CN107678506B

CN107678506B - Safe and controllable server architecture

Info

Publication number: CN107678506B
Application number: CN201710676815.5A
Authority: CN
Inventors: 张斌
Original assignee: Suzhou Inspur Intelligent Technology Co Ltd
Current assignee: Suzhou Inspur Intelligent Technology Co Ltd
Priority date: 2017-08-09
Filing date: 2017-08-09
Publication date: 2020-10-20
Anticipated expiration: 2037-08-09
Also published as: CN107678506A

Abstract

The invention relates to a safe and controllable server architecture which is characterized by comprising two sets of server main boards which are arranged in a mirror symmetry mode, wherein onboard power supply sharing ports and onboard management sharing ports are arranged on the two server main boards, and the onboard power supply sharing ports of the two server main boards are connected through onboard power supply sharing connectors; the onboard management sharing ports of the two server mainboards are connected through a dual-system management SMC module; the two server mainboards are both connected with a power supply module, and an onboard power supply sharing connector is connected to power supply controllers of the two server mainboards through a sharing interconnection component; the interconnection of the power systems of the two sets of server mainboards is realized; the two server main boards are both connected with a hard disk backboard, and the hard disk backboard is connected with a hard disk; the two server mainboards are also provided with a TPM interface and a safety card interface.

Description

Safe and controllable server architecture

Technical Field

The invention belongs to the technical field of server architecture design, and particularly relates to a safe and controllable server architecture.

Background

In recent years, due to frequent information security events, the demand for localization of information industry infrastructure equipment has become higher. The system architecture of the current pure domestic server adopts a standard frame or tower type form, the design of a main board follows EEB specification, the size specification of the main board is large, the number of reserved IO interfaces is large, and the capacity of a heat dissipation module has large allowance. The design does not fully consider the technical characteristics of relatively weak computing power, relatively low power and relatively few IO interfaces of the current domestic processor chip compared with the X86 processor. Resulting in a great waste of deployment density and IO.

In addition, because the function of the domestic server is relatively simple, the requirement on the monitoring management interface is relatively limited, and the application of the current single system design to the monitoring management chip is wasted to a certain extent. Compared with the current green energy-saving environmental protection advocate, the form is not applicable and needs to be upgraded and optimized urgently. This is a disadvantage of the prior art.

Therefore, aiming at the defects in the prior art, a safe and controllable server architecture is provided; it is very necessary to solve the above technical problems.

Disclosure of Invention

The present invention is directed to a secure and controllable server architecture, which solves the above technical problems.

In order to achieve the purpose, the invention provides the following technical scheme:

a safe and controllable server architecture is characterized by comprising two sets of server main boards which are arranged in a mirror symmetry mode, wherein onboard power supply sharing ports and onboard management sharing ports are arranged on the two server main boards, and the onboard power supply sharing ports of the two server main boards are connected through onboard power supply sharing connectors; the onboard management sharing ports of the two server mainboards are connected through a dual-system management SMC module;

the two server mainboards are both connected with a power supply module, and an onboard power supply sharing connector is connected to power supply controllers of the two server mainboards through a sharing interconnection component; the interconnection of the power systems of the two sets of server mainboards is realized;

the two server main boards are both connected with a hard disk backboard, and the hard disk backboard is connected with a hard disk;

the two server mainboards are also provided with a TPM interface and a safety card interface.

Preferably, the server architecture further comprises a left hanging lug and a right hanging lug, wherein a power switch, a USB (universal serial bus) and a VGA (video graphics array) interface are integrated on the left hanging lug and the right hanging lug, and the left hanging lug and the right hanging lug are respectively connected with the two server mainboards through cables.

Preferably, the server framework further comprises two sets of optical drives, and the two sets of optical drives are respectively connected with the two sets of server mainboards through cables.

Preferably, the onboard power sharing connector is a shared power board or a cable.

Preferably, the server main board is connected with the hard disk back board through a mini-SAS interface, and the hard disk back board is connected with the hard disk through an onboard hard disk interface.

Preferably, the dual system management SMC module includes an integrated BMC management chip, and the integrated BMC management chip is connected to two management sharing port connectors, and the two management sharing port connectors are respectively connected to the management sharing ports of the two mainboards.

Preferably, the server architecture further comprises an I/O interface and a PCIE interface.

Preferably, the server structure further comprises a fan module, wherein the fan module is connected with a fan back plate; the heat dissipation of the whole framework system is realized.

The invention has the advantages that the two sets of mainboard systems share the heat dissipation and the basic architecture, and the matching design is made in the aspect of IO by fully considering the calculation performance of the processor. In addition, besides integrating standard TPM interfaces, the security card interfaces are integrated on a system mainboard as standard configurations so as to meet the requirements of safe and controllable information security. Two sets of system main boards in the case are designed in a mirror symmetry mode, and in order to achieve system power sharing and redundancy, an onboard power sharing interface is arranged between the two sets of main boards and is connected with each other through a sharing power board or a cable. The dual-system management SMC module is introduced to monitoring management to directly cross-connect two system mainboards through an onboard management sharing port, so that monitoring management of the dual-system management SMC module is realized, and a set of management interface is externally arranged to realize unified management. The problem of the low deployment density of current standard form domestic server, IO, power supply, heat dissipation, the waste of managerial capability surplus is solved. In addition, the invention has reliable design principle, simple structure and very wide application prospect.

Therefore, compared with the prior art, the invention has prominent substantive features and remarkable progress, and the beneficial effects of the implementation are also obvious.

Drawings

Fig. 1 is a top view of a secure and controllable server architecture provided by the present invention.

Fig. 2 is a front view of a secure and controllable server architecture provided by the present invention.

Fig. 3 is a rear view of a secure and controllable server architecture provided by the present invention.

The system comprises a server mainboard 1, a onboard power supply sharing connector 2, a dual-system management SMC module 3, a power supply module 4, a hard disk backboard 5, a hard disk 6, a TPM interface 7, a safety card interface 8, a left hanging lug 9, a right hanging lug 10, an optical drive 11, an I/O interface 12, a PCIE interface 13 and a fan module 14.

Detailed Description

The present invention will be described in detail below with reference to the accompanying drawings by way of specific examples, which are illustrative of the present invention and are not limited to the following embodiments.

As shown in fig. 1-3, the secure controllable server architecture provided by the present invention includes two sets of server motherboards 1 arranged in mirror symmetry, both server motherboards are provided with onboard power sharing ports and onboard management sharing ports, and the onboard power sharing ports of the two server motherboards are connected through an onboard power sharing connector 2; the onboard management sharing ports of the two server mainboards are connected through a dual-system management SMC module 3;

the two server mainboards are both connected with a power supply module 4, and the onboard power supply shared connector 2 is connected to power supply controllers of the two server mainboards through a shared interconnection component; the interconnection of the power systems of the two sets of server mainboards is realized;

the two server main boards are both connected with a hard disk backboard 5, and the hard disk backboard 5 is connected with a hard disk 6;

the two server mainboards are also provided with a TPM interface 7 and a security card interface 8.

In this embodiment, the server architecture further includes a left suspension loop 9 and a right suspension loop 10, the left and right suspension loops are integrated with a power switch, a USB interface and a VGA interface, and the left and right suspension loops are respectively connected with the two server mainboards through cables.

The server framework further comprises two sets of optical drives 11, and the two sets of optical drives 11 are respectively connected with the two sets of server mainboards through cables.

The onboard power supply sharing connector 2 is a sharing power supply board or a cable.

The server mainboard 1 is connected with the hard disk backboard 5 through a mini-SAS interface, and the hard disk backboard 5 is connected with the hard disk 6 through an onboard hard disk interface.

The dual-system management SMC module 3 comprises an integrated BMC management chip, the integrated BMC management chip is connected with two management sharing port connectors, and the two management sharing port connectors are respectively connected with the management sharing ports of the two mainboards.

The server architecture also includes an I/O interface 12 and a PCIE interface 13.

The server structure also comprises a fan module 14, wherein the fan module 14 is connected with a fan back plate; the heat dissipation of the whole framework system is realized.

The above disclosure is only for the preferred embodiments of the present invention, but the present invention is not limited thereto, and any non-inventive changes that can be made by those skilled in the art and several modifications and amendments made without departing from the principle of the present invention shall fall within the protection scope of the present invention.

Claims

1. A safe and controllable server architecture is characterized by comprising two sets of server main boards (1) which are arranged in a mirror symmetry mode, wherein onboard power supply sharing ports and onboard management sharing ports are arranged on the two server main boards, and the onboard power supply sharing ports of the two server main boards are connected through onboard power supply sharing connectors (2); the onboard management sharing ports of the two server mainboards are connected through a dual-system management SMC module (3);

the two server mainboards are both connected with a power supply module (4), and the onboard power supply sharing connector (2) is connected to power supply controllers of the two server mainboards through a sharing interconnection component;

the two server main boards are both connected with a hard disk backboard (5), and the hard disk backboard (5) is connected with a hard disk (6);

TPM interfaces (7) and safety card interfaces (8) are also arranged on the two server mainboards;

the server architecture also comprises a left hanging lug (9) and a right hanging lug (10), wherein a power switch, a USB (universal serial bus) and a VGA (video graphics array) interface are integrated on the left hanging lug and the right hanging lug, and the left hanging lug and the right hanging lug are respectively connected with the two server mainboards through cables; the server framework also comprises two sets of optical drives (11), wherein the two sets of optical drives (11) are respectively connected with the two sets of server mainboards through cables; the onboard power supply sharing connector (2) is a sharing power supply board or a cable; the server main board (1) is connected with the hard disk back board (5) through a mini-SAS interface, and the hard disk back board (5) is connected with the hard disk (6) through an onboard hard disk interface; the dual-system management SMC module (3) comprises an integrated BMC management chip, the integrated BMC management chip is connected with two management sharing port connectors, and the two management sharing port connectors are respectively connected with the management sharing ports of the two mainboards; the server architecture further comprises an I/O interface (12) and a PCIE interface (13); the server structure further comprises a fan module (14), and the fan module (14) is connected with a fan back plate.