KR102079007B1 - Earthquake-proof system for data center using integrated ceiling-floor-rack structure - Google Patents

Abstract

The present invention relates to an earthquake-resistant system of a data center using an integrated ceiling-floor-seismic rack structure, an earthquake-resistant rack made of high-strength steel and storing computational equipment therein, and seismic vibrations transmitted from the upper portion to the earthquake-resistant rack. It consists of a seismic and seismic unit that separates the seismic vibrations transmitted from the lower layer, and a seismic and seismic unit that separates the seismic rack from the seismic rack. The data center can be effectively stopped due to damage.
In addition, according to the present invention, the earthquake vibration transmitted from the upper floor slab damps its influence by the damper function of the cloth / seismic unit, and the earthquake vibration transmitted from the lower floor slab can be separated from the impact by the seismic isolation function of the ground / seismic unit. Which has an excellent seismic effect.

Description

Seismic system of data center using integrated ceiling-floor-seismic rack structure {EARTHQUAKE-PROOF SYSTEM FOR DATA CENTER USING INTEGRATED CEILING-FLOOR-RACK STRUCTURE}

The present invention relates to an earthquake-resistant system of a data center using an integrated ceiling-floor-seismic rack structure, and more specifically, an earthquake-resistant rack made of high-strength steel and storing computation equipment therein, and seismic vibration transmitted from the upper layer. It consists of a cloth and a seismic unit separating the seismic rack, and a seismic and seismic unit separating seismic vibrations transmitted from the lower layer from the seismic rack, safely storing computer equipment in operation, and computing equipment from left and right vibrations in the event of an earthquake. It relates to the seismic system of the data center using the integrated ceiling-floor-seismic rack structure of a new structure that can effectively prevent the data center from being interrupted by seismic damage.

Starting with the mechanized revolution (industrial revolution) based on the invention of the steam engine in the 18th century, the mass production revolution based on electric energy in the early 19th and 20th centuries passed, and in the second half of the 20th century, the computer and internet-based knowledge and information revolution passed. have.

On the other hand, in the 21st century, artificial intelligence (AI) and ICBM (Internet of Things, cloud computing, big data, and mobile) are the key technologies that trigger the 4th Industrial Revolution. Experts are convinced that when they successfully converge and develop the industry, they can lead in the upcoming fourth industrial revolution.

In Korea, the size of the data industry is increasing every year, and by 2016, it is estimated to be about 2,300 trillion won.In the future, as the cloud, big data, artificial intelligence (AI), and mobile services will emerge, the size of the data industry will increase. It is expected to grow bigger.

Of these, in the case of big data, the hardware foundation called a data center must be accompanied, and the data center can be said to be the core infrastructure for storing and distributing big data, and it is also considered to be the future base of the fourth industrial revolution in the future.

In the case of major domestic companies, there are 136 data centers including NAVER's data centers (each), LG CSN, Hana Financial Group, Cheongna District, Samsung SDS Chuncheon Data Center, etc. It is expected to increase.

On the other hand, due to the nature of the data center that needs to be continuously operated for 24 hours, earthquake disaster is a fatal factor that can lead to downtime.In fact, when the earthquake occurred in Gyeongju, Kakao Talk stopped service due to excessive traffic, and users were in great confusion. There are examples, and each data center is investing heavily in protecting data from earthquakes and other disasters.

Computer equipment used for data storage in these data centers is generally stored in a seismic rack. First, once the design and construction of the data center is completed, contracts with the ceiling material installation company, seismic rack installation company, and floor material contractor are signed. Construction is progressed through.

In the existing method described above, in the process of designing and constructing data centers, ceiling contractors, earthquake-resistant racks, and floor contractors are often different from each other, and this multi-contract acts as a factor that decreases the efficiency of maintenance and work.

In addition, the compatibility between each product is often low, so even if each product has seismic performance, it is very difficult to understand the overall seismic performance in advance when the actual installation is completed. Doing.

First, in accordance with Chapter 4, Article 15 (Judgment Standards) of Seismic Test Method of Telecommunication Equipment, lateral displacement is limited to a maximum of 75mm displacement due to earthquake.

Second, in the event of an earthquake, secondary damage may occur due to the fall of the seismic rack due to the collapse of the ceiling finish of the flooring.

Third, the difference in stiffness caused by the use of heterogeneous materials between the rack and the flooring may cause damage during an earthquake regardless of the stiffness of the rack.

Fourth, it is difficult to maintain, maintain, and manage the inefficiency of construction due to the division of labor of companies that install ceilings, racks, and flooring materials.

Accordingly, there is a growing need to develop new technologies for a new structured earthquake-resistant rack system for data centers that can solve all the above problems and provide reliable stability against earthquakes.

Registered Patent 10-1639658 (announced on July 14, 2016)

The present invention was created to solve the problems of the prior art, and more specifically, it is made of high-strength steel and seismic racks storing computer equipment therein and seismic vibrations transmitted from the upper layer are separated from the seismic racks. It consists of a cloth / seismic unit and a seismic / seismic unit that separates seismic vibrations transmitted from the lower layer from the seismic rack, safely storing the computerized equipment in operation, and separating the computerized equipment from the left and right vibrations in the event of an earthquake to prevent earthquake damage. It is an object of the present invention to provide an earthquake-resistant system in a data center using an integrated ceiling-floor-seismic rack structure that can effectively prevent data center outages.

According to a preferred embodiment of the present invention, it is installed in the space inside the data center to safely store the computer equipment (D) in operation, and in the event of an earthquake, it separates the computer equipment (D) from the left and right vibrations, resulting in a data center caused by earthquake damage. In the seismic system provided to prevent the stoppage of the operation, the seismic system uses the plurality of frames made of aluminum or steel to store the computer equipment (D) therein, and the shape of the computer equipment (D). Seismic rack 100 is assembled to correspond to the; A cloth / seismic unit 200 installed between the seismic rack 100 and the upper layer slab and separating the earthquake vibration transmitted from the upper layer part from the seismic rack 100; It is installed between the lower floor slab and the seismic rack (100), seismic vibration transmitted from the lower layer seismic rack (100) separating the seismic rack (100); characterized in that consisting of.

According to another embodiment of the present invention, an upper side of the seismic rack 100 is provided with a base plate 110 to be connected to the cloth / seismic unit 200, and an image of the base plate 110. It is characterized in that a damper unit 120 is provided between the side surface and the cloth / seismic unit 200 to control the vibration of the upper slab due to the earthquake.

According to another embodiment of the present invention, the cloth / seismic unit 200 includes a truss unit 210 formed of a V-shaped high-strength steel made of aluminum or steel, and the truss unit 210 is an upper layer. It consists of hinge units (220A, 220B, 220C) to be combined with damper units (120) of the slab and seismic rack (100), and some of the hinge units (220A, 220B) are installed on the upper slab to form a V-shape. It is characterized in that it is coupled to both ends of the truss unit 210 of the shape, and the rest 220C is coupled to the upper surface of the damper unit 120 and connected to the vertex of the truss unit 210.

According to another embodiment of the present invention, the hinge unit 220 is a ball-type hinge device that can be rotated 360 degrees to allow seismic control of the composite vibration in the vertical and horizontal directions according to the earthquake. It is characterized by being provided.

According to another embodiment of the present invention, the earthquake and seismic unit 300 includes a support member 310 fixed to the lower layer slab; A slide member 320 provided on the upper side of the support member 310 to slide in the front-rear direction by the guide member 330, and the seismic rack 100 mounted on the upper surface; And a damping means 340 connected to the slide member 320 to attenuate vibration of the slide member 320 due to an earthquake.

According to another embodiment of the present invention, the guide member 330 is a pair of first guide rails 331 provided to extend in the front-rear direction on the upper surface of the support member 310, and the first guide rail It characterized in that it comprises a second guide rail 332 is provided to extend in the lateral direction on the upper side of the (331) slides in the front-rear direction along the first guide rail (331).

According to another embodiment of the present invention, the slide member 320 is characterized in that slidably coupled to the upper surface of the second guide rail 332 in the lateral direction.

According to another embodiment of the present invention, the damping means 340 includes an extension bar 341 extending downward from the circumferential surface of the slide member 320; A support case 342 provided to extend upward from the circumference of the support member 310 and having an opening 342a formed on the upper surface; A support block (343) having a friction groove (343a) in which the lower end of the extension bar (341) is in close contact with the inside of the support case (342) to be elevated; It is characterized in that it comprises; an elastic member 344 which is located below the support block 343 and elastically presses the support block 343 upward.

According to another embodiment of the present invention, the extension bar 341 is in close contact with the friction groove 343a of the support block 343 through the opening 342a of the support case 342, and the friction groove (343a) is characterized in that it is configured to have a concave arc-shaped cross-section downward.

Meanwhile, the present invention may be modified in various ways and may have various embodiments, and specific embodiments will be described in detail in the detailed description. However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

Also, the terms used in the present invention are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In the present application, terms such as “include” or “have” are intended to designate the existence of features, numbers, steps, operations, components, parts, or combinations thereof described in the specification, and one or more other features. It should be understood that the existence or addition possibilities of fields or numbers, steps, operations, components, parts or combinations thereof are not excluded in advance.

According to the present invention, the seismic system of the data center using the integrated ceiling-floor-seismic rack structure has the following effects.

First, through the combination of the ceiling-floor-seismic rack in the data center, it is possible to realize a displacement width lower than the displacement width of 75 mm, which is the current seismic test standard.

Second, by integrating the seismic system with high-strength steel, it is possible to improve seismic and seismic performance, and to prevent damage to the computer equipment (D) due to an earthquake and the fall of the seismic rack.

Third, the efficiency of construction, maintenance, and management can be improved through standardization and standardization of bonding materials such as integrated seismic systems and high-strength steels connected by hinged joints.

1 is a reference diagram showing the installation structure of a rack for a data center according to the prior art,
Figure 2 is a perspective view showing the configuration of a seismic system of a data center using an integrated ceiling-floor-seismic rack structure according to the present invention,
3 is a front view for explaining the seismic system of FIG. 2,
Figure 4 is a side view for explaining the earthquake-resistant system of Figure 2,
5 is a rear view for explaining the seismic system of FIG. 2,
Figure 6 is a reference diagram showing a state in which the seismic system according to the present invention is integrally connected to the upper and lower slabs of the data center,
7 is a plan view showing a seismic and seismic unit of the seismic system according to the present invention;
8 is a front view showing a seismic and seismic unit of the seismic system according to the present invention,
Figure 9 is a side view showing the seismic and seismic unit of the seismic system according to the present invention,
Figure 10 is a reference diagram showing the action of the earthquake-proof and seismic unit of the seismic system according to the present invention,
11 is a reference diagram for explaining the material properties used to manufacture the earthquake-resistant rack of the present invention.

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

Figure 2 is a perspective view showing the configuration of a seismic system of a data center using an integrated ceiling-floor-seismic rack structure according to the present invention.

As shown in Figure 2, the present invention is installed in the space inside the data center to safely store the computer equipment (D) in operation, and seismic damage by separating the computer equipment (D) from the left and right vibration in the event of an earthquake Regarding the seismic system provided to prevent the data center from being shut down, the seismic system is largely composed of a seismic rack 100, a cloth / seismic unit 200, and a seismic / seismic unit 300.

Hereinafter, with reference to the accompanying drawings, the seismic rack 100 and the cloth / seismic unit 200 and the seismic / seismic unit 300 will be described in detail.

Figure 2 is a perspective view showing the configuration of the earthquake-resistant system of the data center using the integrated ceiling-floor-seismic rack structure according to the present invention, Figure 3 is a front view for explaining the earthquake-resistant system of Figure 2, Figure 4 is Figure 2 Side view for explaining the seismic system, FIG. 5 is a rear view for explaining the seismic system of FIG. 2.

As illustrated in FIGS. 2 to 5, first, the earthquake-resistant rack 100 uses a plurality of frames made of aluminum or steel material to store the computer equipment D therein. It is a member assembled to correspond to the shape of).

The aluminum or steel used in the plurality of frames is preferably made of a high-strength steel material that satisfies the material specification shown in FIG. 11 so as not to bend or bend even in the event of a massive earthquake.

However, within the scope that can achieve the object and function of the present invention, it does not exclude the use of materials other than the high-strength steel as exemplified above, rather, it will be said to be entirely included in the scope of the technical spirit of the present invention. .

The upper plate of the seismic rack 100 is provided with a base plate 110 to be connected to the cloth and seismic unit 200.

In addition, a damper unit 120 is provided between the upper surface of the base plate 110 and the cloth / seismic unit 200 to control the vibration of the upper slab due to the earthquake.

Next, the cloth / seismic unit 200 is installed between the seismic rack 100 and the upper slab, and is a member that separates the earthquake vibration transmitted from the upper layer from the seismic rack 100.

Specifically, the cloth / seismic unit 200 is composed of a truss unit 210 and a hinge unit (220A, 220B, 220C).

At this time, the truss unit 210 is a member made of a high-strength steel material made of aluminum or steel in a V shape.

Further, the hinge units 220A, 220B, and 220C are members for the truss unit 210 to be coupled to the damper units 120 of the upper slab and the seismic rack 100, respectively.

To explain the coupling method of the truss unit 210 and the hinge units 220A, 220B, 220C, first, some of the hinge units 220A, 220B are installed on the upper slab to form a V-shaped truss unit 210 ).

Then, the rest 220C is coupled to the upper side of the damper unit 120 to be connected to the vertex of the truss unit 210.

On the other hand, although not shown in the drawing, the hinge unit 220 is provided with a ball-type hinge device that can be rotated 360 degrees to allow seismic control of the composite vibration in the vertical and horizontal directions according to the earthquake. It is preferred.

Likewise, the hinge unit 220 is also not intended to exclude the use of hinge devices of different times within the range capable of achieving the object and function of the present invention, in addition to the ball type, and is generally known as a hinge device. It will be said that the use of is also within the scope of the present invention.

Next, FIG. 7 is a plan view showing the earthquake-resistant unit of the earthquake-resistant system according to the present invention, FIG. 8 is a front view illustrating the earthquake-resistant unit of the earthquake-resistant system according to the present invention, and FIG. 9 is earthquake-resistant according to the present invention It is a side view showing the earthquake and seismic unit of the system.

7 to 9, the ground / seismic unit 300 is installed between the lower floor slab and the seismic rack 100, and the seismic vibration transmitted from the lower layer is connected to the seismic rack 100. It is a member to separate.

The earthquake-proof and seismic unit 300 is provided on the upper side of the support member 310 so that the support member 310 fixed to the lower layer slab and the guide member 330 can slide forward and backward. It is composed of a slide member 320 on which the earthquake-resistant rack 100 is placed, and a damping means 340 connected to the slide member 320 to damp vibration of the slide member 320 due to an earthquake.

The support member 310 is formed of a rectangular plate shape of a high-strength metal material and is fixed to the upper surface of the lower layer slab.

The guide member 330 is a pair of first guide rail 331 provided to extend in the front-rear direction on the upper surface of the support member 310, and extends laterally to the upper side of the first guide rail 331 It is provided so as to be composed of a second guide rail 332 that slides in the front-rear direction along the first guide rail 331.

The slide panel 320 is composed of a rectangular plate shape of a metal material having a slightly smaller area than the support member 310, and is slidably coupled to the upper surface of the second guide rail 332 in the lateral direction.

Therefore, when the support member 310 vibrates in the front-rear or left-right direction due to an earthquake, the second guide rail 332 slides in the front-rear direction along the first guide rail 331.

Then, the slide panel 320 is slid in the lateral direction along the second guide rail 332, thereby minimizing the vibration of the support member 310 to be transmitted to the slide panel 320.

The damping means 340 is provided to extend upwardly from the circumferential portion of the support member 310 and an extension bar 341 extending downward from the circumferential surface of the slide panel 320, and an opening 342a on the upper surface. The support case 342 is formed, the support block 343 coupled to be liftable inside the support case 342, and is located below the support block 343, the support block 343 is burnt upward. It is composed of an elastic member 344 for sexually pressing.

The extension bar 341 is formed of a circular metal material having a high angle, and is composed of four, extending downward from each corner of the slide panel 320.

The support case 342 is composed of a cylindrical shape extending in the vertical direction, the opening 342a is formed in a circular shape on the upper surface of the support member 310.

The support block 343 is composed of a circular block shape extending in the vertical direction, and a friction groove 343a in which the lower end of the extension bar 341 is closely contacted is formed concave downward in the center of the upper surface.

The friction groove 343a is configured to have an arc-shaped cross-sectional shape concave downward.

The elastic member 344 is provided to extend in the vertical direction inside the support case 342 to support the lower surface of the support block 343 to compress the compression coil so that the support block 343 is elastically raised Use spring.

And Figure 10 is a reference diagram showing the operation of the earthquake-resistant seismic unit of the seismic system according to the present invention.

As shown in FIG. 10, the extension bar 341 is located at the center of the friction groove 343a, that is, at the deepest position, and the earthquake causes the support member 310 to move forward or backward. When vibrated by, the extension bar 341 moves outside the friction groove 343a, that is, to a low depth position.

At this time, the support block 343 is lowered while compressing the elastic member 344 due to the shape of the friction groove 343a, thereby isolating the relative movement of the extension bar 341 and the slide member 320 Will do.

Finally, Figure 6 is a reference diagram showing a state in which the seismic system according to the present invention is integrally connected to the upper and lower slabs of the data center.

Therefore, as shown in FIG. 6, the earthquake-resistant system of the data center according to the present invention is composed of a seismic rack 100, a cloth-seismic unit 200, and a ground-seismic unit 300, but the ceiling-bottom. -As the seismic rack structure is integrated and installed, the seismic vibration transmitted from the upper floor slab dampens its influence by the damper function of the cloth / seismic unit 200, and the seismic vibration transmitted from the lower floor slab is the earthquake and seismic unit. The effect can be separated by the seismic isolation function of 300.

That is, the computer equipment stored in the seismic rack 100 integrally connected between the cloth / seismic unit 200 and the seismic / seismic unit 300 by the above-described operation is affected by earthquake vibration. The shaking and movement according to it is minimized, it is possible to prevent the physical damage caused by the computer equipment (D) to fall or bump.

Although the present invention has been described with reference to the embodiments shown in the drawings, these are merely exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

100: earthquake-resistant rack 110: base plate
120: damper unit
200: cloth / seismic unit 210: truss unit
220A, 220B, 220C: hinge unit
300: Earthquake-resistant unit 310: Support member
320: slide member 330: guide member
340: damping means

Claims (7)

It is installed in the space inside the data center to safely store the computer equipment (D) in operation, and when the earthquake occurs, the computer equipment (D) is separated from the left and right vibrations to prevent the data center from being shut down due to earthquake damage. The system includes a seismic rack 100 assembled to correspond to the shape of the computer equipment D using a plurality of frames made of aluminum or steel to store the computer equipment D therein; A cloth / seismic unit 200 installed between the seismic rack 100 and the upper layer slab and separating the earthquake vibration transmitted from the upper layer part from the seismic rack 100; In the seismic system, which is installed between the lower floor slab and the seismic rack (100), seismic vibration transmitted from the lower layer separating the seismic rack (100) seismic unit (300);
The earthquake-proof and seismic unit 300 includes a support member 310 fixed to the lower layer slab; A slide member 320 provided on the upper side of the support member 310 to slide in the front-rear direction by the guide member 330, and the seismic rack 100 mounted on the upper surface; Includes; connected to the slide member 320, damping means 340 to attenuate the vibration of the slide member 320 due to earthquake occurrence;
The guide member 330 is a pair of first guide rail 331 provided to extend in the front-rear direction on the upper surface of the support member 310, and extends laterally to the upper side of the first guide rail 331 It is provided so as to include a second guide rail 332 that slides in the front-rear direction along the first guide rail 331, the slide member 320 slides laterally on the upper surface of the second guide rail 332 Are possibly combined,
The damping means 340 includes an extension bar 341 extending downward from the circumferential surface of the slide member 320; A support case 342 provided to extend upward from the circumference of the support member 310 and having an opening 342a formed on the upper surface; A support block (343) having a friction groove (343a) in which the lower end of the extension bar (341) is in close contact with the inside of the support case (342) to be elevated; It includes; elastic member 344 which is located on the lower side of the support block 343 and elastically presses the support block 343 upwards.
The extension bar 341 is in close contact with the friction groove 343a of the support block 343 through the opening 342a of the support case 342, and the friction groove 343a is an arc-shaped cross section concave downward. It is configured to have, when the support member 310 vibrates in the front-rear or left-right direction by an earthquake, the extension bar 341 moves outward from the center of the friction groove 343a, and is supported by the shape of the friction groove 343a. Block 343 is lowered while compressing the elastic member 344 of the data center using the integrated ceiling-floor-seismic rack structure, characterized in that configured to damp the vibration of the extension bar 341 and the slide member 320 Seismic system.
According to claim 1,
The upper side of the seismic rack 100 is provided with a base plate 110 for connection with the fabric and seismic unit 200, the upper side of the base plate 110 and the fabric and seismic unit 200 Between there is a damper unit 120 for controlling the vibration of the upper floor slab due to the earthquake, the data center seismic system using an integrated ceiling-floor-seismic rack structure.
According to claim 1,
The cloth / seismic unit 200 is
Truss unit 210 made of V-shaped high-strength steel made of aluminum or steel, and hinges for the truss unit 210 to be combined with the upper slab and the damper unit 120 of the seismic rack 100, respectively. It consists of units (220A, 220B, 220C),
Some of the hinge units (220A, 220B) are installed on the upper portion of the slab is coupled to both ends of the V-shaped truss unit 210, the rest (220C) is coupled to the upper surface of the damper unit 120 truss Seismic system of the data center using the integrated ceiling-floor-seismic rack structure characterized in that it is connected to the vertex of the unit 210.
The method of claim 3,
The hinge unit 220 is an integrated ceiling characterized in that it is provided with a ball-type hinge device capable of 360-degree rotation to allow seismic control of the composite vibration in the vertical and horizontal directions according to the earthquake. Seismic system of data center using floor-seismic rack structure.
delete delete delete

Images