CN219164893U - Multi-layer expandable micro-module data center - Google Patents

Abstract

The utility model relates to a multi-layer expandable micro-module data center, which comprises one layer or at least two layers of micro-module units stacked up and down, wherein each micro-module unit comprises two end modules, at least one expansion module is connected between the two end modules, each end module comprises an end floor, an end cabinet and an end closed channel, each expansion module comprises an expansion floor, an expansion cabinet and an expansion closed channel, a first splicing structure is arranged on each end module, and second splicing structures respectively used for being in splicing connection with the first splicing structure or adjacent expansion modules are arranged on the left side and the right side of each expansion module; the micro-module data center further comprises a longitudinal splicing structure for splicing two adjacent layers of micro-module units up and down. The space in the place is utilized to the maximum extent, and the space utilization rate is effectively increased.

Description

Multi-layer expandable micro-module data center

Technical Field

The utility model relates to the technical field of data centers, in particular to a multi-layer expandable micro-module data center.

Background

At present, the traditional data center adopts a mode of constructing at the civil engineering stage firstly, then purchasing and installing electromechanical equipment, wherein the electromechanical equipment is installed by uniformly purchasing equipment such as cabinets, air conditioners, channels and the like, and the mode is long in construction time and the construction quality depends on the technical level of constructors.

The micro module integrates equipment such as a cabinet and air conditioning equipment, and also has a closed cold channel or a closed hot channel, part of electromechanical installation work is arranged in a factory, so that the construction time is shortened, meanwhile, the quality of products is controlled by the factory, the technical level of constructors is limited less, the final delivery quality can be improved, and the construction period is shortened. While for some reconstruction projects, such as warehouse houses, production factories, substations and the like, there is some reconstruction schemes of higher-level space, if only a single-layer data center machine room is adopted, the space is extremely wasted. A new type of micro module is disclosed in the chinese patent document with the grant number CN211019786U, in which a solution adopting a micro module manner is disclosed as a data center, but in a general micro module data center solution, the background condition considered by them is that only one layer of micro module of the data center can be placed for the clean height of the indoor space, but in the actual reconstruction project, there is a warehouse room, a production factory, a transformer substation, and the like, and there is a higher space, at this time, if a traditional micro module of the data center is used, a large amount of space is not used at the upper part, meanwhile, because the space size is different, the traditional micro module cannot be completely adapted to the reconstruction space of us, and the space is larger or smaller, and the traditional micro module of the data center may not be placed or the residual space is too large after being placed in, so that the space is wasted. Therefore, how to design a scalable micro-module to adapt to different installation situations is a problem that needs to be solved by those skilled in the art.

Disclosure of Invention

The utility model aims to provide a multi-layer extensible micro-module data center so as to solve the problem that a micro-module data center in the prior art cannot be adapted to different installation places.

In order to solve the problems, the multi-layer expandable micro-module data center provided by the utility model adopts the following technical scheme:

the multi-layer expandable micro-module data center comprises one or at least two layers of micro-module units stacked up and down, wherein each micro-module unit comprises two end modules which are arranged in a transversely extending mode and are arranged at left and right opposite intervals, at least one expansion module is connected between the two end modules, each end module comprises an end floor, an end cabinet arranged on the end floor and an end closed channel arranged in the middle of the end cabinet, each expansion module comprises an expansion floor spliced with the end floor, an expansion cabinet spliced with the end cabinet and an expansion closed channel communicated with the end closed channel, a first splicing structure is arranged on each end module, and second splicing structures respectively used for being spliced and connected with the first splicing structure or adjacent expansion modules are arranged on the left and right sides of each expansion module; the micro-module data center further comprises a longitudinal splicing structure for splicing two adjacent layers of micro-module units up and down.

Further, the first mosaic structure is including setting up the first rack connecting hole in the concatenation position department of the edge rack of end module, the second mosaic structure is including setting up the second rack connecting hole in the concatenation position department of the edge rack of expansion module, first rack connecting hole and second rack connecting hole pass through the perforation bolt and wear to adorn fixedly, first rack connecting hole and second rack connecting hole have a plurality of departments respectively, along upper and lower direction interval equipartition on the lateral wall of rack.

Further, the first splicing structure comprises a first splicing edge arranged on the floor edge of the end module, the second splicing structure comprises a second splicing edge arranged on the floor edge of the expansion module, the first splicing edge and the second splicing edge are arranged in an up-and-down mode, and fastening bolts extending up and down are arranged between the first splicing edge and the second splicing edge in a penetrating mode.

Further, rubber strips are filled between the first splicing structure and the second splicing structure.

Further, the micro-module unit has more than two layers, the longitudinal splicing structure comprises a plurality of steel columns extending up and down, each steel column is respectively fixed at the peripheral angle position of the side of the micro-module unit, and the steel columns are connected with supporting parts for supporting and matching with each layer of micro-module unit.

Further, the supporting part is a rectangular frame with anchor bolts fixed at the bottom of each layer of micro-module unit, and the rectangular frame is fixedly connected with the anchor bolts between the steel columns.

Furthermore, the front side and the rear side of the end head module and the expansion module are both surrounded by rails.

Furthermore, a lifting rail and a lifting bearing platform which extend up and down are also arranged at the edge position of the end head module.

The beneficial effects of the utility model are as follows: compared with the prior art, the multi-layer expandable micro-module data center creatively adopts a micro-module unit formed by the end modules and the expansion modules in the actual use process, and realizes the transverse expansion of the micro-modules by adding the expansion modules between the end modules; meanwhile, the vertical expansion of the micro-modules is realized through a longitudinal splicing structure by arranging the steel columns on the micro-module units, so that the multi-layer expandable micro-module data center applicable to industrial plants or indoor spaces with higher layer heights is formed. When the method is applied to different space places, a proper number of end modules and expansion modules are selected according to the size of the space, so that the space in the places can be utilized to the maximum extent, the space utilization rate is effectively increased, and the problem of space adaptability of the micro-module data center is solved; meanwhile, the whole structure of the micro-module unit adopted by the data center is more compact, the structure is simple, and the assembly is convenient. Meanwhile, through the splicing connection of the first splicing structure and the second splicing structure, the transverse adaptation splicing fixation between each module can be realized, and the stability of the whole structure is ensured.

Drawings

In order to more clearly illustrate the technical solution of the embodiments of the present utility model, the following briefly describes the drawings that are required to be used in the embodiments:

FIG. 1 is a schematic diagram of the structure of an embodiment of a multi-layered scalable micro-module data center of the present utility model;

FIG. 2 is a front view of the header module of FIG. 1 in a direction;

FIG. 3 is a block diagram of the header module of FIG. 1;

FIG. 4 is a block diagram of the expansion module of FIG. 1;

FIG. 5 is a view of the overall structure of the splice between modules in FIG. 1;

FIG. 6 is an enlarged view of a portion of the splice of the expansion module and the termination module of FIG. 5;

fig. 7 is a schematic structural view of the lifting platform in fig. 1.

Reference numerals illustrate: 1-a micromodule unit; a 2-end module; 3-expanding a module; 4-end floor; 5-end cabinet; 6-end sealing the channel; 7-expanding the floor; 8-expanding a cabinet; 9-expanding a closed channel; 10-a first splicing edge; 11-a second splicing edge; 12-fastening bolts; 13-a first cabinet connection hole; 14-a second cabinet connection hole; 15-perforating bolts; 16-rubber strips; 17-railing; 18-steel columns; 19-H-shaped steel beams; 20-lifting rails; 21-a power section; 22-lifting bearing platform.

Detailed Description

In order to make the technical purpose, technical scheme and beneficial effect of the present utility model more clear, the technical scheme of the present utility model is further described below with reference to the accompanying drawings and specific embodiments. It should be understood that the particular embodiments described herein are illustrative only and are not intended to limit the utility model, i.e., the embodiments described are merely some, but not all, of the embodiments of the utility model. The components of the embodiments of the present utility model generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations.

In the specific embodiment of the multi-layer expandable micro-module data center, as shown in fig. 2, the multi-layer expandable micro-module data center comprises three layers of micro-module units 1 stacked up and down, the structure of each layer of micro-module units 1 is shown in fig. 1 to 7, each layer of micro-module units comprises two end modules 2 which are arranged in a transversely extending mode and are arranged at left and right opposite intervals, and a plurality of expansion modules 3 are connected between the two end modules 2. The transverse expansion of the micro-modules is realized by the superposition of the number of the expansion modules 3, and the vertical expansion of the micro-modules is realized by the vertical superposition of the micro-module units 1.

The end module 2 comprises an end floor 4, an end cabinet 5 arranged on the end floor 4 and an end closed channel 6 arranged in the middle of the end cabinet 5, the concrete structure is shown in fig. 3, the end floor is integrally a steel folded plate floor, the end cabinet 5 is two, is symmetrically arranged on the end floor 4 at intervals along the front-back direction and extends along the left-right direction, one side of the end cabinet 5 in the left-right direction is arranged flush with the corresponding side edge of the end floor 4 up and down, subsequent splicing is facilitated, and other areas on the end floor 4, which are positioned outside the end cabinet 5, are convenient for people to pass through. An end closed channel 6 is formed at the position between the two end cabinets 5, and the end closed channel 6 is used for operating equipment in the cabinets by operators, so that other daily works such as inspection and debugging of workers are facilitated. The front side edge and the rear side edge of the end floor 4 are also provided with end railings 17 which extend up and down and are used for protecting the end floor 4.

The expansion module 3 is shown in fig. 4, and comprises an expansion floor, an expansion cabinet 8 arranged on the expansion floor 7 and an expansion closed channel 9 arranged in the middle of the expansion cabinet 8, wherein the expansion floor has a structure of a steel folded plate floor, two expansion cabinets are symmetrically arranged on the expansion floor 7 at intervals along the front-back direction, meanwhile, the expansion cabinets 8 are arranged in an extending mode along the left-right direction, the left side and the right side of the expansion cabinet 8 are respectively arranged in an up-down flush mode with the edges of the left side and the right side of the expansion floor 7, subsequent splicing is facilitated, the expansion closed channel 9 formed in the position between the two expansion cabinets 8 is used for people to pass through, and the expansion closed channel 9 and the end closed channel 6 are in relatively flush butt joint, so that the two closed channels integrally form a left-right extending closed channel.

In order to realize the splicing and fixing between the end module 2 and the expansion module 3 and between the expansion module 3 and the expansion, the end module 2 is provided with a first splicing structure, and the left side and the right side of the expansion module 3 are respectively provided with a second splicing structure which is respectively used for splicing and connecting with the first splicing structure or the adjacent expansion module 3.

In this embodiment, as shown in the figure, in order to realize connection between the end floor 4 and the expansion floor 7, and between the expansion floor 7 and the expansion floor 7, the first splicing structure includes a first splicing edge 10 disposed at a floor edge of the end module 2, the second splicing structure includes a second splicing edge 11 disposed at a floor edge of the expansion module 3, and the first splicing edge 10 and the second splicing edge 11 are disposed up and down, with a fastening bolt 12 extending up and down penetrating therebetween. The first splicing edges 10 and the second splicing edges 11 at the edge positions of the floors of two adjacent modules are overlapped up and down in a staggered mode, and when the floor is actually assembled, all expansion modules 3 are sequentially attached and overlapped only by means of the sequence, and then the floor is locked through the fastening bolts 12; in the embodiment, the first splicing edges 10 are all located at the bottom side, the second splicing edges 11 are located at the top side, and if a sufficient number of expansion modules 3 exist, the upper and lower positions of the two second splicing edges 11 of the single expansion module 3 can be selected according to actual needs, so that the final assembly requirement is met, and the end surface flatness requirement of the integral floor is realized. Meanwhile, a rubber strip 16 is filled between the first splicing edge 10 and the second splicing edge 11, and meanwhile, the first splicing edge and the second splicing edge are sealed by waterproof sealant.

In order to realize connection between the end cabinet 5 and the expansion cabinet 8, and between the expansion cabinet 8 and the expansion cabinet 8, the first splicing structure comprises a first cabinet connecting hole 13 arranged at the splicing position of the edge cabinet of the end module 2, the second splicing structure comprises a second cabinet connecting hole 14 arranged at the splicing position of the edge cabinet of the expansion module 3, the first cabinet connecting hole 13 and the second cabinet connecting hole 14 are fixedly installed in a penetrating way through a penetrating bolt 15, and the first cabinet connecting hole 13 and the second cabinet connecting hole 14 are respectively distributed at a plurality of positions and uniformly distributed on the side wall of the cabinet at intervals along the up-down direction. And meanwhile, rubber strips 16 are added at the splicing seams of the cabinets, and the two cabinets are fastened by using perforated bolts 15.

By splicing the floor and the cabinet, two adjacent modules form a whole, so that the stability of the whole structure is ensured, and the upward and downward direction and the horizontal direction are avoided.

In order to realize the up-down stacking and splicing of three layers of micro-module units 1 in the vertical direction, the micro-module data center further comprises a longitudinal splicing structure for splicing two adjacent layers of micro-module units up and down, specifically, four steel columns 18 extending up and down are arranged at the positions of the edges of the front side and the rear side of the end floor 4 and are respectively distributed on the front side and the rear side of the two end modules, the steel columns 18 are connected with supporting parts used for supporting and matching with the micro-module units 1 in each layer, in the embodiment, the supporting parts are rectangular frames fixed at the bottoms of the micro-module units in each layer through anchor bolts, the rectangular frames are fixedly connected with the steel columns through the anchor bolts, the rectangular frames are four H-shaped steel beams 19 which are arranged in a surrounding mode, the width of each rectangular frame is consistent with the front-rear dimension of the micro-module units 1, and the length of each rectangular frame is consistent with the dimension of the micro-module units 1 in the whole left-right direction. The rectangular frames of all layers are stacked up and down, are integrally fixed with steel columns 18 through H-shaped steel beams 19 to form a rectangular three-dimensional frame, and then floor anchor bolts of all layers of micro-module units are connected to the rectangular frames of different layers. The method specifically adopts the H-shaped steel beams 19 and the steel columns 18 as supporting structures, the lower floors of the end head modules 2 and the expansion modules 3 are directly erected on a rectangular frame formed by the H-shaped steel beams 19, and the expansion of the micro-modules in the vertical direction is realized under the condition of allowing the layer height.

In addition, in order to facilitate the operator to enter the micro-module units 1 with different layer heights, the edge positions of the end modules 2 are further provided with lifting rails 20 and lifting platforms 22 which extend up and down. Specifically, at the side corner position of the end module 2, a lifting rail 20 extending up and down is arranged, a power part 21 is arranged at the top of the lifting rail 20, and a lifting bearing platform 22 is assembled on the rail part in a sliding manner, so that the vertical direction traffic walking is met, and the lifting bearing platform 22 occupies a small space and is flexible and convenient.

In the actual erection process, according to the space size of an actual workplace, different numbers of end modules 2 and expansion modules 3 are selected, the number of layers with proper height is selected according to the layer height requirement, each micro-module unit 1 is gradually erected from bottom to top, meanwhile, each end module 2 and expansion module 3 are sequentially spliced in each micro-module unit 1 according to the size of a transverse space, and finally an integral micro-module data center is formed.

Of course, in other embodiments, the first splicing structure and the second splicing structure may also be in a form of left-right insertion, for example, an insertion groove is disposed at the edge of the end floor 4, and insertion bosses are disposed at two sides of the expansion floor 7, and are fixed by bolts after insertion along the left-right direction. The edge positions of the end module 2 and the expansion module 3 can be provided with a connecting splicing frame, and the splicing fixation of the adjacent modules can be realized through the splicing frame.

In other embodiments, the longitudinal splicing structure can also be formed by arranging supporting columns on each layer of micro-module units, and the top of each supporting column is fixedly connected with the bottom plate of the micro-module unit on the upper layer through a direct anchor bolt when the micro-module unit is erected. According to the micro-module units with different layers, different numbers of support columns are designed.

In other embodiments, the support part may be designed as two H-shaped steel beams extending left and right instead of the rectangular frame.

Finally, what should be said is: the above embodiments are only for illustrating the technical solution of the present utility model, and any equivalent replacement of the present utility model and modification or partial replacement without departing from the spirit and scope of the present utility model should be covered in the scope of the claims of the present utility model.

Claims (8)

1. The multi-layer expandable micro-module data center is characterized by comprising one layer or at least two layers of micro-module units stacked up and down, wherein each micro-module unit comprises two end modules which are arranged in a transversely extending mode and are arranged at left and right opposite intervals, at least one expansion module is connected between the two end modules, each end module comprises an end floor, an end cabinet arranged on the end floor and an end closed channel arranged in the middle of the end cabinet, each expansion module comprises an expansion floor spliced with the end floor, an expansion cabinet spliced with the end cabinet and an expansion closed channel communicated with the end closed channel, a first splicing structure is arranged on each end module, and second splicing structures respectively used for being spliced and connected with the first splicing structure or adjacent expansion modules are arranged on the left and right sides of each expansion module; the micro-module data center further comprises a longitudinal splicing structure for splicing two adjacent layers of micro-module units up and down.

2. The multi-layer expandable micro-module data center of claim 1, wherein the first splicing structure comprises a first cabinet connecting hole arranged at a splicing position of an edge cabinet of the end module, the second splicing structure comprises a second cabinet connecting hole arranged at a splicing position of an edge cabinet of the expansion module, the first cabinet connecting hole and the second cabinet connecting hole are fixed through penetrating bolts, and the first cabinet connecting hole and the second cabinet connecting hole are respectively distributed on the side wall of the cabinet at intervals along the up-down direction.

3. The multi-layer expandable micro-module data center of claim 2, wherein the first splicing structure comprises a first splicing edge arranged on the floor edge of the end module, the second splicing structure comprises a second splicing edge arranged on the floor edge of the expansion module, and the first splicing edge and the second splicing edge are arranged in an up-and-down mode, and fastening bolts extending up and down are arranged between the first splicing edge and the second splicing edge in a penetrating mode.

4. The multi-layered scalable micro-module data center of claim 2 or 3, wherein rubber strips are filled between the first and second splice structures.

5. The multi-layer expandable micro-module data center according to any one of claims 1-3, wherein the micro-module unit has more than two layers, the longitudinal splicing structure comprises a plurality of steel columns extending up and down, each steel column is respectively fixed at the peripheral angular positions of the edges of the micro-module unit, and the steel columns are connected with supporting parts for supporting and matching with each layer of micro-module unit.

6. The multi-layer expandable micro-module data center of claim 5, wherein the support portion is a rectangular frame with anchor bolts fixed at the bottom of each layer of micro-module units, and the rectangular frame is fixedly connected with the steel columns through the anchor bolts.

7. The multi-layered expandable micro-module data center of claim 5, wherein the front and rear sides of the end head module and the expansion module are surrounded by rails.

8. A multi-layer scalable micro-module data center according to any one of claims 1-3, wherein the end modules are further arranged with lifting rails and lifting platforms extending up and down at the edge positions.

Images