CN214896436U - Modular multi-computing-node GPU server structure - Google Patents

Abstract

The utility model discloses a many compute node GPU server structures of modularization, including the bottom plate, set up a plurality of compute module slots, a plurality of GPU card slots, management system module interface, network processing module interface, heat dissipation power source interface and power input interface on the bottom plate. The utility model has the advantages that: the expansion slots are arranged in a centralized mode, so that high-density slot arrangement is facilitated, various resources such as calculation, storage, management, networks and display cards are effectively integrated, various characteristics such as flexible arrangement and effective expansion of various functional modules are achieved, hot plug installation is achieved, replacement and maintenance are facilitated, when any one module fails, the modules do not affect each other, and normal operation of a server is not affected.

Description

Modular multi-computing-node GPU server structure

Technical Field

The utility model relates to a server technical field, in particular to multinode GPU server structure is a server bottom plate structure that has high density, high extension, based on modularization technical characteristic.

Background

Currently, the computational performance of simple GPU products has not been able to meet compute-intensive workloads, such as complex visual computations, large-scale data rendering, etc. in GPU computing application scenarios. If more GPUs are needed, only a plurality of GPU servers are used for stacking, which is not only unfavorable for installation and deployment, but also inevitably causes cost increase and repeated investment.

With the development of the technology, the blade server has appeared, and multiple complete independent GPU systems can be deployed in the same chassis, but due to the influence of the layout structure of the blade server and the structure of the blade itself, high-density expansion cannot be achieved, and the computing module 16 and the GPU module can only be integrated on the same blade. Meanwhile, the blade server is used as high-performance computing equipment, so that the requirements on operation, maintenance, management and exchange performance are particularly high, the standards are not uniform, the expansion performance is poor, and the cost is high.

SUMMERY OF THE UTILITY MODEL

The utility model discloses to prior art's defect, a many compute node GPU server structure of modularization is provided.

In order to realize the purpose of the utility model, the utility model discloses the technical scheme who takes as follows:

a modular multi-compute node GPU server architecture, comprising: the system comprises a bottom plate 1, a management system module 2, a network processing module 3, a cooling fan module 4, a PSU power supply module 5, a power input back plate 6, a cooling fan module back plate 7 and a case 8;

the bottom board 1 is provided with a computing module slot 9, a GPU card slot 10, a management system module interface 11, a network processing module interface 12, a heat dissipation power interface 13 and a power input interface 14.

The number of the computing module slots 9 is multiple, each computing module slot 9 is inserted with one computing module 16, so that data communication and electric connection between the computing module 16 and the bottom plate 1 are realized, a hot plug function is realized, and the computing module 16 is a server.

The GPU card slots 10 are multiple, each GPU card slot 10 is correspondingly provided with a GPU card additional power supply access interface, the GPU card slots are used for inserting the display cards 15, and one computing module 16 corresponds to one display card 15;

the management system module interface 11 is used for connecting the management system module 2, two electric port network connection ports are arranged on the management system module 2, and the management system module 2 is used for controlling and monitoring the running state of each module on the bottom plate 1, including starting/disconnecting the expansion template, and controlling the rotating speed and starting and stopping of the fan.

The number of the network processing module interfaces 12 is two, the network processing module interfaces 12 are used for accessing the network processing module 3, and the network processing module 3 is used for realizing data communication between the bottom plate 1 and the outside.

The heat dissipation power supply interface 13 is used for connecting the heat dissipation fan module back plate 7, a plurality of heat dissipation fan module interfaces are arranged on the heat dissipation fan module back plate 7, each heat dissipation fan module interface is connected with one heat dissipation fan module 4, and the heat dissipation fan module 4 is used for dissipating heat for the case 8.

Two power input interfaces 14 are respectively connected with the two power input back plates 6; the power input back plate 6 is provided with two PSU power supply module interfaces, and each PSU power supply module interface is provided with one PSU power supply module 5. The power supply module 5 works in a load balancing redundancy mode, and the power supply safety and reliability of the server system are effectively improved on the basis of considering energy conservation.

The chassis 8 is the shell of the modular multi-node GPU server architecture.

Preferably, the network processing module 3, the cooling fan module 4, the computing module 16, the display card 15, the PSU power supply module 5 and the management system module 2 can be hot-plugged;

preferably, the number of the radiator fan modules 4 is eight.

Preferably, the network processing module 3 is provided with three optical port network connection ports.

Preferably, the GPU card slots 10 are ten in number.

Preferably, the number of computing module slots 9 is ten.

Preferably, the plurality of computing module slots 9 are arranged laterally side by side, and the GPU card slot 10 is located corresponding to the computing module slot 9.

Compared with the prior art, the utility model has the advantages of:

1. support the simultaneous centralized placement of multiple compute modules 16 and GPU cards on the same chassis floor.

2. The server backplane structure has the advantages of high availability, high expansion, high density and modularization technology based.

3. The bottom plate is used as a substrate of the modularized layout structure, and all modules are uniformly fused and configured, so that various characteristics such as flexible deployment and effective expansion are realized.

4. The hot plugging installation of multiple functional modules can be realized on the same bottom plate, and the installation, maintenance and operation are very convenient.

5. The functional modules on the same bottom plate are configured with different models of computing modules 16 according to different application requirements.

6. The computing module 16 and the display card on the same bottom plate are separated, and when any one module fails, the modules do not affect each other, and the normal operation of the server is not affected.

7. The monitoring and monitoring of the running state of each functional module system are realized through the management control module, and the management modes include but are not limited to Web end background, PC end application, mobile end APP and the like.

Drawings

FIG. 1 is a schematic structural diagram of a bottom plate according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of the connection between the bottom plate and each module according to the embodiment of the present invention;

fig. 3 is a schematic view illustrating the installation of a display card and a computing module according to an embodiment of the present invention;

fig. 4 is an installation diagram of the management system module, the cooling fan module and the PSU power supply module according to an embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be further described in detail with reference to the accompanying drawings and examples.

As shown in fig. 1 to 4, a modular multi-compute node GPU server architecture comprises: the system comprises a bottom plate 1, a management system module 2, a network processing module 3, a cooling fan module 4, a PSU power supply module 5, a power input back plate 6, a cooling fan module back plate 7 and a case 8;

the bottom board 1 is provided with a computing module slot 9, a GPU card slot 10, a management system module interface 11, a network processing module interface 12, a heat dissipation power interface 13 and a power input interface 14.

The number of the computing module slots 9 is ten, and each computing module slot 9 is inserted with one computing module 16, so that the data communication and the electric connection between the computing module 16 and the bottom plate 1 are realized, and the hot plug function is realized.

The number of the GPU card slots 10 is ten, each GPU card slot 10 is correspondingly provided with a GPU card additional power supply access interface, and the GPU card slots are used for inserting the display cards 15;

the management system module interface 11 is used for connecting the management system module 2, two electric port network connection ports are arranged on the management system module 2, and the management system module 2 is used for controlling and monitoring the running state of each module on the bottom plate 1, including starting/disconnecting the expansion template, and controlling the rotating speed and starting and stopping of the fan.

The number of the network processing module interfaces 12 is two, the network processing module interfaces 12 are used for accessing the network processing module 3, three optical port network connection ports are respectively arranged on the network processing module 3, and different users can select the number of the optical port network connection ports according to requirements to realize data communication between the bottom plate 1 and the outside.

The heat dissipation power supply interface 13 is used for connecting the heat dissipation fan module back plate 7, eight heat dissipation fan module interfaces are arranged on the heat dissipation fan module back plate 7, each heat dissipation fan module interface is connected with one heat dissipation fan module 4, and the heat dissipation fan module 4 is used for dissipating heat for the case 8.

Two power input interfaces 14 are respectively connected with the two power input back plates 6; the power input back plate 6 is provided with two PSU power supply module interfaces, and each PSU power supply module interface is provided with one PSU power supply module 5. The power supply module 5 works in a load balancing redundancy mode, and the power supply safety and reliability of the server system are effectively improved on the basis of considering energy conservation.

The utility model can realize hot plug installation of each functional module on the same server bottom board, and users can configure different numbers of computing modules 16 and display cards 15, wherein the computing modules 16 have multiple optional configurations; meanwhile, the management control module, the cooling fan module, the network processing module and the PSU power supply module which are configured on the bottom plate can be selected according to different requirements.

The utility model discloses the base plate of bottom plate as modularization layout structure is unified to dispose each module. The management control module is responsible for monitoring and controlling the running state of each module configured on the bottom plate, so that a user can conveniently operate and maintain each module through the management control module, and the operation and maintenance are very simple.

It will be appreciated by those of ordinary skill in the art that the examples described herein are intended to assist the reader in understanding the manner of practicing the invention, and it is to be understood that the scope of the invention is not limited to such specific statements and examples. Those skilled in the art can make various other specific modifications and combinations based on the teachings of the present invention without departing from the spirit of the invention, and such modifications and combinations are still within the scope of the invention.

Claims (7)

1. A modular multi-compute node GPU server architecture, comprising: the system comprises a bottom plate (1), a management system module (2), a network processing module (3), a cooling fan module (4), a PSU power supply module (5), a power input back plate (6), a cooling fan module back plate (7) and a case (8);

a computing module slot (9), a GPU card slot (10), a management system module interface (11), a network processing module interface (12), a heat dissipation power interface (13) and a power input interface (14) are arranged on the bottom plate (1);

a plurality of computing module slots (9) are provided, each computing module slot (9) is inserted with one computing module (16) to realize the data communication and the electric connection between the computing module (16) and the bottom plate (1) and realize the hot plug function, and the computing module (16) is a server;

the GPU card slots (10) are provided with a plurality of GPU card slots, each GPU card slot (10) is correspondingly provided with a GPU card additional power supply access interface, the GPU card slots are used for inserting the display cards (15), and one computing module (16) corresponds to one display card (15);

the management system module interface (11) is used for connecting the management system module (2), the management system module (2) is provided with two electric port network connection ports, and the management system module (2) is used for controlling and monitoring the running state of each module on the bottom plate (1), and comprises an opening/closing expansion template, a fan rotating speed control module and a fan starting/closing control module;

the number of the network processing module interfaces (12) is two, the network processing module interfaces (12) are used for being connected to the network processing module (3), and the network processing module (3) is used for realizing data communication between the bottom plate (1) and the outside;

the heat dissipation power supply interface (13) is used for connecting a heat dissipation fan module backboard (7), a plurality of heat dissipation fan module interfaces are arranged on the heat dissipation fan module backboard (7), each heat dissipation fan module interface is connected with one heat dissipation fan module (4), and each heat dissipation fan module (4) is used for dissipating heat for the case (8);

two power input interfaces (14) are respectively connected with the two power input back plates (6); two PSU power supply module interfaces are arranged on the power input back plate (6), and each PSU power supply module interface is provided with one PSU power supply module (5); the power supply module (5) works in a load balancing redundancy mode, and the power supply safety and reliability of the server system are effectively improved on the basis of considering energy conservation;

the chassis (8) is a shell of a modular multi-node GPU server structure.

2. The modular multi-compute node GPU server architecture of claim 1, wherein: the network processing module (3), the cooling fan module (4), the computing module (16), the display card (15), the PSU power supply module (5) and the management system module (2) can be connected in a hot-plugging mode.

3. The modular multi-compute node GPU server architecture of claim 1, wherein: the number of the radiating fan modules (4) is eight.

4. The modular multi-compute node GPU server architecture of claim 1, wherein: the network processing module (3) is respectively provided with three optical port network connection ports.

5. The modular multi-compute node GPU server architecture of claim 1, wherein: the number of GPU card slots (10) is ten.

6. The modular multi-compute node GPU server architecture of claim 5, wherein: the number of the computing module slots (9) is ten.

7. The modular multi-compute node GPU server architecture of claim 6, wherein: the plurality of computing module slots (9) are arranged side by side and transversely, and the GPU card slot (10) corresponds to the computing module slots (9).

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