CN115866937A - Container group - Google Patents

Abstract

The embodiment of the application provides a container group, container group includes first container, second container and connection structure, be provided with first rack and second rack in the first container side by side, and first rack with form first heat transfer passageway between the second rack, be provided with third rack and fourth rack in the second container side by side, and the third rack with form second heat transfer passageway between the fourth rack. The connecting structure is arranged between the first container and the second container, and a cold channel is formed inside the connecting structure. When the container group is applied to a data center, the cold channel can simultaneously carry out heat exchange on the second cabinet and the third cabinet, so that the cooling effect of the container group is ensured.

Description

Container group

Technical Field

The application belongs to the technical field of integrated data center structures, and particularly relates to a container group.

Background

The main body of the traditional data center generally adopts a heavy frame structure such as a steel structure or a reinforced concrete structure, and after the main body of the frame structure is completed, cabinet server equipment, power transformation and distribution equipment, air conditioning equipment, fire fighting equipment, intelligent equipment, pipelines, bridges thereof, decoration and the like are installed in the frame structure.

However, the demand for computing power of the data center in the prior art is higher and higher, and a cabinet in the data center is required to be in an operating state for a long time. And the cabinet machine of long-term operation can produce very big heat, and traditional frame construction is unfavorable for thermal dissipation, has influenced data center's long-term steady operation.

Disclosure of Invention

It is an object of embodiments of the present application to provide a new solution for a container group.

According to an aspect of the embodiments of the present application, there is provided a container group applied to a data center, including:

the container comprises a first container, a second container and a heat exchange device, wherein a first cabinet and a second cabinet are arranged in the first container side by side, and a first heat exchange channel is formed between the first cabinet and the second cabinet;

a third cabinet and a fourth cabinet are arranged in the second container side by side, a second heat exchange channel is formed between the third cabinet and the fourth cabinet, and the second container and the first container are arranged at intervals;

the connecting structure is arranged between the first container and the second container, a cold channel is formed inside the connecting structure, and two sides of the cold channel are close to the second cabinet and the third cabinet respectively.

Optionally, the connection structure comprises a prefabricated top panel connected between the top end of the first container and the top end of the second container and a prefabricated bottom panel connected between the bottom end of the first container and the bottom end of the second container to form the cold aisle between the prefabricated top panel and the prefabricated bottom panel.

Optionally, a first air chamber is arranged in the first container, an air outlet of the first air chamber is communicated with the cold channel, and an air inlet of the first air chamber is communicated with the first heat exchange channel;

and a second air chamber is arranged in the second container, an air outlet of the second air chamber is communicated with the cold channel, and an air inlet of the second air chamber is communicated with the second heat exchange channel.

Optionally, in the height direction of the first container, multiple layers of first mounting structures are formed in the first container, the first cabinet and the second cabinet are arranged in each layer of the first mounting structures side by side, and the first heat exchange channel is formed between each layer of the first cabinet and the second cabinet.

Optionally, in the height direction of the second container, multiple layers of second mounting structures are formed in the second container, the third cabinet and the fourth cabinet are arranged in each layer of the second mounting structures side by side, and the second heat exchange channel is formed between the third cabinet and the fourth cabinet in each layer.

Optionally, one of said first container, one of said second container and one of said connecting structures form a group of container structures, said group of containers comprising a plurality of groups of said container structures.

Optionally, at least one IT shelter, an electric shelter, a refrigeration shelter and a functional shelter are arranged in the first container.

Optionally, the length of the first container is greater than or equal to 12000mm, the width of the first container is greater than or equal to 2400mm, and the height of the first container is greater than or equal to 2800mm.

Optionally, a first bridge is arranged in the first container, and a second bridge is arranged in the second container;

the connection structure includes a connection bridge disposed between the first and second bridges and configured to form a connection between the first and second bridges.

Optionally, a first interface and a first connecting piece are arranged at one end, close to the connecting bridge, of the first bridge, and a second interface and a second connecting piece are arranged at one end, close to the connecting bridge, of the second bridge;

one end of the connecting bridge frame is connected to the first interface through the first connecting sheet, and the other end of the connecting bridge frame is connected to the second interface through the second connecting sheet.

One technical effect of the application lies in:

the embodiment of the application provides a container group, container group includes first container, second container and connection structure, be provided with first rack and second rack in the first container side by side, and first rack with form first heat transfer passageway between the second rack, be provided with third rack and fourth rack in the second container side by side, and the third rack with form second heat transfer passageway between the fourth rack. The connecting structure is arranged between the first container and the second container, and a cold channel is formed inside the connecting structure. When the container group is applied to a data center, the cold channel can simultaneously carry out heat exchange on the second cabinet and the third cabinet, so that the cooling effect of the container group is ensured.

Further features of the present application and advantages thereof will become apparent from the following detailed description of exemplary embodiments thereof, which is to be read in connection with the accompanying drawings.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate embodiments of the application and together with the description, serve to explain the principles of the application.

Fig. 1 is a first top view of a container group according to an embodiment of the present disclosure;

FIG. 2 is a side view of a first container group according to an embodiment of the present disclosure;

FIG. 3 is a second side view of a container group according to an embodiment of the present disclosure;

fig. 4 is a second top view of a container group according to an embodiment of the present disclosure;

FIG. 5 is a schematic view of a first container and a second container connection location assembly of a container group according to an embodiment of the present disclosure;

FIG. 6 is a schematic top corner view of a first container of a group of containers according to an embodiment of the present disclosure;

FIG. 7 is a schematic view of a reinforced structure of a container group according to an embodiment of the present disclosure;

FIG. 8 is a schematic illustration of drainage for a container group according to an embodiment of the present disclosure;

FIG. 9 is a schematic illustration of a container group according to an embodiment of the present disclosure;

FIG. 10 is a schematic view of an IT shelter interior of a container cluster according to an embodiment of the present application;

FIG. 11 is a schematic view of the interior of a power shelter of a container cluster according to an embodiment of the present disclosure;

FIG. 12 is a schematic view of the interior of a refrigerated shelter of a container group according to an embodiment of the present disclosure;

FIG. 13 is a partial top plan view of a container group according to an embodiment of the present disclosure;

FIG. 14 is a partial side view of a container cluster according to an embodiment of the present application.

Wherein:

100. a first container; 1001. a first cabinet; 1002. a second cabinet; 1003. a first heat exchange channel; 1004. a first air chamber;

200. a second container; 2001. a third cabinet; 2002. a fourth cabinet; 2003. a second heat exchange channel; 2004. a second air chamber;

300. a connecting structure; 3001. a cold aisle; 3002. prefabricating a top plate; 3003. a prefabricated bottom plate.

101. A first assembly area; 102. an IT shelter; 103. an electric power shelter; 104. a refrigeration shelter; 105. a functional shelter; 106. a cabinet; 107. a heat exchange channel; 108. a channel interlayer; 109. a steel column; 110. a floor slab; 111. a steel beam; 112. a lap joint region;

201. a second assembly area; 202. a water discharge tank; 203. a drain pipe; 204. a corrugated plate; 205. a water-resistant film; 206. sealing rubber strips;

301. a connecting plate; 302. assembling a bolt;

400. prefabricating a component;

500. reinforcing the structure; 501. a steel pipe; 502. fastening a bolt;

600. and (6) a container top.

11. A first upright post; 12. a first keel; 13. a third keel; 14. a first bridge frame; 141. a first interface; 142. a first connecting piece; 15. a first top plate;

21. a second upright post; 22. a second keel; 23. a fourth keel; 24. a second bridge; 241. a second interface; 242. a second connecting sheet; 25. a second top plate;

31. a first connecting member; 311. a first connection section; 312. a first bending section; 313. a second bending section; 32. a second connecting member; 321. a second connection section; 322. a third bending section; 323. a fourth bending section; 33. connecting the bridge frame;

40. leveling a gasket;

50. a boom;

60. a cooling channel;

70. and a top closing plate.

Detailed Description

Various exemplary embodiments of the present application will now be described in detail with reference to the accompanying drawings. It should be noted that: the relative arrangement of the components and steps, the numerical expressions, and numerical values set forth in these embodiments do not limit the scope of the present application unless specifically stated otherwise.

The following description of at least one exemplary embodiment is merely illustrative in nature and is in no way intended to limit the application, its application, or uses.

Techniques, methods, and apparatus known to those of ordinary skill in the relevant art may not be discussed in detail but are intended to be part of the specification where appropriate.

In all examples shown and discussed herein, any particular value should be construed as merely illustrative, and not limiting. Thus, other examples of the exemplary embodiments may have different values.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, further discussion thereof is not required in subsequent figures.

Referring to fig. 1 and 2, an embodiment of the present application provides a container group applied to a data center, the container group including:

the container comprises a first container 100, a second container 200 and a connecting structure 300, wherein a first cabinet 1001 and a second cabinet 1002 are arranged in the first container 100 side by side, a first heat exchange channel 1003 is formed between the first cabinet 1001 and the second cabinet 1002, and the first heat exchange channel 1003 can facilitate quick dissipation of heat generated by the first cabinet 1001 and the second cabinet 1002.

Referring to fig. 1, a third cabinet 2001 and a fourth cabinet 2002 are arranged in the second container 200 side by side, and a second heat exchange channel 2003 is formed between the third cabinet 2001 and the fourth cabinet 2002, and the second heat exchange channel 2003 can facilitate rapid dissipation of heat generated by the third cabinet 2001 and the fourth cabinet 2002; and the second container 200 and the first container 100 are spaced apart to form a side-by-side group of containers.

Referring to fig. 1, the connection structure 300 is disposed between the first container 100 and the second container 200, that is, the connection structure 300 is disposed in a gap between the first container 100 and the second container 200; the connecting structure 300 forms a cold channel 3001 inside, and two sides of the cold channel 3001 are respectively close to the second cabinet 1002 and the third cabinet 2001.

Specifically, the cold passageway 3001 may be an air-cooled passageway or a liquid-cooled passageway, and when two sides of the cold passageway 3001 are respectively close to the second cabinet 1002 and the third cabinet 2001, effective heat exchange between the cold passageway 3001 and the second cabinet 1002 and the third cabinet 2001 may be achieved, so as to improve a cooling effect of the connection structure 300 on the second cabinet 1002 and the third cabinet 2001.

This application the container group is when being applied to data center, because data center needs very high calculation power, makes first container 100 with cabinet-type air conditioner in the second container 200 needs to be in high-speed running state for a long time, and first container 100 with the high-speed operation of cabinet-type air conditioner can give off very big heat in the second container 200, and cold aisle 3001 can be right simultaneously second rack 1002 with third rack 2001 carries out the heat transfer, has guaranteed the cooling effect of container group can maintain the long-term steady operation of container group when being used for data center.

Optionally, referring to fig. 2, the connecting structure 300 comprises a prefabricated roof 3002 and a prefabricated floor 3003, the prefabricated roof 3002 being connected between the top end of the first container 100 and the top end of the second container 200, the prefabricated floor 3003 being connected between the bottom end of the first container 100 and the bottom end of the second container 200 to form the cold aisle 3001 between the prefabricated roof 3002 and the prefabricated floor 3003.

Specifically, when the second container 200 and the first container 100 are arranged at a distance from each other to form a gap, in order to form a cold path 3001 for efficient heat exchange in the gap, the cold path 3001 may be enclosed by the prefabricated top plate 3002 and the prefabricated bottom plate 3003 together with the first container 100 and the second container 200.

In addition, after the cooling working medium in the cold channel 3001 exchanges heat with the second cabinet 1002 and the third cabinet 2001, the cooling working medium may be introduced into the first heat exchange channel 1003 and the second heat exchange channel 2003 through pipes, so that the cooling working medium exchanges heat with the first cabinet 1001 and the second cabinet 1002 in the first container 100 and the third cabinet 2001 and the fourth cabinet 2002 in the second container 200.

Optionally, referring to fig. 1, a first air chamber 1004 is disposed in the first container 100, an air outlet of the first air chamber 1004 is communicated with the cold passageway 3001, and an air inlet of the first air chamber 1004 is communicated with the first heat exchange passageway 1003;

a second air chamber 2004 is disposed in the second container 200, an air outlet of the second air chamber 2004 is communicated with the cold channel 3001, and an air inlet of the second air chamber 2004 is communicated with the second heat exchange channel 2003.

Specifically, a cooling medium compressor may be disposed in the first air chamber 1004, an air outlet of the first air chamber 1004 is communicated with the cold passageway 3001, and when an air inlet of the first air chamber 1004 is communicated with the first heat exchanging passageway 1003, working medium circulation of the first air chamber 1004, the cold passageway 3001 and the first heat exchanging passageway 1003 may be formed, so as to improve heat exchanging efficiency of the cold passageway 3001 to the inside of the first container 100.

Similarly, a cooling medium compressor may be disposed in the second air chamber 2004, an air outlet of the second air chamber 2004 is communicated with the cold channel 3001, and when an air inlet of the second air chamber 2004 is communicated with the second heat exchanging channel 2003, working mediums of the second air chamber 2004, the cold channel 3001 and the second heat exchanging channel 2003 may circulate to improve the heat exchanging efficiency of the cold channel 3001 to the inside of the second container 200.

Optionally, referring to fig. 2, in the height direction of the first container 100, a plurality of layers of first installation structures are formed in the first container 100, the first cabinet 1001 and the second cabinet 1002 are arranged side by side in each layer of the first installation structure, and the first heat exchange passage 1003 is formed between the first cabinet 1001 and the second cabinet 1002 in each layer.

Specifically, a multi-layer first installation structure is formed in the first container 100, and the vertical expansion of the first container 100 can be realized by using the multi-layer first installation structure, so that the capacity of the first container 100 is effectively expanded, and when the first container 100 is applied to a data center, the construction scale and the calculation power of the data center can be increased, and the application range of the data center is increased.

Optionally, referring to fig. 3, in the height direction of the second container 200, a plurality of layers of second mounting structures are formed in the second container 200, the third cabinet 2001 and the fourth cabinet 2002 are arranged in each layer of the second mounting structures side by side, and the second heat exchange channel 2003 is formed between the third cabinet 2001 and the fourth cabinet 2002 in each layer.

Specifically, a multi-layer second installation structure is formed in the second container 200, and the vertical expansion of the second container 200 can be realized by using the multi-layer second installation structure, so that the capacity of the second container 200 is effectively expanded, and when the second container 200 is applied to a data center, the construction scale and the calculation power of the data center can be increased, and the application range of the data center is increased.

Optionally, one of said first containers 100, one of said second containers 200 and one of said connecting structures 300 form a group of container structures, said group of containers comprising a plurality of groups of said container structures.

In particular, as users demand more and more power from data centers, more and more capacity groups of containers are needed for data centers. And the container group includes the multiunit under the condition of container structure, for example the multiunit container structure can set up side by side on same height, perhaps the multiunit container structure stacks up the setting in the direction of height to show the increase the capacity of container group, guarantee the high computing power operation of container group when being used for data center.

Referring to fig. 3 to 12, the container group includes:

first container 100, second container 200 and connecting structure 300, referring to fig. 5, the top of first container 100 is provided with a first assembling area 101, the bottom of second container 200 is provided with a second assembling area 201, and second container 200 is located on the top of first container 100, that is, first container 100 and second container 200 form a vertically stacked double-layer container structure.

The connecting structure 300 is disposed between the first container 100 and the second container 200, and is configured to connect the first assembling area 101 and the second assembling area 201, so as to ensure stability of the stacked arrangement of the first container 100 and the second container 200.

In addition, on the basis of forming a double-layer container structure, the number of layers of the containers in the height direction can be increased to realize a three-layer or more-layer container group.

The application provides the container group has effectively enlarged the capacity of container group through the mode of perpendicular dilatation, makes when being applied to data center, can increase data center's construction scale and calculation power, has increased data center's application scope.

And the data center formed by the container group can reduce the capital construction cost of the data center on the basis of being suitable for more mainstream data center application scenes.

Alternatively, referring to fig. 5, the connection structure 300 includes a connection plate 301 and a mounting bolt 302;

the connection plate 301 is disposed between the first mounting region 101 and the second mounting region 201, one end of the mounting bolt 302 is connected to the first mounting region 101, and the other end of the mounting bolt 302 passes through the connection plate 301 and is connected to the second mounting region 201.

Specifically, the mounting bolt 302 may be a high-strength bolt, the mounting bolt 302 may be movably connected to the first mounting region 101 and extend from the first mounting region 101, and the mounting bolt may be connected to a threaded hole in the second mounting region 201 after passing through the connecting plate 301. After the first assembling area 101 and the second assembling area 201 are detachably connected through the high-strength bolts, the arrangement of the lower-layer containers can be copied by detaching simple prefabricated roofs under the condition that the container group type data center is put into operation, so that the purpose of vertical and rapid expansion can be achieved.

In an embodiment, the upper side and the lower side of the connecting plate 301 may have limiting protrusions, the first assembly region 101 and the second assembly region 201 may have limiting grooves, respectively, and when the two limiting protrusions on the connecting plate 301 are engaged with the limiting grooves in the first assembly region 101 and the second assembly region 201, respectively, the first container 100 and the second container 200 may be limited, so as to avoid the first container 100 and the second container 200 from shifting.

In addition, the first container 100 and the second container 200 may be directly connected by metal fasteners, and the first container 100 and the second container 200 may also be stably connected and easily detached.

Alternatively, referring to fig. 5 and 6, the first assembly area 101 is located at a corner position of the top of the first container 100;

the second assembly region 201 is located at a corner position of the bottom of the second container 200.

Specifically, the first container 100 and the second container 200 may be both square containers having the same size (the same length, width, height, and the like), and four first assembly regions 101 may be located at four corner positions of the top of the first container 100; four second assembly regions 201 may be located at four corner positions of the bottom of the second container 200. The connecting plate 301, the assembling bolts 302, the first assembling region 101 and the second assembling region 201 correspond in position, so that the assembling bolts 302 are respectively arranged at four top corners of the first container, and the connecting plate 301 is fixedly connected with four bottom corners of the corresponding second container, thereby realizing stable assembling of the first container 100 and the second container 200.

Optionally, referring to fig. 6, the container group further comprises a prefabricated component 400, and the prefabricated component 400 is filled in the first assembly region 101 and the second assembly region 201.

Specifically, when the prefabricated member 400 is filled in the first assembly region 101 and the second assembly region 201 after the first container 100 and the second container 200 are assembled by the connecting plate 301 through the plurality of assembly bolts 302, a gap is formed between the connecting plate 301, the assembly bolts 302, the first assembly region 101, and the second assembly region 201, so that the prefabricated member 400 fills the gap formed by the connecting plate 301, the assembly bolts 302, the first assembly region 101, and the second assembly region 201, the degree of prefabrication of the first container 100 and the second container 200 in the factory is increased, the work of splicing the container group in the field is effectively reduced, and the problem of water leakage of the first container 100 and the second container 200 can be avoided on the basis of reducing the construction period of the container group.

Optionally, referring to fig. 7, the container group further comprises a reinforcing structure 500, and the reinforcing structure 500 is detachably disposed at both sides of the first container 100 and the second container 200.

Specifically, the reinforcing structure 500 may reinforce the structural strength of the first container 100 and the second container 200 at two sides to ensure the safety of the loading equipment for transporting the container group. And when the assembly in the container group finishes, can with reinforced structure 500 dismantles fast to do not influence the normal work that the interior space of container group installation was under construction.

In one embodiment, referring to fig. 7, the reinforcing structure 500 includes a steel pipe 501 and a fastening bolt 502; the steel pipes 501 are arranged on two sides of the first container 100 and the second container 200 in a folding line, for example, the steel pipes 501 on two sides of the first container 100 and the second container 200 can be extended in a W shape, the steel pipes 501 are fixed on the first container 100 and the second container 200 through the fastening bolts 502, and the flexible disassembly and assembly of the reinforcing structure 500 can be realized on the basis of ensuring the reinforcing effect of the reinforcing structure 500 on the first container 100 and the second container 200.

In another embodiment, the reinforcement structure 500 may be formed by installing a protection plate on both sides of the first container 100 and the second container 200, for example, installing a metal plate on both sides of the first container 100 and the second container 200.

Optionally, referring to fig. 8, the corner positions of the top of the second container 200 are provided with drainage grooves 202, for example, four corner positions of the top of the second container 200 are provided with drainage grooves 202, and the drainage grooves 202 are communicated to the bottom of the first container 100 through drainage pipes 203.

Specifically, the top of second container 200 can be provided with and be arched corrugated plate 204, the rainwater at second container 200 top can flow to from corrugated plate 204 in the water drainage tank 202 of second container 200 top edge, specifically can make through the steel sheet metal component water drainage tank 202, water drainage tank 202 has connect drain pipe 203, the drain pipe 203 at second container 200 top can be down the water drainage tank 202 drainage at the first container top of one deck, perhaps the drain pipe 203 at second container 200 top can directly be to ground drainage, in order to realize the drainage of container group in transportation and installation.

Optionally, referring to fig. 3 and 4, at least one IT shelter 102, power shelter 103, refrigeration shelter 104, and functional shelter 105 are disposed within the first container 100.

Specifically, the functional shelter 105 may include functional units such as walkways, decontamination rooms, toilets, hallways, light and strong electricity rooms, fresh air rooms, and smoke exhaust rooms. After a series of debugging and acceptance in a factory, the functional shelter 105 is subjected to temporary waterproof and sealed packaging, then is transported to a project site by sea or land transportation, is subjected to hoisting, installation, splicing and sealing treatment in the project site, and then is subjected to pipeline connection among the functional shelters 105 in the project site. And each IT shelter 102 may be provided with a cabinet 106, a heat exchange channel 107 and a channel sandwich 108.

The IT shelter 102, the electric power shelter 103, the refrigeration shelter 104 and the functional shelter 105 are arranged in one layer in the first container 100 in a combined mode, so that various kinds of shelters in the first container 100 form a large-scale container type data center, the container type data center is enabled to have multiple functions of a large-scale data center, and application scenes of more data centers are met.

In addition, at least one IT shelter 102, an electric shelter 103, a refrigeration shelter 104 and a functional shelter 105 may be provided in the second container 200.

Further, referring to fig. 9, a waterproof film 205 may be disposed on the side of each of the IT shelter 102, the electric power shelter 103, the refrigeration shelter 104 and the functional shelter 105 during transportation, hoisting and installation, the top and the bottom of the waterproof film 205 are both fixed by angle steel edge strips and sealed by sealing strips 206, and the waterproof film 205 is removed until the permanent waterproof measure on the top of the shelter is finished, so that rainwater can be effectively prevented from entering the interior of the shelter from the side during construction, and water leakage does not occur during installation of each shelter.

Optionally, the length of the first container 100 is greater than or equal to 12000mm, the width of the first container 100 is greater than or equal to 2400mm, and the height of the first container 100 is greater than or equal to 2800mm.

Specifically, in order to integrate various types of the IT shelter 102, the electric shelter 103, the refrigeration shelter 104 and the functional shelter 105 into one container, the first container 100 may be configured in a customized manner, for example, the length of the first container 100 is 12192mm, the width of the first container 100 is 2438mm, and the height of the first container 100 is 2896mm, so that various types of the shelters can be completely installed in the first container 100, and the first container 100 can still meet the general requirements of installation and operation and maintenance.

Optionally, referring to fig. 3, the container group further comprises a container roof 600, the container roof 600 being fixed to the top of the second container 200.

Specifically, the container top 600 may be fixed to the top of the second container 200 by welding to protect the container group.

In addition, referring to fig. 6, the first container 100 further includes steel columns 109, a floor 110, steel beams 111, and a lap joint area 112, wherein the floor 110 is a top floor prefabricated as a standardized member, and a sufficient position may be reserved in the first assembly area 101 for the lap joint area 112 extending from the standardized member of the floor 110 to lap joint on a side plate. And the floor slab 110 can be connected and sealed by the special countersunk head screw or structural adhesive, and the repair can be carried out according to the decorative layer, so that the floor slab 110 does not need to be cut and corrected on the project site, and the work load on the project site is greatly reduced.

In addition, the installation space required by the standardized component formed by the floor slab 110 corresponds to the space where the assembly bolt is located, and specifically, the standardized component can be filled after the assembly bolt is installed.

Similarly, the second container 200 has the same structure as the first container 100, that is, the second container 200 may include a steel column 109, a floor 110, a steel beam 111, and a lap joint area 112, and the comparison of the embodiments of the present application is not repeated.

Referring to fig. 13 and 14, the container group includes:

first container 100, second container 200 and connection structure 300, the corner position of first container 100 is provided with first stand 11, for example when first container 100 is square container, four corner positions of first container 100 can be provided with first stand 11 respectively, and a plurality of first stands 11 can regard as the main skeleton texture of first container 100, guarantee first container 100's structural stability.

The corners of the second container 200 are provided with the second columns 21, for example, when the second container 200 is a square container, the four corners of the second container 200 may be respectively provided with the second columns 21, and the plurality of second columns 21 may be used as a main skeleton structure of the second container 200, so as to ensure the structural stability of the second container 200; and the second container 200 is disposed adjacent to the first container 100, that is, the second container 200 and the first container 100 are at the same level.

Referring to fig. 13, the connection structure 300 is disposed between the first container 100 and the second container 200, and is configured to connect the keel of the first upright 11 and the keel of the second upright 21 to ensure the integrity of the container group.

In addition, the container group may be formed by increasing the number of containers connected in the horizontal direction on the basis of the structure of the container in which the first container 100 and the second container 200 are connected, so as to realize three or more container groups connected in series.

The application provides container group has effectively enlarged the capacity of container group through the mode of horizontal dilatation, makes container group when being applied to data center, can increase data center's construction scale and calculation power, has increased data center's application scope.

And the data center formed by the container group can reduce the capital construction cost of the data center on the basis of being suitable for more mainstream data center application scenes.

Optionally, referring to fig. 13, a first keel 12 is connected to the first upright 11, a second keel 22 is connected to the second upright 21, the connecting structure 300 includes a first connecting member 31, the first connecting member 31 includes a first connecting section 311, a first bending section 312 and a second bending section 313, and the first bending section 312 and the second bending section 313 are respectively connected to two ends of the first connecting section 311 and are bent in the same direction;

the first bending section 312 and the first connecting section 311 are matched to be buckled with the first keel 12, and the second bending section 313 and the first connecting section 311 are matched to be buckled with the second keel 22.

Specifically, first buckle section 312 with second buckle section 313 connect respectively in the both ends of first connecting section 311 and the syntropy back of buckling can form the first connecting piece 31 of U font, the U font opening of first connecting piece 31 can be blocked into simultaneously on first fossil fragments 12 and second fossil fragments 22, specifically can be first buckle section 312 and the position of buckling that first connecting section 311 formed with first fossil fragments 12 joint lock, second buckle section 313 with the position of buckling that first connecting section 311 formed with second fossil fragments 22 joint lock, in order to realize second container 200 with the connection of first container 100.

Optionally, referring to fig. 13, a third keel 13 is connected to the first upright 11, a fourth keel 23 is connected to the second upright 21, the connecting structure 300 includes a second connecting member 32, the second connecting member 32 includes a second connecting section 321, a third bending section 322 and a fourth bending section 323, and the third bending section 322 and the fourth bending section 323 are respectively connected to two ends of the second connecting section 321 and are bent in the same direction;

the third bending section 322 is matched with the second connecting section 321 to be buckled with the third keel 13, and the fourth bending section 323 is matched with the second connecting section 321 to be buckled with the fourth keel 23.

Specifically, the third bending section 322 and the fourth bending section 323 are respectively connected to the two ends of the second connecting section 321 and are bent in the same direction, so as to form a U-shaped second connecting member 32, the U-shaped opening of the second connecting member 32 can be simultaneously clamped into the third keel 13 and the fourth keel 23, specifically, the third bending section 322 and the bending position formed by the second connecting section 321 and the third keel 13 are clamped and fastened, and the fourth bending section 323 and the bending position formed by the second connecting section 321 and the fourth keel 23 are clamped and fastened, so as to improve the connection stability of the second container 200 and the first container 100.

Alternatively, referring to fig. 13, the second connecting member 32 and the first connecting member 31 are symmetrically connected to both sides of the first upright 11 and the second upright 21.

Specifically, in order to improve the strength and stability of the connection between the second container 200 and the first container 100, a connection structure may be respectively disposed on the inner side and the outer side of the first column 11 and the second column 21, so that the first connection member 31 on the outer side is fastened to the first keel 12 and the second keel 22, and the second connection member 32 on the inner side is fastened to the third keel 13 and the fourth keel 23, thereby preventing the second container 200 and the first container 100 from shifting after the connection.

Optionally, referring to fig. 13, the container set further includes a plurality of leveling washers 40, a portion of the leveling washers 40 is sandwiched between the connecting structure 300 and the keel of the first upright 11, and the remaining portion of the leveling washers 40 is sandwiched between the connecting structure 300 and the keel of the second upright 21.

Specifically, the keels on the first upright 11 may be first keels 12 and third keels 13 formed by light steel keels, and the keels on the second upright 21 may be second keels 22 and fourth keels 23 formed by light steel keels, so as to improve the structural stability of the second container 200 and the first container 100. And when first fossil fragments 12 and third fossil fragments 13 on the first stand 11 are assembled, can set up a plurality of and first fossil fragments 12 and the matching of third fossil fragments 13 size leveling gasket 40, simultaneously second fossil fragments 22 and the fourth fossil fragments 23 on the second stand 21 are when assembling, can set up a plurality of and second fossil fragments 22 and the matching of fourth fossil fragments 23 size leveling gasket 40 to compensate the error of fossil fragments in the installation, guarantee the precision of fossil fragments assembly. And the leveling gasket 40 is used without cutting the keel, and only simple nailing fixing and sealing treatment are needed, so that the keel fixing process is simplified.

Optionally, referring to fig. 14, a first bridge 14 is disposed in the first container 100, and a second bridge 24 is disposed in the second container 200;

the connection structure 300 includes a connection bridge 33, and the connection bridge 33 is disposed between the first bridge 14 and the second bridge 24 and configured to connect the first bridge 14 and the second bridge 24.

Specifically, the provision of the first tray 14 may facilitate the placement of cables within the first container 100, while the provision of the second tray 24 may likewise facilitate the placement of cables within the second container 200. When the connecting bridge 33 connects the first bridge 14 and the second bridge 24, the continuity and stability of the arrangement of the first bridge 14 and the second bridge 24 can be ensured.

Optionally, referring to fig. 14, one end of the first bridge 14 close to the connecting bridge 33 is provided with a first interface 141 and a first connecting piece 142, and one end of the second bridge 24 close to the connecting bridge 33 is provided with a second interface 241 and a second connecting piece 242;

one end of the connection bridge 33 is connected to the first interface 141 through the first connection piece 142, and the other end of the connection bridge 33 is connected to the second interface 241 through the second connection piece 242.

Specifically, the first connecting piece 142 may be a length-adjustable connecting piece, and when one end of the connecting bridge 33 is connected to the first interface 141 through the first connecting piece 142, the assembling error of the hoisted first bridge 14 and the connecting bridge 33 can be adjusted through the first connecting piece 142, so that the assembling compactness of the first bridge 14 and the connecting bridge 33 is ensured, the first bridge 14 and the connecting bridge 33 do not need to be cut and corrected on the project site, and the project site workload is reduced.

Similarly, the second connecting piece 242 may be a length-adjustable connecting piece, and when the other end of the connecting bridge 33 is connected to the second interface 241 through the second connecting piece 242, the second connecting piece 242 may be used to adjust an assembly error of the hoisted second bridge 24 and the connecting bridge 33, so as to ensure assembly compactness of the second bridge 24 and the connecting bridge 33.

Alternatively, referring to fig. 14, the first container 100 has a first top panel 15 and the second container 200 has a second top panel 25;

the first bridge 14 is connected to the first top plate 15 by a plurality of hanger rods 50, and the second bridge 24 is connected to the second top plate 25 by a plurality of hanger rods 50.

Specifically, when the first bridge 14 is connected to the first top plate 15 by a plurality of suspension rods 50, the length of the plurality of suspension rods 50 may be the same, so as to ensure that the first bridge 14 and the first top plate 15 are parallel to each other; in order to flexibly adjust the installation height of the first bridge 14, the lengths of the suspension rods 50 may not be completely the same.

Similarly, when the second bridge 24 is connected to the second top plate 25 by a plurality of suspension rods 50, the length of the plurality of suspension rods 50 may be the same to ensure that the second bridge 24 and the second top plate 25 are parallel to each other; in order to flexibly adjust the installation height of the second bridge 24, the lengths of the suspension rods 50 may not be completely the same.

Optionally, referring to fig. 14, the container group further comprises a cooling channel 60, the cooling channel 60 being disposed between the first top plate 15 and the second top plate 25.

Specifically, the cooling channel 60 may have an air cooling pipeline therein, so that when the heat generated by the shelter in the container group is large, the container group can be cooled; and the cooling passage 60 is disposed between the first top plate 15 and the second top plate 25, the cooling passage 60 can simultaneously cool the first container 100 and the second container 200 to ensure that the operating temperature of the first container 100 and the second container 200 is in a proper range.

Optionally, referring to fig. 14, the container group further comprises a top cover plate 70, the top cover plate 70 being connected to the inside of the cooling gallery 60 and closing the gap between the first top plate 15 and the second top plate 25.

Specifically, the cooling channels 60 may form prefabricated cooling channels, and the top cover plate 70 may also form a prefabricated top cover plate; when assembling the top sealing plate 70 and the cooling channel 60, a prefabricated cooling channel may be first installed between the first top plate 15 and the second top plate 25, then gaskets are installed on both sides of the prefabricated cooling channel, then the prefabricated top sealing plate is assembled on the inner side of the cooling channel 60, a stable assembly structure of the top sealing plate 70 and the cooling channel 60 is formed by the gaskets, and finally a bridge frame inside the container is installed. The top sealing plate 70 can ensure the internal sealing performance of the first container 100 and the second container 200 after closing the gap between the first top plate 15 and the second top plate 25.

Although some specific embodiments of the present application have been described in detail by way of example, it should be understood by those skilled in the art that the above examples are for illustration only and are not intended to limit the scope of the present application. It will be appreciated by those skilled in the art that modifications may be made to the above embodiments without departing from the scope and spirit of the present application. The scope of the application is defined by the appended claims.

Claims (10)

1. A container group applied to a data center is characterized by comprising:

the container comprises a first container (100), wherein a first cabinet (1001) and a second cabinet (1002) are arranged in the first container (100) side by side, and a first heat exchange channel (1003) is formed between the first cabinet (1001) and the second cabinet (1002);

a second container (200), a third cabinet (2001) and a fourth cabinet (2002) are arranged in the second container (200) side by side, a second heat exchange channel (2003) is formed between the third cabinet (2001) and the fourth cabinet (2002), and the second container (200) and the first container (100) are arranged at intervals;

a connection structure (300), the connection structure (300) being disposed between the first container (100) and the second container (200), a cold passageway (3001) being formed inside the connection structure (300), and both sides of the cold passageway (3001) being respectively close to the second cabinet (1002) and the third cabinet (2001).

2. The container group according to claim 1, wherein the connecting structure (300) comprises a prefabricated roof panel (3002) and a prefabricated floor panel (3003), the prefabricated roof panel (3002) being connected between a top end of the first container (100) and a top end of the second container (200), the prefabricated floor panel (3003) being connected between a bottom end of the first container (100) and a bottom end of the second container (200) to form the cold aisle (3001) between the prefabricated roof panel (3002) and the prefabricated floor panel (3003).

3. The container group according to claim 1, wherein a first air chamber (1004) is arranged in the first container (100), an air outlet of the first air chamber (1004) is communicated with the cold channel (3001), and an air inlet of the first air chamber (1004) is communicated with the first heat exchange channel (1003);

a second air chamber (2004) is arranged in the second container (200), an air outlet of the second air chamber (2004) is communicated with the cold channel (3001), and an air inlet of the second air chamber (2004) is communicated with the second heat exchange channel (2003).

4. The container group according to claim 1, wherein a plurality of layers of first mounting structures are formed in the first container (100) in the height direction of the first container (100), wherein the first cabinet (1001) and the second cabinet (1002) are arranged side by side in each layer of the first mounting structures, and wherein the first heat exchange passage (1003) is formed between the first cabinet (1001) and the second cabinet (1002) in each layer.

5. The container group according to claim 1, wherein a plurality of layers of second mounting structures are formed in the second container (200) in a height direction of the second container (200), the third cabinet (2001) and the fourth cabinet (2002) are arranged side by side in each layer of the second mounting structures, and the second heat exchanging passage (2003) is formed between the third cabinet (2001) and the fourth cabinet (2002) in each layer.

6. A container group according to claim 1, wherein one of said first containers (100), one of said second containers (200) and one of said connecting structures (300) form a group of container structures, said group of containers comprising a plurality of groups of said container structures.

7. The set of containers of claim 1, wherein at least one IT shelter (102), power shelter (103), refrigeration shelter (104) and functional shelter (105) are disposed within the first container (100).

8. The set of containers of claim 1, wherein the length of the first container (100) is greater than or equal to 12000mm, the width of the first container (100) is greater than or equal to 2400mm, and the height of the first container (100) is greater than or equal to 2800mm.

9. The set of containers as claimed in claim 1, wherein a first bridge (14) is provided in the first container (100) and a second bridge (24) is provided in the second container (200);

the connection structure (300) comprises a connection bridge (33), the connection bridge (33) being arranged between the first bridge (14) and the second bridge (24) and configured to connect the first bridge (14) and the second bridge (24).

10. The group of containers as claimed in claim 9, characterized in that one end of said first bridge (14) close to said connection bridge (33) is provided with a first interface (141) and a first connection tab (142), one end of said second bridge (24) close to said connection bridge (33) is provided with a second interface (241) and a second connection tab (242);

one end of the connecting bridge (33) is connected to the first interface (141) through the first connecting piece (142), and the other end of the connecting bridge (33) is connected to the second interface (241) through the second connecting piece (242).

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