CN118102655B

CN118102655B - Server cabinet and server system

Info

Publication number: CN118102655B
Application number: CN202410458030.0A
Authority: CN
Inventors: 刘阳
Original assignee: Suzhou Metabrain Intelligent Technology Co Ltd
Current assignee: Suzhou Metabrain Intelligent Technology Co Ltd
Filing date: 2024-04-16
Publication date: 2024-06-21
Anticipated expiration: 2044-04-16

Abstract

The application discloses a server cabinet and a server system, and belongs to the field of server cabinets. The server cabinet includes: the cabinet body and the connecting frame are arranged in the cabinet body; the link has and holds the chamber, and is provided with first connector joint and second connector joint group on the outer wall of link, and first connector joint is used for connecting the server, and second connector joint group is used for connecting the switch, and first connector joint and the equal partial interior of second connector joint group stretch in holding the chamber, and first connector joint and second connector joint group pass through the cable electricity to be connected, and the cable is located and holds the chamber.

Description

Server cabinet and server system

Technical Field

The application belongs to the field of server cabinets, and particularly relates to a server cabinet and a server system.

Background

With the development of technology, the application of servers is becoming more and more widespread. Typically, the servers are placed in a server enclosure, as shown in FIG. 1, with a switch disposed in the server enclosure, such that the servers can transfer data by connecting the switch to the servers. In the related art, a management network port is provided on a server, one end of a cable is connected to the management network port, and the other end of the cable is connected to a switch. But through such a mode, the cable in the server rack is complicated, and the cable is easily damaged, and the security problem appears to, and the position of server in the switch is different, leads to the length of cable longer, has increased the cost, in addition, in the related art, can't realize the blind of server and switch and insert, and to the power supply of server and switch non-uniformity, leads to the power supply comparatively complicacy, and can't realize the centralized management to each server and switch power.

Disclosure of Invention

The embodiment of the application aims to provide a server cabinet and a server system, which at least solve the problems that cables in the server cabinet are complicated, the cables are easy to damage and have safety problems, and the cables are longer due to different positions of the servers in a switch, so that the cost is increased.

In a first aspect, an embodiment of the present application provides a server cabinet, including: the cabinet body, the link frame set up in the said cabinet body and power supply management unit;

The connecting frame is provided with a containing cavity, a plurality of first connector joints and a plurality of second connector joint groups are arranged on the outer wall of the connecting frame, the first connector joints are used for connecting a server, the second connector joint groups are used for connecting uplink ports of a switch, the first connector joints and the second connector joint groups are partially extended inwards of the containing cavity, each first connector joint and each second connector joint group are electrically connected through a downlink cable, the downlink cables are positioned in the containing cavity, and the power supply management unit is used for connecting the server and the switch and carrying out unified power supply management on the server and the switch;

The power supply management unit is used for connecting the server and the switch and carrying out unified power supply management on the server and the switch; the power supply management unit comprises a power supply centralized management backboard, a fourth connector joint, a fifth connector joint and a sixth connector joint are arranged on the power supply centralized management backboard, the fourth connector joint is used for connecting the server, the fifth connector joint is used for connecting the switch, and the sixth connector joint is connected with a power supply management module;

The power centralized management backboard is provided with a gating device, the power management module is electrically connected with the gating device, the fourth connector joint and the fifth connector joint are electrically connected with the gating device, and the power management module performs power control on the server and/or the switch through the gating device so as to perform unified power supply management on the server and the switch.

Optionally, the cabinet body has a front side and a rear side opposite to each other, and the connecting frame is connected with a rear cover;

The connecting frame faces the front side of the cabinet body, the rear cover faces the rear side of the cabinet body, and the rear cover covers the connecting frame and shields the accommodating cavity.

Optionally, the connecting frame and the rear cover are both cross-shaped, the cabinet body has a first direction and a second direction which are intersected, the connecting frame comprises a first frame body and a second frame body, the first frame body extends along the first direction, the second frame body extends along the second direction, and the first frame body is intersected with the second frame body;

The first connector joint is arranged on the first frame body, and the second connector joint group is arranged on the second frame body.

Optionally, the number of the first connector contacts and the number of the second connector contact groups are multiple;

the first connector joints are distributed on the first frame body at intervals along the first direction, the second connector joint groups are distributed on the second frame body at intervals along the second direction, and each first connector joint is electrically connected with one second connector joint group through a downlink cable.

Optionally, the difference in length between the downlink cables connecting each set of the first connector contacts and the second connector contacts is smaller than a preset value, wherein each set of the first connector contacts and the second connector contacts comprises at least one of the first connector contacts and at least one of the second connector contacts.

Optionally, the switch comprises a data switch and a management switch, each of the second connector sub-sets comprises a first sub-connector and a second sub-connector, the plurality of first sub-connectors are distributed at intervals along the second direction, and the plurality of second sub-connectors are distributed at intervals along the second direction;

The first sub-connector is used for connecting with a downlink port of the management switch, and the second sub-connector is used for connecting with a downlink port of the data switch;

Among the plurality of first connector joints, one first connector joint connects one first sub-joint and one second sub-joint through a downlink cable.

Optionally, the connecting frame has opposite two ends along the first direction, and the two ends of the connecting frame are respectively connected with the top and the bottom of the cabinet body.

Optionally, the cabinet body has a first direction and a second direction intersecting with each other, and the connecting frame is located at a middle position of the cabinet body along the second direction.

Optionally, the second frame has a size smaller than the size of the cabinet along the second direction.

Optionally, the first connector tab and the second connector tab group each have a front face and a back face, the front face is provided with a connection pin and is located outside the accommodating cavity, the connection pin is used for connecting a server or a switch, the back face is located in the accommodating cavity, and the back face of the first connector tab and the back face of the second connector tab group are electrically connected through a downlink cable.

Optionally, the switch comprises a data switch and a management switch, and a third connector joint group is further arranged on the outer wall of the connecting frame and used for connecting an uplink port of the switch;

The third connector joint group comprises a third sub-joint and a fourth sub-joint, the third sub-joint is used for connecting an uplink port of the management switch, and the fourth sub-joint is used for connecting an uplink port of the data switch.

Optionally, the third connector tab set portion is located in the receiving cavity, and the third connector tab set is connected with an uplink cable, which is located in the receiving cavity and passes out from the top of the cabinet.

Optionally, the server is internally provided with a first network card and a second network card, the transmission speeds of the first network card and the second network card are different, the server is provided with a connection joint, the first network card and the second network card are connected to the same connection joint, and the first connector joint is used for being connected with the connection joint.

Optionally, the server has opposite front and rear ends, and the connection joint is disposed at the rear end of the server.

Optionally, the gate is configured to be alternately conducted with each of the fourth connector terminals and each of the fifth connector terminals, so that the power management module is conducted with each of the fourth connector terminals, or the power management module is conducted with each of the fifth connector terminals.

Optionally, a power supply frame is arranged on the cabinet body, and the power supply management module is arranged in the power supply frame.

Optionally, a power supply row is arranged in the cabinet body, a first power connector and a second power connector are arranged on the power supply row, the first power connector is used for being connected with the server so as to supply power to the server, and the second power connector is used for being connected with the switch so as to supply power to the switch.

Optionally, a water dividing and collecting device is arranged in the cabinet body, the water dividing and collecting device comprises a water inlet pipe and a water outlet pipe, the water inlet pipe is communicated with the water outlet pipe, and the water inlet pipe is used for cooling and radiating the server and the exchanger.

In a second aspect, an embodiment of the present application provides a server system, where the server system includes a server, a switch, and a server cabinet according to any one of the first aspects above;

The server and the switch are both positioned in the cabinet body, the server is connected with the first connector joint, and the switch is connected with the second connector joint group;

the server is connected with the fourth connector joint, and the switch is connected with the fifth connector joint, so that the power management module performs power control on the server and/or the switch through the gating device, and unified power supply management is performed on the server and the switch.

Optionally, a first network card and a second network card are arranged in the server, the transmission speeds of the first network card and the second network card are different, a connecting joint is arranged on the server, the first network card and the second network card are connected to the same connecting joint, and the connecting joint is connected with the first connector joint.

Optionally, a power supply row is arranged in the cabinet body, and a first power connector and a second power connector are arranged on the power supply row;

The server and the switch are respectively connected with the first power connector and the second power connector.

In the embodiment of the application, the connecting frame is provided with the accommodating cavity, the outer wall of the connecting frame is provided with the plurality of first connector joints and the plurality of second connector joint groups, and the connecting frame is positioned in the cabinet body, so that when the server and the switch are arranged in the cabinet body, the server can be connected with the first connector joints, the switch is connected with the second connector joint groups, namely, when the server and the switch are pushed into the cabinet body, the server is connected with the first connector joints, and the switch is connected with the second connector joint groups, so that blind insertion of the server and the switch is realized. In addition, because the first connector joint and the second connector joint group are both partially extended in the accommodating cavity, and each first connector joint and the second connector joint group are electrically connected through the downlink cable, the downlink cable is positioned in the accommodating cavity, therefore, after the server and the switch are pushed into the cabinet body, the server is connected with the first connector joint, the switch is connected with the second connector joint group, and the first connector joint and the second connector joint group are electrically connected through the downlink cable, so that the server and the switch are electrically connected, and the downlink cable is positioned in the accommodating cavity, which is equivalent to the downlink cable being accommodated in the connecting frame, and the connecting frame can play a role in protecting the downlink cable. That is, in the embodiment of the present application, the connection frame is disposed in the cabinet body of the server, the first connector joint and the second connector joint group are disposed on the connection frame, the downlink cable is disposed in the accommodating cavity of the connection frame, and the downlink cable is respectively connected with the first connector joint and the second connector joint group, so that once the server and the switch are disposed in the cabinet body, the server is connected with the first connector joint, the switch and the second connector joint group can realize blind insertion of the server and the switch, and the downlink cable is disposed in the accommodating cavity, so that a user cannot see the downlink cable outside the cabinet body, the problem that the downlink cable is staggered and complicated on the cabinet body is avoided, in addition, the connection frame can protect the downlink cable, and the problem that the downlink cable is easily damaged is avoided, thereby improving the safety of the cabinet body. In addition, the power supply management unit can perform unified power supply management on the server and the switch.

Drawings

FIG. 1 is a schematic diagram of a related art server rack with switches and servers;

FIG. 2 is a schematic diagram of a server rack according to an embodiment of the present application;

FIG. 3 illustrates a front view of a server enclosure provided by an embodiment of the present application;

Fig. 4 is a perspective view of a first rear view of a server and a switch installed in a cabinet and including a cable interconnection topology within a rack according to an embodiment of the present application;

Fig. 5 shows a second perspective view of a rear view direction of a complete machine cabinet with a server and a switch installed in a cabinet and including an up cable of the switch inside a connection frame for centralized power supply and heat dissipation according to an embodiment of the present application;

FIG. 6 shows a topology diagram of a power management module polling control server according to an embodiment of the present application;

Fig. 7 is a schematic diagram of a power centralized management backplane connection server and a switch according to an embodiment of the present disclosure;

Fig. 8 shows a third perspective view of a rear view of an entire cabinet with a server and a switch installed in the cabinet and including a centralized power management module according to an embodiment of the present application;

FIG. 9 is a schematic diagram of circuit connection in a server according to an embodiment of the present application;

Fig. 10 shows a schematic diagram of a server according to an embodiment of the present application.

Reference numerals:

001: an uplink cable; 10: a cabinet body; 21: a connecting frame; 211: a first frame body; 212: a second frame body; 30: a first connector fitting; 40: a second connector header set; 41: a first sub-joint; 42: a second sub-joint; 50: a power centralized management backboard; 51: a power management module; 52: a gating device; 501: a fourth connector fitting; 502: a fifth connector fitting; 503: a sixth connector fitting; 60: a power supply frame; 601: a power supply; 70: a power supply row; 71: a positive electrode row; 72: a negative electrode row; 80: a water separator-collector; 81: a water inlet pipe; 82: a drain pipe; 90: a third connector header set; 91: a third sub-linker; 92: a fourth sub-linker; 100: a downlink cable; 200: a server; 201: a centralized power supply module; 210: a first network card; 220: a second network card; 230: a connection joint; 300: a switch; 301: managing the switch; 302: a data switch.

Detailed Description

The features of the application "first", "second" and the like in the description and in the claims may be used for the explicit or implicit inclusion of one or more such features. In the description of the present application, unless otherwise indicated, the meaning of "a plurality" is two or more. Furthermore, in the description and claims, "and/or" means at least one of the connected objects, and the character "/", generally means that the associated object is an "or" relationship.

In the description of the present application, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings are merely for convenience in describing the present application and simplifying the description, and do not indicate or imply that the device or element being referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the present application.

In the description of the present application, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present application will be understood in specific cases by those of ordinary skill in the art.

Referring to fig. 2, a schematic diagram of a server cabinet according to an embodiment of the present application is shown; referring to FIG. 3, a front view of a server enclosure provided by an embodiment of the application is shown; referring to fig. 4, a perspective view of a rear view of a server and a switch installed in a cabinet and including a cable interconnection topology inside a connection rack according to an embodiment of the present application is shown; referring to fig. 5, a perspective view two of a rear view direction of a whole cabinet with a server and a switch installed in a cabinet and including a switch up cable inside a connection frame for centralized power supply and heat dissipation is shown in the embodiment of the present application; referring to fig. 6, a topology diagram of a power management module polling control server according to an embodiment of the present application is shown; referring to fig. 7, a schematic diagram of a power centralized management backplane connection server and a switch according to an embodiment of the present disclosure is shown; referring to fig. 8, a perspective view three of a rear view of an entire cabinet in which a server and a switch are installed in the cabinet and include a centralized power management module according to an embodiment of the present application is shown; referring to fig. 9, a schematic diagram of circuit connection in a server according to an embodiment of the present application is shown. As shown in fig. 2 to 9, the server 200 cabinet includes: the cabinet 10 and the connecting frame 21 arranged in the cabinet 10.

The connection rack 21 has a receiving cavity, and a plurality of first connector joints 30 and a plurality of second connector joint groups 40 are provided on an outer wall of the connection rack 21, the first connector joints 30 are used for connecting the server 200, the second connector joint groups 40 are used for connecting the switch 300, the first connector joints 30 and the second connector joint groups 40 are both partially extended from the receiving cavity, and each first connector joint 30 and each second connector joint group 40 are electrically connected through the downlink cable 100, and the downlink cable 100 is located in the receiving cavity. The power supply management unit is used for connecting the server 200 and the switch 300, and performing unified power supply management on the server 200 and the switch 300. The power supply management unit may include a power supply centralized management backplane 50, on which a fourth connector joint 501, a fifth connector joint 502 and a sixth connector joint 503 are provided, the fourth connector joint 501 being used for connecting with the server 200, the fifth connector joint 502 being used for connecting with the switch 300, the sixth connector joint 503 being connected with the power supply management module 51; the power centralized management back plate 50 is provided with a gating device 52, the power management module 51 is electrically connected with the gating device 52, the fourth connector joint 501 and the fifth connector joint 502 are electrically connected with the gating device 52, and the power management module 51 performs power control on the server 200 and/or the switch 300 through the gating device 52 so as to perform unified power supply management on the server 200 and the switch 300.

In this embodiment of the present application, the first connector terminal 30 and the second connector terminal set 40 each have a front surface and a back surface, the front surface is provided with connection pins, and the connection pins are located outside the accommodating cavity, the connection pins are used for connecting the server 200 or the switch 300, the back surface is located in the accommodating cavity, and the back surface of the first connector terminal 30 and the back surface of the second connector terminal set 40 are electrically connected through the downlink cable 100.

In the embodiment of the present application, since the connection frame 21 has the accommodating cavity, the plurality of first connector tabs 30 and the plurality of second connector tab groups 40 are provided on the outer wall of the connection frame 21, and the connection frame 21 is located in the cabinet 10, when the server 200 and the switch 300 are disposed in the cabinet 10, the server 200 may be connected to the connection pins on the first connector tabs 30, the switch 300 may be connected to the connection pins on the second connector tab groups 40, that is, when the server 200 and the switch 300 are pushed into the cabinet 10, the server 200 and the switch 300 are connected to the connection pins on the first connector tabs 30, and the switch 300 is connected to the connection pins on the second connector tab groups 40, thereby equivalently realizing blind insertion of the server 200 and the switch 300. In addition, since the first connector tab 30 and the second connector tab set 40 extend partially inward from the accommodating cavity, and each of the first connector tab 30 and the second connector tab set 40 is electrically connected by the down cable 100, the down cable 100 is located in the accommodating cavity, and thus after pushing the server 200 and the switch 300 into the cabinet 10, the server 200 is connected to the first connector tab 30, the switch 300 is connected to the second connector tab set 40, and the first connector tab 30 is electrically connected to the second connector tab set 40 by the down cable 100, so that the server 200 and the switch 300 are electrically connected, and the down cable 100 is located in the accommodating cavity, which corresponds to the down cable 100 being accommodated in the connection rack 21, and the connection rack 21 can protect the down cable 100. That is, in the embodiment of the present application, by arranging the connection rack 21 in the cabinet body 10 of the server 200, and arranging the first connector tab 30 and the second connector tab set 40 on the connection rack 21, the down cable 100 is arranged in the accommodating cavity of the connection rack 21, and the down cable 100 is respectively connected to the back surface of the first connector tab 30 and the back surface of the second connector tab set 40, once the server 200 and the switch 300 are placed in the cabinet body 10, the server 200 is connected with the first connector tab 30, the switch 300 is connected with the second connector tab set 40, blind insertion of the server 200 and the switch 300 can be achieved, and the down cable 100 is located in the accommodating cavity, so that a user cannot see the down cable 100 outside the cabinet body 10, the problem that the down cable 100 is complicated on the cabinet body 10 is avoided. In addition, the power supply management unit may perform unified power supply management for the server 200 and the switch 300.

Since the power centralized management back plate 50 is provided in the cabinet 10, the fourth connector joint 501, the fifth connector joint 502 and the sixth connector joint 503 are provided on the power centralized management back plate 50, and the sixth connector joint 503 is connected with the power management module 51, when the server 200 and the switch 300 are placed in the cabinet 10, the server 200 can be connected with the fourth connector joint 501, and the switch 300 can be connected with the fifth connector joint 502. Since the fourth connector terminal 501 and the fifth connector terminal 502 are electrically connected to the power management module 51, once the server 200 is connected to the fourth connector terminal 501, the switch 300 is connected to the fifth connector terminal 502, so that both the server 200 and the switch 300 can be electrically connected to the power management module 51, and the power management module 51 can perform power control on the server 200 and/or the switch 300. That is, by arranging the power centralized management back plate 50, and arranging the fourth connector joint 501, the fifth connector joint 502 and the sixth connector joint 503 on the power centralized management back plate 50, the sixth connector joint 503 is connected with the power management module 51, and the fourth connector joint 501 and the fifth connector joint 502 are electrically connected with the power management module 51, the server 200 and the switch 300 can be uniformly power-managed after the server 200 and the switch 300 are placed in the cabinet 10, thereby facilitating centralized power management on the server 200 and the switch 300, that is, centralized power supply to the switch 300 and the server 200 is realized.

Since the power centralized management backplane 50 is provided with the gate 52, the power management module 51 is electrically connected with the gate 52, and the fourth connector joint 501 and the fifth connector joint 502 are electrically connected with the gate 52, the power management module 51 is electrically connected with the fourth connector joint 501 and the fifth connector joint 502 through the gate 52, so that the power management module 51 can perform power control on the server 200 and/or the switch 300. That is, by providing the gate 52, the power management module 51 can be electrically connected with the fourth connector joint 501 and the fifth connector joint 502, and further, after the server 200 and the switch 300 are placed in the cabinet 10, the power management module 51 is convenient to perform power control on the server 200 and/or the switch 300, so that the power management module 51 can perform unified power supply management on the server 200 and the switch 300.

As can be seen from the foregoing, in the embodiment of the present application, by providing the connection rack 21 in the cabinet 10 of the server 200, providing the first connector terminal 30 and the second connector terminal set 40 on the connection rack 21, providing the downlink cable 100 in the accommodating cavity of the connection rack 21, and respectively connecting the back surface of the first connector terminal 30 and the back surface of the second connector terminal set 40 with the downlink cable 100, and providing the power supply management unit in the cabinet 10, not only can the blind insertion of the server 200 and the switch 300 be realized, but also the downlink cable 100 is located in the accommodating cavity, so that the user cannot see the downlink cable 100 outside the cabinet 10, and the problem that the downlink cable 100 is intricate and complex on the cabinet 10 is avoided.

It should be noted that, the power management module 51 may be a power management control (Power Management Circuit, PMC) structure. In addition, in the embodiment of the present application, the power centralized management backplane 50 may be a printed circuit board (Printed Circuit Board, PCB), and at this time, the power management module 51 may be provided with a plug connector, and the plug connector is plugged into the sixth connector 503, so that the power management module 51 is electrically connected to the fourth connector 501 and the fifth connector 502, respectively. Of course, the power management module 51 may also be connected to a connection line, and the connection line is provided with a plug connector, and the plug connector is connected to the sixth connector 503 on the power centralized management backplane 50, so as to implement electrical connection with the fourth connector 501 and the fifth connector 502. Of course, the power central management back plate 50 may also be a plate structure formed by other types of materials, for example, the power central management back plate 50 is formed by metal, the power central management back plate 50 is in a hollow structure, the fourth connector joint 501, the fifth connector joint 502 and the sixth connector joint 503 are all disposed on the power central management back plate 50, connecting wires are disposed inside the power central management back plate 50, and the fourth connector joint 501, the fifth connector joint 502 and the sixth connector joint 503 are electrically connected through the connecting wires. The embodiments of the present application are not limited in this regard.

It should be noted that, in the embodiment of the present application, the gate 52 may be a chip, for example, the gate 52 is a PAB9548 chip. Of course, the gate 52 may also be a circuit board with control functions. Embodiments of the present application are not limited herein with respect to the particular type of gate 52.

In addition, in some embodiments, the gate 52 is configured to alternate between conducting with each fourth connector tab 501 and each fifth connector tab 502 to conduct the power management module 51 to each fourth connector tab 501 or to conduct the power management module 51 to each fifth connector tab 502.

With this arrangement, when the power management module 51 is operated, the gate 52 and each of the fourth connector terminals 501 and each of the fifth connector terminals 502 are alternately turned on, that is, the gate 52 and each of the fourth connector terminals 501 are turned on and each of the fifth connector terminals 502 are turned off, which corresponds to the power management module 51 being electrically connected to only the fourth connector terminals 501, thereby performing power management control on the server 200, and the gate 52 and each of the fifth connector terminals 502 are turned on and each of the fourth connector terminals 501 are turned off, which corresponds to the power management module 51 being electrically connected to only the fifth connector terminals 502, thereby performing power management control on the switch 300. That is, the power management module 51 can perform polling management on the server 200 and the switch 300, corresponding to the gating device 52, so that the load of the bus connecting the power management module 51 with the fourth connector terminal 501 and the fifth connector terminal 502 can be reduced, and the quality of the management signal transmitted by the power management module 51 can be improved.

Note that, the number of the fourth connector terminals 501 may be plural, and in this case, the gate 52 may be alternately turned on with the plural third connectors in sequence, so that the power management module 51 performs the polling management on the server 200 connected to the plural fourth connector terminals 501. For example, the number of fourth connector tabs 501 is 10, the gate 52 may be first connected to the 1 st fourth connector tab 501 and disconnected from the remaining 9 fourth connector tabs 501, such that the power management module 51 manages power to the server 200 on the fourth connector tab 501 connected to the gate 52, after which the controller is connected to the 2 nd fourth connector tab 501 and disconnected from the remaining 9 fourth connector tabs 501, and so on, until the gate 52 is disconnected from the remaining 9 fourth connector tabs 501 after being connected to the 10 th fourth connector tab 501, and then the gate 52 is again connected to the 1 st fourth connector tab 501 and disconnected from the remaining 9 fourth connector tabs 501.

Similarly, when the fourth connector terminal 501 and the fifth connector terminal 502 are plural, the gate 52 may sequentially turn on the fourth connector terminal 501 and the fifth connector terminal 502.

In addition, in the related art, after the servers 200 and the switch 300 are placed in the cabinet of the servers 200, the number of the servers 200 is plural, the positions of the plural servers 200 in the cabinet of the servers 200 are different, in order to achieve that the servers 200 in different positions are all electrically connected with the switch 300, the servers 200 in different positions are electrically connected with the switch 300 through cables, but the positions of the servers 200 are different, so that when the servers 200 and the switch 300 are connected, an operator needs to first access one end of the cable to the servers 200 and then access the other end of the cable to the switch 300, and the cable may need to be looped outside the cabinet of the servers 200, resulting in the cable connecting the servers 200 and the switch 300 being complicated, not easy to arrange and easy to make mistakes. Further, the operator needs to manually connect the cables to the server 200 and the switch 300, respectively, and blind insertion of the server 200 and the switch 300 cannot be achieved.

In the embodiment of the present application, the first connector joint 30 and the second connector joint set 40 are disposed on the connection frame 21 by disposing the connection frame 21, and the downlink cable 100 is disposed in the accommodating cavity of the connection frame 21, so that the downlink cable 100 is connected with the first connector joint 30 and the second connector joint set 40 respectively, and the downlink cable 100 does not need to encircle in the connection frame 21, so that the required length of the downlink cable 100 is shorter, the cost is reduced, and the downlink cable 100 is in the connection frame 21, thereby avoiding the downlink cable 100 from being complicated. Moreover, by arranging the connecting frame 21, when the server 200 and the switch 300 are placed in the cabinet body 10 of the cabinet of the server 200, an operator can directly push the server 200 into the cabinet body 10 and push the switch 300 into the cabinet body 10, so that the server 200 can be connected with the first connector joint 30, the switch 300 is connected with the second connector joint group 40, namely, the operator only needs to push the server 200 and the switch 300 into the cabinet body 10, the server 200 can be directly connected with the first connector joint 30, the switch 300 is connected with the second connector joint group 40, manual wiring of the operator is not needed, and blind insertion of the server 200 and the switch 300 is realized.

It should be noted that, in the embodiment of the present application, a sliding rail or a sliding slot may be provided in the cabinet 10, when the server 200 and the switch 300 are placed in the cabinet 10, the server 200 may be placed in the corresponding sliding rail or sliding slot, the switch 300 may be placed in the corresponding sliding rail or sliding slot, and an operator applies a force to the server 200 and the switch 300 to push the server 200 and the switch 300 into the cabinet 10. In addition, the positions of the first connector tab 30 and the second connector tab set 40 may be set such that the first connector tab 30 corresponds to the server 200 and the second connector tab set 40 corresponds to the switch 300, so that once the server 200 is pushed into the cabinet 10, the switch 300 is pushed into the cabinet 10, the server 200 may be connected with the first connector tab 30 and the switch 300 connected with the second connector tab set 40.

In addition, in the embodiment of the present application, the first connector 30 and the second connector 40 are both connectors for transmitting data, that is, after the first connector 30 and the second connector 40 are connected to the server 200 and the switch 300, respectively, the server 200 and the switch 300 can transmit data therebetween.

In addition, in the embodiment of the present application, the switch 300 includes a data switch 302 and a management switch 301, and the outer wall of the connection rack 21 is further provided with a third connector joint group 90, where the third connector joint group 90 is used to connect the upstream port of the switch 300; wherein the third connector sub-group 90 comprises a third sub-sub 91 and a fourth sub-sub 92, the third sub-connector 91 is used for connecting to an upstream port of the management switch 301, and the fourth sub-connector 92 is used for connecting to an upstream port of the data switch 302. With such an arrangement, once the switch 300 is connected to the server 200, data can be transferred between the server 200 and the switch 300.

In addition, in the embodiment of the present application, the third connector tab set 90 is partially located in the receiving cavity, and the third connector tab set 90 is connected with an uplink cable 001, and the uplink cable 001 is located in the receiving cavity and passes out from the top of the cabinet 10. Wherein the third connector terminal group 90 has a front face and a back face, the back face is located in the accommodation chamber, the back face is connected with an uplink cable 001, and the uplink cable 001 passes through the connection frame 21 and is led out from the top end of the rear side of the cabinet 10. That is, in the embodiment of the present application, by providing the second connector tab set 40 and the third connector tab set 90, the second connector tab set 40 is connected to the first connector tab 30, the downstream port of the switch 300 is connected to the second connector tab set 40, and when the server 200 is connected to the first connector tab 30, the connection between the switch 300 and the server 200 is achieved, and the third connector tab set 90 is connected to the upstream port of the switch 300, so that once the switch 300 is connected to the server 200, data can be transferred between the server 200 and the switch 300.

In addition, when the third connector tab group 90 includes the third sub-tab 91 and the fourth sub-tab 92, the third sub-tab 91 has a front face and a rear face, the fourth sub-tab 92 also has a front face and a rear face, the rear face of the third sub-tab 91 and the rear face of the fourth sub-tab 92 are located in the accommodation cavity of the connection frame 21, and both the rear face of the third sub-tab 91 and the rear face of the fourth sub-tab 92 are connected with an uplink cable 001, wherein the uplink cable 001 connected with the rear face of the third sub-tab 91 is used for connecting with an uplink management port of the total switch 300 outside the cabinet 10, and the uplink cable 001 connected with the rear face of the fourth sub-tab 92 is used for connecting with an uplink data port of the total switch 300 outside the cabinet 10.

Additionally, in some embodiments, the cabinet 10 may have opposite front and rear sides, with the connection frame 21 having a rear cover attached thereto; the connecting frame 21 faces the front side of the cabinet 10, the rear cover faces the rear side of the cabinet 10, and the rear cover covers the connecting frame 21 and shields the accommodating cavity.

Since the connection frame 21 is connected with the rear cover, the rear cover can shield the accommodating cavity, so that the rear cover further protects the downlink cable 100 in the accommodating cavity. Since the connection frame 21 faces the front side of the cabinet 10 and the rear cover faces the rear side of the cabinet 10, when the server 200 and the switch 300 are placed in the cabinet 10, the server 200 and the switch 300 can be placed in the cabinet 10 from the front side to the rear side of the cabinet 10, so that the server 200 can be directly connected with the first connector contacts 30 on the connection frame 21, and the switch 300 can be directly connected with the second connector contact group 40 on the connection frame 21, so that the downlink cable 100 can not be seen from the front side to the rear side of the cabinet 10, and the downlink cable 100 can not be seen from the rear side to the front side of the cabinet 10. That is, by installing both the first connector tab 30 and the second connector tab set 40 on the connection frame 21, the server 200 and the switch 300 can be directly connected to the first connector tab 30 when the server 200 and the switch 300 are placed in the cabinet 10, the switch 300 is connected to the second connector tab set 40, and the operator cannot see the downlink cable 100.

It should be noted that, in the embodiment of the present application, the connection frame 21 and the rear cover may be detachably connected, for example, a clamping groove is provided on the connection frame 21, and a buckle is provided on the rear cover, and when the connection frame 21 needs to be connected with the rear cover, the buckle may be clamped into the clamping groove to realize connection between the connection frame 21 and the rear cover. For another example, a first clamping buckle is arranged on the connecting frame 21, a second clamping buckle is arranged on the rear cover, and the first clamping buckle can be connected with the second clamping buckle when the connecting frame 21 is required to be connected with the rear cover. For another example, a through hole is provided in the connection frame 21, a through hole is provided in the rear cover, and the connection frame 21 and the rear cover are connected by bolts. Of course, the connecting frame 21 and the rear cover may also be fixedly connected, for example, by welding the connecting frame 21 and the rear cover. The embodiment of the present application is not limited herein with respect to the specific connection manner of the connection frame 21 and the rear cover.

In addition, in the embodiment of the present application, by providing the connection frame 21 and the rear cover, after the first connector fitting 30 and the second connector fitting group 40 are both provided on the connection frame 21, the downlink cable 100 connected by the first connector fitting 30 and the second connector fitting group 40 is located in the accommodating cavity enclosed by the connection frame 21 and the rear cover, so that no matter the cabinet 10 is observed from the front side to the rear side of the cabinet 10 or the cabinet 10 is observed from the rear side to the front side of the cabinet 10, the operator cannot see the downlink cable 100, thereby making the cabinet 10 tidy and avoiding the downlink cable 100 from being complicated. In addition, the rear cover may protect the downlink cable 100.

In addition, in some embodiments, as shown in fig. 5, the connection frame 21 and the rear cover may be cross-shaped, the cabinet 10 has a first direction and a second direction intersecting each other, the connection frame 21 includes a first frame 211 and a second frame 212, the first frame 211 extends along the first direction, the second frame 212 extends along the second direction, and the first frame 211 intersects the second frame 212; the first connector fitting 30 is disposed on the first frame 211, and the second connector fitting set 40 is disposed on the second frame 212.

Since the first frame 211 extends in the first direction and the second frame 212 extends in the second direction, the first connector tab 30 may be disposed on the first frame 211, the second connector tab set 40 may be disposed on the second frame 212, and the extending direction of the first frame 211 may ensure that a plurality of first connector tabs 30 are disposed on the first frame 211, so that a plurality of servers 200 may be disposed in the cabinet 10.

It should be noted that the first direction may be parallel to the gravity direction, that is, the first direction may be a vertical direction, and the second direction may be perpendicular to the first direction, that is, the second direction may be a horizontal direction.

Additionally, in some embodiments, the number of first connector contacts 30 and the number of second connector contact sets 40 may each be multiple; the plurality of first connector contacts 30 are spaced apart from the first frame 211 along the first direction, the plurality of second connector contacts 40 are spaced apart from the second frame 212 along the second direction, and each first connector contact 30 is electrically connected to the second connector contacts 40 through the downlink cable 100.

Since the plurality of first connector tabs 30 are spaced apart from the first frame 211 along the first direction, a plurality of servers 200 may be provided in the cabinet 10, each server 200 being connected to one first connector tab 30. Since the plurality of second connector sub-sets 40 are spaced apart from the second rack 212 along the second direction, the plurality of interfaces on the switch 300 can be respectively connected to the plurality of second connector sub-sets 40 after the switch 300 is disposed in the cabinet 10. Since each of the first connector contacts 30 is electrically connected to the second connector contact set 40 through the downlink cable 100, which corresponds to one of the first connector contacts 30 being electrically connected to one of the second connector contact sets 40 through the downlink cable 100, once the plurality of servers 200 are disposed in the cabinet 10 and the switch 300 is disposed in the cabinet 10, the plurality of servers 200 can be electrically connected to the switch 300, so that data can be transmitted between the plurality of servers 200 and the switch 300.

In addition, in some embodiments, the difference in length between the downstream cables 100 connecting each set of first and second connector contacts 30, 40 is less than a preset value, wherein each set of first and second connector contacts 30, 40 includes at least one first connector contact 30 and at least one second connector contact set 40.

Since the difference in length between the down cables 100 connecting each of the first connector sub 30 and the second connector sub set 40 is smaller than the preset value, it is equivalent to that the difference in length between the different down cables 100 is smaller than the preset value when the different first connector sub 30 is connected to the different second connector sub set 40 through the down cables 100, so that it is possible to ensure that the lengths of the different down cables 100 are approximately equal, so that the insertion loss of the links between the different first connector sub 30 and the corresponding second connector sub set 40 can meet the requirements, and also reduce the processing burden and the material cost caused by the inconsistent lengths of the down cables 100 when the lengths of the down cables 100 are approximately equal. That is, by setting the difference in length between the down cables 100 connecting each of the first connector sub 30 and the second connector sub 40 to be smaller than the predetermined value, the insertion loss requirement can be satisfied, and the efficiency of processing the down cables 100 can be improved and the material cost of the down cables 100 can be reduced. The insertion loss refers to the insertion loss SI requirement of the Ethernet KR protocol signal.

It should be noted that, in the embodiment of the present application, a specific value of the preset value may be set according to actual needs, for example, the preset value may be 3cm, for example, the preset value may be 2cm, and for example, the preset value may be 4cm. The specific values of the preset values are not limited herein.

For example, as shown in fig. 4, among the plurality of first connector tabs 30 on the first frame 211, when the first connector tab 30 located above the second frame 212 is connected with the second connector tab group 40 on the second frame 212 through the down cable 100, the first connector tab 30 located at the top of the first frame 211 may be connected with the second connector tab group 40 located at the middle of the second frame 212 through the down cable 100, and the first connector tab 30 near the second frame 212 may be connected with the second connector tab group 40 at the edge of the second frame 212 through the down cable 100, so that it may be ensured that the difference in length between the down cables 100 connecting each group of the first connector tab 30 and the second connector tab group 40 is less than a preset value. Similarly, among the plurality of first connector tabs 30 on the first frame body 211, when the first connector tab 30 located below the second frame body 212 is connected with the second connector tab group 40 on the second frame body 212 through the downlink cable 100, the first connector tab 30 located at the bottom of the first frame body 211 may be connected with the second connector tab group 40 located at the middle of the second frame body 212 through the downlink cable 100, and the first connector tab 30 near the second frame body 212 may be connected with the second connector tab group 40 at the edge of the second frame body 212 through the downlink cable 100, so that it may be ensured that the difference in length between the downlink cables 100 connecting each group of the first connector tab 30 and the second connector tab group 40 is smaller than a preset value.

In addition, in the embodiment of the present application, each of the first connector tab 30 and the second connector tab set 40 may include one first connector tab 30 and one second connector tab set 40. Of course, each set of first connector contacts 30 and second connector contact sets 40 may include two first connector contacts 30 and two second connector contact sets 40. The embodiments of the present application are not limited in this regard.

In addition, in some embodiments, the switch 300 may include a data switch 302 and a management switch 301, the second connector tab group 40 includes a first sub-tab 41 and a second sub-tab 42, the plurality of first sub-tabs 41 are spaced apart along the second direction, and the plurality of second sub-tabs 42 are spaced apart along the second direction; the first sub-connector 41 is used for connecting with the downstream port of the management switch 301, and the second sub-connector 42 is used for connecting with the downstream port of the data switch 302; of the plurality of first connector contacts 30, one first connector contact 30 is connected to one first sub-contact 41 and one second sub-contact 42 by a downlink cable 100.

Since the plurality of first sub-connectors 41 are spaced apart along the second direction, the plurality of second sub-connectors 42 are spaced apart along the second direction, and the first sub-connectors 41 and the second sub-connectors 42 are spaced apart along the first direction, when the management switch 301 and the data switch 302 are placed in the cabinet 10, the management switch 301 can be connected to the first sub-connectors 41, the data switch 302 can be connected to the second sub-connectors 42, that is, the plurality of downstream ports on the management switch 301 can be connected to the plurality of first sub-connectors 41, and the plurality of downstream ports on the data switch 302 can be connected to the plurality of second sub-connectors 42, so that accurate connection of both the management switch 301 and the data switch 302 is ensured. Since one first connector tab 30 connects one first sub tab 41 and one second sub tab 42 through the downlink cable 100, after the server 200 is placed in the cabinet 10 and the server 200 is connected with the first connector tab 30, the server 200 can be electrically connected with the management switch 301 and the data switch 302 at the same time, so that data can be transferred between the server 200 and the management switch 301 and the data switch 302. That is, by providing a first connector tab 30 to connect a first sub-tab 41 and a second sub-tab 42 via the downlink cable 100, it is ensured that the server 200 can electrically connect the management switch 301 and the data switch 302 at the same time, thereby transmitting data.

In this embodiment of the present application, a first network card 210 and a second network card 220 are disposed inside the server 200, the transmission speeds of the first network card 210 and the second network card 220 are different, a connection joint 230 is disposed on the server 200, the first network card 210 and the second network card 220 are connected to the same connection joint 230, and the first connector joint 30 is used for being connected to the connection joint 230.

Since the first network card 210 and the second network card 220 are connected to the same connection terminal 230, the connection terminal 230 is connected to the first connector terminal 30, and thus the number of connection terminals 230 provided on the server 200 is reduced, so that one first connector terminal 30 can be connected to one connection terminal 230 on the server 200 after the server 200 is placed in the cabinet 10. In addition, once the number of connection tabs 230 on the server 200 is reduced, the cost of the server 200 can be reduced, and the problem of high cost caused by providing a plurality of connection tabs 230 on the server 200 can be avoided. In addition, the first network card 210 and the second network card 220 are both connected to the same connection joint 230, so that the total length of the downlink cable 100 connecting the first network card 210 with the connection joint 230 and the second network card 220 with the connection joint 230 can be reduced, and the purpose of saving the downlink cable 100 can be achieved.

In addition, in some embodiments, the server 200 has opposite front and back ends, and the connection joint 230 is disposed at the back end of the server 200.

By providing the connection tab 230 at the rear end of the server 200, the connection tab 230 at the rear end can be directly connected to the first connector tab 30 on the connection rack 21 after the server 200 is placed in the cabinet 10. I.e., the connection terminal 230 is provided at the rear end of the server 200, it is convenient for the server 200 to be connected with the first connector terminal 30 after being placed in the cabinet 10.

In addition, in some embodiments, the connection frame 21 has opposite ends along the first direction, and the two ends of the connection frame 21 are connected to the top and bottom of the cabinet 10, respectively.

By connecting the two ends of the connection frame 21 with the top and the bottom of the cabinet body 10 respectively, the connection frame 21 can be ensured to be stable in the cabinet body 10, and the problem that the connection frame 21 may shake in the cabinet body 10, so that the server 200 and the switch 300 are not easy to be connected with the first connector joint 30 and the second connector joint set 40 respectively is avoided. That is, by providing both ends of the connection frame 21 to be connected to the top and bottom of the cabinet 10, respectively, it is possible to ensure that the server 200 and the switch 300 are conveniently installed in the cabinet 10 and that the server 200 is electrically connected to the switch 300.

It should be noted that, in the embodiment of the present application, two ends of the connecting frame 21 may be fixedly connected to the top and the bottom of the cabinet 10, for example, two ends of the connecting frame 21 are welded to the top and the bottom of the cabinet 10, respectively. Of course, the two ends of the connecting frame 21 may also be detachably connected with the top and the bottom of the cabinet body 10, for example, the two ends of the connecting frame 21 are respectively provided with through holes, the top and the bottom of the cabinet body 10 are respectively provided with through holes, the through holes penetrating through the top of the cabinet body 10 through bolts and the through holes penetrating through one end of the connecting frame 21 are connected with the top of the cabinet body 10, the through holes penetrating through the bottom of the cabinet body 10 through bolts and the through holes penetrating through the other end of the connecting frame 21 are connected with the bottom of the cabinet body 10. For another example, the two ends of the connecting frame 21 are respectively provided with a first buckle, the top and the bottom of the cabinet body 10 are respectively provided with a second buckle, and the first buckle and the second buckle are clamped, so that the two ends of the connecting frame 21 are respectively connected with the top and the bottom of the cabinet body 10. The embodiment of the present application is not limited herein as to the specific manner in which the two ends of the connection frame 21 are respectively connected to the top and bottom of the cabinet 10.

Additionally, in some embodiments, the cabinet 10 has first and second directions that intersect, and the connector 21 may be located at an intermediate position of the cabinet 10 along the second direction.

By providing the connection frame 21 at the middle position of the cabinet 10, the problem of extremely long downlink cable 100 can be avoided when the first connector on the first frame 211 in the connection frame 21 is connected with the second connector on the second frame 212 through the downlink cable 100. The connection frame 21 is cross-shaped, the first frame 211 extends along the first direction, the second frame 212 extends along the second direction, and therefore, after the plurality of servers 200 are placed in the cabinet 10 and the switch 300 is placed in the cabinet 10, the servers 200 are located on both sides of the switch 300, and if the connection frame 21 is not in the middle position, the positions of the second connector groups 40 need to be adjusted in order to connect the switch 300 with the second connector groups 40 on the connection frame 21, so that the length of the downlink cable 100 increases, and the problem that the downlink cable 100 is extremely too long may occur, which affects the insertion loss. In the embodiment of the present application, the connecting frame 21 is disposed at the middle position of the cabinet 10, so as to avoid the problem that the downlink cable 100 is extremely too long.

Additionally, in some embodiments, the second frame 212 may have a size that is smaller than the size of the cabinet 10 in the second direction.

Since the size of the second frame 212 is smaller than the size of the cabinet 10, the second frame 212 does not contact the cabinet 10 when the connecting frame 21 is disposed in the cabinet 10, thereby facilitating the disposition of the connector in the cabinet 10, and the size of the second frame 212 is smaller than the size of the cabinet 10, thereby saving material cost. If the size of the second frame 212 is equal to or greater than the size of the cabinet 10, when the connection frame 21 is disposed in the cabinet 10, the second frame 212 may contact the inner wall of the cabinet 10, and it is difficult to dispose connection in the cabinet 10.

It should be noted that, along the second direction, the size of the cabinet 10 may be the width of the cabinet 10, that is, the size of the cabinet 10 is the distance between two opposite sidewalls of the cabinet 10 along the second direction. The size of the second frame 212 along the second direction may be the length of the second frame 212, that is, the size of the second frame 212 is the distance between opposite ends of the second frame 212 along the second direction.

In addition, in some embodiments, a power frame 60 is provided on the cabinet 10, and a power management module 51 is provided in the power frame 60.

By providing the power frame 60 in the cabinet 10, the power management module 51 can be directly provided in the power frame 60, thereby facilitating the provision of the power management module 51. That is, by providing the power frame 60, it is possible to facilitate the provision of the power management module 51 in the cabinet 10.

In addition, in some embodiments, a power supply row 70 is disposed in the cabinet 10, and a first power connector and a second power connector are disposed on the power supply row 70, where the first power connector is used to connect with the server 200 to supply power to the server 200, and the second power connector is used to connect with the switch 300 to supply power to the switch 300.

By providing the power supply line 70, and providing the first power connector and the second power connector on the power supply line 70, when the server 200 and the switch 300 are placed in the cabinet 10, the server 200 can be connected with the first power connector, and the switch 300 is connected with the second power connector, so that power can be supplied to the server 200 and the switch 300 at the same time. That is, by providing the power supply line 70 and providing the first power connector and the second power connector on the power supply line 70, centralized power supply to the server 200 and the switch 300 can be realized, so that power supply to the server 200 and the switch 300 is unified. The dc power supply modules are disposed in the server 200 and the switch 300, the power supply line 70 is electrically connected with the dc power supply modules, and is used for intensively supplying power to the switch 300 and the switch 200, and the gate 52 can be electrically connected with the dc power supply modules in the server 200 and the switch 300, so as to perform unified power supply management on the server 200 and the switch 300.

The power supply line 70 may include a positive electrode line 71 and a negative electrode line 72.

In addition, in the embodiment of the present application, when the power frame 60 is provided in the cabinet 10, a power supply 601 may be provided in the power frame 60, the power supply 601 is electrically connected to the power supply bank 70, and the power supply 601 is electrically connected to the power management module 51. The power supply 601 may be a PSU power supply.

It should be noted that the power supply 601 may be electrically connected to the power management backplane 50, so that the power supply 601 may supply power to the gate 52 on the power management backplane 50, so that the gate 52 may operate normally.

In addition, in some embodiments, a water separator-collector 80 is disposed in the cabinet 10, the water separator-collector 80 includes a water inlet pipe 81 and a water outlet pipe 82, the water inlet pipe 81 is in communication with the water outlet pipe 82, and the water inlet pipe 81 is used for cooling and dissipating heat to the server 200 and the switch 300.

By providing the water dividing and collecting device 80, after the server 200 and the switch 300 are placed in the cabinet 10, the server 200 and the switch 300 can be connected to the water dividing and collecting device 80, so that after the cooling water enters through the water inlet pipe 81, the cooling water can cool and radiate the server 200 and the switch 300, and then the cooling water flows out of the water outlet pipe 82. That is, by providing the water separator-collector 80, it is possible to facilitate cooling and heat dissipation of the servers 200 and the switches 300 in the cabinet 10.

In addition, in the embodiment of the present application, when the power supply row 70 and the water diversion device 80 are disposed in the cabinet body 10, the power supply row 70 and the water diversion device 80 may be distributed at intervals along the second direction, that is, the power supply row 70 is disposed on one side of the cabinet body 10, and the water diversion device 80 is disposed on the other side of the cabinet body 10, so that the problem that the power supply row 70 and the water diversion device 80 may affect each other is avoided.

In the embodiment of the present application, since the connection frame 21 has the receiving cavity, and the plurality of first connector tabs 30 and the plurality of second connector tab groups 40 are provided on the outer wall of the connection frame 21, and the connection frame 21 is located in the cabinet 10, when the server 200 and the switch 300 are disposed in the cabinet 10, the server 200 may be connected to the connection pins on the first connector tabs 30, the switch 300 may be connected to the connection pins on the second connector tab groups 40, that is, when the server 200 and the switch 300 are pushed into the cabinet 10, after the server 200 and the switch 300 are pushed into the cabinet 10, The server 200 is connected to the connection pins on the first connector header 30, and the switch 300 is connected to the connection pins on the second connector header set 40, thereby achieving blind mating of the server 200 and the switch 300. In addition, since the first connector tab 30 and the second connector tab set 40 are partially protruded from the receiving cavity and each of the first connector tab 30 and the second connector tab set 40 is electrically connected by the down cable 100, the down cable 100 is positioned in the receiving cavity, after pushing the server 200 and the switch 300 into the cabinet 10, the server 200 is connected with the first connector tab 30, the switch 300 is connected with the second connector tab set 40, and the first connector tab 30 is electrically connected with the second connector tab set 40 by the down cable 100, so that the server 200 is electrically connected with the switch 300, The down cable 100 is located in the accommodating cavity, which corresponds to the down cable 100 being accommodated in the connection frame 21, and the connection frame 21 can protect the down cable 100. In addition, the power supply management unit may perform unified power supply management for the server 200 and the switch 300. That is, in the embodiment of the present application, by providing the connection frame 21 in the cabinet 10 of the server 200 and providing the first connector tab 30 and the second connector tab set 40 on the connection frame 21, providing the down cable 100 in the receiving cavity of the connection frame 21 and connecting the rear surface of the first connector tab 30 and the rear surface of the second connector tab set 40 with the down cable 100, respectively, so that once the server 200 and the switch 300 are placed in the cabinet 10, the server 200 is connected with the first connector tab 30, the switch 300 is connected with the second connector tab set 40, blind insertion of the server 200 and the switch 300 can be achieved, And down cable 100 is located and holds the chamber for thereby the user can't see down cable 100 outside cabinet body 10, avoid down cable 100 to appear on cabinet body 10 the complicated problem of staggering, in addition, link 21 can play the guard action to the cable, avoid the cable to easily damage the problem to appear, thereby can improve cabinet body 10's security, in addition, the cable is located and holds the chamber, just can realize through shorter cable that first connector joint 30 and second connector joint group 40 electricity are connected, thereby can practice thrift the cable, and then reduce cost. In addition, the power supply management unit may perform unified power supply management on the server 200 and the switch 300, so that the server 200 and the switch 300 may be centrally powered.

The embodiment of the application provides a server 200 system, and the server 200 system includes a server 200, a switch 300, and a cabinet of the server 200 in any of the foregoing embodiments.

The server 200 and the switch 300 are both located in the cabinet 10, and the server 200 is connected to the first connector sub 30, and the switch 300 is connected to the second connector sub set 40. The server 200 is connected to the fourth connector terminal 501, and the switch 300 is connected to the fifth connector terminal 502, so that the power management module 51 performs power control on the server 200 and/or the switch 300 through the gate 52 to perform unified power management on the server 200 and the switch 300.

In the embodiment of the present application, since the connection frame 21 has the receiving cavity, and the plurality of first connector tabs 30 and the plurality of second connector tab groups 40 are provided on the outer wall of the connection frame 21, and the connection frame 21 is located in the cabinet 10, when the server 200 and the switch 300 are disposed in the cabinet 10, the server 200 may be connected to the connection pins on the first connector tabs 30, the switch 300 may be connected to the connection pins on the second connector tab groups 40, that is, when the server 200 and the switch 300 are pushed into the cabinet 10, after the server 200 and the switch 300 are pushed into the cabinet 10, The server 200 is connected to the connection pins on the first connector header 30, and the switch 300 is connected to the connection pins on the second connector header set 40, thereby achieving blind mating of the server 200 and the switch 300. In addition, since the first connector tab 30 and the second connector tab set 40 are partially protruded from the receiving cavity and each of the first connector tab 30 and the second connector tab set 40 is electrically connected by the down cable 100, the down cable 100 is positioned in the receiving cavity, after pushing the server 200 and the switch 300 into the cabinet 10, the server 200 is connected with the first connector tab 30, the switch 300 is connected with the second connector tab set 40, and the first connector tab 30 is electrically connected with the second connector tab set 40 by the down cable 100, so that the server 200 is electrically connected with the switch 300, The down cable 100 is located in the accommodating cavity, which corresponds to the down cable 100 being accommodated in the connection frame 21, and the connection frame 21 can protect the down cable 100. That is, in the embodiment of the present application, by providing the connection frame 21 in the cabinet 10 of the server 200 and providing the first connector tab 30 and the second connector tab set 40 on the connection frame 21, providing the down cable 100 in the receiving cavity of the connection frame 21 and connecting the back of the first connector tab 30 and the back of the second connector tab set 40 with the server 200 and the switch 300 placed in the cabinet 10, respectively, the server 200 is connected with the first connector tab 30, the switch 300 is connected with the second connector tab set 40, blind insertion of the server 200 and the switch 300 can be achieved, and the down cable 100 is located in the accommodating cavity, so that a user cannot see the down cable 100 from the outside of the cabinet 10, the problem that the down cable 100 is intricate on the cabinet 10 is avoided, in addition, the connecting frame 21 can protect the down cable 100, the problem that the down cable 100 is easy to damage is avoided, the safety of the cabinet 10 can be improved, in addition, the down cable 100 is located in the accommodating cavity, the first connector joint 30 and the second connector joint group 40 can be electrically connected through the shorter down cable 100, thereby saving the down cable 100, further reducing the cost, further, the security of the server 200 system is improved, and the cost is reduced. In addition, the power supply management unit may perform unified power supply management on the server 200 and the switch 300, so that the server 200 and the switch 300 may be centrally powered. That is, the server 200 system in the embodiment of the application not only can realize blind insertion of the server 200 and the switch 300, but also can perform unified power supply management on the server 200 and the switch 300, and can also improve the security of the server 200 system and reduce the cost.

In addition, in some embodiments, as shown in fig. 10, a first network card 210 and a second network card 220 are disposed inside the server 200, the transmission speeds of the first network card 210 and the second network card 220 are different, a connection joint 230 is disposed on the server 200, the first network card 210 and the second network card 220 are connected to the same connection joint 230, and the connection joint 230 is connected to the first connector joint 30.

It should be noted that, in the embodiment of the present application, the first network card 210 may be a network card for transmitting the management network interface signal of the 1G-BASE-KR, for example, the second network card 220 may be a network card for transmitting the data network interface signal of the 100G-BASE-KR 4. In addition, server 200 may transmit data in the 100G-BASE-KR4 Ethernet protocol as well as in the 1G-BASE-KR Ethernet protocol. The 100G-BASE-KR4 Ethernet protocol is used for transmitting management data, and the 1G-BASE-KR Ethernet protocol is used for transmitting service data.

In addition, in some embodiments, a power supply row 70 is provided in the cabinet 10, and a first power connector and a second power connector are provided on the power supply row 70; the server 200 and the switch 300 are connected to the first power connector and the second power connector, respectively. Wherein, be provided with first power plug on the server 200, switch 300 is inside to be provided with power module, is provided with the second power plug on the switch 300, and power module is connected with the second power plug electricity, and first power plug is connected with first power plug, and the second power plug is connected with the second power plug.

Since the power supply module is disposed inside the switch 300 and is electrically connected to the second power plug, once the server 200 and the switch 300 are placed in the cabinet 10, the first power plug is connected to the first power plug on the power strip 70, the second power plug is connected to the second power plug, and the power strip 70 can supply power to the server 200 through the first power plug and supply power to the switch 300 through the second power plug. Generally, the voltage required by the server 200 is different from the voltage required by the switch 300, so that once the power of the power bank 70 is transferred to the switch 300, the power module can convert the power, so that the converted power meets the requirements of the switch 300. That is, by providing the power supply module inside the switch 300, once the server 200 and the switch 300 are placed in the cabinet 10 and connected to the power supply line 70, the centralized power supply of the server 200 and the switch by the power supply line 70 can be achieved.

The server 200 is provided with a centralized power supply module 201, and the centralized power supply module 201 is electrically connected to the first power plug. The centralized power supply module 201 may be a PAB centralized power supply module 201.

In addition, in the embodiment of the present application, the switch 300 has an uplink port and a downlink port, the downlink port is connected to the second connector tab set 40 on the connection frame 21, the uplink port of the switch 300 is connected to the third connector tab set 90 on the connection frame 21, and the back surface of the third connector tab set 90 is connected to an uplink cable 001, and the uplink cable 001 is located in the accommodating cavity of the connection frame 21 and passes through the connection frame 21 and is led out from the top end of the rear side of the cabinet 10.

In the description of the present specification, reference to the terms "one embodiment," "some embodiments," "illustrative embodiments," "examples," "specific examples," or "some examples," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the application. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

While embodiments of the present application have been shown and described, it will be understood by those of ordinary skill in the art that: many changes, modifications, substitutions and variations may be made to the embodiments without departing from the spirit and principles of the application, the scope of which is defined by the claims and their equivalents.

Claims

1. A server enclosure, the server enclosure comprising: the cabinet body, the link frame set up in the said cabinet body and power supply management unit;

The connecting frame is provided with a containing cavity, a plurality of first connector joints and a plurality of second connector joint groups are arranged on the outer wall of the connecting frame, the first connector joints are used for connecting a server, the second connector joint groups are used for connecting downlink ports of a switch, the first connector joints and the second connector joint groups extend into the containing cavity partially, each first connector joint and each second connector joint group are electrically connected through a downlink cable, and the downlink cable is positioned in the containing cavity;

2. The server cabinet of claim 1, wherein the cabinet has opposite front and rear sides, the connector frame having a rear cover attached thereto;

3. The server cabinet of claim 2, wherein the connection rack and the rear cover are cross-shaped, the cabinet body has a first direction and a second direction that intersect, the connection rack comprises a first rack body and a second rack body, the first rack body extends along the first direction, the second rack body extends along the second direction, and the first rack body intersects the second rack body;

4. The server cabinet of claim 3, wherein a plurality of the first connector contacts are spaced apart from the first rack along the first direction and a plurality of the second connector contact sets are spaced apart from the second rack along the second direction.

5. The server cabinet of claim 4, wherein a difference in length between downstream cables connecting each of the first connector header and the second connector header sets is less than a preset value, wherein each of the first connector header and the second connector header sets includes at least one of the first connector header and at least one of the second connector header sets.

6. The server cabinet of claim 4, wherein the switch comprises a data switch and a management switch, each of the second connector tab groups comprises a first sub-tab and a second sub-tab, the plurality of first sub-tabs being spaced apart along the second direction, the plurality of second sub-tabs being spaced apart along the second direction;

7. The server cabinet of claim 1, wherein the connection frame has opposite ends along a first direction, the ends of the connection frame being connected to the top and bottom of the cabinet, respectively.

8. The server cabinet of claim 1, wherein the cabinet has a first direction and a second direction that intersect, and wherein the connector rack is located at a middle position of the cabinet along the second direction.

9. The server cabinet of claim 3, wherein in the second direction, the second frame has a size that is smaller than a size of the cabinet.

10. The server cabinet of claim 1, wherein the first connector header and the second connector header set each have a front face provided with connection pins for connecting servers or switches and a back face located in the housing cavity, the back face of the first connector header and the back face of the second connector header set being electrically connected by a downlink cable.

11. The server cabinet of claim 1, wherein the switch comprises a data switch and a management switch, and a third connector joint set is further disposed on an outer wall of the connection rack, and the third connector joint set is used for connecting an uplink port of the switch;

12. The server cabinet of claim 11, wherein the third connector header set portion is located in the receiving cavity and the third connector header set is connected with an uplink cable that is located in the receiving cavity and passes out of the top of the cabinet.

13. The server cabinet according to claim 1, wherein a first network card and a second network card are arranged inside the server, transmission speeds of the first network card and the second network card are different, a connection joint is arranged on the server, the first network card and the second network card are connected to the same connection joint, and the first connector joint is used for being connected with the connection joint.

14. The server cabinet of claim 13, wherein the server has opposite front and rear ends, the connection joint being disposed at the rear end of the server.

15. The server cabinet of claim 1, wherein the gate is configured to alternate between conducting with each of the fourth connector contacts and each of the fifth connector contacts to conduct the power management module with each of the fourth connector contacts or to conduct the power management module with each of the fifth connector contacts.

16. The server cabinet of claim 1, wherein a power frame is disposed on the cabinet body, and wherein the power management module is disposed in the power frame.

17. The server cabinet of claim 1, wherein a power supply row is provided in the cabinet body, and a first power connector and a second power connector are provided on the power supply row, wherein the first power connector is used for being connected with the server to supply power to the server, and the second power connector is used for being connected with the switch to supply power to the switch.

18. The server cabinet of claim 1, wherein a water separator-collector is disposed in the cabinet body, the water separator-collector comprises a water inlet pipe and a water outlet pipe, the water inlet pipe is communicated with the water outlet pipe, and the water inlet pipe is used for cooling and radiating the server and the switch.

19. A server system comprising a server, a switch, and the server enclosure of any one of claims 1-18;

20. The server system according to claim 19, wherein a first network card and a second network card are provided inside the server, transmission speeds of the first network card and the second network card are different, a connection connector is provided on the server, the first network card and the second network card are connected to the same connection connector, and the connection connector is connected to the first connector.

21. The server system of claim 20, wherein the server has opposite front and back ends, and the connection joint is disposed at the back end of the server.

22. The server system of claim 19, wherein a power strip is disposed in the cabinet, the power strip having a first power connector and a second power connector disposed thereon;