CN220123191U - Server cluster container and containerized server cluster device - Google Patents

Abstract

The utility model discloses a server cluster container and container type server cluster equipment. The integrated server cluster equipment comprises a server cluster container and a plurality of servers, wherein the servers are arranged on the rack and connected with the electric control system. The server cluster container disclosed by the utility model has the advantages that a plurality of servers are integrated to form the integrated server cluster equipment, the high-density deployment is realized, the calculation efficiency is high, and the mobility is strong.

Description

Server cluster container and containerized server cluster device

Technical Field

The utility model relates to the field of computing equipment, in particular to a server cluster container and container type server cluster equipment.

Background

A container server cluster is a cluster device that integrates components such as multiple servers, cooling systems, power supplies, and control systems into a container. With the tremendous growth in data processing demands, container server clusters have received attention for their ease of transportation and deployment.

How to set up the containerized server cluster in the container, improving the working efficiency of the server cluster is a technical problem that needs to be solved by the skilled person.

Disclosure of Invention

The utility model aims to provide a server cluster container which improves the working efficiency of the server cluster through reasonable layout in the container.

Another object of the present utility model is to provide a containerized server cluster tool comprising the server cluster container described above.

In order to achieve the above purpose, the server cluster container of the present utility model comprises a box body, a rack and an electric control system, wherein the rack and the electric control system are respectively arranged in the box body, and the electric control system comprises a power distribution cabinet connected with a server carried on the rack. The server cluster container disclosed by the utility model has the advantages that a plurality of servers are integrated to form the integrated server cluster equipment, the high-density deployment is realized, the calculation efficiency is high, and the mobility is strong.

The server cluster container comprises a rack and a power distribution cabinet, wherein the rack and the power distribution cabinet are arranged in a row along the length direction of the box body to form equipment rows, a plurality of servers are integrated in an optimal space arrangement mode, and space in the box body is fully utilized.

The server cluster container is characterized in that the racks are arranged on two sides of the power distribution cabinet. According to the utility model, the racks are arranged at two sides of the power distribution cabinet, the power supply lines led out from the two sides of the power distribution cabinet supply power to the servers on the racks at two sides, the power supply lines led out from the two sides of the power distribution cabinet are clear in wiring, management and maintenance of workers are easy, trouble caused by excessive overlong power supply lines of single-side leads and complicated line redundancy can be avoided, and maintenance manpower and equipment cost are reduced.

The server cluster container comprises a container body and a plurality of servers, wherein the container body comprises a first side radiating long side extending along the length direction, and the first side radiating long side is provided with a dustproof net and/or a shutter and/or a water curtain structure. Through setting up dust screen and/or shutter and/or cascade structure, dispel the heat to the server in the box, guarantee the high-efficient operation of system.

The server cluster container comprises a box body and a power distribution cabinet, wherein the box body comprises a second side radiating long side extending along the length direction, and a maintenance door is arranged at the position, corresponding to the power distribution cabinet, on the second side radiating long side. The maintenance door which is positioned outside the second long side and is right opposite to the power distribution cabinet is arranged, when maintenance is needed, a worker can walk outside the second long side of the box body, can directly walk into the box body by opening the maintenance door, and performs professional operation on the power distribution cabinet.

The server cluster container is characterized in that the second side radiating long side is provided with a cooling structure. Through setting up cooling structure, dispel the heat to the server in the box, guarantee the high-efficient operation of system.

The first side heat dissipation long side and the second side heat dissipation long side are oppositely arranged to form convection air cooling, so that the cooling effect is good and the cost is low.

The server cluster container is characterized in that a first maintenance channel is arranged between the first side heat dissipation long side of the container body and the equipment row. The first maintenance channel of the utility model is spacious and smooth, and is used for the staff to periodically check, maintain and maintain the system, equipment, network and the like, so that the system, the equipment, the network and the like can be ensured to normally run, faults and accidents are prevented, and the reliability and the stability of the system are improved.

The server cluster container comprises a box body and a plurality of storage units, wherein the box body comprises a first side short side and a second side short side which extend symmetrically along the width direction, and the positions of the first side short side and/or the second side short side corresponding to the first maintenance channel are provided with doors. The door is arranged on at least one side of the first side short side and the second side short side corresponding to the first maintenance channel, workers can enter the maintenance channel from the door, and go out from the door after checking, maintaining and maintaining the systems, equipment and networks in the box body, so that the working efficiency can be effectively improved.

The server cluster container, wherein the floor corresponding to the first maintenance channel in the container body is an insulating plate. The insulating floor can effectively isolate the electric connection between the ground and the electric equipment, and protect the safety of personnel and the equipment.

The server cluster container is characterized in that the positions of the first side short side and/or the second side short side of the container body, which correspond to the rack, and between the rack and the second side heat dissipation long side of the container body are closed walls. The first side short side and the second side short side are not corresponding to the first maintenance channel and are provided with a sealing wall sealing to the top, so that unnecessary design is simplified, and potential safety hazards and maintenance and equipment manufacturing cost are reduced.

The server cluster container is characterized in that a second maintenance channel is arranged between the second side heat dissipation long side of the container body and the equipment row. The second maintenance channel can be used for maintaining the cooling structure of the second side heat dissipation long side and equipment on the equipment row.

The server cluster container is characterized in that the width of the second maintenance channel along the width direction of the container body is larger than the thickness of the cooling structure, so that the cooling structure can be arranged in the container body.

The server cluster container is characterized in that the floor corresponding to the second maintenance channel in the container body is made of steel plates, so that firm ground support can be provided, and the strength, stability and the like of the container body are improved.

The server cluster container comprises a box body, wherein a wall plate is arranged at the position, corresponding to the power distribution cabinet, of the first side heat dissipation long side of the box body, and a cable leading-in port corresponding to the top end of the power distribution cabinet is arranged at the top of the wall plate. The cable inlet is directly corresponding to the top of the power distribution cabinet, the power utilization cable is introduced through the cable inlet and connected to the power distribution cabinet, the path is direct, the length of the power utilization cable inside and outside the box body is reduced, the space occupied by the power utilization cable in the box body is reduced, a large number of large-volume power utilization cables are prevented from being piled and extended in the box body, and the power utilization cable is convenient for workers to perform daily inspection, maintenance and maintenance work on systems, equipment and networks in the box body.

The server cluster container is characterized in that a cable supporting structure is arranged between the top of the power distribution cabinet and the cable introduction port and used for bearing the power cable introduced by the cable introduction port and connected to the power distribution cabinet.

The server cluster container comprises a cable frame groove and a hoisting structure, wherein the cable frame groove is used for supporting an electric cable, and the hoisting structure is used for hoisting the cable frame groove at the top of the container body.

The server cluster container comprises a box body, wherein the box body comprises a bottom plate, the machine frame vertically extends and is fixed on the bottom plate, and the power distribution cabinet is fixed on the bottom plate. The equipment row formed by the power distribution cabinet and the rack is fixedly connected with the bottom plate of the box body, so that the toppling and shifting in the loading, unloading and transporting processes are avoided.

The server cluster container is characterized in that the rack and the power distribution cabinet are fixedly arranged. Adopt the connecting piece to fix each other between frame and the switch board, the structure is more firm. In the process of transporting the container over a long distance, the container may be bumped, tilted, shaken, etc. due to the influence of road, weather, human factors, etc., resulting in damage to the goods. According to the server cluster container, the rack and the power distribution cabinet are stably fixed in the container, and long-distance transportation is more reliable and safer.

The server cluster container comprises a rack and a plurality of storage racks, wherein the rack comprises a plurality of partition plates, and the partition plates are of a net-shaped structure. The division board is netted, can not cause the shielding to put the server on it, and the staff of being convenient for in time observes the condition of each pilot lamp of each server, knows the operating condition of server at any time, can discover whether the server breaks down or abnormal conditions fast, helps in time taking measures, prevents that the server from shutting down because of the trouble, improves the reliability and the stability of server.

The server cluster container comprises a rack and a plurality of server cluster containers, wherein the rack comprises wire arranging grooves, and the wire arranging grooves comprise L-shaped clamping pieces which are oppositely arranged. The wire arranging clamp groove is used for wiring and accommodating cables such as communication wires. The wire arranging grooves are arranged at intervals along the partition plates, for example, and the wires are orderly fixed in the wire arranging grooves. The cable arranging clamp groove can avoid the conditions of loosening, dropping and entanglement of cables, and reduce wire damage, so that the equipment safety and the production efficiency are improved, the box body can be tidier, and the daily maintenance and management of staff are facilitated.

The server cluster container comprises an electric control system and a plurality of power distribution units, wherein the electric control system comprises a plurality of power distribution units connected with the power distribution units, and the power distribution units are arranged on the outer sides of the partition boards and used for providing power sources for servers arranged on the partition boards of the rack.

The server cluster container is characterized in that the power supply distributor is arranged on the partition plate at the non-bottommost layer, namely, the power supply distributor is not arranged on the partition plate at the bottommost layer of the rack, so that the damage of water vapor and dirt to the power supply distributor is avoided.

The server cluster container further comprises an extension baffle plate, wherein the extension baffle plate horizontally extends from the partition plate, and the length of the rack along the width direction is increased.

The server cluster container is characterized in that a power distributor is arranged on the outer side of the partition plate and/or the extension baffle plate, and provides power sources for servers arranged on the partition plate and/or the extension baffle plate of the rack.

The server cluster container described above, wherein the partition plate includes a high partition plate higher than or equal to a set height and a low partition plate lower than the set height, and the extension baffle is disposed outside each high partition plate. The set height is, for example, the height of the maintainer, namely, the position higher than the height of the maintainer is provided with the extension baffle, so that the supporting space of the frame is expanded under the condition that the daily work of the maintainer is not influenced.

According to the server cluster container, the extension baffle is arranged on the outer side of the partition plate at the topmost layer, the integration quantity of servers is increased based on the limited space, and the computing capacity of the container type server cluster equipment can be improved.

The server cluster container further comprises a top-level device state feedback device. The working state of the server positioned at the topmost layer can be known in time by a worker during maintenance.

The server cluster container, wherein the top-level equipment state feedback device comprises a reflector observation device. The state feedback device of the top-layer equipment adopts a reflector observation device, does not need to carry out any software and hardware investment on the server, and can monitor the state of the server in real time by means of a state indicator lamp of the server. The number of mirror observation devices may be one or plural.

The server cluster container comprises a plurality of feedback areas, wherein each feedback area corresponds to at least one server arranged on the topmost partition plate and/or the extension baffle, and the working state of each server is fed back in real time, so that workers can conveniently and timely process the server, and the working efficiency of equipment is guaranteed.

The server cluster container further comprises an intelligent monitoring system connected with the electric control system. The intelligent monitoring system can improve the reliability, stability and safety of the equipment, reduce the maintenance cost, improve the working efficiency, and simultaneously can provide data support to help the management and optimization of the equipment.

The server cluster container comprises a server cluster container body, wherein the intelligent monitoring system further comprises an access control authority module, an illumination sensing module, an anti-theft monitoring module and one of fireproof modules, and each functional module of the whole system is intelligently monitored to timely treat abnormal conditions.

The server cluster container is characterized in that a partition plate is arranged on one side of the frame along the length direction of the container body. The plane where the isolation plate is located divides the interior of the container into a hot area and a cooling area, wherein the cold area is the area where the first maintenance channel is located, and the hot area is the other area.

The server cluster container is characterized in that the isolation plate is arranged close to an air outlet of a server borne by the rack. The servers are arranged on the rack and are provided with air inlets and air outlets, wherein the air inlets of the servers are positioned in the cold area, and the air outlets of the servers are positioned in the hot area.

The server cluster container is characterized in that the air outlet of the server borne by the corresponding rack on the isolation plate is provided with a vent. The ventilating openings corresponding to the air outlets of the servers are formed in the isolating plates, so that hot air in the servers is discharged to the cold area, and the isolating plates ensure smooth removal of the hot air in the servers and can prevent the hot air in the hot area from flowing back to the cold area.

The utility model relates to a container type server cluster device, which comprises a plurality of servers and the server cluster container, wherein the servers are arranged on a rack and are connected with an electric control system.

The utility model will now be described in more detail with reference to the drawings and specific examples, which are not intended to limit the utility model thereto.

Drawings

FIG. 1 is a perspective view of one embodiment of a server farm container of the present utility model;

FIG. 2 is a perspective view of an embodiment of a server farm container (the first side heat dissipating long side is not shown);

FIG. 3 is a front view of an embodiment of a server farm container of the present utility model (viewed from a first side heat sink long side perspective);

FIG. 4 is a front view of an embodiment of the present utility model showing a distribution bracket apparatus for a container;

FIG. 5 is a perspective view of one embodiment of a server farm container of the present utility model (top panel of the enclosure not shown);

FIG. 6 is a perspective view of one embodiment of a server farm container of the present utility model (top panel of the enclosure not shown);

FIG. 7 is a top view of one embodiment of a server farm container of the present utility model (top panel of the enclosure not shown);

FIG. 8 is a side view of one embodiment of a server farm container of the present utility model;

FIG. 9 is a front view of an embodiment of a server farm container of the present utility model (viewed from a first side heat sink long side perspective);

FIG. 10 is a partial view of the cable tray and bar of the server farm container of the present utility model;

FIG. 11 is a front view of an embodiment of a server farm container of the present utility model (viewed from a second side heat sink long side perspective);

FIG. 12 is a perspective view of one embodiment of a rack of a server farm container of the present utility model;

FIG. 13 is an enlarged view of a portion of FIG. 12;

fig. 14 is a side view (with power distributor connected) of one embodiment of a rack of a server farm container of the present utility model.

Wherein reference numerals are used to refer to

1: server cluster container

11: corner post

12: bottom side beam

13: top side beam

14: corner fitting

100: box body

110: long heat dissipation edge of first side

120: second side radiating long side

130: short side of the first side

140: second side short side

150: bottom plate

200. 200a, 200b, 200c, 200d: rack

210. 210a, 210b, 210c, 210d, 210e, 210f, 210g: partition plate

230: extension baffle

240: wire arranging groove

310. 310a, 310b: power distribution cabinet

330a1, 330a2, 330b, 330c, 330d, 330e, 330f: power supply distributor

400: equipment row

500: first maintenance channel

600: door

700: closure wall

801: wall board

802: cable leading-in port

803: cable frame groove

804: stop lever

900: maintenance door

S: distribution bracket device for container

Detailed Description

The following detailed description of the present utility model is provided with reference to the accompanying drawings and specific embodiments, so as to further understand the purpose, the scheme and the effects of the present utility model, but not to limit the scope of the appended claims.

Certain terms are used throughout the description and following claims to refer to particular components or elements, and it will be appreciated by those of ordinary skill in the art that a technical user or manufacturer may refer to the same component or element by different terms or terminology. The present specification and the following claims do not take the form of an element or component with the difference in name, but rather take the form of an element or component with the difference in function as a criterion for distinguishing. In the following description and in the claims, the terms "include" and "comprise" are used in an open-ended fashion, and thus should be interpreted to mean "include, but not limited to. The term "coupled," as used herein, includes any direct or indirect electrical connection. Indirect electrical connection means include connection via other devices.

It should be noted that, in the description of the present utility model, terms such as "transverse," "longitudinal," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and "about," or "about," "substantially," "left and right," etc. indicate orientations or positional relationships or parameters, etc. based on the orientation or positional relationships shown in the drawings, are merely for convenience of description and simplicity of description, and do not indicate or imply that the apparatus or elements being referred to must have a specific orientation, a specific size, or be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

Currently, container-type servers have become a dominant device in the computing device industry. The server cluster container 1 in some embodiments of the utility model is used to load and integrate multiple server devices to form a containerized server cluster device. Referring to fig. 1 and 2, a server cluster container 1 according to some embodiments of the present utility model includes a box 100, a rack 200, and an electric control system, where the rack 200 and the electric control system are respectively disposed and integrated in the box 100, and the rack 200 is used to carry a plurality of servers, and the electric control system is connected to the plurality of servers carried on the rack 200 to provide services such as power distribution, communication, and so on for the servers.

The electrical control system includes a power distribution cabinet 310, the power distribution cabinet 310 being connected to a server carried on the rack 200. The power distribution cabinet 310 is used to provide power to the entire system, and includes at least one of a main power input, a power management unit, a battery pack, a UPS (uninterruptible power supply), and the like.

As shown in fig. 2 and 3, the racks 200 and the power distribution cabinets 310 are arranged in a row along the length direction of the cabinet 100 to form an equipment row 400, and the space in the cabinet 100 is fully utilized.

In some embodiments, the setup rack 200 is configured on both sides of the power distribution cabinet 310.

Through setting up frame 200 in switch board 310 both sides, the power supply line that switch board 310 was drawn forth to both ends is supplied power to the server on the frame 200 of both sides, and the power supply line that switch board 310 was drawn forth to both ends walks the line clearly, and the staff is easy to manage and maintain, can avoid the trouble that the power supply line of unilateral lead wire too much overlength, the redundant complicacy of circuit arouse, has reduced the manpower and the equipment cost of maintaining.

In some embodiments, the racks 200 are symmetrically disposed on both sides of the power distribution cabinet 310.

Through setting up the frame 200 symmetry configuration of switch board 310 both sides, can arrange the server of the same quantity specification on the frame 200, the power supply line that switch board 310 was drawn forth to both ends is even and the line is clear, and the staff is easy to manage and maintain, can avoid the trouble that the power supply line of unilateral lead wire too much overlength, the redundant complicacy of circuit arouse, has reduced the manpower and the equipment cost of maintaining. And moreover, the balance of the whole counterweight of the container can be further ensured, and the reliability of the whole equipment is improved.

In some embodiments, as shown, one rack 200a and 200b are respectively configured on two sides of the power distribution cabinet 310a, and the specifications of the racks 200a and 200b are the same, or that is, the lengths, widths, and heights of the racks 200a and 200b are the same, so as to have the capability of carrying the same number of servers with the same specifications.

It should be noted that, herein, a rack refers to a rack that is not a physical rack, but refers to racks on two sides of a power distribution cabinet that have the same specifications and the same capacity of carrying servers, so that the power distribution cabinet uniformly supplies power to two sides. The racks on the two sides of the power distribution cabinet can be connected with each other to form a whole.

In other embodiments, two or more racks 200 with the same specifications and the same number may be symmetrically configured on two sides of the power distribution cabinet 310, so as to ensure that the power distribution cabinet 310 transmits power to the uniform leads of the servers on the racks on the two sides.

As shown in fig. 4, a power distribution cabinet 310 is used as a power distribution bracket device S for a container together with symmetrically arranged racks 200 on both sides, and of course, the power distribution bracket device S for a container may further include accessories such as power supply lines, communication lines, and the like. In the embodiment shown in fig. 2 and 3, two container power distribution bracket apparatuses S are disposed in the case 100, that is, the power distribution cabinet 310a has the same rack 200a and 200b disposed on both sides thereof, and the power distribution cabinet 310b has the same rack 200c and 200d disposed on both sides thereof. Preferably, the specifications of the racks 200a, 200b, 200c and 200d are the same, and balance can be achieved in both power line distribution and weight distribution.

The two distribution bracket devices S for the containers are arranged in a row side by side, so that the number of the configurable servers is increased in a multiplied way on the premise of ensuring reliable electric control measures such as distribution and the like, and the calculation power of the integrated server cluster equipment is increased in a multiplied way. When the computing power of the integrated server cluster equipment is improved, requests and tasks can be processed more quickly, so that the response speed and the processing efficiency are improved, a large amount of data is supported to be processed, more complex application is supported, and higher performance requirements can be met.

Of course, in other embodiments, only one container power distribution bracket apparatus S may be provided in the case 100, or three or more container power distribution bracket apparatuses S may be provided, depending on the size of the case 100, the power demand, and the power distribution mode.

The electric control system not only has a power distribution function, but also comprises an air conditioning function, a cabinet power management function, a remote monitoring function and the like, wherein the air conditioning function, the cabinet power management function and the remote monitoring function are used for ensuring the normal operation and management of the server container through cooperation among all components. The air conditioning function part comprises an air conditioning controller, a compressor, a fan and other components, is used for maintaining the temperature and humidity inside the server container, the cabinet power management function part is used for monitoring and managing the power supply of each cabinet, and comprises power on/off, restarting, power consumption monitoring and the like, and the remote monitoring function part is used for remotely monitoring the state of the server container, and comprises acquisition and analysis of information such as temperature, humidity, power consumption, network connection and the like.

Referring back to fig. 1, the container 1 in some embodiments of the present utility model adopts a standard container structure, for example, the container body 100 of the container 1 in some embodiments of the present utility model is made of steel, aluminum alloy, and other materials, and has the characteristics of high strength, corrosion resistance, wear resistance, and the like. The container body 100 has corner posts 11, bottom side beams 12, top side beams 13, corner pieces 14, etc. arranged as a standard container, and is a main structural member of the container for supporting and reinforcing the container body 100 to have sufficient strength and rigidity to withstand the weight of goods and vibration and impact received during transportation.

As shown in fig. 5 to 7, the case 100 of the server farm container 1 according to some embodiments of the present utility model includes a first side heat dissipation long side 110, a second side heat dissipation long side 120, a first side short side 130, and a second side short side 140, wherein the first side heat dissipation long side 110 and the second side heat dissipation long side 120 are symmetrically disposed along the length direction of the case 100, and the first side short side 130 and the second side short side 140 are symmetrically disposed along the width direction of the case 100.

In some embodiments of the present utility model, the first side heat dissipation long side 110 and the second side heat dissipation long side 120 are provided with an air inlet and an air outlet, and a heat dissipation channel is formed between the air inlet and the air outlet. In some embodiments of the present utility model, the first side heat dissipating long side 110 and/or the second side heat dissipating long side 120 are provided with cooling structures. In some embodiments of the present utility model, the first side heat dissipation long side 110 and/or the second side heat dissipation long side 120 are provided with dust screens and/or louvers. In some embodiments of the present utility model, the first side heat dissipation long side 110 is provided with a water curtain structure, and the second side heat dissipation long side 120 is provided with a fan cooling structure.

The server farm container 1 in some embodiments of the present utility model is a hexahedral shape formed by extending the first side heat dissipation long side 110, the second side heat dissipation long side 120, the first side short side 130 and the second side short side 140 to a height, and may have a size identical to that of a standard container of the current mainstream, for example, 20 ruler, 40 ruler, etc., and may be handled and transported in the same manner as the standard container, for example, using the same lifting and forklift handling equipment as the standard container, and the transportation equipment such as a land transportation vehicle, a sea transportation ship, etc., so as to greatly reduce the transportation cost. Of course, the server farm container 1 in some embodiments of the present utility model may be smaller than a standard container, and the standard container is used for loading during transportation, so as to avoid damage such as collision, displacement, etc. that may occur during transportation and loading and unloading. Further, a standard container may be loaded with one or more server farm containers 1 in some embodiments of the utility model.

The rack 200 and the power distribution cabinet 310 are arranged in a row, and the equipment row 400 is arranged along the extending direction of the first side heat dissipation long side 110 and the second side heat dissipation long side 120, and two sides of the equipment row 400 respectively abut against the first side short side 130 and the second side short side 140.

The integrated server cluster equipment is high-power density equipment, and needs to consume a large amount of electric energy to work, so that a large amount of heat can be generated in the working process, and heat dissipation treatment is needed to ensure the normal operation of the equipment.

The server cluster container 1 in some embodiments of the present utility model adopts air-cooled heat dissipation, which is a heat dissipation mode with high efficiency and low consumption, and the principle is that external air is introduced into the container to transfer heat into the air, and then the hot air is discharged out of the container, so as to achieve the purpose of heat dissipation.

The first side heat dissipation long side 110 is provided with an air inlet structure, and the second side heat dissipation long side 120 is provided with a cooling structure. The first side heat dissipation long side 110 and the second side heat dissipation long side 120, which are disposed opposite to each other, form a wind flow, and perform heat dissipation and cooling on the servers in the box 100.

In one embodiment, the first side heat dissipation long side 110 is provided with a shutter structure, and the second side heat dissipation long side 120 is provided with a cooling fan (as shown in fig. 6); alternatively, the first side heat dissipation long side 110 is provided with a dust-proof net structure, and the second side heat dissipation long side 120 is provided with a cooling fan (not shown), wherein the dust-proof net structure is made of a metal cutting net or a metal braiding net with net holes; or the first side radiating long side 110 is provided with a shutter and a dustproof net structure, and the second side radiating long side 120 is provided with a cooling fan, so that the cooling fan has good impurity prevention and air cooling effects; or, the outer side of the first side heat dissipation long side 110 is provided with a water curtain structure, so that air outside the box body 100 enters the cavity through a wet curtain with strong water absorption, water on the wet curtain evaporates in an adiabatic state to take away a large amount of latent heat, and purified, cooled and oxygen-enriched air is sent into the box body 100 through continuous convection, so that the heat dissipation effect is further improved. Or at least two of a dust screen structure, a louver structure, and a water curtain structure are installed at the outer side and/or the inner side of the first side heat dissipation long side 110.

The second side heat dissipation long side 120 is provided with a plurality of cooling fans, and the outside air is introduced into the container to flow through the cooling fans, thereby taking away heat so as to keep the temperature inside the container from being excessively high. In other embodiments, the cooling fan may be used in conjunction with a cooling tube, typically composed of a series of metal tubes, through which heat is transferred to the tank wall and then dissipated to the outside air. The method can increase the heat dissipation area of the container and improve the heat dissipation effect. Alternatively, the cooling fan may be used in combination with a heat sink consisting of a series of metal sheets through which heat is transferred to the air and then carried away. The method can increase the heat dissipation area of the container and improve the heat dissipation effect. In order to ensure the heat dissipation effect, it is necessary to ensure smooth ventilation around the container.

In some embodiments of the present utility model, the first side heat dissipation long side 110 and the second side heat dissipation long side 120 are opposite, so that the structure is simple, the cost is low, and the heat dissipation effect is good.

Further, the outer side of the first side heat dissipation long side 110 is provided with a water curtain structure, so that air outside the box 100 enters the cavity through a wet curtain with strong water absorption, water on the wet curtain evaporates in an adiabatic state to take away a large amount of latent heat, and purified, cooled and oxygen-enriched air is sent into the box 100 through continuous convection, so that the heat dissipation effect is further improved.

As shown in fig. 7 and 8, a first maintenance channel 500 is provided between the first heat dissipation long side 110 and the device row 400, and the first short side 130 and the second short side 140 are provided with a door 600 corresponding to the position of the first maintenance channel 500.

The device row 400 is disposed in parallel between the first heat dissipation long side 110 and the second heat dissipation long side 120, and the first maintenance channel 500 between the first heat dissipation long side 110 and the device row 400 is used for the staff to perform periodic inspection, maintenance and service on the system, the device, the network, etc., so as to ensure that they can normally run, prevent faults and accidents, and improve the reliability and stability of the system. The periodic maintenance can prolong the service life of the system, equipment, network and the like, reduce the times and cost of replacement and maintenance, improve the performance and efficiency of the system and reduce the waste of resources by optimizing the system, the equipment, the network and the like. Meanwhile, the maintenance channel can also carry out security check and protection on systems, equipment, networks and the like, and the security and confidentiality of information are guaranteed. Therefore, the maintenance channel plays an important role in ensuring the normal operation of the system and improving the reliability, stability, performance and safety of the system.

In some embodiments of the present utility model, the first maintenance channel 500 is spacious and smooth, and the doors 600 are disposed corresponding to at least one of the first side short side 130 and the second side short side 140 of the first maintenance channel 500, in this embodiment, the first side short side 130 and the second side short side 140 are respectively provided with the doors 600, and a worker can enter the first maintenance channel 500 from one of the doors 600, and then go out from the other door 600 after checking, maintaining and maintaining the systems, devices and networks in the box 100, thereby being convenient and fast and capable of effectively improving the working efficiency.

The floor of the first maintenance channel 500 in the embodiment of the utility model adopts insulating materials, so that the electrical safety of equipment maintenance and overhaul by workers is ensured.

In the embodiment of the utility model, the door 600 adopts an escape door structure, so that a worker can smoothly open the door 600 for escape in dangerous situations.

In one embodiment of the server farm container 1 according to some embodiments of the present utility model, the first side short side 130 and the second side short side 140 correspond to the rack 200 and the positions between the rack 200 and the second side heat dissipation long side 120 are the closed walls 700. That is, the door 600 provided on the first side short side 130 and the second side short side 140 is a half-open door, and the door is openable and closable only at the position corresponding to the first maintenance channel 500, and the position of the first side short side 130 and the second side short side 140 not corresponding to the first maintenance channel 500 is a top-sealed closed wall, so that unnecessary design is simplified, and potential safety hazards and maintenance and equipment manufacturing costs are reduced.

Meanwhile, the door 600 is provided with a door lock, the door lock supports various door opening modes, such as passwords, fingerprints, card swiping and the like, a proper unlocking mode is selected according to actual conditions, the door lock also supports various alarm modes, such as sound alarm, short message alarm and the like, and alarms are carried out on the conditions which do not accord with unlocking settings, so that loss is avoided.

In addition, the door lock can be subjected to authority management in a mode of setting an administrator password, so that only authorized personnel can know the password. Further, the door lock authority is set, and the door lock authorities of different users, such as an administrator, maintenance personnel, a common user and the like, are set. Different users have different authorities, and better management of the door lock can be realized. For example, parameters such as door opening time, door closing time, alarm time and the like of the door lock can be set so as to meet different use requirements, for example, the door opening time of a common user is limited to be short, the door opening time of maintenance personnel is long, and the door opening time of an administrator is not limited.

In some embodiments, a second maintenance channel is provided between the second side heat dissipating long side 120 and the device row 400. The width of the second maintenance channel in the width direction of the case 100 is greater than the thickness of the cooling structure. The floor of the box body 100 corresponding to the second maintenance channel is made of steel plates, so that firm ground support can be provided, and the strength, stability and the like of the box body are improved.

In some embodiments, the frame is provided with a spacer plate on one side along the length of the case. Illustratively, the racks and the power distribution cabinets form equipment rows along the length of the cabinet. And a separation plate is arranged on one side of the equipment row along the length direction of the box body. Illustratively, the separator is disposed proximate to an air outlet of a server carried on the rack. An air vent is provided on the partition plate, corresponding to the air outlet of the server carried on the rack.

In some embodiments, a partition plate is disposed on a side, away from the first maintenance channel 500, of the equipment row 400 formed by the power distribution cabinet 310 and the rack 200, where the partition plate extends along the length direction and the width direction of the container, the height of the partition plate is substantially consistent with the height of the space in the container, the length of the partition plate is substantially consistent with the length of the space in the container, and the plane of the partition plate divides the interior of the container into a hot area and a cooling area. The cold zone is the region where the first maintenance channel 500 is located, and the hot zone is another region.

In some embodiments, a plurality of servers are installed on the rack 200, the servers having air inlets and air outlets, wherein the air inlets of the servers are located in the cold zone and the air outlets of the servers are located in the hot zone. The corresponding vent corresponding to the air outlet of the server is formed in the isolation plate, so that hot air in the server is discharged to the cold area, and the isolation plate ensures smooth removal of the hot air in the server and can prevent the hot air in the hot area from flowing back to the cold area.

In the server farm container 1 according to some embodiments of the present utility model, as shown in fig. 5, 7 and 9, the equipment row 400 formed by the power distribution cabinet 310 and the rack 200 is located between the first heat dissipation long side 110 and the second heat dissipation long side 120, and the first heat dissipation long side 110 is provided with a shutter (and/or a dust screen and/or a water curtain structure), where a wall plate 801 is further provided on a portion of the power distribution cabinet 310 corresponding to the equipment row 400 of the first heat dissipation long side 110, and the shutter (and/or the dust screen and/or the water curtain structure) is provided corresponding to the position of the rack 200, so that damage to the power distribution cabinet 310 caused by moisture or sunlight is avoided while external wind is ensured to enter the box 100 through the shutter (and/or the dust screen and/or the water curtain structure). As shown in fig. 9, the wall panels 801 are disposed between adjacent louvers (and/or dust screens and/or water curtain structures).

The wall plate 801 is made of, for example, steel plate. The portion of the wall plate 801 can be reinforced with transverse and longitudinal ribs, so that the overall strength of the box body 100 is improved, the deformation resistance and extrusion resistance of the box body 100 are enhanced, and the possibility of damage during loading, unloading and transportation is reduced.

Further, as shown in fig. 5 and 6, the top of the wall plate 801 has a cable introduction port 802, and the cable introduction port 802 is disposed corresponding to the top end of the power distribution cabinet 310.

The server power cable needs to use a high-quality copper core cable to ensure stability and reliability of current transmission. Meanwhile, the outer skin of the cable should have certain performances of wear resistance, high temperature resistance, corrosion resistance and the like. The length of the server power cable needs to be selected according to practical situations. In general, the cable length should not be too long to avoid excessive resistance and power loss during current transfer. The electric cable for the server needs to have certain safety performance, such as fire prevention, explosion prevention, electric shock prevention, and the like. In selecting a cable, care needs to be taken whether relevant security authentication criteria, such as UL, CE, etc., are met.

The power consumption of the server is large, and the sectional area of the power consumption cable of the server needs to be large enough to meet the high power requirement of the server. When the power distribution cabinet 310 needs more servers for power supply, the number and the size of the power cables connected with the power distribution cabinet 310 are larger.

In some embodiments of the present utility model, by arranging the cable inlet 802 at the top end of the wall plate 801, the cable inlet 802 directly corresponds to the top of the power distribution cabinet 310, and the power utilization cable is introduced through the cable inlet 802 and connected to the power distribution cabinet 310, so that the path is direct, the length of the power utilization cable inside and outside the box body 100 is reduced, the space occupied by the power utilization cable in the box body 100 is reduced, a large number of large-volume power utilization cables are prevented from being accumulated and extended in the box body 100, and the daily inspection, maintenance and maintenance work of the system, equipment and network in the box body 100 are facilitated for staff.

Further, a cable support structure is provided between the top of the power distribution cabinet 310 and the cable introduction port 802, and the cable support structure includes a cable frame slot for supporting a cable and a hoisting structure for hoisting the cable frame slot to the top of the box.

As shown in fig. 6 and 7, a cable frame groove 803 is provided between the top of the power distribution cabinet 310 and the cable introduction port 802. The cable frame 803 is led from the top of the wall plate 801 directly to the top of the power distribution cabinet 310, and after the power cable is led in from the cable lead-in port 802, the power cable is connected to the power distribution cabinet 310 through the bearing of the cable frame 803. From the perspective of the interior of the enclosure 100, for example, from the perspective of the interior of the first maintenance channel 500, the cable frame groove 803 spans across the first maintenance channel 500, and the cable frame groove 803 is located above the first maintenance channel 500 between the power distribution cabinet 310 and the wall plate 801, so that the cable frame groove 803 is generally not touched by a worker during the daily work of walking in the first maintenance channel 500, and the presence of the cable frame groove 803 does not affect the daily work of the worker.

In detail, referring to fig. 10, in this embodiment, the cable frame 803 has a U shape with two curved sides, and the power cable is connected to the power distribution cabinet 310 through the cable frame 803 via the cable inlet 802, so that the power distribution cabinet is safe and reliable. Both sides of the cable frame 803 are provided with a blocking lever 804 for preventing the power cable in the cable frame 803 from falling from the side. Preferably, the stop bars 804 are arranged in pairs, for example, in the middle of the two sides of the cable tray 803. In other embodiments, the blocking rods 804 may be arranged in pairs, and are separated along two sides of the cable frame 803, so that the anti-falling effect is better. The stop lever 804 is made of a material with higher strength, for example, a metal material, and may be in a rod shape or a sheet shape, or the top of the opposite stop lever 804 may be bent and expanded to form an inlet, which is beneficial to the introduction of the power cable. Of course, the lever 804 may also be used as a lifting structure for lifting the cable frame slot 803 to the top of the box 100.

In this embodiment, the cable frame slot 803 is a mesh structure, so that the load can be observed in time, and the weight is light.

In the server farm container 1 according to some embodiments of the present utility model, the equipment row 400 formed by the power distribution cabinet 310 and the rack 200 is located between the first heat dissipation long side 110 and the second heat dissipation long side 120. Referring to fig. 6 and 11, the second long side 120 is provided with a heat dissipating device such as a heat dissipating fan, where a maintenance door 900 is disposed at a position of the second long side 120 corresponding to the power distribution cabinet 310 of the device row 400, and the heat dissipating device such as a heat dissipating fan is disposed at a position corresponding to the rack 200 of the device row 400, so that the heat dissipating device can take away heat dissipated by the server on the rack 200, and a worker can perform professional work such as cleaning, checking, maintenance, replacement, and upgrading on the power distribution cabinet 310 through the maintenance door 900.

Since the power distribution cabinet 310 is in a high temperature, high humidity operating environment, maintenance is required periodically to ensure safe and reliable operation thereof. When maintenance is required, a worker walks out of the second long side 120 of the box 100, opens the maintenance door 900 between the heat dissipating devices and facing the power distribution cabinet 310, and can walk into the box 100 directly and perform professional operation on the power distribution cabinet 310.

It should be noted that maintenance of the power distribution cabinet 310 needs to follow related safety standards and operation rules, so as to avoid safety accidents. In performing maintenance and repair, specialized tools and equipment are required and associated operating procedures and safety standards are followed.

Based on this, the maintenance door 900 in some embodiments of the present utility model is provided with a door lock, which generally supports a plurality of door opening modes, such as password, fingerprint, card swiping, etc., and selects a suitable door opening mode according to practical situations. The door lock also supports various alarm modes, and alarms are given to the condition that the unlocking setting is not met. In short, the door lock can also be locked by a special tool lock, and only a professional technician with a professional unlocking tool can unlock the door lock.

As shown in fig. 2, the enclosure 100 of the server farm container 1 according to some embodiments of the present utility model includes a bottom plate 150, a rack 200 vertically extends and is fixed to the bottom plate 150, and a power distribution cabinet 310 is fixed to the bottom plate 150. That is, the equipment row 400 formed by the power distribution cabinet 310 and the rack 200 is fixedly connected with the bottom plate 150 of the box body 100, so that toppling and displacement in the processes of loading, unloading and transporting are avoided.

The rack 200 and the power distribution cabinet 310 can be mutually fixed by adopting connecting pieces, so that the structure is more stable. In the process of transporting the container over a long distance, the container may be bumped, tilted, shaken, etc. due to the influence of road, weather, human factors, etc., resulting in damage to the goods. The server cluster container 1 in some embodiments of the present utility model stably fixes the rack 200 and the power distribution cabinet 310 in the box 100, and the rack 200 and the power distribution cabinet 310 are also mutually fixed, so that long-distance transportation is more reliable and safer.

As shown in fig. 2 and 3, the distribution bracket device S for a container according to some embodiments of the present utility model includes a rack 200 and a distribution cabinet 310, the rack 200 and the distribution cabinet 310 are arranged in a row at intervals, the rack 200 is symmetrically disposed at both sides of the distribution cabinet 310, and the rack 200 and the distribution cabinet 310 are fixed to each other. The racks 200 disposed on both sides of the power distribution cabinet 310 have the same specifications to carry the same number of servers. The racks 200 on both sides of the power distribution cabinet 310 may be in a split structure or may be connected together.

According to the distribution bracket device S for the container, the racks on two sides of the distribution cabinet are symmetrically arranged, servers with the same number and specification can be arranged on the racks, and the distribution cabinet has the advantages of average power supply lines led out to the two ends, clear wiring and weight balance.

Further, the power distribution cabinet 310 and the rack 200 are correspondingly arranged in multiple groups, that is, the container power distribution bracket devices S in some embodiments of the present utility model are configured in multiple groups and connected to each other. In the embodiment shown in fig. 2 and 3, two sets of distribution tray means S for containers are arranged side by side. In other embodiments, the container power distribution bracket apparatuses S may be arranged in columns or in a matrix, which is within the scope of the present utility model.

As shown in fig. 12, the rack 200 includes a partition plate 210, and the partition plate 210 has a mesh structure. There are various kinds of indication lamps on the server, such as a power supply indication lamp indicating whether to power on, a network indication lamp indicating whether to connect to a network, a status indication lamp indicating an operating status, a fault indication lamp indicating whether a fault occurs, a temperature indication lamp indicating whether a temperature is normal, a fan indication lamp indicating whether a fan is operating normally, etc. The indicator lights may provide useful information about the status and failure of the server, which may help staff to quickly diagnose and solve the problem. In order to know the working state of each server, the state of each indicator light needs to be paid attention to in time.

In some embodiments of the present utility model, the partition board 210 of the rack 200 adopts a mesh structure, which does not cause shielding of the servers disposed thereon, so that a worker can observe the condition of each indicator light of each server in time, know the working state of the server at any time, and can quickly find out whether the server has a fault or an abnormal condition, thereby being helpful for taking measures in time, preventing the server from being stopped due to the fault, and improving the reliability and stability of the server.

As shown in fig. 13, the rack 200 includes a wire arranging slot 240, and the wire arranging slot 240 includes an L-shaped clip member disposed opposite to each other for routing and accommodating cables such as communication wires. The wire-arranging grooves 240 are provided at intervals along the partition plate 210, for example, and the wires are fixed in order in the wire-arranging grooves 240. The wire arranging groove 240 can avoid the condition that the cable is loose, falls and is entangled, and reduce the damage of the wire, thereby improving the safety and the production efficiency of the equipment, and enabling the inside of the box 100 to be more neat, and facilitating the daily maintenance and management of staff.

The container server cluster apparatus in some embodiments of the present utility model is formed by integrally loading a plurality of servers with the server cluster container 1, or that is, the container server cluster apparatus in some embodiments of the present utility model is formed by integrally loading a plurality of servers with the server cluster container 1 including the distribution bracket device for the container.

The server arrangement is disposed on the rack 200 and is connected to the power distribution cabinet 310 and other communication modules included in the electronic control system. The container server cluster equipment in some embodiments of the utility model can be manufactured to be of standard container size, can be loaded and unloaded with the standard container and can be transported, and can also be manufactured to be smaller than the standard container in size and can be loaded into the standard container for loading and unloading.

As shown in fig. 12 and 13, the distance between the separate layers of the rack 200 corresponds to the height at which the servers stand, i.e., the servers stand on the separate layers of the rack 200.

The electric control system comprises a plurality of power distributors connected with the power distribution cabinet 310, wherein the power distributors are configured on the outer side of each partition board 210 of the rack 200 and are used for providing power for servers arranged on each partition board 210 of the rack 200. Generally, the power supply distributor is disposed on a non-bottom partition plate of the rack 200, i.e., the power supply distributor is not disposed on the bottom partition plate of the rack 200, so as to prevent the damage of moisture and dirt to the power supply distributor. Of course, the utility model is not limited thereto.

At the top of the rack 200, the space up to the top of the cabinet 100 is insufficient to accommodate an upright server device. In order to improve the calculation power of the integrated server cluster equipment, the number of servers is improved while the calculation capability of a single server is ensured, so that an effective mode for improving the calculation power is realized.

The utility model prolongs the length of the uppermost partition plate 210 of the rack 200 along the width direction of the box body 100 by arranging the extension baffle 230, can enable the servers to be arranged upside down, increases the integration quantity of the servers, and can improve the computing capability of the containerized server cluster equipment. Of course, the servers at the topmost level may be arranged normally upright, where the head space permits.

The extension baffle 230 of the rack 200 of the present utility model is not limited to the uppermost partition plate, and in some embodiments, the extension baffle 230 extends horizontally from the partition plate 210 at any one or more positions to increase the length of the rack 200 in the width direction. The outside of the partition plate 210 and/or the extension baffle 230 is provided with a power distributor.

In some embodiments of the present utility model, the partition plate 210 includes a high partition plate higher than or equal to a set height and a low partition plate lower than the set height, and the extension baffle 230 is disposed at an outer side of each high partition plate. The set height is, for example, the height of the maintainer, that is, the position higher than the height of the maintainer is provided with the extension baffle 230, so that the supporting space of the rack 200 is expanded without affecting the daily work of the maintainer.

The top-most partition plate of the rack 200 is provided with two power distributors, a server on the top-most partition plate of the rack 200 is connected with one power distributor, the other power distributor on the top-most partition plate is connected with a server on a partition plate of the next layer, and the servers on the other partition plates are respectively connected with the power distributors on the partition plates of the previous layer.

Taking the rack 200 shown in fig. 14 as an example, the rack 200 has 7 partition plates 210a to 210g from top to bottom, wherein the partition plate 210a is located at the topmost layer and the partition plate 210g is located at the bottommost layer. Servers are arranged in an array on the partition plates 210a to 210g, respectively. The top-most partition plate 210a is connected with an extension baffle 230 in an extending manner, the outer side of the extension baffle 230 is connected with a power supply distributor 330a1, the outer side of the top-most partition plate 210a is connected with a power supply distributor 330a2, the outer side of the partition plate 210b is connected with a power supply distributor 330b, the outer side of the partition plate 210c is connected with a power supply distributor 330c, the outer side of the partition plate 210d is connected with a power supply distributor 330d, the outer side of the partition plate 210e is connected with a power supply distributor 330e, the outer side of the partition plate 210f is connected with a power supply distributor 330f, and the outer side of the partition plate 210g is not connected with a power supply distributor.

The servers arranged on the partition plate 210g are connected with the power distributor 330f of the previous layer, the servers arranged on the partition plate 210f are connected with the power distributor 330e of the previous layer, the servers arranged on the partition plate 210e are connected with the power distributor 330d of the previous layer, the servers arranged on the partition plate 210d are connected with the power distributor 330c of the previous layer, the servers arranged on the partition plate 210c are connected with the power distributor 330b of the previous layer, the servers arranged on the partition plate 210b are connected with the power distributor 330a2 of the previous layer, and the servers arranged on the partition plate 210a are connected with the power distributor 330a 1.

That is, each partition plate below the topmost partition plate forms a "up-down" connection relationship in which the power supply distributor on the upper partition plate connects the servers on the lower partition plate. Not only is the operation convenient, but also the damage of water vapor and stains in the box body 100 to the power supply distributor can be reduced.

In the related art, a switch is respectively arranged on each power supply distributor to control the power-on or power-off. In some embodiments, a switch module is provided in the power distribution cabinet 310 that controls each power distributor, the switch module enabling independent control of each power distributor. For example, the switch module realizes the power-on or power-off control of each power supply distributor, when a certain power supply distributor needs to be maintained or a server connected to the certain power supply distributor needs to be subjected to power-off maintenance, the power-off treatment is only required to be independently carried out on the certain power supply distributor through the switch module, the maintenance is convenient, and the safety is improved. In addition, since the switch module is arranged in the power distribution cabinet in a centralized manner, the control of all the power distributors can be realized in a centralized manner, and the operation is convenient, for example, when a plurality of power distributors need to be turned off or on, the operation of moving to the vicinity of each corresponding power distributor is not needed.

Referring to fig. 12 and 13, in order to enhance the overall strength of the rack 200, in an embodiment of the present utility model, the top partition 210a and the extension baffle 230 are in a plate shape, and a worker cannot know the working state of the server located at the top partition 210a in time during maintenance. The integrated server cluster device in some embodiments of the present utility model further includes a top-level device status feedback device configured to feedback a top-level device status. The top-level device state feedback device is realized in various modes such as software monitoring, hardware monitoring, remote monitoring, log monitoring and the like.

In an embodiment of the utility model, the state feedback device of the top-level equipment adopts a reflector observation device, so that the state of the server can be monitored in real time by means of a state indicator lamp of the server without any software and hardware investment on the server. The mirror observation device is connected to a server provided in the case 100 on the partition plate 210a corresponding to the topmost layer.

The number of mirror observation devices is at least one, and each mirror observation device corresponds to at least one server. For example, each mirror viewing device corresponds to 1, 2 or more servers, and the present utility model is not limited in this regard.

The mirror observation device includes a plurality of feedback areas, each corresponding to at least one server disposed on the topmost partition plate 210a, for feeding back an operating state of the at least one server. The number of the reflector observation devices can be one or a plurality of, the working states of the servers can be fed back in time, workers can process the reflectors in time, and the working efficiency of equipment is guaranteed.

In other embodiments, the top-most divider plate 210a and the extension baffle 230 may also be formed in a net shape to facilitate the status monitoring thereof by the staff. In this case, the setting of the top-level device status feedback means may be canceled.

In some embodiments, the server farm container 1 includes a top bulkhead and a top corrugated board disposed opposite each other with a top wiring line between the top bulkhead and the top corrugated board. The top baffle realizes hiding protection to the top wiring pipeline. In some embodiments, a thermal insulating layer is further provided on the upper side of the top partition, and is made of a thermal insulating material, so that the outside and heat can be isolated from entering the area below the top partition. Further, a foaming material, such as polyurethane foaming material, is filled between the heat insulation layer and the top corrugated plate, so that the heat insulation effect is further improved.

The integrated server cluster device in some embodiments of the utility model further comprises an intelligent monitoring system connected with the server and the electric control system, wherein the intelligent monitoring system can improve the reliability, stability and safety of the device, reduce the maintenance cost, improve the working efficiency, and provide data support and help to manage and optimize the device.

The intelligent monitoring system also comprises an access control authority module, a lighting sensing module, an anti-theft monitoring module, a fireproof module, a water immersion alarm module and the like.

For example, the intelligent monitoring system of the integrated server cluster device may be set by the following steps:

determining a monitoring index: first, the indexes to be monitored, such as information of the running state of the structure, temperature, access control, illumination, monitoring, fire prevention and the like, need to be determined. These indices may be specifically determined according to the use environment.

Selecting a sensor and a monitoring device: and using proper sensors and monitoring equipment according to the index to be monitored. For example, a temperature sensor, an entrance guard controller, an illumination controller, a monitoring camera, and other devices may be selected, information such as temperature, entrance guard status, light quantity, images, and the like may be collected and converted into useful information, which may be used to monitor device status, predict device failure, optimize production processes, and the like.

Connection device and sensor: the sensor and monitoring device are connected to the server cluster in a cartridge, for example by means of a network connection or a physical connection.

And (3) installing a monitoring assembly: the monitoring component can monitor the state, performance, log and other information of the equipment and provide alarm and notification functions.

And (3) configuring a monitoring system: the monitoring system is configured according to the needs, such as setting monitoring indexes, alarm thresholds, notification modes and the like.

In the testing and using process, the functions and performances of the system can be continuously optimized and adjusted so as to ensure the normal operation and accuracy of the monitoring system and meet the use requirements. The system can adopt a human-computer interface form, and display on-site data and information to operators in an intuitive way through devices such as a display screen, a keyboard and a mouse, so that the operators can monitor and control conveniently. And the functions of remote monitoring, remote maintenance, data analysis and the like can be realized through the cloud platform, so that the production efficiency and the management level are improved.

The intelligent monitoring system in some embodiments of the utility model also comprises system operation and infrastructure operation and maintenance monitoring, and can set and switch control equipment through a remote operation platform.

In an embodiment of the server cluster container of the present utility model, the server cluster container 2 includes a box 100, a rack 200 and an electric control system, where the rack 200 and the electric control system are respectively disposed and integrated in the box 100, and the rack 200 is used for carrying a plurality of servers, and the electric control system is connected to the plurality of servers carried on the rack 200 to provide services such as power distribution, communication, etc. for the servers. The racks 200 and the power distribution cabinets 310 are arranged in a row along the length direction of the cabinet 100 to form an equipment row 400, and the space in the cabinet 100 is fully utilized. The rack 200 is symmetrically disposed at two sides of the power distribution cabinet 310. The case 100 includes a first side heat dissipation long side 110, a second side heat dissipation long side 120, a first side short side 130, and a second side short side 140, wherein the first side heat dissipation long side 110 and the second side heat dissipation long side 120 are symmetrically arranged along a length direction of the case 100, and the first side short side 130 and the second side short side 140 are symmetrically arranged along a width direction of the case 100. The server farm container 2 is a hexahedral shape formed by extending the first side heat dissipation long side 110, the second side heat dissipation long side 120, the first side short side 130 and the second side short side 140 to a height, and can be the same size as the standard container of the current mainstream, for example, 20 ruler, 40 ruler and the like, and can be handled and transported in the same manner as the standard container, for example, by using the same handling equipment of lifting and fork truck as the standard container, and the transportation equipment of land transportation vehicles, sea transportation vessels and the like, thereby greatly reducing the transportation cost. Naturally, the server cluster container 2 can be smaller than a standard container, and the standard container is used for loading during transportation, so that damages such as collision and displacement possibly generated during transportation and loading and unloading are avoided. Further, a standard container may be loaded with one or more server farm containers 2 in some embodiments of the utility model.

The rack 200 and the power distribution cabinet 310 are arranged in a row, and the equipment row 400 is arranged along the extending direction of the first side heat dissipation long side 110 and the second side heat dissipation long side 120, and two sides of the equipment row 400 respectively abut against the first side short side 130 and the second side short side 140.

The first side heat dissipation long side 110 and the equipment row 400 are provided with a first maintenance channel 500, and the first side short side 130 and the second side short side 140 are provided with a door 600 corresponding to the first maintenance channel 500.

The device row 400 is disposed in parallel between the first heat dissipation long side 110 and the second heat dissipation long side 120, and the first maintenance channel 500 between the first heat dissipation long side 110 and the device row 400 is used for the staff to perform periodic inspection, maintenance and service on the system, the device, the network, etc., so as to ensure that they can normally run, prevent faults and accidents, and improve the reliability and stability of the system.

In some embodiments of the present utility model, the first maintenance channel 500 is spacious and smooth, and the doors 600 are disposed corresponding to at least one of the first side short side 130 and the second side short side 140 of the first maintenance channel 500, for example, the first side short side 130 and the second side short side 140 are respectively provided with the doors 600, and a worker can enter the first maintenance channel 500 from one of the doors 600, and then go out from the other door 600 after checking, maintaining and maintaining the systems, devices and networks in the box 100, thereby being convenient and fast and effectively improving the working efficiency.

The positions of the first side short side 130 and the second side short side 140 corresponding to the rack 200 and between the rack 200 and the second side heat dissipation long side 120 are the closed walls 700. That is, the door 600 provided on the first side short side 130 and the second side short side 140 is a half-open door, and the door is openable and closable only at the position corresponding to the first maintenance channel 500, and the position of the first side short side 130 and the second side short side 140 not corresponding to the first maintenance channel 500 is a top-sealed closed wall, so that unnecessary design is simplified, and potential safety hazards and maintenance and equipment manufacturing costs are reduced.

The first side heat dissipation long side 110 is provided with a dust screen and/or a louver, and the second side heat dissipation long side 120 is provided with a cooling structure. In addition, a water curtain structure can be installed on the outer side of the first side heat dissipation long side 110, so that the heat dissipation effect is further improved.

The portion of the first heat dissipation long side 110 corresponding to the power distribution cabinet 310 of the equipment row 400 is further provided with a wall plate 801, and the louver (and/or the dust screen) is arranged at a position corresponding to the rack 200, so that external wind is prevented from damaging the power distribution cabinet 310 by water vapor or sunlight while entering the box body 100 through the louver (and/or the dust screen). As shown in fig. 9, the wall panels 801 are disposed between adjacent louvers (and/or dust screens).

The wall plate 801 is made of, for example, steel plate. The portion of the wall plate 801 can be reinforced with transverse and longitudinal ribs, so that the overall strength of the box body 100 is improved, the deformation resistance and extrusion resistance of the box body 100 are enhanced, and the possibility of damage during loading, unloading and transportation is reduced.

Further, the top of the wall plate 801 is provided with a cable inlet 802, and the cable inlet 802 is arranged corresponding to the top end of the power distribution cabinet 310.

The power consumption of the server is large, and the sectional area of the power consumption cable of the server needs to be large enough to meet the high power requirement of the server. When the power distribution cabinet 310 needs more servers for power supply, the number and the size of the power cables connected with the power distribution cabinet 310 are larger.

In some embodiments of the present utility model, by arranging the cable inlet 802 at the top end of the wall plate 801, the cable inlet 802 directly corresponds to the top of the power distribution cabinet 310, and the power utilization cable is introduced through the cable inlet 802 and connected to the power distribution cabinet 310, so that the path is direct, the length of the power utilization cable inside and outside the box body 100 is reduced, the space occupied by the power utilization cable in the box body 100 is reduced, a large number of large-volume power utilization cables are prevented from being accumulated and extended in the box body 100, and the daily inspection, maintenance and maintenance work of the system, equipment and network in the box body 100 are facilitated for staff.

Further, a cable frame groove 803 is provided between the top of the power distribution cabinet 310 and the cable introduction port 802. The cable frame 803 is led from the top of the wall plate 801 directly to the top of the power distribution cabinet 310, and after the power cable is led in from the cable lead-in port 802, the power cable is connected to the power distribution cabinet 310 through the bearing of the cable frame 803. From the perspective of the interior of the enclosure 100, for example, from the perspective of the interior of the first maintenance channel 500, the cable frame groove 803 spans across the first maintenance channel 500, and the cable frame groove 803 is located above the first maintenance channel 500 between the power distribution cabinet 310 and the wall plate 801, so that the cable frame groove 803 is generally not touched by a worker during the daily work of walking in the first maintenance channel 500, and the presence of the cable frame groove 803 does not affect the daily work of the worker.

The cable frame 803 is, for example, U-shaped with two curved sides, and the power cable is connected to the power distribution cabinet 310 through the cable frame 803 via the cable inlet 802, so that the power distribution cabinet is safe and reliable. Both sides of the cable frame 803 are provided with a blocking lever 804 for preventing the power cable in the cable frame 803 from falling from the side. Preferably, the stop bars 804 are arranged in pairs, for example, in the middle of the two sides of the cable tray 803. In other embodiments, the blocking rods 804 may be arranged in pairs, and are separated along two sides of the cable frame 803, so that the anti-falling effect is better. The stop lever 804 is made of a material with higher strength, for example, a metal material, and may be in a rod shape or a sheet shape, or the top of the opposite stop lever 804 may be bent and expanded to form an inlet, which is beneficial to the introduction of the power cable. The lever 804 may also be used as a lifting structure for lifting the cable tray 803 to the top of the housing 100. The cable frame groove 803 is a mesh structure, can observe the load in time, and is light in weight.

Of course, the present utility model is capable of other various embodiments and its several details are capable of modification and variation in light of the present utility model, as will be apparent to those skilled in the art, without departing from the spirit and scope of the utility model as defined in the appended claims.

Claims (35)

1. The server cluster container is characterized by comprising a box body, a rack and an electric control system, wherein the rack and the electric control system are respectively arranged in the box body, and the electric control system comprises a power distribution cabinet connected with a server borne on the rack; the box includes along the long limit of length direction extension's first side heat dissipation, the long limit of first side heat dissipation is provided with the cascade structure.

2. The server farm container of claim 1, wherein the racks and the power distribution cabinets are arranged in a row along a length of the cabinet to form a row of equipment.

3. The server farm container of claim 1, wherein the racks are disposed on both sides of the power distribution cabinet.

4. The server farm container of claim 1, wherein the first side heat dissipating long side is provided with a dust screen and/or a louver.

5. The server farm container of claim 1, wherein the housing includes a second side heat dissipating long side extending in a length direction, and wherein a maintenance door is provided on the second side heat dissipating long side at a position corresponding to the power distribution cabinet.

6. The server farm container of claim 5, wherein the second side heat dissipating long side is provided with a cooling structure.

7. The server farm container of claim 2, wherein the first side heat dissipating long side of the housing has a first maintenance channel between the equipment row.

8. The server farm container of claim 7, wherein the housing includes first and second side short sides extending symmetrically in a width direction, the first and/or second side short sides being provided with doors corresponding to positions of the first maintenance aisle.

9. The server farm container of claim 7, wherein the floor within the housing corresponding to the first maintenance aisle is an insulating panel.

10. The server farm container of claim 1, wherein the locations of the first and/or second side short sides of the enclosure corresponding to the rack and between the rack and the second side heat dissipating long side of the enclosure are enclosure walls.

11. The server farm container of claim 2, wherein a second maintenance channel is provided between the second side heat dissipating long side of the housing and the equipment row.

12. The server farm container of claim 11, wherein the width of the second maintenance channel in the width direction of the housing is greater than the thickness of the cooling structure.

13. The server farm container of claim 12, wherein the floor within the housing corresponding to the second maintenance aisle is steel.

14. The server farm container of claim 1, wherein a wall is provided on a first side of the housing at a location corresponding to the power distribution cabinet, the top of the wall having a cable entry corresponding to the top of the power distribution cabinet.

15. The server farm container of claim 14, wherein a cable support structure is disposed between the top of the power distribution cabinet and the cable entry.

16. The server farm container of claim 15, wherein the cable support structure comprises a cable trough that supports cables and a lifting structure that lifts the cable trough to the top of the bin.

17. The server farm container of claim 1, wherein the housing comprises a floor, the rack extends vertically and is secured to the floor, and the power distribution cabinet is secured to the floor.

18. The server farm container of claim 17, wherein the rack and the power distribution cabinet are fixedly disposed.

19. The server farm container of claim 1, wherein the rack comprises a plurality of divider plates, the divider plates being in a mesh configuration.

20. The server farm container of claim 1, wherein the rack includes a line card slot including oppositely disposed L-shaped clips.

21. The server farm container of claim 19, wherein the electrical control system comprises a plurality of power distributors coupled to the power distribution cabinet, the power distributors being disposed outside of each of the divider panels.

22. The server farm container of claim 21, wherein the power supply dispensers are disposed on the non-bottommost separator plate.

23. The server farm container of claim 21, wherein the rack further comprises an extension baffle extending horizontally from the divider plate.

24. The server farm container of claim 23, wherein the power distributor is provided outside the partition plate and/or the extension barrier.

25. The server farm container of claim 23, wherein the divider panels include a high divider panel above or equal to a set height and a low divider panel below the set height, the extension baffle being disposed outside each of the high divider panels.

26. The server farm container of claim 23, wherein the extension baffle is disposed outside of the topmost divider.

27. The server farm container of claim 26, further comprising a top level device status feedback means.

28. The server farm container of claim 27, wherein the top level device status feedback means comprises mirror viewing means.

29. The server farm container of claim 28, wherein the mirror viewing device comprises a plurality of feedback zones, each feedback zone corresponding to at least one server disposed on the topmost divider and/or the extension baffle.

30. The server farm container of any of claims 1-29, further comprising an intelligent monitoring system connected to the electronic control system.

31. The server farm container of claim 30, wherein the intelligent monitoring system further comprises one of an access rights module, a lighting sensing module, a theft protection monitoring module, and a fire protection module.

32. The server farm container of claim 1, wherein the rack is provided with a spacer plate on one side along the length of the bin.

33. The server farm container of claim 32, wherein the spacer is positioned proximate to an air outlet of a server carried on the rack.

34. The server farm container of claim 32, wherein the separator is provided with vents corresponding to the air outlets of the servers carried by the racks.

35. A packaged server cluster comprising a plurality of servers, and further comprising a server cluster container according to any one of claims 1 to 34, said servers being disposed in an array on said rack and connected to said electronic control system.