CN216927521U - Extended power supply module and server - Google Patents

Abstract

The specification provides an extended power module and a server, and relates to the technical field of communication. An extended power supply module is applied to a server and comprises: the power supply frame is provided with a module channel which is used for connecting the outside of the server and the inside of the server and is used for accommodating the power supply module; the power supply back plate is fixed on one side of the power supply frame close to the inside of the server, and a connector connected with the power supply module is arranged on the power supply back plate; and the bus bar is electrically connected with the connector. Through above-mentioned extension power module, can satisfy the power supply demand of server, promote the flexibility of server configuration.

Description

Extended power supply module and server

Technical Field

The specification relates to the technical field of communication, in particular to an extended power module and a server.

Background

With the development of network technology, the configuration requirement of a server as a load-bearing network application is more and more abundant, so that the power consumption of the server is higher and higher, and the requirement on power supply is higher and higher.

Therefore, how to increase power supply in a limited space of a server is a problem that needs to be solved by those skilled in the art.

Disclosure of Invention

In order to overcome the problems in the related art, the specification provides an extended power module and a server.

In combination with the first aspect of the embodiments of the present specification, the present application provides an extended power module, which is applied to a server, and includes:

the power supply frame is provided with a module channel which is used for connecting the outside of the server and the inside of the server and is used for accommodating the power supply module;

the power supply back plate is fixed on one side of the power supply frame close to the inside of the server, and a connector connected with the power supply module is arranged on the power supply back plate;

and the bus bar is electrically connected with the connector.

Optionally, a fixing nail is arranged on the power supply back plate in a penetrating manner, and a fixing hole is formed in one side of the power supply frame, which is close to the inside of the server;

through the cooperation of staple and fixed orifices, the power backplate is fixed in the power frame.

Optionally, a clamping groove is formed in a corner of the power supply backboard, a clamping hook matched with the clamping groove is arranged at a position, close to one side inside the server, of the power supply frame, and the clamping hook penetrates through the clamping groove to clamp and fix the power supply backboard.

Optionally, fixing nails penetrate through corners of the upper side of the power supply back plate, and fixing holes matched with the fixing nails are formed in opposite positions of one side, close to the inside of the server, of the power supply frame;

a clamping groove is formed in the corner of the lower side of the power supply back plate, a clamping hook matched with the clamping groove is arranged at the opposite position of one side, close to the inside of the server, of the power supply frame, and the clamping hook penetrates through the clamping groove to clamp and fix the power supply back plate.

Optionally, a partition plate is arranged in the module channel, and the module channel is divided into at least two accommodating cavities by the partition plate;

the connector arranged on the power supply back plate corresponds to the accommodating cavity.

Optionally, the bus bar, comprising:

the fixing part is connected with a power supply circuit on a main board in the server;

the connecting part is connected with the mounting hole on the power supply back plate;

and the bending part is connected between the fixing part and the connecting part.

Further, the fixing part is fixed on a power supply circuit on a main board in the server through a screw.

Optionally, the power frame further includes:

the clamping portion is located at a corner portion, close to the inside of the server, of the power frame and used for clamping the power frame of the lower side power module.

In combination with the second aspect of the embodiments of the present specification, the present application provides a server, including:

a main board;

the power supply module is close to the mainboard;

the expansion power supply module is arranged on the upper side of the power supply module.

The technical scheme provided by the implementation mode of the specification can have the following beneficial effects:

in the embodiment of the specification, the hard disk and the expansion card which are positioned on the upper side of the power supply module are replaced by the expansion power supply module, the space application of the server is more flexible, and when the expansion power supply module is replaced, the power supply of the server can be improved, and the requirement of the server for larger power consumption is met.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the specification.

Drawings

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

Fig. 1 is a schematic structural diagram of a server according to an embodiment of the present application;

fig. 2 is a schematic structural diagram of an extended power module according to an embodiment of the present disclosure;

fig. 3 is a schematic structural diagram of a connection relationship between a power backplane and a power frame according to an embodiment of the present disclosure;

fig. 4 is a schematic structural diagram of another connection relationship between a power backplane and a power frame according to an embodiment of the present disclosure;

fig. 5 is a schematic structural diagram of another connection relationship between a power backplane and a power frame according to an embodiment of the present disclosure;

fig. 6 is a side view of an extended power supply module according to an embodiment of the present application.

Detailed Description

Reference will now be made in detail to the exemplary embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, like numbers in different drawings represent the same or similar elements unless otherwise indicated. The embodiments described in the following exemplary embodiments do not represent all embodiments consistent with the present specification.

The present application provides an extended power module 100, applied to a server 200, as shown in fig. 1, including:

a power frame 1, the power frame 1 being provided with a module channel 2 for accommodating the power module 300, which connects the outside of the server 200 and the inside of the server 200.

And a power backplane 3 fixed to the power frame 1 at a side close to the inside of the server 200, wherein the power backplane 3 is provided with a connector 30 connected to the power module 300.

And a bus bar 4, the bus bar 4 being electrically connected to the connector 30.

The server 200 may include a motherboard 5, and a power module 400 (which may be referred to as a basic power module) may be plugged into the motherboard 5, where the power module 400 is the power module 400 of the server 200. The expansion power module 100 may be disposed on the upper side of the power module 400. Corresponding through holes can be formed between the power module 400 and the expansion power module 100, and the power module 400 and the expansion power module 100 can be fixed by riveting through rivets.

The power module 400 and the extended power module 100 each include a power frame 1, and the power frame 1 may be surrounded by a plurality of sides, and a module channel may be formed between the sides, and the module channel connects the outside of the server 200 and the inside of the server 200, and may receive the power module 300 therein. As shown in fig. 2, the extended power module 100 may include a power frame 1, and the edges of the power frame 1 surround to form a module channel 2. Through this module channel 2, the plugging of the power module 300 can be completed from the outside of the server 200.

The power supply backboard 3 is arranged on the side, located on the inner side of the server 200, of the power supply frame 1, the power supply backboard 3 can be fixed to the power supply frame 1 in different connection modes, the connection modes can include multiple modes, for example, the connection modes can be matched with a fixing nail and a fixing hole, can also be matched with a clamping hook and a clamping groove, can also be bonded through glue, different connections can be arranged at different positions of the power supply backboard 3, and the like, and the connection modes are not limited.

The power supply backplane 3 is further provided with a power supply circuit for receiving the electric energy input by the power supply module 300, and since the power supply backplane 3 is a printed circuit board 31, during the manufacturing process, a required circuit pattern is formed on the printed circuit board 31, for example, the formed circuit pattern may include a power supply transmission circuit. Connectors 30 for realizing electrical connection and mounting holes connected with the bus bars 4 may be respectively provided at both ends of the power supply transmission circuit, and after the bus bars 4 are mounted to the power supply backplane through the mounting holes, the electrical connection between the bus bars 4 and the connectors 30 may be realized through the power supply transmission circuit.

Specifically, as shown in fig. 3, fixing nails 32 may be inserted into the power supply back plate 3, and fixing holes 10 may be provided in the power supply frame 1 on the side closer to the inside of the server 200. The power supply backboard 3 is fixed on the power supply frame 1 through the matching of the fixing nails 32 and the fixing holes 10.

The fixing nail 32 may be a loose screw, a rivet, or a screw, and the fixing holes 10 may be respectively corresponding fixing forms. The fixing hole 10 may be provided as a screw hole, for example, when the fixing nail 32 is a screw.

In order to reliably fix the power supply back panel 3, 4 fixing nails 32 may be provided at four corners of the power supply back panel 3, and correspondingly, four fixing holes 10 may be provided at four corners of the power supply frame 1 located at the inner opening of the server 200.

Optionally, as shown in fig. 4, a card slot 33 is disposed at a corner of the power backplane 3, and a hook 11 that is matched with the card slot 33 is disposed at a position of the power frame 1 that is opposite to the side close to the inside of the server 200, where the hook 11 passes through the card slot 33 to clamp and fix the power backplane 3. The through is understood to mean that part of the hook 11 passes through the slot 33 and holds the power supply back plate 3.

In order to fix the power backplane 3 quickly, 4 slots 33 may be disposed at four corners of the power backplane 3, and correspondingly, four hooks 11 are disposed at four corners of the power frame 1 located at the inner opening of the server 200.

Specifically, the hook 11 may include a supporting portion 11A and a clamping portion 11B extending upward from a tail portion of the supporting portion 11A. The size of the gap between the clamping part 11B and the edge of the power frame 1 is equal to or slightly smaller than that of the printed circuit board 31, so that the clamping of the printed circuit board 31 by the clamping part 11B and the edge of the power frame 1 can be realized, and the printed circuit board 31 is supported in the gap by the supporting part 11A, thereby realizing the fixation of the printed circuit board 31 and the power frame 1.

Preferably, as shown in fig. 5, fixing nails 32 are inserted into the upper corners of the power supply back plate 3, and fixing holes 10 for fitting the fixing nails 32 are provided at the opposite positions of the power supply frame 1 near the inside of the server 200.

A clamping groove 33 is arranged at the corner of the lower side of the power supply backboard 3, a clamping hook 11 matched with the clamping groove 33 is arranged at the opposite position of one side of the power supply frame 1 close to the inside of the server 200, and the clamping hook 11 penetrates through the clamping groove 33 to clamp and fix the power supply backboard 3.

Through the setting, can realize setting up fast based on trip 11 and draw-in groove 33 at power backplate 3's downside, afterwards, can realize that power backplate 3 is fixed reliably with power frame 1 through the staple 32 and the fixed orifices 10 of upside to compromise setting speed and fixed reliability.

Optionally, a partition 12 is provided in the module channel 2, and the module channel 2 is divided into at least two receiving chambers 13 by the partition 5. The connector 30 provided on the power backplane 3 corresponds to the accommodation chamber 13. That is, the number of power modules 300 can be more reasonably disposed according to the size of the power frame 1 and the size of the power modules 300.

Alternatively, the bus bar 4, as shown in fig. 6, includes:

a fixing part 40 connected to a power supply circuit on the main board 5 in the server 200;

a connecting part 41 connected with the mounting hole on the power supply backboard 3;

the bent portion 42 is connected between the fixing portion 40 and the connecting portion 41.

Through the setting of kink 42, busbar 4 has certain elasticity, when connecting power backplate 3 and mainboard 5 through busbar 4, can absorb the tolerance on power frame 1, power backplate 3 and the mainboard 5 through this elasticity to realize the reliable connection between power backplate 3 and the mainboard 5.

In addition to the fixing by screws 43, the fixing portion 40 may be fixed to the power supply circuit on the main board 5 in the server 200, and may have another columnar fixing structure, and may be fixed by another method such as welding.

Generally, in the case of providing the extended power module 100, in order to realize the splicing between the extended power module 100 and the power module 400 more quickly in the power module 400 below the extended power module 100, the power frame 1 further includes:

the clamping portion 14 is located at a corner of the power frame 1 near the inside of the server 200, and the clamping portion 14 is used for clamping the power frame 401 of the lower power module (i.e., the power module 400).

In order to enable the extended power supply module to be mounted more easily, the power supply module closer to the main board is generally referred to as a base power supply module, but the invention is not limited thereto. In some cases, the power module farther from the motherboard may be set first, and the power module below may be regarded as the extended power module, but in this case, the clamping portion 14 is not required to be set for clamping.

Correspondingly, the present application provides a server, as shown in fig. 1, including:

a main board 5;

the power module 400 is close to the mainboard 5;

the extended power module 100 is located on the upper side of the power module 400 (the power module 400 may be referred to as a basic power module).

The technical scheme provided by the implementation mode of the specification can have the following beneficial effects:

in the embodiment of the specification, the hard disk and the expansion card which are positioned on the upper side of the power supply module are replaced by the expansion power supply module, the space application of the server is more flexible, and when the expansion power supply module is replaced, the power supply of the server can be improved, and the requirement of the server for larger power consumption is met.

It will be understood that the present description is not limited to the precise arrangements described above and shown in the drawings, and that various modifications and changes may be made without departing from the scope thereof.

The above description is only for the purpose of illustrating the preferred embodiments of the present disclosure and is not to be construed as limiting the present disclosure, and any modifications, equivalents, improvements, etc. made within the spirit and principle of the present disclosure are intended to be included within the scope of the present disclosure.

Claims (9)

1. The utility model provides an extended power supply module which characterized in that is applied to the server, includes:

the power supply frame is provided with a module channel which is connected with the outside of the server and the inside of the server and is used for accommodating a power supply module;

the power supply back plate is fixed on one side of the power supply frame, which is close to the inside of the server, and a connector connected with the power supply module is arranged on the power supply back plate;

a bus bar electrically connected with the connector.

2. The extended power supply module of claim 1, wherein a fixing nail is arranged on the power supply back plate in a penetrating manner, and a fixing hole is arranged on one side of the power supply frame, which is close to the inside of the server;

through the cooperation of staple with the fixed orifices, the power backplate is fixed in the power frame.

3. The extended power supply module of claim 1, wherein a slot is disposed at a corner of the power supply backplane, and a hook matched with the slot is disposed at a position of the power supply frame opposite to a side close to the inside of the server, wherein the hook passes through the slot to fix the power supply backplane in a clamping manner.

4. The extended power supply module of claim 1, wherein fixing nails are inserted into corners of the upper side of the power supply back plate, and fixing holes matched with the fixing nails are arranged at opposite positions of one side of the power supply frame close to the inside of the server;

the power supply frame is close to the relative position of one side in the server is provided with a clamping hook matched with the clamping groove, wherein the clamping hook penetrates through the clamping groove to fix the power supply backboard in a clamping manner.

5. The extended power module of claim 1, wherein a partition is disposed in the module channel, and the module channel is divided into at least two receiving cavities by the partition;

the connector arranged on the power supply back plate corresponds to the accommodating cavity.

6. The extended power module of claim 1, wherein the bus bar comprises:

the fixing part is connected with a power supply circuit on a main board in the server;

the connecting part is connected with the mounting hole on the power supply back plate;

and the bending part is connected between the fixing part and the connecting part.

7. The extended power module of claim 6, wherein the fixing portion is fixed to a power supply circuit on a main board in the server by screws.

8. The extended power module of claim 1, wherein the power frame further comprises:

the joint portion is located the power frame is close to inside one side bight of server, joint portion is used for the power frame of joint downside power module.

9. A server, comprising:

a main board;

the power supply module is close to the mainboard;

the extended power module of any one of claims 1-8, located on an upper side of the power module.

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