KR102201474B1 - Underground Cable Support Device - Google Patents

Abstract

The present invention relates to an underground power distribution cable support device capable of improving seismic performance of a cable support. The underground power distribution cable support device includes: an upper plate (30) including an upper half-moon support part (31) for supporting a lower portion of a cable (20); a lower plate (40) including a lower half-moon support part (41) making close contact with an upper portion of the cable (20); side plates (50, 60) vertically installed between the upper plate (30) and the lower plate (40); fastening elongated holes (32, 42) formed in the upper plate (30) and the lower plate (40); bending coupling parts (51, 52, 61, 62) formed at upper and lower ends of the side plates (50, 60), respectively; upper through-holes (33a, 33b) formed in the upper plate (30); lower through-holes (43a, 43b) formed in the lower plate (40); a hanger bolt (22) inserted into the upper through-hole (33b) and the lower through-hole (43b), and installed on a structure ceiling (21); hanger nuts (23, 24) coupled to the hanger bolt (22); a pressing bolt (83) inserted into the upper through-hole (33a) and the lower through-hole (43a); a pressing nut (84) coupled to a lower end of the pressing bolt (83); upper reinforcing ribs (34, 35) formed on left and right edges of the upper plate (30); lower reinforcing ribs (44, 45) formed on left and right edges of the lower plate (40); a hollow spacer (70) for maintaining an interval between the side plates (50, 60); horizontal through-holes (53, 63) formed in the side plates (50, 60); and protrusion rods (71, 72) formed at both ends of the hollow spacer (70) and protruding outward through the horizontal through-holes (53, 63).

Description

Underground Cable Support Device

The present invention relates to an underground power distribution cable support device, and more particularly, to an underground power distribution cable support device capable of stacking and installing cables and responding to earthquake resistance.

Underground lines are mainly installed in areas where overhead line facilities are technically impossible and maintenance is difficult, especially in areas where overhead lines are concentrated, high load density and high-rise buildings to provide supply capacity. It is installed in places where it is technically difficult to configure multiple lines to secure.

In the conventional cable support device used in such an underground line, as shown in the accompanying drawings, FIGS. 1 and 2, the vertical long hole 12 is fixed in the vertical direction in the angle 11 installed perpendicular to the wall surface 10 of the power tool. It is formed so as to form an interval, and a "T"-shaped stopper 13 that is inserted into the vertical hole 12 is formed on the side of the cable support 14, and is at a right angle at the center of the lower end of the cable support 14. When the bent locking protrusion 15 is formed so that the cable support 14 is tilted upward, the catch 13 is inserted into the vertical long hole 12 and then the cable support 14 is lowered horizontally. At the same time, the locking protrusion 15 formed on the cable support 14 is caught on the end of the angle 11 while being caught by the vertical long hole 12.

That is, the catch 13 formed on the cable support 14 serves to prevent the lateral separation, and the catch 15 serves to keep the cable support 14 horizontal.

However, since such a conventional cable support device does not have a device that can prevent it when a force is applied to the cable support 14 upward, there is a problem that the cable support 14 is separated from the angle 11 when an earthquake occurs. there was.

Korean Registered Patent Publication No. 10-1019372 (announcement date 2011.03.07.) Korean Registered Patent Publication No. 10-0920148 (announcement date 2009.10.05.)

The present invention has been made to solve the above problems, and an object thereof is to provide an underground distribution cable support device capable of stacking cables up and down and improving the seismic performance of the cable support.

The cable support device for underground distribution for achieving the object of the present invention includes: an upper plate having an upper half-moon support portion supporting a lower portion of the cable formed in parallel at regular intervals; A lower plate in which a lower half-moon support part in close contact with the upper part of the cable is formed in parallel at regular intervals; A pair of side plates installed vertically while spaced apart from each other between the upper plate and the lower plate; Fastening holes formed on the upper and lower plates, respectively; A bending coupling portion formed at the upper and lower ends of the side plate and bent after being inserted into the fastening hole; An upper through hole formed to penetrate the upper plate vertically; A lower through hole formed to penetrate the lower plate vertically, the upper through hole and the lower through hole formed to be aligned with the center in the vertical direction; A hanger bolt inserted into the upper through hole and the lower through hole and installed on the ceiling of the structure; A hanger nut coupled to the hanger bolts and in close contact with the upper surface of the uppermost layer and the lower surface of the lowermost layer; A pressure bolt inserted into the upper through hole and the lower through hole; A pressure nut coupled to the lower end of the pressure bolt; A pair of upper reinforcing ribs formed vertically from the left and right edges of the upper plate toward the lower side; A pair of lower reinforcing ribs formed vertically from the left and right edges of the lower plate toward the upper side; A hollow spacer installed between the side plates and maintaining a gap between the side plates; Horizontal through-holes each formed in the side plate so that the center of the hollow spacer is aligned; It has an outer diameter smaller than the outer diameter of the hollow spacer and is formed at both ends of the hollow spacer, and includes a protruding rod protruding outward through a horizontal through hole.

The present invention is a screw hole each formed in the center of the protruding rod; Cross bolts formed in a straight line with the hollow spacer between adjacent protruding rods at a certain distance from each other, and having both ends coupled to the screw holes; It is coupled to the cross bolt and has a feature including a lock nut that is in close contact with the end of the protruding rod.

The present invention is a channel coupling portion bent in a direction away from each other from the rear end of the side plate; T-type bosses respectively installed in the channel coupling unit; It is formed in a vertical channel installed on the wall of the structure at regular intervals from each other in the vertical direction, and includes a keyhole-shaped reverse ottogi hole through which a T-shaped boss is inserted.

As described above, the present invention uses the fastening holes 32, 42 and the bending joints 51, 52, 61 and 62 to connect the side plates 50 and 60 to the upper plate 30 and the lower plate ( Since it is configured to be assembled to 40), the rigidity of the cable support 100 is greatly improved, as well as the effect of enabling weight reduction.

The upper reinforcing ribs 34 and 35 formed on the upper plate 30 and the lower reinforcing ribs 44 and 45 formed on the lower plate 40 can greatly improve the flexural stiffness of the upper plate 30 and the lower plate 40. It works.

Before assembling the side plates 50 and 60 to the upper plate 30 and the lower plate 40, the hollow spacer 70 allows the distance between the side plates 50 and 60 to be kept constant. ) It is possible to conveniently match the bending coupling portions 51, 52, 61, 62 formed in 60 with the fastening holes 32 and 42 formed in the upper plate 30 and the lower plate 40. It works.

Since it is configured to be able to connect between the cable support 100 with cross bolts 80 using the protruding rods 71, 72 formed at both ends of the hollow spacer 70 and screw holes 71t, 72t, earthquakes There is an effect that can greatly improve the seismic performance against vibration that may be applied to the cable support 100 by.

Since the upper half-delivery support part 31 that is in close contact with the lower part of the cable 20 and the lower half-delivery support part 41 that is in close contact with the upper part of the cable 20 are provided, the cable support 100 with the cable 20 interposed therebetween. Since it can be installed by stacking two or more layers in the vertical direction, there is a convenience that can increase the laying of the cable 20 lightly.

Furthermore, in the present invention, the cable support 100 is attached to the hanger bolt 22 by the upper through holes 33a and 33b formed in the upper plate 30 and the lower through holes 43a and 43b formed in the lower plate 40. Since it is configured to obtain a support force from the structure ceiling 21 by using, an effect of greatly improving the support force of the cable support base 100 can be expected.

1 is a front perspective view showing a conventional cable support device
Figure 2 is an exploded perspective view of a rear side showing a conventional cable support device
3 is a perspective view according to the present invention
Figure 4 is a side view according to the present invention
5 is a plan view according to the present invention
6 is a partially enlarged exploded perspective view according to the present invention
Figure 7 is a partially enlarged side view showing a cable support according to the present invention
Figure 8 is an exploded perspective view showing a cable support according to the present invention
9 is a cross-sectional view taken along line A-A' of FIG. 7
10 is a partially enlarged plan sectional view showing a hollow spacer, a protruding rod, a cross bolt and a lock nut according to the present invention

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

As shown in the accompanying drawings 3 to 10, the present invention includes an upper plate 30 having an upper half-moon support portion 31 supporting a lower portion of the cable 20 formed in parallel at regular intervals; A lower plate 40 having a lower half-moon support part 41 in close contact with the upper part of the cable 20 formed in parallel at regular intervals; It includes a pair of side plates 50 and 60 installed vertically while spaced apart from each other between the upper plate 30 and the lower plate 40.

The upper plate 30, the lower plate 40, and the side plate 50, 60 can be formed using a steel plate having a certain thickness, and in particular, the upper plate 30 and the lower plate 40 are the same as shown in FIG. If the top and bottom are reversed after molding so that the upper plate 30 and the lower plate 40 are compatible with each other.

The upper plate 30, the lower plate 40, the side plates 50, 60, and the hollow spacer 70 below constitute one cable support 100.

The present invention includes fastening holes 32 and 42 formed in the upper plate 30 and the lower plate 40, respectively; It is formed at the upper and lower ends of the side plates 50, 60, respectively, and includes a bending coupling portion 51, 52, 61, 62 that is bent after being inserted into the fastening holes 32 and 42.

The fastening holes 32 and 42 may be formed in a rectangular shape to have a width corresponding to the thickness of the bending coupling portions 51, 52, 61, 62, as shown in FIGS. 8 and 9, and bending The coupling portions 51, 52, 61, and 62 are integrally formed on the side plates 50 and 60.

Insert the bending joints 51, 52, 61, 62 into the fastening holes 32, 42, and then bend the side plates 50, 60 at a right angle toward each other to face each other, and place the side plates 50 and 60 on the top plate 30. It is coupled to the lower plate 40.

The present invention includes an upper through hole (33a) (33b) formed to penetrate the upper plate (30) up and down; It is formed to penetrate the lower plate 40 vertically, and includes upper through holes 33a and 33b and lower through holes 43a and 43b formed to have the centers aligned in the vertical direction.

The upper through-holes 33a and 33b and the lower through-holes 43a and 43b may be formed in a circular shape corresponding to the diameters of the hanger bolts 22 and the pressure bolts 83.

The present invention is inserted into the upper through hole (33b) and the lower through hole (43b), the hanger bolt 22 installed in the structure ceiling 21; Hanger nuts 23 and 24 which are coupled to the hanger bolts 22 and are in close contact with the upper surface of the uppermost plate 30 and the lower surface of the lowermost plate 40; A pressing bolt 83 inserted into the upper through hole 33a and the lower through hole 43a; It includes a pressure nut 84 coupled to the lower end of the pressure bolt 83.

As shown in Figure 4, the cable support 100 positioned on the upper and lower sides using the hanger nuts 23 and 24 coupled to the hanger bolt 22 and the pressure nut 84 coupled to the pressure bolt 83 The cables 20 located between the cable supports 100 are pressed by moving them in a direction closer to each other.

The cable support 100 may be installed by stacking two or more in the vertical direction with the cable 20 interposed therebetween.

The present invention includes a pair of upper reinforcing ribs 34 and 35 formed vertically from the left and right edges of the upper plate 30 toward the lower side; It includes a pair of lower reinforcing ribs 44 and 45 formed vertically from the left and right edges of the lower plate 40 toward the upper side.

The upper reinforcing ribs 34 and 35 may be integrally formed with the upper plate 30, and the lower reinforcing ribs 44 and 45 may also be integrally formed with the lower plate 40.

By the upper reinforcing ribs 34 and 35 and the lower reinforcing ribs 44 and 45, the flexural stiffness of the upper plate 30 and the lower plate 40 can be greatly improved.

The present invention is installed between the side plates 50, 60, the hollow spacer 70 for maintaining the spacing of the side plates 50, 60; Horizontal through-holes 53 and 63 respectively formed in the side plates 50 and 60 so that the center of the hollow spacer 70 is aligned with each other; It is formed at both ends of the hollow spacer 70 with an outer diameter smaller than the outer diameter of the hollow spacer 70, and includes protruding rods 71 and 72 protruding outward through the horizontal through holes 53 and 63.

The hollow spacer 70 and the protruding rods 71 and 72 can be integrally formed by turning using a metal round rod as shown in Figs. 9 and 10, and the length of both ends of the hollow spacer 70 The distance between the side plates 50 and 60 is determined by.

Before assembling the side plates 50 and 60 to the upper plate 30 and the lower plate 40, the hollow spacer 70 may be used to maintain a constant spacing between the side plates 50 and 60.

The present invention is a screw hole (71t) (72t) each formed in the center of the protruding rod (71) (72); Cross bolts 80 formed in a straight line with the hollow spacer 70 between the protruding rods 71 and 72 adjacent to each other at a certain distance and having both ends coupled to the screw holes 71t and 72t; It includes lock nuts 81 and 82 that are coupled to the cross bolt 80 and are in close contact with the ends of the protruding rods 71 and 72.

The cross bolt 80 maintains a constant spacing between the cable supports 100 installed along the length direction of the cable 20 as shown in FIGS. 3 and 5, and binds the two cable supports 100 to each other. It serves to improve support.

The lock nuts 81 and 82 are for preventing loosening of the cross bolt 80.

The present invention is a channel coupling portion (54, 64) that is bent in a direction away from each other from the rear end of the side plate (50) (60); T-type bosses 55 and 65 respectively installed in the channel coupling units 54 and 64; It is formed at regular intervals from each other in the vertical channel 26 installed on the structure wall 25 in the vertical direction, and includes a reverse hole 27 in the shape of a keyhole through which the T-shaped bosses 55 and 65 are inserted. .

6 and 7, when the T-type boss 55 and 65 are inserted into the reverse hole 27 formed in the vertical channel 26 and then the cable support 100 is lowered, the T-type boss 55 The cable support 100 is installed in the vertical channel 26 while the 65 is caught in the reverse hole 27.

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

3 to 10, a vertical channel 26 is installed on the structure wall 25, and then T-shaped bosses 55 and 65 located at the rear of the cable support 100 are connected to the vertical channel 26. When inserted into the reverse hole 27 formed in) and then lowered the cable support 100, the cable support 100 is coupled to the vertical channel 26.

At this time, as shown in FIGS. 3 and 5, when the cable support 100 is connected in a horizontal direction along the length direction of the cable 20, the protruding rods 71 and 72 formed at both ends of the hollow spacer 70 When both ends of the cross bolt 80 are connected to the screw holes 71t and 72t and tightened strongly using the lock nuts 81 and 82, the cable support 100 located at the same height is attached to the cross bolt 80. They stay connected to each other.

After that, the cable 20 is raised and supported on the upper half-delivery support part 31 formed on the upper plate 30 of the cable support 100, and then the cable is transferred to the lower half-delivery support part 41 formed on the lower plate 40 of the other cable support 100. When the cable support 100 is coupled to the vertical channel 26 while covering the upper part of the 20, as shown in FIG. 4, the cable support 100 is placed on the upper and lower portions of the cable 20 with the cable 20 interposed therebetween. Is located.

At this time, after inserting the structure hanger bolt 22 and the pressure bolt 83 through the upper through hole (33a) (33b) formed in the upper plate (30) and the lower through hole (43a) (43b) formed in the lower plate (40) When the cable supports 100 located in the upper and lower parts are moved in a direction closer to each other by using the hanger nuts 23 and 24 and the pressure nut 84, the cables 20 located between the cable supports 100 are pressed. do.

20: cable 21: structure ceiling
22: hanger bolt 23, 24: hanger nut
25: structure wall 26: vertical channel
27: reverse hole 30: top plate
31: upper half moon support part 32,42: fastening length
33a,33b: upper through hole 43a,43b: lower through hole
34,35: upper reinforcing rib 40: lower plate
41: lower half moon support part 44,45: lower reinforcing rib
50,60: side plate 51,52,61,62: bending joint
53,63: horizontal through hole 54,64: channel coupling part
55,65: T-type boss 70: Hollow spacer
71,72: protruding bar 71t,72t: screw hole
80: cross bolt 81,82: lock nut
83: pressure bolt 84: pressure nut
100: cable support

Claims (3)

An upper plate 30 having an upper half-moon support portion 31 supporting the lower portion of the cable 20 formed in parallel at regular intervals;
A lower plate 40 having a lower half-moon support part 41 in close contact with the upper part of the cable 20 formed in parallel at regular intervals;
A pair of side plates 50 and 60 installed vertically while spaced apart from each other between the upper plate 30 and the lower plate 40;
Fastening holes 32 and 42 formed in the upper plate 30 and the lower plate 40, respectively;
Bending coupling portions 51, 52, 61 and 62 formed at the upper and lower ends of the side plates 50 and 60, respectively, and bent after being inserted into the fastening holes 32 and 42;
Upper through-holes (33a) (33b) formed to vertically penetrate the upper plate (30);
A lower through hole (43a) (43b) formed to penetrate the lower plate (40) up and down, and the upper through hole (33a) (33b) and the lower through hole (43a) (43b) formed to be aligned with the center in the vertical direction;
A hanger bolt 22 inserted into the upper through hole 33b and the lower through hole 43b and installed on the structure ceiling 21;
Hanger nuts 23 and 24 which are coupled to the hanger bolts 22 and are in close contact with the upper surface of the uppermost plate 30 and the lower surface of the lowermost plate 40;
A pressing bolt 83 inserted into the upper through hole 33a and the lower through hole 43a;
A pressure nut 84 coupled to the lower end of the pressure bolt 83;
A pair of upper reinforcing ribs 34 and 35 formed vertically from the left and right edges of the upper plate 30 toward the lower side;
A pair of lower reinforcing ribs 44 and 45 formed vertically from the left and right edges of the lower plate 40 toward the upper side;
A hollow spacer (70) installed between the side plates (50) (60) and maintaining a gap between the side plates (50) (60);
Horizontal through-holes 53 and 63 respectively formed in the side plates 50 and 60 so that the center of the hollow spacer 70 is aligned with each other;
Protruding rods 71 and 72 formed at both ends of the hollow spacer 70 with an outer diameter smaller than the outer diameter of the hollow spacer 70 and protruding outward through the horizontal through holes 53 and 63;
Cable support device for underground distribution, characterized in that it comprises a. The method according to claim 1,
Screw holes 71t and 72t respectively formed in the centers of the protruding rods 71 and 72;
Cross bolts 80 formed in a straight line with the hollow spacer 70 between the protruding rods 71 and 72 adjacent to each other at a certain distance and having both ends coupled to the screw holes 71t and 72t;
A lock nut (81) (82) coupled to the cross bolt (80) and in close contact with the ends of the protruding rods (71) (72);
Cable support device for underground distribution, characterized in that it comprises a. The method according to claim 1,
Channel coupling portions 54 and 64 that are bent in a direction away from each other from the rear ends of the side plates 50 and 60;
T-type bosses 55 and 65 respectively installed in the channel coupling units 54 and 64;
An inverted hole 27 in the shape of a keyhole formed at regular intervals from each other in the vertical channel 26 installed on the structure wall 25 in the vertical direction, and the T-shaped bosses 55 and 65 are inserted therein;
Cable support device for underground distribution, characterized in that it comprises a.

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