CN220156866U - Packaging container and packaging server device - Google Patents

Abstract

The utility model discloses a packaged container and packaged server equipment, the packaged container comprises a container body, a rack and an electric control system, wherein the rack and the electric control system are respectively fixed in the container body, the outer outline size of the container body is smaller than the inner space size of a standard container, and the container body can be integrally loaded in the standard container. The utility model combines the design compactness, high working efficiency, high maintenance performance, high structural strength and high vibration and impact resistance, and simultaneously, the external dimensions of the length, the width and the height of the box body are designed to be smaller than the internal space dimension of the standard container, so that the packaged container can be integrally loaded in the standard container, the safety in the transportation process is improved, and the loss is reduced.

Description

Packaging container and packaging server device

Technical Field

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

Background

The integrated server cluster refers to that a plurality of servers are integrated in a container or a modularized cabinet to form a server cluster which can be rapidly deployed and moved. The method can improve the density and efficiency of the server, meet the rapidly-increased data processing requirement, reduce the energy consumption and the cost, and have flexibility and expandability.

How to keep the security and stability of the integrated server cluster in the long-distance transportation process under the condition of maximizing the integration, and reducing the damage in the transportation process are technical problems to be solved by the technicians in the field.

Disclosure of Invention

The utility model aims to provide a packaged container which is packaged in a standard container for long-distance transportation, so that the transportation safety and stability are ensured under the condition of maximizing integration, and the damage rate in the transportation process is greatly reduced.

It is a further object of the present utility model to provide a packaging server device comprising the packaging container as described above.

In order to achieve the above object, the container set according to the present utility model includes a container body having an outer peripheral dimension smaller than an inner space dimension of a standard container, and being capable of being integrally loaded in the standard container. The container referred to in the present utility model may be regarded as a special container. The suit container includes box, frame and electrical system, and frame and electrical system are fixed in the box respectively, and the outline size of box is less than the incasement space size of standard container, and the box can wholly load in standard container. The nested container disclosed by the utility model has the advantages that the compactness, the high working efficiency, the high maintenance performance, the high structural strength and the high vibration and impact resistance are combined, and the overall dimensions of the length, the width and the height of the container body are slightly smaller than those of the internal space of the standard container, so that the nested container disclosed by the utility model can be integrally loaded in the standard container, the safety in the transportation process is improved, and the loss is reduced.

The above-mentioned suit container, wherein, when the box is loaded in standard container, the left and right sides wall along length direction of box and the left and right inner walls along length direction of standard container have first clearance and/or second clearance respectively. Preferably, the sum of the first gap and the second gap is 90+ -20 mm.

The sleeved container is characterized in that the front side wall and the rear side wall of the container body along the width direction and the front and rear inner walls of the standard container along the width direction are respectively provided with a third gap and/or a fourth gap. Preferably, the sum of the third gap and the fourth gap is 90+ -20 mm.

The sleeved container is characterized in that a fifth gap is formed between the top wall of the container body and the top inner wall of the standard container. Preferably, the fifth gap is 40.+ -.10 mm.

The first to fifth gaps are used for providing moving mutual moving distance for the case of loading the suit container in the standard container, and providing assembly allowance for manufacturing errors, moving shaking and micro deformation, so as to prevent the case that the suit container cannot enter the standard container or is clamped in the loading process and cannot move relatively.

The container set comprises a first gap, a second gap, a third gap, a fourth gap and a fifth gap.

The buffer parts are filled in the first gap to the fifth gap, so that shaking and collision can be further prevented.

The buffer member includes a wooden structural member disposed at a bottom of at least one of the first to fifth gaps. Convenient operation and good buffering effect.

The buffer piece comprises an angle protection structural piece which is arranged on the corner piece of the box body. The corner protection members are for example wood, plastic, foam or rubber members. The corner piece parts of the box body are buffered by the corner protection structural parts, so that acting force when the corner piece collides with the inside of the standard container is reduced, and the box body is protected.

The buffer piece comprises a prismatic structure piece, wherein the prismatic structure piece is arranged on at least one of a corner post, a bottom side beam and a top side beam of the box body. The rib members are, for example, L-shaped, and are made of wood, plastic, foam or rubber. The side beam parts of the box body are buffered by the edge structural members, so that acting force when the side beam collides with the inside of the standard container is reduced, and the box body is protected from being safe.

The buffer member includes a foam member filled in at least one of the first to fifth gaps. The foam piece is used for buffering between each wall surface of the box body and the standard container.

The buffer parts can be combined for use to respectively buffer and protect different parts of the box body or to protect multiple parts of the box body.

The nested container further comprises a limiting piece, wherein the limiting piece is arranged in at least one of the first gap to the fifth gap and used for limiting the position of the nested container in the standard container, and the possibility that the nested container collides with the standard container is reduced.

The sleeved container comprises a limiting piece, wherein the limiting piece comprises a left limiting structural piece and a right limiting structural piece, and the left limiting structural piece and the right limiting structural piece are arranged in the middle of the first gap and/or the second gap along the length direction of the standard container. The first gap and the second gap are kept equal when the nested container is loaded in a standard container by arranging the limiting structural members on the left side and the right side.

The sleeved container comprises a limiting piece, wherein the limiting piece comprises a front limiting structural piece and a rear limiting structural piece, and the front limiting structural piece and the rear limiting structural piece are arranged in a third gap or a fourth gap far away from an inlet of the standard container. The third gap and the fourth gap remain equal when the nested container is loaded in a standard container by the arrangement of the front and rear side limiting structures.

According to the nested container, the movable auxiliary accessory which is convenient to move is arranged between the bottom of the container body and the bottom of the standard container, so that the friction force between the nested container and the standard container in the process of loading and unloading the nested container is reduced, and vibration and abrasion are reduced.

The above-mentioned encasement container, wherein the mobile auxiliary accessory comprises a roller device connected to the bottom of the container body. The roller device is connected to the bottom of the corner fitting of the box body, or the roller device is connected to the bottom side beam of the box body and/or the bottom of the corner fitting. The roller device is, for example, a metal wheel mounted on the bottom of the container, so that the container can move on the ground. The container wheels may be fixed or rotatable to facilitate adjustment of the orientation of the container.

The above-mentioned suit container, wherein, remove auxiliary accessory and include slide rail device, slide rail device connects in the bottom of box, or slide rail device connects on the bottom plate of standard container. The slide rail device is generally made of metal, so that the container can slide along the slide rail, the weight and friction of the container can be borne, and the container can be moved conveniently.

The above-mentioned nested container, wherein the auxiliary moving accessory comprises a slide plate device connected to the bottom of the container body or connected to the bottom plate of the standard container. A sliding plate is arranged between the bottom of the standard container and the bottom of the sleeved container, and the sliding plate device is made of metal plates, so that relative sliding is generated between the two devices, and friction force when the container moves is reduced.

The above-mentioned suit container, wherein, at least one box is loaded in standard container along the length direction of box. In other words, a plurality of nested containers can be loaded within one standard container.

The above-mentioned nested container, wherein the box includes the corner fitting. The nested container of the utility model further comprises a tightening piece connected between the corner fitting and the inner wall of the standard container, the tightening piece being used for locking the nested container with the standard container.

The above-mentioned suit container, wherein, electrical system includes the switch board, and the frame symmetry sets up in the both sides of switch board. Through setting up the frame symmetry configuration of switch board both sides, can arrange the server of the same quantity specification in the frame, the switch board is on average to the power supply line that both ends were drawn forth and is walked the line definition, and easily staff's management is maintained, can avoid the trouble that too much overlength of the power supply line of unilateral lead wire, line redundancy are complicated to cause, 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.

The suit container, wherein, the box is including the long limit of first side heat dissipation and the second side heat dissipation that set up relatively, and the long limit of first side heat dissipation is provided with dust screen and/or shutter, and the long limit of second side heat dissipation is provided with cooling structure. The utility model adopts air-cooled heat dissipation, which is a heat dissipation mode with high efficiency and low consumption, and has simple structure, low cost and good heat dissipation effect.

The suit container, wherein, cooling structure includes fan and fan mounting bracket, and the fan passes through the fan mounting bracket and installs in the box.

The sleeved container comprises the fan mounting frame and the supporting frame, wherein the connecting frame is connected to the container body, the supporting frame is detachably connected to the inner side or the outer side of the connecting frame through the fasteners, and the fan is arranged on the supporting frame. The fan is connected to the inner side or the outer side of the connecting frame through the supporting frame and can be arranged on the rear outer side of the inner side of the box body, so that the conversion between the inner side and the outer side of the fan is realized, and the different heat dissipation requirements of different areas are met.

The container is characterized in that the supporting frame comprises a fixing part and a supporting part, the fixing part is used for detachably connecting the connecting frame through a fastener, and the supporting part is used for supporting the fan. The supporting frame comprises a limiting part for limiting the displacement of the fan. The supporting frame is formed by bending and processing a metal plate to form a fixing part, a supporting part and a limiting part, and is simple to process and firm in structure.

The container set comprises a container body, wherein the container body is provided with a connecting frame, and the connecting frame is also connected with at least one of a top side beam, a bottom side beam and a corner post of the container body. The top side beam, the bottom side beam and the corner post structures of the container are utilized for installing the connecting frame, so that the structure is firm and is not easy to deform.

The sleeved container is characterized in that a protection wall is arranged at the position, corresponding to the power distribution cabinet, of the first side heat dissipation long side, and a dustproof net and/or a shutter are arranged at the position, corresponding to the rack, of the first side heat dissipation long side. The protective wall is made of, for example, steel plate and corner posts. The part of the protective wall can be added with transverse and longitudinal reinforcing ribs, so that the overall strength of the box body is improved, the deformation resistance and extrusion resistance of the box body are enhanced, and the possibility of damage during loading, unloading and transportation is reduced.

The suit container of foretell, wherein still include the cascade cooling structure and accomodate the cascade structure of accomodating the cascade cooling structure, the cascade is accomodate the structure and is located the box. Wherein, still include the annex case that is fixed in the box. The water curtain containing structure, the accessory box and the like are arranged in the box body, accessory facilities outside the box body are removed and fixed in the box body during transportation, and the size of the box body is minimized.

The packaging server device comprises a plurality of servers, and the packaging container is arranged on a rack and connected with an electric control system.

The packaged server equipment comprises a rack, wherein the top of the rack is provided with a topmost partition plate and an extension baffle plate horizontally extending from the topmost partition plate, and the topmost partition plate and/or the extension baffle plate is/are provided with a server. According to the utility model, the extension baffle plate connected to the outer side of the uppermost partition plate along the width direction of the box body is arranged, so that the length of the uppermost partition plate of the rack along the width direction of the box body is increased, the integration quantity of servers is increased, and the computing capacity of equipment can be improved.

The packaged server equipment further comprises a top equipment state feedback device, wherein the top equipment state feedback device is used for feeding back the working state of the servers on the topmost partition plate and/or the extension baffle plate.

The packaged server equipment comprises a top-layer equipment state feedback device and a top-layer equipment state feedback device. The utility model adopts the reflector as the state feedback device of the top-layer equipment, does not need any software and hardware investment on the server, and can monitor the state of the server in real time by means of the state indicator lamp of the 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 information in time, and the working efficiency of equipment is guaranteed.

The packaged server equipment comprises a reflector observation device, wherein the reflector observation device comprises a plurality of feedback areas, and each feedback area corresponds to at least one server arranged on the topmost partition plate and/or the extension baffle plate. Each feedback area corresponds to at least one server arranged on the topmost layered barrier, and the working state of each server is fed back in real time, so that workers can conveniently and timely make treatment, and the working efficiency of equipment is guaranteed.

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 shipping container kit of the present utility model;

FIG. 2 is a perspective view of one embodiment of a shipping container of the present utility model (top panel of the container is not shown);

fig. 3 to 5 are process diagrams of the nested container of the present utility model loaded in a standard container;

FIG. 6 is a perspective view of one embodiment of a shipping container of the present utility model (components located at the first side heat dissipating long side not shown);

FIG. 7 is a top view of FIG. 2;

FIG. 8 is a perspective view of one embodiment of a shipping container of the present utility model (showing the second side heat dissipating long side);

FIG. 9 is a partially exploded view of one embodiment of a shipping container kit of the present utility model;

FIG. 10 is an enlarged view of a portion of FIG. 9;

FIG. 11 is a partially exploded view of one embodiment of a shipping container kit of the present utility model;

FIG. 12 is a perspective view of one embodiment of a first support shelf of the shipping container kit of the present utility model;

FIG. 13 is an M-direction view of FIG. 12;

FIG. 14 is a perspective view of one embodiment of a second support shelf of the shipping container kit of the present utility model;

FIG. 15 is an N-directional view of FIG. 14;

FIG. 16 is a side view of an embodiment of a shipping container kit of the present utility model;

Fig. 17 is a side view of one embodiment of a rack of the packaged server device of the present utility model.

Wherein reference numerals are used to refer to

1. 1a, 1b, 1c: packaged container

11: corner post

12: bottom side beam

13: top side beam

14: corner fitting

2. 2a, 2b, 2c: standard container

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

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

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

230: extension baffle

310. 310a, 310b: power distribution cabinet

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

400: equipment row

500: maintenance access

600: door leaf

700: closure wall

801: protective wall

802: cable leading-in port

900: cooling structure

910. 910a, 910b: blower fan

920: connecting frame

930: supporting frame

931: first supporting frame

9311: first supporting and fixing part

9312: first spacing fixed part

9313: a first supporting part

9314: first limit part

9315: first auxiliary supporting part

932: second supporting frame

9321: second spacing fixed part

9322: second upper limit part

9323: second lower limit part

9324: a second upper supporting part

9325: a second lower supporting part

9326: second auxiliary supporting part

940: sealing frame

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.

References in the specification to "an embodiment," "another embodiment," "this embodiment," etc., indicate that the embodiment described may include a particular feature, structure, or characteristic, but every embodiment may not necessarily include the particular feature, structure, or characteristic. Furthermore, such phrases are not intended to refer to the same embodiment. Further, when a particular feature, structure, or characteristic is described in connection with an embodiment, it is submitted that it is within the knowledge of one skilled in the art to effect such feature, structure, or characteristic in connection with other embodiments whether or not explicitly described.

Certain terms are used throughout the description and following claims to refer to particular components or features, as one of ordinary skill in the art will appreciate that a technical user or manufacturer may refer to the same component or feature in different terms or terms. 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. In addition, the term "coupled" as used herein includes any direct or indirect connection.

It should be noted that, in the description of the present utility model, the directions or positional relationships indicated by the terms "lateral", "longitudinal", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present utility model and simplifying the description, and do not indicate or imply that the apparatus or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model. For purposes of clarity, the ordinal terms "first," "second," "third," "fourth," etc., herein are used for distinguishing an element, region, section, and the like from another element, region, section, or the like, and are not intended to limit the particular element, region, section, or the like.

The container server device is a solution of integrating a plurality of servers and network devices thereof into one box, has compact design, can accommodate the plurality of servers and network devices, provides high-performance computing and storage capacity in a limited space, saves space and reduces energy costs, and is usually preloaded with an operating system and management software for easy monitoring, management and maintenance. Because the server and the network equipment are both in one box body, the maintenance is more convenient.

As shown in fig. 1 and 2, fig. 1 and 2 are respectively an external integral structure representation of an embodiment of the shipping container of the present utility model and an internal integral structure representation without a roof. The nested container 1 according to some embodiments of the present utility model includes a container 100, a rack 200, and an electronic control system, where the rack 100 and the electronic control system are respectively fixed in the container 100, and the electronic control system is used to connect with a server carried by the rack 200. The electric control system includes a power distribution cabinet 310, and the rack 200 and the power distribution cabinet 310 are arranged in a row along the length direction of the box 100 to form a device row 400.

The overall dimensions of the length, width and height of the container body 100 of the shipping container 1 according to some embodiments of the present utility model are slightly smaller than the dimensions of the space within the standard container, so that the shipping container 1 according to some embodiments of the present utility model can be integrally loaded into the standard container. Referring to fig. 3 to 5, fig. 3 to 5 show loading process diagrams of the whole nested container 1 loaded in the standard container 2 according to some embodiments of the present utility model.

As shown in fig. 1, the container 1 of some embodiments of the present utility model adopts a standard container structure, that is, the container body 100 of the container 1 of some embodiments of the present utility model is made of materials such as steel, aluminum alloy, etc., and has the characteristics of high strength, corrosion resistance, wear resistance, etc. The container body 100 has corner posts 11, bottom side beams 12, top side beams 13, corner pieces 14, etc. arranged as in 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.

The nested container 1 according to some embodiments of the present utility model combines design compactness, high working efficiency, high maintenance performance, high structural strength and high vibration impact resistance, and the overall dimensions of the length, width and height of the container body 100 are designed to be slightly smaller than those of the space in the container 2, so that the nested container 1 according to some embodiments of the present utility model can be integrally loaded in the standard container 2.

The size of standard containers is generally specified in accordance with the ISO 668 standard and is divided into 20, 40, 45 etc. different sizes. Among them, the side-opening standard container of 20 rule (length about 6058mm, width about 2438mm, height about 2438 mm), 40 rule (length about 12192mm, width about 2438mm, height about 2438 mm), 40 rule high box (length about 12192mm, width about 2438mm, height about 2896 mm) is the mainstream form that is widely used in logistics transportation field, and the handling measure is perfect. The standardized container size facilitates the loading, unloading and transporting of goods and improves the efficiency and safety of the goods transportation.

The shipping container 1 of some embodiments of the present utility model is preferably used with 20-gauge and 40-gauge side-opening standard shipping containers 2. For example, when the container is used in combination with a standard container 2a of 20 gauge, the size of the space in the standard container 2a of 20 gauge is about 5898mm (length) x2352mm (width) x2393mm (height), and the external dimensions of the length, width and height of the container body 100 of the container 1a are slightly smaller than the size of the space in the standard container 2a of 20 gauge.

When the container is used together with a 40-scale standard container 2b, the size of the space in the container 2b is 12032mm (length) x2352mm (width) x2393mm (height), and the external dimensions of the length, width and height of the container body 100 of the container 1b are slightly smaller than the size of the space in the container 2 b.

When the standard container 2c with 40-gauge high container is used, the space size in the standard container 2c with 40-gauge high container is about 12032mm (length) x2352mm (width) x2698mm (height), and the external dimensions of the length, width and height of the container body 100 of the packaged container 1c are slightly smaller than the space size in the standard container 2c with 40-gauge high container. For practical application, the height of the 40-ruler high box is higher, so that the height of the packaged container 1 capable of being carried is also higher, and the integrated performance is higher.

It should be noted that the foregoing is merely exemplary, and the container package according to some embodiments of the present utility model may be used with standard containers of any size, which are all within the scope of the present utility model.

In addition, a plurality of shipping containers 1 according to some embodiments of the utility model may be loaded into a single standard shipping container. For example, when the container is used in combination with a 40-gauge standard container 2b, two nested containers 1a which are loaded by the 20-gauge standard container 2a can be loaded by one 40-gauge standard container 2b, and the two nested containers 1a are sequentially loaded along the length direction of the 40-gauge standard container 2 b.

Alternatively, two container sets of a standard container with a size slightly smaller than 10 and one container set of a standard container with a size slightly smaller than 20 are loaded through the standard container 2b with a size of 40, and two container sets of a standard container with a size slightly smaller than 10 and one container set with a size slightly smaller than 20 are sequentially loaded along the length direction of the standard container 2c with a size of 40. Alternatively, four containers having a size slightly smaller than 10 standard containers are loaded through the standard container 2b of 40 standard, and four containers having a size slightly smaller than 10 standard containers are sequentially loaded along the length direction of the standard container 2b of 40 standard. Similarly a standard container 2c of 40 gauge tall case may also be loaded with a plurality of nested containers of the same size or different sizes.

The length of the space size in the container is the distance from the inner side plate of the container door to the inner lining plate of the end wall, the width is the distance between the inner lining plates, and the height is the distance from the bottom plate surface to the lowest surface of the top plate, and the size is slightly different due to different ship carriers.

The server container adopts the structural form of the container, and the structural design of the container has the characteristics of standardization, generalization, high efficiency and the like, thereby facilitating the transportation and loading and unloading of cargoes. However, if the container is directly transported and loaded and unloaded as a container, the container may be damaged to different degrees with respect to the goods and the container itself if the container is knocked, shaken, etc. during the long-distance transportation of the container, including land transportation and sea transportation. Specific consequences include damage to the container itself, and possibly damage to the container body, door, sealing means, etc. due to knocks, jolts, etc., such as deformation, breakage, poor sealing, etc. It is also likely that the cargo within the container may be damaged, e.g., broken, deformed, etc., by knocks, jolts, etc.

For the nested container 1 according to some embodiments of the present utility model, if the nested container 1 is used as a standard container to directly carry out long-distance transportation such as sea transportation, land transportation, etc., the nested container 1 is easily damaged during the transportation, and the outside of the box 100 is damaged if the nested container 1 is light, including deformation, damage, etc., to the air cooling structure, the accessory connection structure, etc. at the periphery of the box 100, the structures such as heat dissipation, sealing, etc. of the server are directly affected, so that the server and the network equipment cannot work normally for a long time, and the frame 200, the electronic control system, etc. in the box 100 are damaged if the whole system cannot be used, and the loss is huge.

It can be seen that the combination of the nested containers 2 according to some embodiments of the present utility model has the characteristics of compact design, high working efficiency, easy maintenance, safety and reliability. The method for transporting the packaged container according to some embodiments of the utility model comprises the following steps:

as shown in fig. 3 to 5, the transportation method of the container package 1 according to some embodiments of the present utility model is as follows:

placing a packaged container 1 for arranging a plurality of servers into a standard container 2, wherein the external dimension of the packaged container or the external dimension of the packaged container is slightly smaller than the internal space dimension of the standard container;

The nested container 1 is discharged from the standard container.

The side walls around the container body 100 of the nested container 1 and the inner walls around the standard container 2 have a first gap to a fourth gap, respectively, and the top wall of the container body 100 of the nested container 1 and the top inner wall of the standard container 2 have a fifth gap, in detail, the left and right side walls of the container body 100 along the length direction and the left and right inner walls of the standard container 2 along the length direction have a first gap and/or a second gap, respectively. The front and rear side walls of the case 200 in the width direction and the front and rear inner walls of the standard container 2 in the width direction have a third gap and/or a fourth gap, respectively. The top wall of the case 100 has a fifth gap with the top inner wall of the standard container 2. The sum of the first gap and the second gap is set to 90+/-20 mm, the sum of the third gap and the fourth gap is set to 90+/-20 mm, and the fifth gap is set to 40+/-10 mm.

The gaps may be distances between the peripheral wall surfaces and the top wall surfaces of the case 100 and the peripheral and top inner walls of the standard container 2. In some embodiments, each corner piece 14 of the case 100 protrudes from the opposite wall, and each gap may be a distance between a side or top profile of each corner piece 14 of the case 100 and the periphery and top inner wall of the standard container 2.

The first to fifth gaps are used for providing a moving mutual moving distance for the nested container 1 when being loaded on the standard container 2, and providing assembly allowance for manufacturing errors, moving shaking and micro deformation, so as to prevent the nested container 1 from being unable to enter the standard container 2 or from being clamped and unable to move relatively in the loading process.

When the container is loaded, the packaged container 1 is pushed into the standard container 2 through a forklift or a hydraulic push rod; at the time of unloading, the corner pieces 14 of the case 100 of the shipping container 1 are connected by connecting members (e.g., ropes, wires, etc.) to pull the shipping container 1 out of the standard shipping container 2.

Preferably, the nested container 1 assists in pushing or pulling out the standard container 2 by means of bottom mounted rollers or slides, reducing friction with the standard container 2 during loading and unloading of the nested container 1, thereby reducing vibration and wear. The movement aid is, for example, a roller attached to the bottom of the container 100 of the nested container 1, or a rail device attached between the bottom of the container 100 and the floor of the standard container 2, etc.

In detail, the movement assisting attachment includes a roller device attached to the bottom of the case 100. The roller means is attached to the bottom of the corner fitting 14 of the box 100 or the roller means 100 is attached to the bottom side rail 12 and/or the bottom of the corner fitting 14 of the box 100. The roller device is, for example, a metal wheel mounted on the bottom of the container, so that the container can move on the ground. The container wheels may be fixed or rotatable to facilitate adjustment of the orientation of the container.

The mobile auxiliary accessory comprises a slide rail device which is connected to the bottom of the case 100 or to the floor of the standard container 2. The slide rail device is generally made of metal, so that the container can slide along the slide rail, the weight and friction of the container can be borne, and the container can be moved conveniently.

The mobile auxiliary accessory comprises a slide plate device attached to the bottom of the container 100 or to the floor of the standard container 2. A sliding plate is arranged between the bottom of the standard container and the bottom of the sleeved container, and the sliding plate device is made of metal plates, so that relative sliding is generated between the two devices, and friction force when the container moves is reduced.

And includes a tension member connected between the corner fitting 14 of the container body 100 and the inner wall of the standard container 2. In detail, after the nested container 1 is pushed into the standard container 2, the corner pieces 14 of the container body 100 of the nested container 1 are connected with the rope rings arranged at the corresponding corners in the standard container 2 through the tightening pieces. The tensioning piece is, for example, a bolt for tensioning, the purpose of tensioning is achieved by screwing the bolt and the nut, the structure is stable, and the dismounting is convenient. The tensioning piece can also adopt a tensioning rod, the two parts are firmly connected by using the tensioning rod or the connecting rod, and the middle part is tensioned by using the nut, so that the structure is light. Or the tensioning piece is a steel wire piece, so that the tension is very large, the flexibility is good, and the operation is convenient.

After the nested container 1 is pushed into the standard container 2, a buffer member is placed in at least one of the first gap to the fifth gap, so that shaking and collision can be further prevented.

The cushioning members include wood structural members, corner protection structural members, edge structural members, foam members, and the like. The wooden structural member is disposed at a bottom of at least one of the first to fifth gaps. Convenient operation and good buffering effect. The corner fittings are mounted to the corner pieces 14 of the box 100. The corner protection members are for example wood, plastic, foam or rubber members. The corner protection structural members buffer the corner pieces 14 of the box body 100, so that acting force when the corner pieces 14 collide with the inside of the standard container 2 is reduced, and the box body 100 is protected. The prism member is attached to at least one of the corner post 11, bottom side member 12, and top side member 13 of the box body 100. The rib members are, for example, L-shaped, and are made of wood, plastic, foam or rubber. The side beams and corner posts of the box body 100 are buffered by the edge structural members, so that acting force generated when the side beams and the corner posts collide with the inside of the standard container 2 is reduced, and the box body is protected from being safe. The foam member fills at least one of the first to fifth gaps. The foam members serve to cushion between the walls of the container body 100 and the standard container 2.

The above-mentioned buffer members can be used in combination to perform buffer protection or multiple protection on different parts of the case 100.

In some embodiments of the present utility model, the container 1 further includes a limiting member, where the limiting member is disposed in at least one of the first to fifth gaps, for limiting a position of the container 1 in the standard container 2, so as to reduce a possibility that the container 1 collides with the standard container 2.

The limiting piece comprises a left limiting structural piece and a right limiting structural piece, wherein the left limiting structural piece and the right limiting structural piece are arranged in the first gap and/or the second gap and are arranged along the length direction of the standard container 2 so as to limit the third gap and the fourth gap to keep equal when the nested container is loaded in the standard container. For example, left and right sides of the entrance of the standard container 2 are provided with left and right side restraining members having a certain width (for example, 35 mm), so that the set container 1 can be positioned at the middle of the width direction of the standard container 2 when being loaded. When the set container 1 is integrally loaded in the standard container 2, the set container 1 and the standard container 2 have a first gap and a second gap substantially equal to each other in front and rear sides in the longitudinal direction. The left and right limiting structures can be arranged at any position between the standard container 2 and the nested container 1 in the height direction in the first gap and the second gap.

The stopper includes front and rear side stopper structures provided at a third gap or a fourth gap apart from the entrance of the standard container 2 to restrict the third gap and the fourth gap from being kept equal when the nested container 1 is loaded in the standard container 2. For example, when the nested container 1 is loaded in the standard container 2, a third gap is formed between the entrance end of the standard container 2 and the nested container 1, a fourth gap is formed between the other end far from the entrance end and the nested container 1, and a front-rear side limiting structure (for example, 30 mm) with a certain width can be arranged in the fourth gap, so that when the nested container 1 is loaded in the standard container 2, the front end of the nested container 1 is abutted against the front-rear side limiting structure once, which indicates that the nested container 1 is already loaded in place, and the third gap on the front side and the rear side of the nested container 1 and the standard container 2 can be kept equal. And when the nested container 1 is loaded in place, the third gap at the entrance is also provided with front and rear side limiting structural members with certain width, so that the nested container 1 is prevented from shifting in the front and rear directions in the standard container 2. The front and rear limiting structures may be disposed at any position between the standard container 2 and the nested container 1 in the height direction in the third gap and the fourth gap.

In some embodiments of the present utility model, as shown in fig. 2, 6 and 7, the racks 200 and the power distribution cabinets 310 are arranged in a row along the length direction of the cabinet 100 to form a device row 400, so that the space in the cabinet 100 is fully utilized. Preferably, the racks 200 are symmetrically disposed on both sides of the power distribution cabinet 310 according to some embodiments of the present utility model.

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 this embodiment, as shown in fig. 6, two sides of the power distribution cabinet 310a are respectively configured with one rack 200a and 200b, where 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 specification.

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. For example, racks 200a and 200b having the same specifications are respectively disposed on both sides of the power distribution cabinet 310a, and racks 200c and 200d having the same specifications are respectively disposed on both sides of the power distribution cabinet 310 b. 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.

Further, the power distribution cabinet 310 and the racks 200 on both sides thereof serve as a power distribution bracket device S for containers, and in some embodiments, a plurality of power distribution bracket devices S for containers may be arranged side by side in a row according to the size, the power calculation requirement and the power distribution mode of the box 100, so that the number of configurable servers is increased by a multiple on the premise of ensuring reliable electric control measures such as power distribution, and the power calculation of packaged server devices is improved by a multiple. When the computing power of the packaged server equipment is improved, the requests and tasks can be processed more quickly, so that the response speed and the processing efficiency are improved, a large amount of data can be processed and more complex application is supported, and higher performance requirements can be met.

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 to fig. 2, 6 and 7, a container body 100 of a shipping 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 arranged along a length direction of the container body 100, and the first side short side 130 and the second side short side 140 are symmetrically arranged along a width direction of the container body 100.

In some embodiments of the present utility model, the side wall of the case 100 corresponding to the first side heat dissipation long side 110 and the side wall of the case 100 corresponding to 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 cooling structure 900 is disposed on the side wall of the case 100 corresponding to the first side heat dissipation long side 110 and/or on the side wall of the case 100 corresponding to the second side heat dissipation long side 120. In some embodiments of the present utility model, the first side heat dissipation long side 110 corresponds to a side wall of the case 100 and/or the second side heat dissipation long side 120 corresponds to a side wall of the case 100 and is provided with a dust screen and/or a shutter. In some embodiments of the present utility model, the first side heat dissipation long side 110 is provided with a water curtain cooling structure corresponding to the side wall of the box 100, and the second side heat dissipation long side 120 is provided with a fan cooling structure corresponding to the side wall of the box 100.

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 packaged server equipment is high-power-density equipment, and needs to consume a large amount of electric energy for working, 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 nested container 1 of 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.

As shown in fig. 1, 7 and 8, 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 900. 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. Some embodiments of the present utility model provide a first side heat dissipation long side 110 and a second side heat dissipation long side 120, which are opposite to each other, and the present utility model has a simple structure, low cost, and good heat dissipation effect.

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 structure 900; 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 structure 900, 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 heat dissipation long side 110 is provided with a shutter and a dustproof net structure, and the second side heat dissipation long side 120 is provided with a cooling structure 900, so that the cooling structure has good impurity prevention and air cooling effects; or, the outside of the long side 110 of the first side heat dissipation is provided with a water curtain cooling 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 great deal of latent heat, and purified and cooled air for oxygenation is sent into the box 100 to further improve the heat dissipation effect through continuous convection. Or at least two of a dust screen structure, a louver structure, and a water curtain cooling structure are installed at the outer side and/or the inner side of the first side heat dissipation long side 110.

As shown in fig. 8 and 9, the cooling structure 900 includes a plurality of fans 910, and the outside air is introduced into the interior of the container, so that the air flows through the fans 910 to remove heat so as to keep the temperature of the interior of the container from being excessively high. In other embodiments, the blower 910 may be used in conjunction with a heat pipe, typically composed of a series of metal pipes, 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, blower 910 may be used in conjunction with a heat sink that is composed 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.

The cooling structure 900 further includes a connection frame 920 and a support bracket 930, wherein the connection frame 920 is connected to the bottom side rail 12 and the top side rail 13 of the box body 100, or in some embodiments, the connection frame 920 is connected to the bottom side rail 12, the top side rail 13, and the corner posts 11 of the box body 100, and the structure is stable.

The support frame 930 is detachably connected to the connection frame 920 by a plurality of fasteners, and the blower 910 is disposed on the support frame 930. And, the fan 910 is connected with the power distribution cabinet 310 of the electric control system.

In detail, the cooling mechanism 900 is connected between the bottom side beam 12, the top side beam 13 and the corner posts 11 of the second side heat dissipation long side 120 of the box 100, and the supporting frame 930 is connected to the inner side of the connecting frame 920 located in the box 100 during long distance transportation of the container 1 according to some embodiments of the present utility model, and the fan 910 is located on the supporting frame 930, that is, the fan 910 is located in the space between the second side heat dissipation long side 120 and the equipment row 400 and does not protrude out of the box 100. In use, the shipping container 1 of some embodiments of the present utility model may be in a shipping state with the blower 910, i.e., the blower 910 is still inside the container 100 for operation. The support frame 930 is detachably connected to the inner side of the connection frame 920, which is located on the inner side of the box 100, and meanwhile, the outer side of the connection frame 920, which is located on the box 100, is also provided with a support frame connecting portion, and the support frame 930 can be connected to the support frame connecting portion of the connection frame 920, which is located on the outer side of the box 100, so as to realize the external arrangement of the fan 910.

In some embodiments of the present utility model, the connection frames 920 are, for example, multiple groups, wherein at least one group of connection frames 920 is partially connected to the front corner post of the case 100 on the front side, and at least one group of connection frames 920 is partially connected to the rear corner post of the case 100 on the rear side. Of course, in some embodiments, the connection frames 920 may also be a group.

In the embodiment shown in fig. 6 and fig. 9, the four groups of connection frames 920 correspond to the servers carried on the rack 200a, the servers carried on the rack 200b, the servers carried on the rack 200c, and the servers carried on the rack 200d, respectively, so that the heat dissipation performance is better. Each group of connection frames 920 carries 4 fans through the support frame 930, and the 4 fans are arranged in a shape of a Chinese character 'tian'. However, the number of fans of the cooling structure 900 is not limited in some embodiments of the present utility model, and the fans may be arranged according to the size, shape and exhaust amount of the fans on the premise of meeting the heat dissipation requirement.

The support frame 930 is formed, for example, by bending a metal plate, and specifically, the support frame 930 is formed with a fixing portion detachably connected to the inner side or the outer side of the connection frame 920 by a fastener, a supporting portion for supporting the blower fan, and a limiting portion for limiting the blower fan 910 on the supporting portion to prevent the blower fan 910 from moving or shaking.

Referring to fig. 10, 12 and 13, the support frame 930 includes a first support frame 931, and the first support frame 931 includes a first support fixing portion 9311, a first limit fixing portion 9312, a first support portion 9313 and a first limit portion 9314. The first support fixing portion 9311 is connected to the first support portion 9313, and the first limit fixing portion 9312 is connected to the first limit portion 9314. The first support fixing portion 9311 is formed by, for example, bending a metal plate material integral with the first support portion 9313 downward by ninety degrees, the first limit portion 9314 is formed by, for example, bending a metal plate material integral with the first support portion 9313 upward by ninety degrees, and the first limit fixing portion 9312 is formed by, for example, bending a metal plate material integral with the first limit portion 9314 in a direction away from the first support portion 9313. Preferably, the first supporting and fixing portion 9311 and the first limiting and fixing portion 9312 are located on the same plane. As shown in fig. 12, the first support fixing portion 9311 is connected to one short side of the first support portion 9313, two first limiting portions 9314 are provided, and two first limiting portions 9314 are provided at a limiting angle, which are connected to the first support portion 9313 and are different from two adjacent sides (one long side and one short side) of the first support fixing portion 9311. The other short side of the first support fixing portion 9311 is also bent downward to form a first auxiliary support portion 9315, and the first auxiliary support portion 9315 has a reinforcing rib function, which can enhance the support strength of the first support fixing portion 9311.

The first support fixing portion 9311 and the first limit fixing portion 9312 are respectively provided with a connection hole, and the fastener is connected to the inside or the outside of the connection frame 920 through the connection holes of the first support fixing portion 9311 and the first limit fixing portion 9312.

Referring to fig. 10, the first support frames 931 are disposed corresponding to corners of the fan 910a, and the two first support frames 931 are disposed opposite to each other and correspond to two corners of the bottom of the fan 910 a. The other two corners of the bottom of the blower 910a may be supported on the connection frame 920. That is, the two corners of the bottom of the fan 910a, which are farther from the second side heat dissipation long side 120, are respectively limited by the limiting angle of the first support bracket 931, which is constituted by the first limiting portion 931, and the two corners of the bottom of the fan 910a, which are closer to the second side heat dissipation long side 120, are supported by the connection frame 920.

Meanwhile, as shown in fig. 11, the cooling structure 900 further includes a sealing frame 940, where the sealing frame 940 is, for example, an integrally formed metal member, and the fan 910 is limited and sealed by the sealing frame 940 from the outside of the case 100.

Preferably, the four corners of the blower 910 are supported and restrained by the first support frame 931. Four first support frames 931 are oppositely and oppositely connected to the connection frame 920 corresponding to four corners of the fan 910.

Note that, when the fan 910 is arranged in a shape of a Chinese character 'ji', the connection frame 920 is shaped like a Chinese character 'ji', and the fan 910 is connected to each of the Chinese characters 'ji' of the connection frame 920.

In some embodiments, the connection frame 920 is, for example, in the shape of a bar, and when the fans 910 are arranged in a cross shape, the connection frame 920 is, for example, in the shape of a cross, and the cross-shaped connection frame 920 forms a frame for connection of the first support frame 931 together with the top side rail 13, the bottom side rail 12, and the corner posts 11 of the cabinet 100. For example, the first support frame 931 corresponding to the bottom corner of the blower fan 910 may be connected to the corner post 11 and/or the bottom side member 12, and the first support frame 931 corresponding to the top corner of the blower fan 910 may be connected to the corner post 11 and/or the top side member 13. At this time, the other two corners of the bottom of the blower fan 910 may be supported by the bottom side member 12.

The sealing frame 940 is disposed along four sides of the blower fan 910. A sealant or a sealing strip is provided between the sealing frame 940 and the connection frame 920.

As shown in fig. 10, 14 and 15, the support frame 930 further includes a second support frame 932, and the second support frame 932 is connected between the fans 910a and 910b disposed above and below, for supporting and limiting an upper corner of the lower fan 910a and a bottom corner of the upper fan 910b, i.e., the second support frame 932 can perform the functions of two first support frames 931 disposed adjacent to each other above and below. When the blower 910 is disposed up and down, the second support 932 may be used instead of the two first support 931 disposed adjacently up and down, so that the occupied area of the support can be reduced, and the area of the blower can be increased, thereby improving the air volume.

As shown in the drawing, the second support frame 932 includes a second limiting fixing portion 9321, a second upper limiting portion 9322, a second lower limiting portion 9323, a second upper supporting portion 9324, and a second lower supporting portion 9325, the second upper limiting portion 9322 and the second lower limiting portion 9323 are disposed up and down, the second limiting fixing portion 9321 is connected to vertical sides of the second upper limiting portion 9322 and the second lower limiting portion 9323, and the second upper supporting portion 9324 and the second lower supporting portion 9325 are laterally connected between the second upper limiting portion 9322 and the second lower limiting portion 9323.

The second upper limiting portion 9322 and the second lower limiting portion 9323 are integrally and vertically arranged metal plates, and the second limiting fixing portion 9321 is formed by bending the metal plates integrally formed with the second upper limiting portion 9322 and the second lower limiting portion 9323 in a direction away from the fan 910, based on limiting surfaces of the second upper limiting portion 9322 and the second lower limiting portion 9323 facing the fan 910. The second upper support portion 9324 and the second lower support portion 9325 are connected to the surfaces of the second upper limit portion 9322 and the second lower limit portion 9323, and are disposed up and down. The second upper supporting portion 9324 is formed by bending the upper side edge of the vertically disposed metal plate connected between the second upper limiting portion 9322 and the second lower limiting portion 9323 downward by ninety degrees toward the direction where the fan 910 is located, and the second lower supporting portion 9325 is formed by bending the lower side edge of the vertically disposed metal plate connected between the second upper limiting portion 9322 and the second lower limiting portion 9323 upward by ninety degrees toward the direction where the fan 910 is located.

Further, the second support frame 932 further includes a second auxiliary support portion 9326, and the second auxiliary support portion 9326 is connected between a second upper support portion 9324 and a second lower support portion 9325 that are disposed in parallel up and down. The second auxiliary supporting portions 9326 are two opposite to each other, and are formed by bending the left and right sides of the metal plate vertically disposed at the second upper supporting portions 9324 and the second lower supporting portions 9325 by ninety degrees toward the second upper supporting portions 9324 and the second lower supporting portions 9325. The second auxiliary supporting portion 9326 has a supporting reinforcing function, and can enhance the supporting strength of the second upper supporting portion 9324 and the second lower supporting portion 9325.

The second limiting and fixing portion 9321 is provided with a connection hole, and the fastening member is connected to the inner side or the outer side of the connection frame 920 through the connection hole of the second limiting and fixing portion 9321.

In some embodiments of the present utility model, when a plurality of fans 910 are arranged up and down, the first supporting frame 931 may be disposed corresponding to a bottom corner of the lower fan 910, or the first supporting frame 931 may be disposed corresponding to a bottom corner of the lower fan 910 and a top corner of the upper fan 910, and the upper fan 910 and the lower fan 910 are supported and limited by the second supporting frame 932. The second upper limiting portion 9322 and the second upper supporting portion 9324 of the second support frame 932 respectively correspond to the bottom corner of the upper fan 910, and the second lower limiting portion 9323 and the second lower supporting portion 9325 of the second support frame 932 respectively correspond to the top corner of the lower fan 910.

When the fans 910 are arranged in three or more layers, the first support frame 931 and the second support frame 932 are used in the same manner, the first support frame 931 is arranged corresponding to the bottom corner of the bottommost fan and the top corner of the topmost fan, and the second support frame 932 is arranged corresponding to the other opposite corners except the bottommost corner and the topmost corner of the fans, and is used for supporting and limiting the corresponding corners of the upper fan and the lower fan.

It should be noted that, when the side space of the case 100 allows, or the air volume of the blower 910 is sufficient, the first support frame 931 may be used. Of course, in some embodiments, the second support brackets 932 may also each be employed.

When the fan 920 is required to be externally positioned, the sealing frame 940 on the outside of the case 100 is removed, the first support 9313 of the first support 931 is connected to the connection frame 920 on the outside of the case 100, and the fan 910 is pulled to the outside of the case 100 along the plane formed by the first support 9313 of the first support 931, the second upper support 9324 of the second support 932, the second lower support 9325, and the connection frame 920. During the pulling process, the first limiting portion 931 of the first support frame 931, the second upper limiting portion 9322 of the second support frame 932 and the second lower limiting portion 9323 form a movement limit of the fan 910.

The supporting frame 930 of the cooling structure 900 is connected to the connection frame 920 by fasteners in the case 100 when the shipping container 1 according to some embodiments of the present utility model is loaded and transported. In actual use, the fan 910 may be external or internal, so as to meet the requirements of different geographic conditions and heat dissipation conditions.

As shown in fig. 7 and 16, a maintenance channel 500 is provided between the first heat dissipation long side 110 and the equipment row 400, and a door leaf 600 is disposed at a position corresponding to the maintenance channel 500 on the first short side 130 and the second short side 140.

The device row 400 is disposed in parallel between the first side heat dissipation long side 110 and the second side heat dissipation long side 120, and the maintenance channel 500 between the first side heat dissipation long side 110 and the device row 400 is used for a worker to periodically inspect, maintain and maintain the system, the device, the network, etc., so as to ensure that the system, the device, the network, etc. can normally operate, 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, optimize the performance of the system by optimizing and adjusting the system, the equipment, the network and the like, improve the performance and efficiency of the system and reduce the waste of resources. 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.

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

In one embodiment of the shipping 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 leaf 600 disposed on the first side short side 130 and the second side short side 140 is a half-open door leaf, and only the position corresponding to the maintenance channel 500 is a switchable door leaf, and the position of the first side short side 130 and the second side short side 140 not corresponding to the maintenance channel 500 is a top sealing wall, so that unnecessary design is simplified, and potential safety hazards and maintenance and equipment manufacturing costs are reduced.

Meanwhile, the door lock 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 the packaging container 1 according to some embodiments of the present utility model, as shown in fig. 1, 2 and 7, the equipment row 400 formed by the power distribution cabinet 310 and the rack 200 is located between the first side heat dissipation long side 110 and the second side heat dissipation long side 120, and the first side heat dissipation long side 110 is provided with a shutter (and/or a dust screen), where a portion of the power distribution cabinet 310 corresponding to the equipment row 400 of the first side heat dissipation long side 110 is further provided with a protection wall 801, and the shutter (and/or the dust screen) is arranged 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). As shown in fig. 9, the protective wall 801 is disposed between adjacent louvers (and/or dust screens).

The protection wall 801 is made of, for example, a steel plate and a corner post. The portion of the protective wall 801 may be reinforced with transverse and longitudinal ribs to increase the overall strength of the case 100, to enhance the deformation and extrusion resistance of the case 100, and to reduce the likelihood of damage during handling and transportation.

Further, the top of the protection wall 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.

According to the embodiment of the utility model, the cable inlet 802 is arranged at the top end of the protection wall 801, the cable inlet 802 directly corresponds to the top of the power distribution cabinet 310, the power utilization cable is introduced through the cable inlet 802 and connected to the power distribution cabinet 310, 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 system, equipment and network in the box body 100 can be conveniently inspected, maintained and maintained by staff in daily life.

Further, the water curtain cooling structure is installed on the outer side of the first side heat dissipation long side 110, so that air outside the box body 100 enters the cavity through the 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 and cooled air with oxygen increased by cooling is sent into the box body 100, and the heat dissipation effect is further improved through continuous convection.

During transportation, the water curtain cooling structure is stored in the box 100 through a water curtain storage structure, for example, a water curtain storage structure for fixing a water curtain is arranged on the inner side of the protection wall 801, and the water curtain storage structure can be a hook, a rope ring, a clamping groove and the like. In use, the water curtain cooling mechanism is removed from the housing 100 and installed along the first side heat dissipating long side 110 outside of the dust screen and/or the louvers.

The shipping container 1 of some embodiments of the present utility model further includes an accessory case secured within the case 100 for carrying necessary accessory facilities such as a canopy, canopy fixtures, water curtain lines, communication lines, etc.

As shown in fig. 2 and 17, the rack 200 in the shipping container 1 has a plurality of partitions for placing servers, and the distance between the partitions corresponds to the height at which the servers stand, that is, the servers stand on the partitions of the rack 200. 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 packaged server equipment, the number of the 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.

In some embodiments of the present utility model, the extension baffle 230 is provided, so that the length of the uppermost partition plate 210 of the rack 200 along the width direction of the box body 100 is prolonged, the servers can be inverted on the extension baffle, the number of integrated servers is increased, and the computing capability of the packaged server devices can be improved. Of course, the servers at the topmost level may be arranged normally upright, where the head space permits.

The electric control system comprises a plurality of power distributors, two power distributors are arranged on the top-most partition plate of the rack 200, a server on the top-most partition plate of the rack 200 is connected with one power distributor, another power distributor on the top-most partition plate is connected with a server on a partition plate of the next layer, and 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. 17 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 distributor 330a1, and the outer side of the top-most partition plate 210a is connected with a power distributor 330a2. In addition, the outside of the partition plate 210b is connected with a power distributor 330b, the outside of the partition plate 210c is connected with a power distributor 330c, the outside of the partition plate 210d is connected with a power distributor 330d, the outside of the partition plate 210e is connected with a power distributor 330e, the outside of the partition plate 210f is connected with a power distributor 330f, and the outside of the partition plate 210g is not connected with a power 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, the partitions below the topmost partition plate form a connection relationship in which the power supply distributor on the upper partition plate is connected to the "up-down" of the servers on the lower partition plate, so that the power supply distributor does not need to be installed on the partition plate nearest to the box floor. 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, the short circuit risk and the like 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. The partitions of the rack 200 are, for example, made in a net shape, so that the operation states of the servers on the partitions can be easily observed.

As shown in fig. 2, in order to enhance the overall strength of the rack 200, in an embodiment of the present utility model, the top partition plate 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 plate 210a in time during maintenance. The packaged server device according to some embodiments of the present utility model further includes a top-level device status feedback device for feeding back 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 method for installing the packaged server equipment comprises the following steps of:

the container body 100 is discharged from the standard container 2;

mounting a plurality of servers on the rack 200;

and connecting the plurality of servers with an electronic control system.

The water curtain cooling structure fixedly accommodated in the box body 100 is taken out from the box body, and is arranged on the outer side of the dust screen and/or the shutter along the long heat dissipation edge of the first side.

The awning fixedly stored in the box 100 is unfolded and mounted on the top of 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.

Wherein, when the environment needs, the method further comprises the step of pulling the fan 910 of the cooling structure 900 out of the box 200 from the inside of the box 100 to make the fan 910 be external.

In one embodiment of the present utility model, the case size 5950mmx2200mmx2500mm (LxWxH) of the case 100 of the packaged server device. The equipment has 162 equipment sites for bearing servers, the total power is 700kW, the input voltage is 380V-415 VAC, the frequency is 50/60Hz, the weight is less than 3T, and the authentication standard comprises UL, CE, CSA. The box body 100 is provided with a frame 2 sleeve, a power distribution cabinet 1 sleeve, a power supply distributor 14 sleeve, 8 negative pressure fans, 2 groups of shutters, 2 groups of wet curtains, 10 switches and 162 tail end net wires.

In another embodiment of the utility model, the case size of the case 100 of the packaged server device is 11900mmx2200mmx2500mm (LxWxH). The equipment units with the bearing servers are 324, the total power is 700 kW.2, the input voltage is 380V-415 VAC, the frequency is 50/60Hz, the weight is less than 6T, and the authentication standard comprises UL, CE, CSA. The box body 100 is provided with a rack 4 set, a power distribution cabinet 2 set, a power supply distributor 28 set, a negative pressure fan 16 set, a shutter 4 set, a wet curtain 4 set, a switch 20 set and an end net wire 324.

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 (60)

1. The utility model provides a suit container, its characterized in that includes the box, the outline size of box is less than the incasement space dimension of standard container, the box can wholly load in the standard container, the box load in the standard container, the box along length direction's left and right sides wall with the standard container has first clearance and/or second clearance respectively along length direction's left and right sides wall.

2. The shipping container of claim 1, wherein the sum of the first gap and the second gap is 90 ± 20mm.

3. The encasement container according to claim 1, wherein front and rear side walls of the container body in a width direction and front and rear inner walls of the standard container in a width direction have a third gap and/or a fourth gap, respectively.

4. A shipping container kit according to claim 3, wherein the sum of the third and fourth gaps is 90 ± 20mm.

5. The shipping container of claim 1, wherein the top wall of the container body has a fifth gap from the top interior wall of the standard container.

6. The shipping container of claim 5, wherein the fifth gap is 40 ± 10mm.

7. The shipping container of any of claims 1-6, further comprising a buffer disposed in at least one of the first through fifth gaps.

8. The shipping container of claim 7, wherein the cushioning member comprises corner bead members mounted to corner members of the housing.

9. The shipping container of claim 7, wherein the cushioning member comprises a prismatic member mounted to at least one of the corner posts, bottom side beams, top side beams of the container body.

10. The shipping container of any of claims 1-6, further comprising a stop disposed in at least one of the first to fifth gaps.

11. The shipping container of claim 10, wherein the restraint comprises left and right restraint structures disposed in the first and/or second gaps and along the length of the standard shipping container.

12. The shipping container of claim 10, wherein the restraint comprises front and rear restraint structures disposed at a third gap or a fourth gap away from the standard shipping container access.

13. The shipping container kit of claim 1, wherein a mobile auxiliary accessory is provided between the bottom of the container body and the bottom of the standard shipping container for ease of movement.

14. The shipping kit of claim 7, wherein a mobile auxiliary accessory is provided between the bottom of the container body and the bottom of the standard shipping container for ease of movement.

15. The shipping container kit of claim 10, wherein a mobile auxiliary accessory is provided between the bottom of the container body and the bottom of the standard shipping container for ease of movement.

16. The packaging container according to any one of claims 13-15, wherein the mobile auxiliary accessory comprises a roller device attached to the bottom of the case.

17. A shipping container kit according to claim 16, wherein the roller means is attached to the bottom side beams of the container body and/or the bottom of the corner fittings.

18. The shipping container of claim 13, wherein the mobile auxiliary accessory comprises a rail means attached to the bottom of the container body or to the floor of the standard shipping container.

19. The shipping container kit of claim 13, wherein the mobile auxiliary accessory comprises a skateboard device attached to the bottom of the container body or to the floor of the standard shipping container.

20. The shipping container kit of claim 1, wherein at least one of the containers is loaded into the standard container along the length of the container.

21. The shipping container set of claim 1, wherein the case includes corner fittings.

22. The shipping container of claim 21, further comprising a tension member coupled between the corner fitting and an inner wall of the standard shipping container.

23. The utility model provides a suit container, its characterized in that includes box, frame and electrical system, the frame with electrical system is fixed in respectively in the box, the outline size of box is less than standard container's incasement space size, the box can wholly load in the standard container, the box along length direction control lateral wall with the standard container has first clearance and/or second clearance along length direction's control inner wall respectively.

24. The shipping container of claim 23, wherein the sum of the first gap and the second gap is 90 ± 20mm.

25. The encasement container according to claim 23, wherein front and rear side walls of the container body in a width direction and front and rear inner walls of the standard container in a width direction have a third gap and/or a fourth gap, respectively.

26. The shipping container of claim 25, wherein the sum of the third gap and the fourth gap is 90 ± 20mm.

27. The shipping container of claim 23, wherein the top wall of the container body has a fifth gap from the top interior wall of the standard shipping container.

28. The shipping container of claim 27, wherein the fifth gap is 40 ± 10mm.

29. The shipping container of any of claims 23 to 28, further comprising a buffer disposed in at least one of the first to fifth gaps.

30. The shipping container of claim 29, wherein the cushioning member comprises corner bead members mounted to corner members of the housing.

31. The shipping container of claim 29, wherein the cushioning members comprise prismatic members mounted to at least one of the corner posts, bottom side beams, top side beams of the container body.

32. The shipping container of any of claims 23-28, further comprising a stop disposed in at least one of the first to fifth gaps.

33. The shipping container of claim 32, wherein the restraint comprises left and right restraint structures disposed in the first and/or second gaps and along the length of the standard shipping container.

34. The shipping container of claim 32, wherein the restraint comprises front and rear restraint structures disposed at a third gap or a fourth gap away from the standard shipping container access.

35. The shipping container of claim 23, wherein a mobile auxiliary accessory is provided between the bottom of the container body and the bottom of the standard shipping container to facilitate movement.

36. The shipping container of claim 29, wherein a mobile auxiliary attachment is provided between the bottom of the container body and the bottom of the standard shipping container for facilitating movement.

37. The shipping container of claim 32, wherein a mobile auxiliary accessory is provided between the bottom of the container body and the bottom of the standard shipping container to facilitate movement.

38. The shipping container kit of any of claims 35-37, wherein the mobile auxiliary accessory comprises a roller device attached to the bottom of the container.

39. A shipping container as claimed in claim 38, wherein the roller means is attached to the bottom side beams of the container and/or the bottom of the corner fittings.

40. The shipping container of claim 35, wherein the mobile auxiliary accessory comprises a rail means attached to the bottom of the container body or to the floor of the standard shipping container.

41. The shipping container of claim 35, wherein the mobile auxiliary accessory comprises a skateboard device attached to the bottom of the container body or to the floor of the standard shipping container.

42. The shipping container of claim 23, wherein the case includes corner fittings.

43. The shipping container of claim 23, wherein at least one of the boxes is loaded into the standard shipping container along the length of the box.

44. The shipping container of claim 23, wherein the electrical control system comprises a power distribution cabinet, and wherein the racks are symmetrically disposed on either side of the power distribution cabinet.

45. The shipping container of claim 44, wherein the housing comprises oppositely disposed first and second sides, the first side being provided with dust screens and/or louvers and the second side being provided with cooling structure.

46. The shipping container of claim 45, wherein the cooling structure comprises a fan and a fan mount, the fan being mounted to the enclosure by the fan mount.

47. The shipping container of claim 46, wherein the fan mount comprises a connection frame and a support frame, the connection frame being connected to the housing, the support frame being removably connected to an inside or an outside of the connection frame by a plurality of fasteners, the fan being disposed on the support frame.

48. The shipping container of claim 47, wherein the connecting frame is further partially connected to the corner posts of the container body.

49. The shipping container of claim 47, wherein the support shelf includes a securing portion for removably connecting the connection frame by the fastener and a support portion for supporting the fan.

50. The shipping container of claim 49, wherein the support shelf includes a stop for limiting displacement of the blower.

51. The shipping container of claim 50, wherein the support frame is bent from sheet metal and machined to form the securing portion, the support portion and the retaining portion.

52. The shipping container of claim 47, wherein the connecting frame is further partially connected to at least one of the top side beams, bottom side beams, and corner posts of the container body.

53. The shipping container of claim 45, wherein the first side heat dissipating long side is provided with a protective wall corresponding to the location of the power distribution cabinet, and the first side heat dissipating long side is provided with the dust screen and/or the louver corresponding to the location of the rack.

54. The shipping container of claim 53, further comprising a water curtain cooling structure and a water curtain receiving structure receiving the water curtain cooling structure, the water curtain receiving structure being located within the enclosure.

55. The shipping container of claim 23, further comprising an accessory box secured within the box body.

56. A packaging server apparatus comprising a plurality of servers, and further comprising the packaging container of any one of claims 1 to 55, said servers being arranged in a rack and connected to an electronic control system.

57. The packaged server apparatus according to claim 56 wherein said top of said rack has a topmost divider plate and an extension baffle extending horizontally from said topmost divider plate, said server being disposed on said topmost divider plate and/or said extension baffle.

58. The packaged server apparatus according to claim 57 further comprising a top level apparatus status feedback device for feeding back the operational status of said servers on said top-most separator plate and/or said extension barrier.

59. The packaged server device according to claim 58 wherein the top level device status feedback means is a mirror viewing means.

60. The packaged server apparatus according to claim 59 wherein said mirror viewing device comprises a plurality of feedback zones, each of said feedback zones corresponding to at least one server disposed on said topmost divider and/or said extension baffle.