KR102462734B1 - Quake-proof suspension device - Google Patents

Abstract

It relates to a suspension device for supporting a conduit or cable tray suspended from a ceiling, or similar wiring or luminaire, and more particularly, to a seismic suspension device having a structure capable of withstanding earthquake vibrations, the vertical piston and the length of the vertical piston drawn out A vertical earthquake-resistant part made of a piston stopper for fixing the, a connection part for connecting the lower end of the vertical earthquake-resistant part to the suspension, and an anchor part for connecting the upper end of the vertical earthquake-resistant part to the ceiling, Stable to the vibrations of earthquakes An object of the present invention is to provide a seismic suspension device having a suspension structure that can withstand the

Description

Quake-proof suspension device

The present invention relates to a suspension device for supporting a conduit or cable tray suspended from a ceiling, or similar wiring or luminaire, and more particularly, to a seismic suspension device having a structure capable of withstanding earthquake vibration.

In normal buildings or facilities, cables for lighting, communication, or power distribution are sometimes embedded in walls, but in the form of trays, conduits, wiring ducts, or chamber-type devices or structures supporting these cables or lighting devices are suspended from the ceiling It is often installed as

These trays, conduits, or wiring ducts are formed long and are often installed in a form in which several branches are connected to each other, so that a suspension member is used for each predetermined length so that it can be suspended in an orderly manner to the ceiling structure.

However, in Korea too, the frequency of earthquakes has increased in the Yeongnam region for several years. In particular, a magnitude 4.0 earthquake occurred in Uljin-gun, Gyeongsangbuk-do, on April 22, 2019, and an earthquake of 3.9 in Sangju, Gyeongbuk on July 21. On October 27, a 3.4-magnitude earthquake occurred in Changnyeong-gun, Gyeongsangnam-do, requiring countermeasures against the earthquake.

In particular, ceiling lighting equipment such as luminaires are not installed in a form that is firmly attached to the ceiling structure, but are installed in a form that is suspended from the bottom by a certain length. there is

Light-emitting means such as power devices and LED elements can be installed in communication trays, conduits, or raceways for luminaires. There is also a risk of an electric shock accident due to damage to the connection between the wires, so it is necessary to minimize the impact of vibration caused by earthquakes.

In addition, since luminaires installed to illuminate a large indoor area, such as a raceway, are manufactured to be long, it is necessary to prevent the luminaire from swinging in the horizontal direction in an earthquake situation. In this case, the damage to the luminaire can be minimized only by preventing the swaying phenomenon and also attenuating the transmission of vibration.

However, at present, the technology for earthquake-resistant means for maintaining a stable installation state of suspension structures such as communication trays, conduits, or raceways for luminaires has not been developed in earnest.

Registered Patent Publication No. 10-1776026

Accordingly, the present invention provides a seismic suspension device having a suspension structure that can stably withstand earthquake vibrations so that a conduit or cable tray suspended from the ceiling or a suspension device supporting similar wiring or luminaires can be stably maintained against earthquake vibrations. would like to provide

In order to achieve this object, the earthquake-resistant suspension device according to the present invention is a suspension device for suspending a suspension consisting of any one of a cable tray, a luminaire, a conduit, or a chamber-type mechanism formed long in the ceiling of a facility, the upper end of which is opened. A vertical seismic-proof part comprising a vertical cylinder, a vertical piston removably inserted into the vertical cylinder, and a piston stopper for fixing a withdrawal length of the vertical piston, and a connection part for connecting a lower end of the vertical earthquake-resistant part to the suspension; It includes an anchor unit for connecting the upper end of the vertical seismic resistance to the ceiling.

Here, a lower horizontal plate is preferably installed in the lateral direction at the lower end of the vertical seismic-resistant part by welding, and the connection part is bent at both sides of the upper plate and the upper plate to extend downward, and a side plate is formed, and each side plate is horizontal from the lower end. A lower horizontal plate fastening bolt and a lower horizontal plate fastening nut for fixing a lower horizontal plate fastening bolt and a lower horizontal plate fastening bolt that pass through the lower horizontal plate and the upper plate at the same time are provided, the lower horizontal plate and the connection part may be combined with each other.

In this case, the lower horizontal plate may be formed integrally extending from the lower end of the vertical piston, preferably bent in the horizontal direction from the lower end of the vertical piston.

Alternatively, the lower horizontal plate is coupled to the lower end of the vertical piston, preferably the vertical cylinder and the vertical piston are formed in a rectangular horizontal cross section, and on the bottom of the vertical piston, one edge of the four corners constituting the bottom of the vertical piston A corner slit in the form of a long hole formed by cutting is formed, the lower horizontal plate is bent at one side to form a vertical panel, and the lower horizontal plate and the vertical piston are connected to each other with the vertical panel inserted into the corner slit. It can be welded together.

At this time, among the two long sides of the corner slit, the long side of the bottom surface of the vertical piston and the rear surface of the vertical panel may be in close contact with each other.

On the other hand, the vertical piston preferably has a plurality of height selection holes formed at regular intervals along the longitudinal direction, the vertical cylinder is formed with a stopper hole at a position capable of communicating with the height selection hole, the stopper is a stopper hole By being installed to pass through and the height selection hole at the same time, it may be possible to select a length at which the vertical piston is drawn out from the vertical cylinder.

In this case, the vertical width of the stopper hole may be formed to be greater than the width of the stopper.

The earthquake-resistant suspension device according to the present invention is stable against earthquake vibration so that it can be stably maintained against the vibration of an earthquake even when conduits, cable trays, lighting fixtures, and other ceiling installation facilities installed on the ceiling of a building or facility are suspended in a long elongated form. It has the effect of having a suspension structure that can withstand

1 is a schematic view of a seismic suspension device according to the present invention;
2 is a perspective view of a seismic suspension device according to the present invention;
3 is an exploded perspective view of FIG. 2;
Figure 4 is a partial enlarged view of Figure 3;
5 is a combined view of FIG. 4;

Specific structural or functional descriptions presented in the embodiments of the present invention are only exemplified for the purpose of describing embodiments according to the concept of the present invention, and the embodiments according to the concept of the present invention may be implemented in various forms. In addition, it should not be construed as being limited to the embodiments described herein, and should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 2 , the suspension device according to the present invention includes a vertical earthquake-resistant part, a connection part, and an anchor part.

Here, the suspension device refers to a device for suspending a suspension (hereinafter referred to as 'suspension (R)') consisting of any one of a cable tray or a luminaire formed long, a conduit, or a chamber-type device on the ceiling (C) of the facility. . For reference, the member in the horizontal direction shown at the bottom in FIG. 1 refers to the suspension (R).

The vertical seismic part 10 includes a vertical cylinder 12 with an open upper end as shown in FIG. 2 , a vertical piston 13 that is retractably inserted into the vertical cylinder 12 , and withdrawal of the vertical piston 13 . It consists of a piston stopper 131 for fixing the length. The stopper 131 is a pin-shaped member and is installed to pass through the vertical piston 13 and the vertical cylinder 12 at the same time, and fixes the relative positions of the vertical piston 13 and the vertical cylinder 12 .

A ceiling plate 11 may be coupled to the upper end of the vertical cylinder 12 . At this time, the anchor part 20 is a member that connects the upper end of the vertical earthquake-resistant part 10 to the ceiling, as shown in FIG. 2 . In FIG. 2 , the ceiling plate 11 is quadrangular and the anchor unit 20 is illustrated to be installed at every corner of the ceiling plate 11 , but the ceiling plate 11 is not necessarily limited to a quadrangular shape, and the anchor unit 20 ) is also not necessarily limited to four.

The connection part 30 is a member that connects the lower end of the vertical earthquake-resistant part 10 to the suspension R. More specifically, as shown in FIG. 3 , the connection part 30 includes the upper plate 32 and two sidewalls 31 formed by bending at both sides of the upper plate 32 to extend downward, and sidewalls for each sidewall 31 . (31) The flange 33 extending in the horizontal direction from the lower end is integrally formed.

At this time, as shown in Fig. 3, the lower horizontal plate fastening bolt 15 and the lower horizontal plate fastening bolt 15 that pass through the lower horizontal plate 133 and the upper plate 32 simultaneously are provided with a lower horizontal plate fastening nut for fixing the lower horizontal plate fastening bolt 15 , the lower horizontal plate 133 and the connecting portion 30 are coupled to each other.

In this case, the lower horizontal plate 133 may have two embodiments.

The first embodiment for the lower horizontal plate 133 is a form in which the lower horizontal plate 133 is integrally attached to the lower end of the vertical piston 13 as shown in FIG. 4A . In this case, the vertical piston 13 is manufactured in a hollow form and an open lower portion, and then four corners are cut from the lower end to a certain height, and four parts that can be cut and folded are created (not shown), the Two parts are cut and removed, and one of the remaining two parts is bent inward to become the bottom surface of the vertical piston 13 , and the remaining part of the remaining two parts is bent outward in the horizontal direction to form a lower horizontal plate 133 . is the form to be

If the lower horizontal plate 133 is separately manufactured and attached to the lower side surface of the vertical piston 13, there is a risk of falling off due to repeated loads, but as shown in FIG. There is no risk of the lower horizontal plate 133 falling off, rather, a little elasticity is exerted, and even if there is external vibration, relative variation between the vertical piston 13 and the suspension R is allowed to some extent, so the ability to withstand vibration is reduced. can be improved

A second embodiment of the lower horizontal plate 133 is the form shown in FIG. 4B. In this case, the lower horizontal plate 133 is coupled to the lower end of the vertical piston 13 , the vertical cylinder 12 and the vertical piston 13 are formed in a rectangular horizontal cross section, and the bottom surface of the vertical piston 13 is vertical A corner slit 1301 in the form of a long hole is formed by cutting one of the four corners constituting the bottom surface of the piston 13, and the lower horizontal plate 133 has one side bent to form a vertical panel 1332. The lower horizontal plate 133 and the vertical piston 13 are welded to each other in a state in which the vertical panel 1332 is inserted into the corner slit 1301 .

In the second embodiment of FIG. 4B , more specifically, the lower horizontal plate 133 is formed by bending the horizontal panel 1331 and the vertical panel 1332 arranged in the vertical direction while being integral with each other.

In the second embodiment shown in Fig. 4b, although the lower horizontal plate 133 is manufactured separately, since the front of the vertical panel 1332 and the inner peripheral buck of the vertical piston 13 are in close contact with each other, the suspension R Even if a load is applied, the force is applied in a direction in which the coupling between the lower horizontal plate 133 and the vertical piston 13 is in close contact rather than in a falling direction, and durability is ensured. Also, as in the first embodiment, the lower horizontal plate 133 ), since the horizontal panel 1331 and the vertical panel 1332 are integral, a certain elastic force is applied, so that external vibration is buffered to a certain extent.

At this time, the bottom side long side and the back surface of the vertical panel 1332 among the bottom side long side and the side long side of the vertical piston 13 constituting the two long sides of the corner slit 1301 may be in close contact with each other. That is, when the vertical panel 1332 is inserted into the corner slit 1301, the lower end of the rear surface of the vertical panel 1332 is in close contact with the inner circumferential surface of the corner slit 1301. (not shown) In this case, the lower horizontal plate 133 is Since it is not pushed back, the welding line ML shown in FIG. 5 may be firmly maintained.

On the other hand, as shown in FIG. 3 , the vertical piston 13 is provided with a height selection hole 132 , which is a plurality of holes formed at regular intervals along the longitudinal direction, and the vertical cylinder 12 has a height selection hole 132 . A stopper hole 121 is formed at a position capable of communicating with, and the stopper 131 is installed to pass through the stopper hole 121 and the height selection hole 132 at the same time so that the vertical piston 13 is moved from the vertical cylinder 12 Selection of the length to be drawn may be possible.

In addition, as shown in FIG. 2 , the vertical width of the stopper hole 121 is formed to be larger than the diameter of the stopper 131 , so that when vibration is generated by an earthquake or a similar factor, the vertical cylinder 12 and the vertical piston (13) Since the relative variable by a certain interval is allowed, the vibration of the vertical cylinder 12 can be constantly absorbed in the process of being transmitted to the vertical piston 13, and the ability to withstand the vibration can be further improved. have.

The present invention described above is not limited by the above-described embodiments and the accompanying drawings, and it is common in the technical field to which the present invention pertains that various substitutions, modifications and changes are possible within the scope without departing from the technical spirit of the present invention. It will be clear to those who have the knowledge of

C: Ceiling ML: Welding line
R : Suspension W : Wall
10: vertical seismic part 11: ceiling plate
12: vertical cylinder 13: vertical piston
15: lower horizontal plate fastening bolt 20: anchor part
21: ceiling fixing bolt 30: connection part
31: side wall 32: top plate
33: flange 121: stopper hole
131: stopper 132: height selection hole
133: lower horizontal plate 331: flange fastening hole
1301: corner slit 1331: horizontal panel
1332: vertical panel

Claims (7)

In the suspension device for suspending a suspension consisting of any one of a cable tray or a luminaire, a conduit, or a chamber-type mechanism formed long, on the ceiling of a facility,
a vertical seismic-resistant part comprising a vertical cylinder with an open top, a vertical piston that is retractably inserted into the vertical cylinder, and a piston stopper that fixes the length of the vertical piston with which it is drawn out;
a connection part connecting the lower end of the vertical seismic part to the suspension;
and an anchor part connecting the upper end of the vertical earthquake-resistant part to the ceiling;
A lower horizontal plate is installed at the lower end of the vertical seismic resistance by welding in the lateral direction,
The connection part is formed by integrally forming a side plate that is bent from both sides of the upper plate and the upper plate and is formed to extend downward, and a side flange extending in the horizontal direction from the lower end for each of both side plates,
A lower horizontal plate fastening bolt passing through the lower horizontal plate and the upper plate at the same time and a lower horizontal plate fastening nut for fixing the lower horizontal plate fastening bolt are provided, and the lower horizontal plate and the connecting part are coupled to each other. . delete delete According to claim 1,
The lower horizontal plate is coupled to the lower end of the vertical piston,
The vertical cylinder and the vertical piston are formed in a rectangular horizontal cross section,
On the bottom of the vertical piston, a corner slit in the shape of a long hole is formed by cutting one of the four corners constituting the bottom of the vertical piston,
One side of the lower horizontal plate is bent to form a vertical panel,
The seismic suspension device, characterized in that the lower horizontal plate and the vertical piston are welded to each other with the vertical panel inserted into the corner slit. 5. The method of claim 4,
The seismic suspension device, characterized in that the long side of the bottom side of the vertical piston among the two long sides of the corner slit and the rear surface of the vertical panel are in close contact with each other. According to claim 1,
The vertical piston is formed with a plurality of height selection holes at regular intervals along the longitudinal direction,
A stopper hole is formed in the vertical cylinder at a position capable of communicating with the height selection hole,
The stopper is installed to pass through the stopper hole and the height selection hole at the same time, so that the length at which the vertical piston is drawn out from the vertical cylinder can be selected. 7. The method of claim 6,
The seismic suspension device, characterized in that the vertical width of the stopper hole is formed to be larger than the width of the stopper.

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