KR102424824B1 - The subrack assembly - Google Patents

Abstract

The present invention defines an inner space, a sub-rack case having a front opening formed in the front side, a pair of mounting flanges disposed to face each other with the front opening interposed therebetween, and disposed inside the sub-rack case, the sub-rack case It is possible to improve the seismic performance of the sub-rack assembly with improved seismic performance by including a reinforcing frame to reinforce the .

Description

Subrack assembly with improved seismic performance {THE SUBRACK ASSEMBLY}

The present invention relates to a subrack assembly having improved seismic performance, and more particularly, to a subrack assembly having improved seismic performance improved seismic performance.

In general, substrates having various functions are used in electronic communication devices such as general-purpose computers, digital exchange systems, and large-capacity monitoring and control devices. For example, a board for a communication module, a board for an I/O module, a board for a power module, etc. may be used. These substrates may be installed inside the sub-rack.

On the other hand, the sub-rack of the nuclear power plant safety level controller is designed to mount various card modules and is installed in the cabinet. The sub-rack has a predetermined size and protects internal components in case of internal vibration or external earthquake. Due to the occurrence of vibrations such as earthquakes, there is a problem in that the sub-rack is separated from the cabinet, or the internal components inside the sub-rack are damaged and displaced by vibration. Therefore, it is important that the sub-rack has excellent seismic performance against vibrations, especially earthquakes. In particular, since vibration is dependent on acceleration according to weight, it is important to secure efficient seismic performance in consideration of this.

An embodiment of the present invention, it is an object of the present invention to provide a sub-rack assembly with improved seismic performance that effectively improves the seismic performance.

In order to achieve the above object, a sub-rack assembly with improved seismic performance according to an embodiment of the present invention defines an internal space, and includes a sub-rack case having a front opening formed in the front surface, and a front opening between the sub-rack assembly. and a pair of mounting flanges disposed to face each other, and a reinforcing frame disposed inside the sub-rack case and reinforcing the sub-rack case.

In addition, the mounting flange is characterized in that it includes a coupling plate coupled to one surface of the sub-rack case, and a fixing plate disposed at an end of the coupling plate.

In addition, one surface of the sub-rack case has a first length with respect to a first direction from the front opening toward the rear of the sub-rack case, and the coupling plate has a second length that is at least half of the first length with respect to the first direction characterized in that

In addition, the reinforcing frame is characterized in that it extends along a direction toward the other from any one of the pair of mounting flanges.

In addition, the sub-rack case includes a pair of side surfaces coupled to a pair of mounting flanges, one end of the reinforcing frame is coupled to any one of the pair of sides, and the other end of the reinforcing frame is the other one of the pair of side surfaces. characterized by combining with

In addition, it characterized in that it further comprises a fastening means fastened to the end of the reinforcing frame along the direction from the outside to the inside of the pair of side surfaces.

In addition, the reinforcing frame is characterized in that it includes a lower reinforcing frame disposed on the lower surface of the sub-rack case, and an upper reinforcing frame disposed on the upper surface of the sub-rack case.

In addition, the reinforcing frame, characterized in that it further comprises a side reinforcing frame disposed on the rear surface facing the front opening.

In addition, it is disposed on the rear surface and further includes a terminal board including terminals, wherein at least a portion of the terminal board is interposed between the side reinforcement frame and the rear surface.

In addition, the sub-rack case further includes a guide rail disposed on at least one of the lower surface and the upper surface, and the lower reinforcing frame or the upper reinforcing frame is covered by the guide rail.

In addition, the sub-rack assembly with improved seismic performance according to another embodiment of the present invention includes a pair of side plates, an upper plate, a lower plate and a rear plate, the sub-rack case defining an internal space and a front opening; A pair of mounting flanges coupled to a pair of side plates, a pair of mounting flanges facing each other, a rotating frame disposed in front of the top plate and rotatably disposed about one axis, and a sub-rack case disposed inside the sub-rack case It is characterized in that it comprises a reinforcing frame for reinforcing the.

In addition, the reinforcing frame is characterized in that it is disposed between the pair of side plates.

According to the present invention, it is possible to prevent damage by ensuring excellent seismic performance while considering factors such as cost and manufacturing.

1 is a perspective view schematically illustrating a sub-rack assembly having improved seismic performance according to an embodiment of the present invention.
FIG. 2 is an exploded perspective view of the sub-rack assembly having improved seismic performance shown in FIG. 1 .
FIG. 3 is a view illustrating the rear plate shown in FIG. 2 .
FIG. 4 is a view showing the lower surface plate shown in FIG. 2 .
FIG. 5 is a view showing the upper plate shown in FIG. 2 .
FIG. 6 is a view showing a side plate and a mounting flange shown in FIG. 2 .

Hereinafter, the sub-rack assembly 1 with improved seismic performance according to a preferred embodiment of the present invention will be described in detail.

1 is a perspective view schematically showing a sub-rack assembly 1 with improved seismic performance according to an embodiment of the present invention, and FIG. 2 is a sub-rack assembly 1 with improved seismic performance shown in FIG. It is an exploded perspective view, FIG. 3 is a view showing the back plate 130 shown in FIG. 2, FIG. 4 is a view showing the lower plate 120 shown in FIG. 2, and FIG. 5 is shown in FIG. It is a view showing the upper surface plate (110).

1 to 5 , the sub-rack assembly 1 with improved seismic performance according to an embodiment of the present invention includes a sub-rack case 10 and a pair of mounting flanges to effectively improve seismic performance against vibration. (20), including a reinforcing frame (30).

The sub-rack case 10 defines an internal space and has a front opening (O) formed on the front side. A pair of mounting flanges 20 are disposed to face each other with the front opening O interposed therebetween. The reinforcing frame 30 is disposed inside the sub-rack case 10 and reinforces the sub-rack case 10 . The reinforcement frame 30 is fastened to the sub-rack case 10 by the fastening means 40 . Accordingly, it is possible to improve the seismic performance by increasing the rigidity of the sub-rack case 10 without changing the weight as much as possible. Here, the fastening means 40 includes screws, bolts, and the like.

In one embodiment, the sub-rack case 10 includes a pair of side plates 100 , an upper plate 110 , a lower plate 120 , and a rear plate 130 . A pair of side plates 100 are disposed to face each other. The upper plate 110 is disposed on the upper end of the side plate 100 , and the lower plate 120 is disposed on the lower end of the side plate 100 . The rear plate 130 is disposed on the edges of the side plate 100 , the upper plate 110 , and the lower plate 120 .

The mounting flange 20 is coupled to overlap the side surface of the sub-rack case 10 . The mounting flange 20 may extend above and below the front opening O of the sub-rack case 10 . In an embodiment, the mounting flange 20 may include a coupling plate 200 and a fixing plate 210 . The coupling plate 200 is coupled to overlap one side (side) of the sub-rack case 10 . That is, the coupling plate 200 is coupled to be in face-to-face contact with the sub-rack case 10 . The fixing plate 210 is disposed at the end of the coupling plate 200 . The fixing plate 210 may be disposed perpendicular to the coupling plate 200 .

An embodiment of the present invention may further include a terminal board 50 , a guide rail 60 , and a rotation frame 70 . At least one terminal board 50 may be disposed on the rear plate 130 . The guide rail 60 is disposed under the sub-rack case 10 . That is, the guide rail 60 may be disposed on the lower surface plate 120 . The terminal board 50 includes a terminal 51 . The PCB substrate (not shown) may be guided through the guide rail 60 and mounted on the terminal 51 .

FIG. 6 is a view showing the side plate 100 and the mounting flange 20 shown in FIG. 2 .

1 to 6 , the mounting flange 20 may be mounted in a separate cabinet (frame) to fix the sub-rack assembly 1 having improved seismic performance. To this end, the mounting flange 20 may have a fastening hole 211 . Stress due to vibration is concentrated on the fixing plate 210 of the mounting flange 20 , in particular, the fastening hole 211 . Accordingly, when vibration occurs, the mounting flange 20 is easily damaged. According to the present invention, the coupling plate 200 is coupled face-to-face to the side plate 100 , it is possible to relieve the stress of the fixing plate 210 . Accordingly, the seismic performance is improved.

In one embodiment, the coupling plate 200 is extended by a predetermined length along one edge of the sub-rack case (10). Specifically, one surface (side) of the sub-rack case 10 has a first length L1 based on the first direction X1 from the front opening O toward the rear of the sub-rack case 10 . The coupling plate 200 has a second length L2 that is at least half of the first length L1 based on the first direction X1. At this time, the height (direction perpendicular to the first direction) of one surface of the coupling plate 200 and the sub-rack case 10 may be the same. Thereby, the stress concentration of the mounting flange 20 can be relieved. As an example, it was shown that the stress measured around the fastening hole 211 of the fixing plate 210 was significantly reduced from 153 MPa to 33.68 MPa.

The reinforcing frame 30 may extend along a direction (second direction X2) from any one of the pair of mounting flanges 20 to the other. In addition, the reinforcing frame 30 may be disposed between both ends of the plate 120 with respect to the first direction X1. In one embodiment, one end of the reinforcing frame 30 is coupled to any one of a pair of side plates 100 of the sub-rack case 10 , and the other end of the reinforcing frame 30 is a pair of side plates 100 . combine with the other of The reinforcing frame 30 improves seismic performance in the longitudinal direction of the reinforcing frame 30 . Thereby, the maximum stress is generated in the side plate 100 , and thus it is possible to prevent separation (damage) of the terminal board 50 and the like disposed inside the sub-rack case 10 .

In one embodiment, the reinforcing frame 30 may include a lower reinforcing frame 300 . In addition, the reinforcing frame 30 may further include an upper reinforcing frame 310 and a side reinforcing frame 320 . The lower reinforcement frame 300 is disposed on the lower surface plate 120 of the sub-rack case 10 . The lower reinforcement frame 300 may improve the seismic performance of the lower plate 120 to prevent separation (damage) of the guide rail 60 and the like.

The upper reinforcement frame 310 is disposed on the upper surface of the sub-rack case 10 . The upper reinforcing frame 310 may improve the seismic performance of the upper plate 110 to prevent separation (damage) of the guide rail 60 disposed on the upper reinforcing frame 310 .

On the other hand, the guide rail 60 is disposed above the lower reinforcement frame (300). In addition, the guide rail 60 is disposed under the upper reinforcing frame 310 . That is, the guide rail 60 is disposed to cover the lower reinforcing frame 300 and the upper reinforcing frame 310 . In addition, the guide rail 60 may be bolted or screwed directly or indirectly to the lower reinforcing frame 300 or the upper reinforcing frame 310 . When indirectly connected, the guide rail 60 may be fastened to the reinforcing frame 30 through the fixed frame 61 . Accordingly, the seismic performance of the guide rail 60 may be improved.

The side reinforcement frame 320 is disposed on the rear surface facing the front opening (O). At least a portion of the terminal board 50 is interposed between the side reinforcement frame 320 and the rear plate 130 . That is, the side reinforcement frame 320 is disposed to cover at least a portion of the terminal board 50 . Thereby, detachment (damage) of the terminal board 50 can be prevented. On the other hand, when the pair of terminal boards 50 are vertically disposed on the rear plate 130 , the side reinforcement frame 320 may be disposed to cover adjacently disposed edges of the pair of terminal boards 50 . .

The rotating frame 70 is disposed in front of the upper plate 110 . The rotating frame 70 is rotatably disposed based on one axis parallel to the longitudinal direction of the reinforcing frame 30 . In one embodiment, the rotation frame 70 may be rotatably connected to a pair of mounting flanges 20 or a pair of side plates 100 . The rotating frame 70 may open or shield the upper portion of the front opening O of the sub-rack case 10 by its rotation. Thereby, it is possible to increase the security of the sub-rack assembly 1 with improved seismic performance.

On the other hand, an embodiment of the present invention may further include a fastening means (40). The fastening means 40 is fastened to the end of the reinforcing frame 30 along the direction X2 from the outside to the inside of the pair of side plates 100 . Vibration may vibrate up and down based on the longitudinal direction of the reinforcing frame 30 . Therefore, when the fastening means 40 is fastened in the vertical direction of the reinforcing frame 30, it may be separated and damaged by vibration. In the case of the present invention, since the fastening means 40 is fastened in the longitudinal direction of the reinforcing frame 30 , the seismic performance of the reinforcing frame 30 in the longitudinal direction is improved.

Although the invention made by the present inventors has been described in detail according to the above embodiments, the present invention is not limited to the above embodiments, and various modifications can be made without departing from the gist of the present invention.

1: Sub-rack assembly with improved seismic performance
10: sub rack case
100: side plate
110: top plate
120: lower plate
130: back plate
20: mounting flange
200: coupling plate
210: fixed plate
30: reinforcement frame
300: lower reinforcement frame
310: upper reinforcement frame
320: side reinforcement frame
40: fastening means
50: terminal board
60: guide rail
70: rotating frame

Claims (12)

a sub-rack case defining an inner space and having a front opening formed in the front;
a pair of mounting flanges facing each other with a front opening therebetween; and
It is disposed inside the sub-rack case, and includes a reinforcing frame for reinforcing the sub-rack case,
mounting flange,
a coupling plate coupled to one side of the sub-rack case; and
Comprising a fixed plate disposed at the end of the coupling plate,
One surface of the sub-rack case has a first length based on a first direction from the front opening toward the rear of the sub-rack case,
The coupling plate has a second length that is more than half the first length based on the first direction, and the sub-rack assembly has improved seismic performance for relieving stress concentration of the mounting flange. delete delete The method of claim 1,
The reinforcing frame is a sub-rack assembly with improved seismic performance extending along the direction from one of the pair of mounting flanges to the other. The method of claim 1,
The subrack case includes a pair of sides that engage a pair of mounting flanges;
One end of the reinforcement frame is combined with any one of the pair of sides,
A sub-rack assembly with improved seismic performance in which the other end of the reinforcing frame is combined with the other one of the pair of sides. 6. The method of claim 5,
The sub-rack assembly with improved seismic performance further comprising a fastening means fastened to the end of the reinforcing frame along a direction from the outside to the inside of the pair of side surfaces. The method of claim 1,
reinforcement frame,
a lower reinforcement frame disposed on the lower surface of the sub-rack case; and
A sub-rack assembly with improved seismic performance including an upper reinforcement frame disposed on the upper surface of the sub-rack case. 8. The method of claim 7,
reinforcement frame,
A sub-rack assembly with improved seismic performance further comprising a side reinforcement frame disposed on the rear surface facing the front opening. 9. The method of claim 8,
It is disposed on the rear surface, further comprising a terminal board comprising a terminal,
At least a portion of the terminal board is interposed between the side reinforcement frame and the rear sub-rack assembly with improved seismic performance. 8. The method of claim 7,
It further includes a guide rail disposed on at least one of the lower surface and the upper surface of the sub-rack case,
The lower reinforcing frame or upper reinforcing frame is a sub-rack assembly with improved seismic performance covered by guide rails. delete delete

Images