includes a support (16). These acupressure tools 18 may be paired with each other and installed at both ends of the fastening slot 12, respectively.

2 and 5, the fastening part 14 of the acupressure tool 18 is inserted through the fastening slot 12 at the end of the fastening slot 12 and placed between the bottom 11 and the fixing plate 13 And, the support 16 is placed in an upright state at the end of the fastening slot 12 upward. As the fastening means such as the fastening bolt 22 is tightened, the fastening part 14 is compressed between the fixing plate 13 and the floor 11, and the acupressure tool 18 is fixed to the end of the fastening slot 12.

The pair of acupressure tools 18 are disposed at both ends of the fastening slot 12, so that the supports 16 face each other.

The fastening means includes a fastening bolt 22 through which the bolt body 24 passes through the fastening slot 12 and a fastening nut 28 fastened to the fastening bolt 22 . This fastening means is fastened to the fastening nut 28 in a state where the bolt body 24 of the fastening bolt 22 passes through the fastening slots 12 and 30 of the fixing plate 13 and the floor 11, and the machine equipment (10) is fixed to the floor (11).

The fastening means may vary depending on the shape of the floor 11. When the floor 11 is made of steel plate, the equipment 10 is fixed to the steel plate of the floor 11 by the fastening bolt 22 and the fastening nut 28. It can be.

When the floor 11 is a concrete floor, anchor bolts may be pre-buried so that the bolt body extends from the concrete floor. there is. In this embodiment, a form of fixing the equipment 10 to the floor steel plate is presented.

The elastic body 34 is formed with a press-in groove 32 into which the bolt head 26 or the fastening nut 28 of the fastening bolt 22 is press-fitted, and both ends of the elastic body 34 are attached to a pair of acupressure tools 18. each supported.

The elastic body 34 may be made of an elastic material such as rubber, and a press-in groove 32 into which the bolt head 26 or the fastening nut 28 of the fastening bolt 22 is press-fitted is formed at the center. As shown in FIG. 5, when the equipment 10 is fixed to the floor steel plate 11 by the fastening bolt 22 and the fastening nut 28, the bolt head 26 of the fastening bolt 22 is at the upper part. In this case, since the bolt head 26 of the fastening bolt 22 is press-fitted into the press-fitting groove 32 of the elastic body 34, the support 16 of the acupressure sphere 18 in which the elastic body 34 is facing each other ) is located between

On the other hand, when the bolt body of the anchor bolt protrudes upward, such as on a concrete floor, the equipment 10 is fixed to the floor 11 by the fastening nut. ) As it is press-fitted, the elastic body 34 is positioned between the supports 16 of the acupressure spheres 18 facing each other.

When a seismic wave is generated in the direction of the fastening slot 12 of the equipment 10 fixed to the floor 11, relative movement occurs between the fastening bolt 22 and the equipment 10 in the direction of the fastening slot 12. In this process, the bolt head 26 or the fastening nut 28 applies pressure to the elastic body 34, and vibration can be absorbed by the elasticity of the elastic body 34 supported by the acupressure sphere 18.

Referring to FIG. 3, the elastic body 34 is in the form of a rubber ring, and is inserted into the press-fit groove 32 in a state in which the equipment 10 is fastened to the floor 11 by the fastening bolt 22 and the fastening nut 28. The elastic body 34 is fastened to the bolt head 26 so that the bolt head 26 is press-fitted. At this time, both ends of the elastic body 34 are in close contact with the support 16 of the acupressure sphere 18 facing each other.

The seismic isolation structure for equipment facilities according to the present embodiment may further include reinforcing caps 38 each press-fitted to a pair of supports 16 whose both ends face each other.

The support 16 of the acupressure tool 18 extends upward in a cantilever shape with respect to the fastening portion 14, so that the support 16 may be broken due to the pressure of the elastic body 34 due to an earthquake. In order to prevent such breakage, the pair of supports 16 are connected to each other by forcibly fitting the reinforcing caps 38 to the supports 16 facing each other, thereby increasing the stiffness against breakage.

Referring to FIG. 4, the reinforcing cap 38 according to the present embodiment includes a pair of bent parts 40 facing each other on the outer surface of the pair of supports 16 and a pair of bent parts 40 It has a body portion 42 connecting the top of the.

In the state in which the elastic body 34 is coupled to the bolt head 26, the pair of bent parts 40 are each press fit on the outside of the support 16 facing each other, and the reinforcing cap 38 is coupled. As the acupressure spheres 18 that are spaced apart are connected to each other, stiffness against breakage may be increased.

For the interference fit of the reinforcing cap 38 to the support 16, the outer surface of the support 16 is formed with a first inclined surface 20 inwardly, and the inner surface of the bent portion 40 is formed with a first inclined surface ( A second inclined surface 44 parallel to 20) may be formed. Referring to FIG. 5, as the reinforcing cap 38 is pressed from the top or pushed in from the side, the first inclined surface 20 and the second inclined surface 44 face each other and the reinforcing cap 38 attaches to the support 16. It can be coerced. Meanwhile, irregularities may be formed in the vertical direction on the first inclined surface 20 and the second inclined surface 44 to prevent the reinforcing cap 38 from slipping sideways after the interference fit.

According to the installation of the reinforcing cap 38, the elastic body 34, the acupressure tool 18, etc. are covered to prevent exposure of the coupling portion.

Meanwhile, as shown in FIG. 5 , an elastic plate 36 made of a material such as rubber may be interposed between the fixing plate 13 and the floor 11 of the equipment 10 . When the elastic plate 36 is interposed between the fixing plate 13 and the floor 11 of the equipment 10 and the fastening is performed by the fastening means, the elastic plate 36 is compressed and the fixing plate 13 is placed on the floor ( 11) is adhered to.

As the elastic plate 36 is interposed between the fixed plate 13 and the floor 11 of the equipment 10, vibration in the vertical direction can be absorbed, and the frictional force caused by the compression of the elastic plate 36 in the horizontal direction vibrations can also be absorbed.

A process of fixing the equipment 10 to the floor 11 using the seismic isolation structure for equipment equipment according to the present embodiment is as follows.

First, the elastic plate 36 is laid on the floor 11 on which the equipment 10 is installed, and the equipment 10 directs the fastening slot 12 of the fixing plate 13 of the equipment 10 to the direction of the seismic wave. is placed on the elastic plate 36. Next, for each fastening slot 12, the acupressure tool 18 is installed at both ends of the fastening slot 12 so that the fastening part 14 is inserted between the fixing plate 13 and the bottom 11. Next, tighten the fastening nut 28 and the fastening bolt 22 in a state where the bolt body 24 of the fastening bolt 22 passes through the fastening slots 12 and 30 of the fixing plate 13 and the floor 11 . Next, the elastic body 34 is installed between the supports 16 facing each other so that the bolt head 26 of the fastening bolt 22 is press-fitted into the press-in groove 32 of the elastic body 34 . Next, the reinforcing caps 38 are installed by press-fitting the reinforcing caps 38 to the supporters 16 facing each other.

The fastening of the fastening means, the installation of the elastic body 34, and the installation of the reinforcing cap 38 are performed for each of the necessary fastening slots 12, respectively.

In the above method, the equipment 10 is installed on the floor 11, and when vibration occurs in the direction of the fastening slot 12 due to an earthquake, the bolt head 26 of the fastening bolt 22 is attached to the elastic body 34. It can absorb vibration while being elastically supported.

7 is a modified example of acupressure tool of a seismic isolation structure for equipment facilities according to an embodiment of the present invention, and FIG. 8 is a modified example of a reinforcing cap of a seismic isolation structure for equipment equipment according to an embodiment of the present invention. And, FIG. 9 is a view showing an installation state according to a modified example of a seismic isolation structure for equipment facilities according to an embodiment of the present invention.

7 to 9, the bottom 11, the fastening slots 12 and 30, the fixing plate 13, the fastening part 14, the support 16, the acupressure tool 18 ', the first inclined surface 20, Fastening bolt (22), bolt body (24), bolt head (26), fastening nut (28), elastic body (34), elastic plate (36), reinforcing cap (48), fixing protrusion (50), fixing groove ( 52) is shown.

In this modified example, a pressure ball 18' and a reinforcing cap 48 are provided to correspond to the propagation directions of seismic waves in various directions.

As shown in FIG. 7, the acupressure sphere 18' according to this modified example is a pair of acupressure spheres 18' facing each other. it is formed in the form Accordingly, when the fastening parts 14 of the acupressure tools 18' are inserted and fixed at both ends of the fastening slots 12 of the equipment 10, the half-ring shaped supports 46 face each other and have a circular space inside. this is provided

In a state in which the fastening bolt 22 is fastened through the circular space, the elastic body 34 is attached to the semi-circular support so that the bolt head 26 of the fastening bolt 22 is press-fitted into the press-in groove 32 of the elastic body 34. It is inserted into the circular space prepared by (46). While the elastic body 34 is supported on the circular space formed by the two supports 46, it can respond to seismic waves or vibrations in various directions.

And, in this case, in order to prevent breakage of the support 46 protruding upward when an earthquake occurs, as shown in FIG. 8, a circular reinforcing cap in which the two supports 46 forming a circular space are tightly fitted ( 48) may be further provided.

By forcibly fitting the circular reinforcing cap 48 to the two supports 46 in a state where the elastic body 34 is inserted, the pair of supports 46 are connected to each other to increase the stiffness against breakage.

And, as shown in FIGS. 7 and 8, a fixing protrusion 50 is formed on one of the half-ring shaped support 46 and the circular reinforcing cap 48, and the fixing protrusion 50 is inserted into the other one. A fixing groove 52 may be formed. When the reinforcing cap 48 is inserted into the two supports 46, the fixing protrusion 50 is inserted into the fixing groove 52, and a mechanically strong coupling can be established by the elastic force of the elastic body 34. In this embodiment, a fixing protrusion 50 is formed on the support 46 and a fixing groove 52 is formed on the reinforcing cap 48, but on the contrary, a fixing groove is formed on the support 46 and reinforced. It is also possible to form a fixing protrusion on the cap 48.

On the other hand, in this case, the floor 11 may be made of a steel plate, and the fastening slot 12 of the equipment 10 and the fastening slot 30 formed in the steel plate for the floor located below it are “十” shaped with each other. When an earthquake occurs, the floor steel plate and the fixing plate 13 of the equipment 10 relatively slide in the "十"-shaped crossed fastening slots 12 and 30 to respond to earthquakes or vibrations in various directions.

10 is a view showing a state in which an elastic body of a seismic isolation structure for equipment installation according to another embodiment of the present invention is installed.

10 shows a fastening part 14, a first fastening slot 15, a second fastening slot 17, an acupressure tool 18, a bolt head 26, and an elastic body 34.

In this embodiment, a first fastening slot 15 long in one direction and a second fastening slot 17 crossing the first fastening slot 15 are formed in a "十" shape in the equipment, This is to respond to seismic waves and vibrations.

In this case, as shown in FIG. 7, the acupressure tools 18 are installed in pairs at both ends of the first fastening slot 15 and the second fastening slot 17, respectively. The elastic body 34 installed on the bolt head 26 is installed between the four acupressure spheres 18 to absorb seismic waves or vibrations in various directions.

Although the embodiments of the present invention have been described above, the spirit of the present invention is not limited to the embodiments presented herein, and those skilled in the art who understand the spirit of the present invention may add elements within the scope of the same spirit. However, other embodiments can be easily proposed by means of changes, deletions, additions, etc., but these will also fall within the scope of the present invention.

10: equipment equipment 11: floor
12, 15, 17, 30: fastening slot 13: fixing plate
14: attachment part 16, 46: support
18, 18 ': acupressure sphere 20: first slope
22: fastening bolt 24: bolt body
26: bolt head 28: fastening nut
32: press-in groove 34: elastic body
36: elastic plate 38, 48: reinforcing cap
40: bent portion 42: body portion
44: second inclined surface 50: fixed protrusion
52: fixed groove

Claims (12)

As a seismic isolation structure for equipment equipment fixed to the floor,
A pair of acupressure tools installed at both ends of the fastening slot, including a fastening part inserted inwardly from the end of the fastening slot of the equipment and a support extending upward from the fastening part.具) and;
a fastening means for fixing the equipment to the floor, including a fastening bolt through which the bolt body passes through the fastening slot, and a fastening nut fastened to the fastening bolt;
A seismic isolation structure for equipment installation, comprising an elastic body having a press-fitting groove into which the bolt head of the fastening bolt or the fastening nut is press-fitted, and both ends of which are respectively supported by the pair of acupressure tools.
According to claim 1,
A seismic isolation structure for equipment installation, further comprising reinforcing caps, each of which is press-fitted to the pair of supports, both ends of which are opposed to each other.
According to claim 2,
The reinforcing cap,
A pair of bent parts facing the outer surfaces of the pair of supports, and a body part connecting upper ends of the pair of bent parts,
The base isolation structure for equipment installation, characterized in that the outer surface of the support is formed with a first inclined surface inwardly, and the inner surface of the bent portion is formed with a second inclined surface parallel to the first inclined surface.
According to claim 1,
The fastening slot is formed on the fixing plate of the equipment,
A seismic isolation structure for equipment installation, further comprising an elastic plate interposed between the fixing plate and the floor.
According to claim 1,
The seismic isolation structure for equipment installation, characterized in that the fastening slot has an elongated hole shape in one direction, and the long hole-shaped fastening slot is formed in an expected propagation direction of the seismic wave.
According to claim 1,
The seismic isolation structure for equipment equipment, characterized in that the fastening bolt is an anchor bolt whose bolt body extends from the floor.
According to claim 1,
the floor,
A seismic isolation structure for equipment equipment, characterized in that it is a steel plate on which another fastening slot opposite to the fastening slot is formed.
According to claim 1,
The fastening slot includes a first fastening slot long in one direction and a second fastening slot crossing the first fastening slot,
Characterized in that the pair of acupressure tools are respectively installed in the first fastening slot and the second fastening slot.
According to claim 1,
The seismic isolation structure for equipment installation, characterized in that the support has a half-ring shape so that the inside of the support of the pair of acupressure tools facing each other forms a circle.
According to claim 9,
The seismic isolation structure for equipment installation, further comprising a circular reinforcing cap into which the pair of supports are press-fitted.
According to claim 10,
A seismic isolation structure for equipment installation, characterized in that a fixing protrusion is formed on one of the support rod and the circular reinforcing cap, and a fixing groove into which the fixing protrusion is inserted is formed on the other one.
According to claim 9,
the floor,
A seismic isolation structure for equipment equipment, characterized in that it is a steel plate on which another fastening slot crossing the fastening slot is formed.

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