KR102004830B1 - A earthquake-proof rack for mounting server and network apparatus - Google Patents

Abstract

The present invention relates to a seismic rack for a communication device having a seismic performance against an earthquake of magnitude 7 or more while using a light aluminum profile that has been used in the past. The seismic rack for a communication device according to the present invention is installed in a horizontal direction on a lower surface thereof. A lower front frame made of a steel plate material; A main frame of aluminum material vertically coupled to both ends of the front frame; Both front ends are horizontally coupled to the upper end of the main frame, the upper front frame made of a steel sheet material; A lower connecting frame connecting the distal side of the lower front frame and made of a steel plate material; An upper connecting frame connecting the distal side of the upper front frame and made of a steel plate material; It is installed on the connecting portion of the upper and lower front frame and the main frame, the coupling reinforcing bracket for strengthening the coupling of the upper and lower front frame and the main frame; includes.

Description

A-EARTHQUAKE-PROOF RACK FOR MOUNTING SERVER AND NETWORK APPARATUS}

The present invention relates to a seismic rack for a communication device, and more particularly, to a seismic rack for a communication device having a seismic performance against an earthquake of magnitude 7 or more while using a light aluminum profile and a steel plate material without a welded structure. will be.

In general, a communication equipment rack is a mechanism for mounting various communication equipment, such as a communication exchange. In addition, the communication device rack is manufactured based on the international standard, and the communication device rack includes a network communication device rack for mounting network equipment and a server communication device rack for mounting a server.

However, such communication device racks are generally made of aluminum profiles that are lightweight and easy to process. However, the communication device rack made of such aluminum profile has a problem of low seismic performance due to the weak structural stability of the connection portion.

Meanwhile, a seismic rack for compensating the low seismic performance of the general rack is generally manufactured using heavy and thick steel sheets, and has a structure in which the steel sheets are firmly bonded by welding.

Therefore, the conventional seismic rack is very difficult to manufacture, takes a long time, and also has a very heavy disadvantage.

The technical problem to be solved by the present invention is to provide a seismic rack for a communication device having a seismic performance against the earthquake of magnitude 7 or more while using a light aluminum profile used as a main material.

The earthquake-resistant rack for a communication device according to the present invention for solving the above-described technical problems, is installed in the horizontal direction on the lower surface, the lower front frame made of a steel plate material; A main frame of aluminum material vertically coupled to both ends of the front frame; Both front ends are horizontally coupled to the upper end of the main frame, the upper front frame made of a steel sheet material; A lower connecting frame connecting the distal side of the lower front frame and made of a steel plate material; An upper connecting frame connecting the distal side of the upper front frame and made of a steel plate material; It is installed on the connecting portion of the upper and lower front frame and the main frame, the coupling reinforcing bracket for strengthening the coupling of the upper and lower front frame and the main frame; includes.

In the earthquake resistant rack for a communication device according to the present invention, the upper and lower front frames and the upper and lower connection frames are preferably made of cold rolled steel sheets.

In the present invention, the main frame is preferably a profile produced by compressing aluminum.

In addition, the coupling reinforcing bracket in the present invention, the first plate material in close contact with the surface of the upper and lower front frame; A second plate bent vertically to the first plate and adhered to the surface of the main frame; A fixed plate member for fixing the first and second plate members on a side thereof; A first coupling member coupling the first plate and the upper and lower front frames; It is preferable to include; a second coupling member for coupling the second plate and the main frame.

According to the earthquake-resistant rack for communication devices of the present invention, by using a combination of light aluminum profiles and cold rolled steel sheets, which are used in the prior art, sufficient strength can be secured and manufactured by simple assembly without difficult tasks such as welding. It has the advantage of having seismic performance.

1 is a perspective view showing the structure of a seismic rack for a communication device according to an embodiment of the present invention.
Figure 2 is a partial perspective view showing a coupling state of the coupling reinforcing bracket according to an embodiment of the present invention.
Figure 3 is an exploded perspective view showing the configuration of the coupling reinforcement bracket according to an embodiment of the present invention.
Figure 4 is a partial cross-sectional view showing a coupling state of the coupling reinforcing bracket according to an embodiment of the present invention.

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

As shown in FIG. 1, the seismic rack 100 for a communication device according to the present embodiment includes a lower front frame 110, a main frame 120, an upper front frame 130, and a lower connection frame 140. It may be configured to include an upper connection frame 150 and the coupling reinforcement bracket 160.

First, the lower front frame 110, as shown in Figure 1, is installed in the horizontal direction on the lower surface, is a component made of a steel plate material. The lower front frame 110 forms a bottom plate of the seismic rack 100 and is made of a steel plate material for structural stability. In particular, the lower front frame 110 is preferably made of cold rolled steel sheet.

Next, as shown in FIG. 1, the main frame 120 is a component that is vertically coupled to both ends of the front frame 110, and preferably made of aluminum. The main frame 120 serves as a pillar in the earthquake-resistant rack 100 according to the present embodiment, and is preferably made of a profile manufactured by compressing aluminum for sufficient strength and light weight. The aluminum profile is light and has sufficient strength, and has the advantage of easy processing such as bending and cutting.

And the inner surface of the main frame 120, as shown in Figure 2, the installation hole 122 for providing a gap in which the second coupling member 167 is installed for installation of the coupling reinforcing bracket 160 to be described later It is formed long in the vertical direction.

Next, as shown in Figure 1, the upper front frame 130, both ends are horizontally coupled to the upper end of the main frame 120 is installed, is a component made of a steel plate material. That is, the upper front frame 130 is made up and down symmetrical with the lower front frame 110, and constitutes an upper plate (upper plate) of the earthquake-resistant rack (100). The upper front frame 130 is also made of a steel sheet material for sufficient strength and structural stability, in particular, preferably made of cold rolled steel sheet.

Next, as shown in FIG. 1, the lower connection frame 140 connects the distal side portion of the lower front frame 110 and is a component made of a steel plate material. That is, the lower connection frame 140 is combined with the lower front frame 110 to form a lower plate, and is made of a steel plate for sufficient strength and structural stability, in particular cold rolled steel sheet.

Meanwhile, as shown in FIG. 1, the upper connection frame 150 connects the distal side portion of the upper front frame 130 and is a component made of a steel plate material. The upper connection frame 150 is installed symmetrically with the lower connection frame 140, it is combined with the upper front frame 130 to form an upper plate.

Next, the coupling reinforcement bracket 160 is installed at the connecting portion between the upper and lower front frames 110 and 130 and the main frame 120, and the upper and lower front frames 110 and 130 and the main frame 120 are connected to each other. It is the component that strengthens the bond. Therefore, in the present embodiment, the coupling reinforcement bracket 160 is installed at the connection portions of the main frame 120 made of aluminum profiles and the front frames 110 and 130 made of steel, respectively, and serves to increase seismic performance. .

To this end, in this embodiment, the coupling dropping bracket 160 is specifically shown in FIG. 3, the first plate 161, the second plate 162, the fixed plate 163 and 164, and the first coupling member. 168 and the second coupling member 167 may be configured. First, as shown in FIGS. 2 and 3, the first plate 161 is a component in close contact with the surface of the lower front frame 110 or the upper front frame 130. This first plate member 161 is also preferably made of a steel sheet, particularly a cold rolled steel sheet. In this case, a first through hole 165 is formed in the first plate 161 to fasten the first coupling member 168 to be described later. As shown in FIG. 3, the first through hole 165 may be formed of a hexagonal hole for easy fastening of the first coupling member 168.

As shown in FIG. 3, the second plate 162 is bent and installed vertically with the first plate 161 and is a component in close contact with the surface of the main frame 120. Therefore, the first and second plate members 161 and 162 are coupled in a vertically bent state so that the cross-sectional shape has a '-' shape. In this case, the first and second plate members 161 and 162 are preferably structurally stable, in which one plate member is bent.

The second plate 162 is also provided with a second through hole 166 in the thickness direction for fastening the second coupling member 167. Two second through holes 166 are horizontally spaced apart from each other at a predetermined interval and are formed in a circular shape having a diameter through which the second coupling member 167 can pass.

Next, as shown in FIGS. 2 and 3, the fixing plates 163 and 164 are components for fixing the first and second plates 161 and 162 at the sides thereof. Accordingly, the fixed plate members 163 and 164 are provided on both left and right sides of the first and second plate members 161 and 162, respectively, to maintain the bending angles of the first and second plate members 161 and 162. , 2 is firmly coupled to the sides of the plate (161, 162) by welding.

Next, as shown in FIGS. 2 and 3, the first coupling member 168 is a component that couples the first plate 161 and the upper and lower front frames 110 and 130. Specifically, the first coupling member 168 may be composed of a fastening bolt 168a fastened from the lower side to an upper side and a hexagon nut 168b fastened at the first through hole 165 of the first plate 161. Can be. At this time, the hexagon nut 168b is fastened in a state where a lower end is inserted into the hexagonal first through hole 165, and thus, the fastening operation is easy.

In this case, the fastening bolt 168a is installed to be slidable in the front-rear direction while being fastened to the lower front frame 110 and the first plate 161, since the seismic performance may be improved.

Next, as shown in FIGS. 2 and 3, the second coupling member 167 is a component that couples the second plate 162 and the main frame 120. The second coupling member 167 may be specifically configured of the seismic fastening bolt 167b and the fastening plate 167a. In this case, the seismic fastening bolt 167b has a male plate portion 167b for fastening and a tool coupling portion 167e, and a plate having a diameter smaller than that of the male screw portion between the tool coupling portion 167e and the male screw portion 167b. The passage part 167d is formed.

The plate passing portion 167d is provided over the second through hole 166 of the second plate 162 in a state where the second plate 162 (and the main frame 120 are fastened). The small diameter of the portion 167d may impart movement to the second coupling member 167 to prevent the earthquake-resistant rack 100 from being damaged during an earthquake.

In addition, the fastening plate 167a has an elongated plate shape, and a plurality of female screw holes 167c are formed in the vertical direction. The male screw portion 167b is fastened to the female screw hole 167c, and the fastening plate 167a is installed in close contact with a rear surface of the installation hole 122 of the main frame 120. Therefore, the fastening plate 167a may move up and down along the installation hole 122 in a state where the fastening plate 167a is fastened to the second fastening member 167, while preventing the earthquake-resistant rack 100 from being damaged during an earthquake. Maintain a strong bond.

Meanwhile, as illustrated in FIGS. 1 and 2, the seismic rack 100 for a communication device according to the present embodiment may further include an auxiliary coupling member 170. The auxiliary coupling member 170 is a component for strengthening and assisting the lower coupling portion of the lower front frame 110 and the main frame 120 from the outside. Specifically, one end of the auxiliary coupling member 170 is coupled to one end of the lower front frame 120, and the other end is coupled to one end of the main frame 120, so that the lower front frame 120 and the main frame 120 are connected to each other. ) Firmly assists in the engagement of

100: earthquake-resistant rack for a communication device according to an embodiment of the present invention
110: lower front frame 120: main frame
130: upper front frame 140: lower connection frame
150: upper connection frame 160: bonding reinforced bracket

Claims (4)

It is installed in the horizontal direction on the lower surface, the lower front frame made of cold rolled steel;
A main frame vertically coupled to both ends of the lower front frame and formed of a profile manufactured by compressing aluminum;
Both front ends are horizontally coupled to the upper end of the main frame, the upper front frame made of a steel sheet material;
A lower connecting frame connecting the distal side of the lower front frame and made of a steel plate material;
An upper connecting frame connecting the distal side of the upper front frame and made of a steel plate material;
It is installed on the connecting portion of the upper and lower front frame and the main frame, the coupling reinforcing bracket for strengthening the coupling of the upper and lower front frame and the main frame;
The inner surface of the main frame is provided with an installation hole 122 long in the vertical direction,
The coupling reinforcement bracket,
A first plate that is in close contact with the surface of the upper and lower front frames and has a first through hole 165 penetrating in a thickness direction;
A second plate member bent perpendicularly to the first plate member and formed with a second through hole 166 formed to penetrate in the thickness direction and in close contact with the surface of the main frame;
A pair of fixed plate members which are installed by bending and welding the first and second plate members on both sides, and maintaining the bent state of the first and second plate members;
A fastening bolt 168a fastened to penetrate the lower front frame and the first plate from a lower side to an upper side or through the upper front frame and the first plate from an upper side to a lower side thereof, and a first penetration of the first plate 161. A first coupling member including a hexagon nut 168b fastened in the hole 165 and coupling the first plate and the upper and lower front frames to be moved back and forth from the upper and lower front frames;
The fastening plate 167a and the second through hole 166 which are installed to be movable upward and downward in the main frame through the installation hole 122 are vertically movable to be fastened to the fastening plate 167a. A seismic rack for a communication device, comprising: a seismic fastening bolt (167b), the second coupling member coupling the second plate with the main frame. delete delete delete

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