CN215421022U - Container data center modular framework and data center - Google Patents

Abstract

The utility model discloses a container data center modular architecture and a data center, and relates to the technical field of data center structures. The container data center modular framework comprises two groups of data integration units, wherein each group of integration units is composed of a plurality of integration modules, and each integration module comprises: the lower box body is used for arranging a data center cabinet; the upper box body is connected above the lower box body; the positioning and locking structure is arranged between the upper box body and the lower box body so as to fix the lower box body on the upper box body; and the air conditioning module is arranged on one side of the upper box body and is respectively communicated with the upper box body and the lower box body. The utility model can solve the problems of complex construction and long construction period of the existing data center.

Description

Container data center modular framework and data center

Technical Field

The utility model relates to the technical field of data center structures, in particular to a container data center modular framework and a data center.

Background

At present, data center construction is rapidly developed, and data center is as a building body, and conventional structural style such as reinforced concrete structure and steel construction are adopted to major structure mostly. After the main structure is built, cabinet server equipment, power transformation and distribution equipment, air conditioning equipment, fire fighting equipment, decoration and the like required by the data center are arranged in the structure body to form the function of the data center.

In recent years, the demand of data centers at home and abroad is gradually increased, and the conventional structural forms such as reinforced concrete structures or steel structures sometimes cannot meet the requirement of rapid construction and production; moreover, the construction environment of the construction site is generally poor, the workers are in short supply, the labor cost is continuously increased, and the conventional structure cannot be built in a factory.

The conventional structure needs to be subjected to complicated construction on site, such as a reinforced concrete structure, steel bars need to be bound and concrete needs to be poured on site, the construction is complicated, constructors need to have certain skills, and the site construction time is long; for example, in a steel structure, although a lot of components are processed in a factory, adjustment and installation on site are required, installation is complex, special connection is required, and installation time is long, so that a construction period of a data center is long.

SUMMERY OF THE UTILITY MODEL

In order to solve the problems in the prior art, the embodiment of the utility model provides a container data center modular architecture and a data center. The technical scheme is as follows:

in a first aspect, a modular architecture for a container data center is provided, which includes two sets of data integration units, each set of integration units is composed of a plurality of integration modules, and each integration module includes:

the lower box body is used for arranging a data center cabinet;

the upper box body is connected above the lower box body;

the positioning and locking structure is arranged between the upper box body and the lower box body so as to fix the lower box body on the upper box body;

and the air conditioning module is arranged on one side of the upper box body and is respectively communicated with the upper box body and the lower box body.

In one embodiment, the positioning and locking structure comprises:

the positioning groove is arranged at the edge of the lower box body, and a baffle is arranged at the edge of one end of the positioning groove;

the limiting rod piece is connected to the edge of the upper box body and is connected in the positioning groove in a sliding manner;

the sliding wheel is connected to the limiting rod piece and can be connected to the bottom of the positioning groove in a rolling mode;

the sliding wheel and the limiting rod piece are arranged in the positioning groove, when one end of the limiting rod piece is abutted to the baffle, the other end of the limiting rod piece extends into the positioning groove, and the edge of the upper box body is aligned with the edge of the upper box body.

In one embodiment, a sealing glue layer is arranged between the limiting rod piece and the side wall of the positioning groove.

In one embodiment, the outer wall of the positioning groove and the limiting rod piece are respectively provided with a threaded hole;

the limiting rod piece is arranged in the positioning groove in a sliding mode, when one end of the limiting rod piece is abutted to the baffle, the threaded hole in the outer wall of the positioning groove is aligned with the threaded hole in the limiting rod piece, and a bolt is connected between the outer wall of the positioning groove and the threaded hole of the limiting rod piece.

In one embodiment, a gap is formed between each two corresponding integrated modules of the two sets of data integration units.

In one embodiment, the container data center modular architecture further comprises service corridors disposed on two side edges within the upper box.

In one embodiment, the modular container data center architecture further comprises a routing bridge disposed on one side of the lower cabinet.

In one embodiment, the container data center modular framework further comprises an arc-shaped steel plate roof, the arc-shaped steel plate roof is arranged between the two sets of data integration units, and two ends of the arc-shaped steel plate roof are respectively connected to the edges of the upper box bodies of the two adjacent integration modules.

In one embodiment, the container data center modular architecture further comprises a first diagonal brace attached to an upper box side wall and a second diagonal brace attached to a lower box side wall;

two first inclined struts are arranged on the side wall of the upper box body, one ends of the two first inclined struts are respectively connected to the upper end corner of the upper box body, and the other ends of the two first inclined struts are connected to the lower end edge of the upper box body;

the second bracing on the lower box lateral wall is provided with two, two the one end of second bracing connect respectively in on the lower extreme corner of box down, the other end connect in the upper end edge of box down.

In a second aspect, a data center is provided, which includes the modular architecture of the container data center in any one of the above embodiments.

The technical scheme provided by the embodiment of the utility model has the following beneficial effects:

in the embodiment of the utility model, through the arrangement of the upper box body and the lower box body, when the data center is constructed, the preset lower box body and the upper box body can be directly spliced, the air conditioning module is installed, then the edges of the upper box body and the lower box body can be aligned with each other after the upper box body and the lower box body are spliced by the positioning and locking structure, and then the upper box body and the lower box body can be stably fixed by the structure.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

Fig. 1 is a schematic overall structural diagram of a container data center modular architecture provided by an embodiment of the present invention;

FIG. 2 is a schematic front view of a modular architecture of a container data center provided by an embodiment of the utility model;

fig. 3 is a schematic cross-sectional structural diagram of the modular structure of the container data center at the upper box and the lower box according to the embodiment of the present invention

FIG. 4 is a schematic cross-sectional view of a container data center modular framework provided by an embodiment of the present invention with the upper housing fully secured to the lower housing at the alignment lock;

fig. 5 is a schematic structural diagram of the modular framework of the container data center, which is provided by the embodiment of the present invention, at the upper outer wall of the upper box body and the lower box body.

Description of reference numerals:

11. an upper box body; 12. a lower box body; 21. positioning a groove; 22. a limiting rod piece; 23. a sliding wheel; 24. a baffle plate; 3. an air conditioning module; 4. a gap seam; 5. overhauling the packway; 6. a wiring bridge frame; 7. an arc-shaped steel plate roof; 81. a first diagonal brace; 82. and a second inclined strut.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, embodiments of the present invention will be described in detail with reference to the accompanying drawings. Terms such as "upper," "above," "lower," "below," "first end," "second end," "one end," "another end," and the like, used herein to denote relative spatial positions, are used for ease of description to describe one element or feature's relationship to another element or feature as illustrated in the figures. The spatially relative positional terms may be intended to encompass different orientations of the device in use or operation in addition to the orientation depicted in the figures. For example, if the device in the figures is turned over, elements described as "below" or "beneath" other elements or features would then be oriented "above" the other elements or features. Thus, the exemplary term "below" can encompass both an orientation of above and below. The device may be otherwise oriented (rotated 90 degrees or at other orientations) and the spatially relative descriptors used herein interpreted accordingly.

Furthermore, the terms "mounted", "disposed", "provided", "connected", "slidably connected", "fixed" and "sleeved" are to be understood in a broad sense. For example, "connected" may be a fixed connection, a detachable connection, or a unitary construction; can be a mechanical connection, or an electrical connection; may be directly connected, or indirectly connected through intervening media, or may be in internal communication between two devices, elements or components. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art as appropriate.

The embodiment of the utility model provides a container data center modular architecture, which is arranged in a data center. As shown in fig. 1 and 2, the container data center modular architecture includes two sets of data integration units, each set of integration units is composed of a plurality of integration modules, and the integration modules include: the air conditioner comprises a lower box body 12, an upper box body 11, a positioning and locking structure and an air conditioning module 3, wherein the lower box body 12 can be used for arranging a data center cabinet so as to fix the cabinet in the lower box body 12. The upper case 11 is connected above the lower case 12, and the upper case 11 and the lower case 12 are communicated with each other, so that the air flow entering the lower case 12 can enter the upper case 11 and be discharged from the upper case 11, thereby achieving the flow of the air.

The positioning and locking structure is provided between the upper casing 11 and the lower casing 12, so that when the upper casing 11 is set on the lower casing 12, the upper casing 11 can be mounted on a designated position of the lower casing 12 by using the positioning and locking structure, and the lower casing 12 can be stably fixed on the upper casing 11.

The air conditioning module 3 is arranged on one side of the upper box body 11, and an air outlet channel and an air return channel of the air conditioning module 3 are respectively communicated with the upper box body 11 and the lower box body 12, so that a cabinet in the lower box body 12 is refrigerated, and backflow hot air flows back through the upper box body 11.

It should be noted that the lower box 12 and the air conditioning module 3 are both fixed on a preset foundation, for example, the lower box 12 and the air conditioning module 3 are stably fixed on the foundation by a bolt or other connecting member.

In one embodiment, as shown in fig. 3 and 4, the positioning and locking structure includes a positioning groove 21, a stopper rod 22 and a sliding wheel 23, wherein the positioning groove 21 is disposed at the edge of the lower case 12, and a stopper 24 is disposed at one end edge of the positioning groove 21; the stopper rod 22 is fixedly coupled to an edge of the upper case 11, and the stopper rod 22 is disposed along a length direction of the upper case 11, so that the stopper rod 22 is slidably coupled in the positioning groove 21 when the upper case 11 is mounted to the lower case 12.

The sliding wheels 23 are provided in plurality, the sliding wheels 23 are fixedly mounted on the limit rod member 22, and the sliding wheels 23 can be connected to the bottom of the positioning groove 21 in a rolling manner. Therefore, when the upper box body 11 needs to be installed on the lower box body 12, the limiting rod and the sliding wheel 23 can extend into the positioning groove 21 of the lower box body 12, and then the upper box body 11 is pushed to move relatively, so that the upper box body 11 is installed at the designated position of the lower box body 12, and the installation is more convenient. In the process of moving the upper case 11, when one end of the position-limiting rod 22 abuts against the blocking piece 24, the other end of the position-limiting rod 22 completely extends into the positioning groove 21, and the edge of the upper case 11 is aligned with the edge of the upper case 11, so that the upper case 11 is aligned with the lower case 12.

In one embodiment, as shown in the figure, a sealant layer is disposed between the stopper member 22 and the sidewall of the positioning groove 21, so that the sealant layer can be used to seal between the stopper member 22 and the positioning groove 21 after the upper case 11 is mounted on the lower case 12.

For the above-mentioned sealing glue layer, before installing the upper box body 11 to the lower box body 12, a certain sealing glue is smeared on the side wall of the limit rod 22, and then after installing the upper box body 11 to the lower box body 12, the limit rod 22 is completely located in the positioning groove 21, and after a period of time, the sealing glue can be relatively solidified to form the sealing glue layer, and by this way, while the sealing between the upper box body 11 and the box body is ensured, the upper box body 11 and the lower box body 12 can be further limited and fixed.

In one embodiment, as shown in the figure, threaded holes are respectively preset on the outer wall of the positioning groove 21 and the stopper rod 22, wherein when the stopper rod 22 is slidably disposed in the positioning groove 21 and one end of the stopper rod 22 abuts against the blocking piece 24, the threaded holes on the outer wall of the positioning groove 21 and the threaded holes on the stopper rod 22 are aligned with each other, and at this time, the outer wall of the positioning groove 21 and the threaded holes of the stopper rod 22 can be connected by bolts, so as to stably fix the upper box body 11 and the lower box body 12.

In one embodiment, as shown in fig. 2, a gap 4 is provided between each two corresponding integrated modules of the two sets of data integrated units, that is, a certain gap 4 is provided between the integrated module on the left side and the integrated module on the right side in the two sets of data integrated units, so that the adverse effect of thermal expansion or seismic expansion can be resisted to a certain extent.

In an embodiment, as shown in fig. 2, the container data center modular framework further includes an access corridors 5, the access corridors 5 are disposed on two side edges in the upper box 11, and through the arrangement of the access corridors 5, when the upper box 11 needs to be maintained, a worker can perform maintenance through the access corridors 5.

For the above-mentioned maintenance walkway 5, it may be that the maintenance walkway 5 is directly preset in the upper box 11 when the upper box 11 is preset, or it may be that the maintenance walkway 5 is fixed in the upper box 11 when the upper box 11 is preset, for example, it is fixed by bolt or it is fixed by welding directly.

In one embodiment, as shown in fig. 2, the container data center modular architecture further includes a cable tray 6, and the cable tray 6 is disposed on one side of the lower box 12, so that for a cabinet disposed in the lower box 12, cables of the cabinet can be set up on the cable tray 6 to avoid cables from being scattered. For the cable tray, it may be directly and integrally connected into the lower cabinet 12.

In an embodiment, as shown in fig. 2, the container data center modular framework further includes an arc-shaped steel plate roof 7, the arc-shaped steel plate roof 7 is disposed between the two sets of data integration units, and two ends of the arc-shaped steel plate roof 7 are respectively connected to edges of the upper box bodies 11 of the two adjacent integration units, so that the two sets of data integration units can be covered by the arc-shaped steel plate roof 7, and in rainy days, the problem of rainwater leakage caused by rainwater falling onto the upper box bodies 11 of the two sets of data integration units can be further avoided.

In one embodiment, as shown in fig. 5, the modular architecture of the container data center further includes two first braces 81 fixedly connected to the side wall of the upper box 11 and two second braces 82 fixedly connected to the side wall of the lower box 12, where the two first braces 81 are provided on the side wall of the upper box 11, one end of each of the two first braces 81 is connected to an upper corner of the upper box 11, and the other end of each of the two first braces 81 is connected to a central position of a lower edge of the upper box 11, and similarly, the first brace 81 is also provided on a corresponding side wall of the upper box 11. Two second inclined struts 82 are also arranged on the side wall of the lower box body 12, one ends of the two second inclined struts 82 are respectively connected to the lower end corner of the lower box body 12, the other ends of the two second inclined struts 82 are connected to the upper end edge of the lower box body 12, and similarly, the second inclined struts 82 are also socially made on the corresponding side wall of the lower box body 12.

Therefore, through the arrangement of the first inclined strut 81 and the second inclined strut 82, a certain support can be formed on the side walls of the upper box body 11 and the lower box body 12, so as to further enhance the structural strength of the upper box body and the lower box body.

Based on the same technical concept, the embodiment of the utility model also provides a data center, and the data center comprises the container data center modular architecture involved in the embodiment.

Through setting up this container data center modularization framework to in the data center after, when setting up it, only need install this lower box 12 on the ground base paper in proper order earlier, later install each last box 11 respectively, connect air conditioner module 3 isotructure after that, because this last box 11, lower box 12 and air conditioner module 3 isotructure all preset in advance, consequently when installing it, can directly hoist and mount it can to it, relatively simple when the construction, also need not carry out relatively great adjustment during the simultaneous construction, thereby can reduce the construction cycle relatively.

In the embodiment of the utility model, through the arrangement of the upper box body 11 and the lower box body 12, when the data center is constructed, the preset lower box body 12 and the upper box body 11 can be spliced directly, the air-conditioning module 3 is installed, then the edges of the upper box body 11 and the lower box body 12 can be aligned after the upper box body 11 and the lower box body 12 are spliced by a positioning and locking structure, then the upper box body 11 and the lower box body 12 can be stably fixed by the structure, so that the construction and the splicing are convenient and the construction is relatively simple, and the connection of some components is not needed on site, so that the construction period of the data center can be relatively reduced, meanwhile, when the upper box body 11 is arranged on the lower box body 12, the positioning locking structure is convenient for the upper box body 11 to be arranged at the appointed position of the lower box body 12 and fixed, and is more convenient for the construction of workers.

The present invention is not limited to the above preferred embodiments, and any modifications, equivalent replacements, improvements, etc. within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. A modular architecture for a container data center, comprising two sets of data integration units, each set of integration units comprising a plurality of integration modules, said integration modules comprising:

the lower box body is used for arranging a data center cabinet;

the upper box body is connected above the lower box body;

the positioning and locking structure is arranged between the upper box body and the lower box body so as to fix the lower box body on the upper box body;

and the air conditioning module is arranged on one side of the upper box body and is respectively communicated with the upper box body and the lower box body.

2. The container data center modular architecture of claim 1, wherein the positioning and locking structure comprises:

the positioning groove is arranged at the edge of the lower box body, and a baffle is arranged at the edge of one end of the positioning groove;

the limiting rod piece is connected to the edge of the upper box body and is connected in the positioning groove in a sliding manner;

the sliding wheel is connected to the limiting rod piece and can be connected to the bottom of the positioning groove in a rolling mode;

the sliding wheel and the limiting rod piece are arranged in the positioning groove, when one end of the limiting rod piece is abutted to the baffle, the other end of the limiting rod piece extends into the positioning groove, and the edge of the upper box body is aligned with the edge of the upper box body.

3. The container data center modular architecture of claim 2, wherein a sealant layer is disposed between the restraining bar and the side wall of the positioning slot.

4. The modular container data center architecture of claim 3, wherein threaded holes are respectively pre-formed in the outer wall of the positioning slot and the stopper rod;

the limiting rod piece is arranged in the positioning groove in a sliding mode, when one end of the limiting rod piece is abutted to the baffle, the threaded hole in the outer wall of the positioning groove is aligned with the threaded hole in the limiting rod piece, and a bolt is connected between the outer wall of the positioning groove and the threaded hole of the limiting rod piece.

5. The container data center modular architecture of claim 1, wherein there is a gap between each two corresponding said integration modules of said two sets of data integration units.

6. The modular container data center architecture of claim 1, further comprising service corridors disposed on both side edges within the upper box.

7. The modular container data center architecture of claim 1, further comprising a trace bridge disposed on a side of the lower box.

8. The modular container data center architecture of claim 1, further comprising an arc-shaped steel plate roof, wherein the arc-shaped steel plate roof is disposed between the two sets of data integration units, and two ends of the arc-shaped steel plate roof are respectively connected to edges of the upper box bodies of two adjacent integration modules.

9. The modular container data center architecture of claim 1, further comprising a first brace attached to the upper box side wall and a second brace attached to the lower box side wall;

two first inclined struts are arranged on the side wall of the upper box body, one ends of the two first inclined struts are respectively connected to the upper end corner of the upper box body, and the other ends of the two first inclined struts are connected to the lower end edge of the upper box body;

the second bracing on the lower box lateral wall is provided with two, two the one end of second bracing connect respectively in on the lower extreme corner of box down, the other end connect in the upper end edge of box down.

10. A data center comprising the modular container data center architecture of any of claims 1 to 8.

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