CN219590910U

CN219590910U - Data center system

Info

Publication number: CN219590910U
Application number: CN202320496153.4U
Authority: CN
Inventors: 吴浩; 蓝汉明; 詹隆; 任静; 宋健; 张炜明; 杨付平; 郑健; 杨翔志
Original assignee: Dongguan Shenzhen Communication Information Technology Co ltd
Current assignee: Dongguan Shenzhen Communication Information Technology Co ltd
Priority date: 2023-03-14
Filing date: 2023-03-14
Publication date: 2023-08-25
Anticipated expiration: 2033-03-14

Abstract

The utility model discloses a data center system, which comprises a monitoring component, a monitoring terminal and a plurality of cabinets, wherein each cabinet is provided with an independent code, the monitoring component is in communication connection with the monitoring terminal, the monitoring component can movably acquire independent code images and state image information of any cabinet, the independent code images and the state image information are sent to the monitoring terminal, the monitoring terminal positions the current cabinet according to the independent code images, and monitors the running state and the safety state of the current cabinet according to the state image information; the utility model effectively reduces the manual inspection cost, is easy to analyze the running state and the safety state of any cabinet by means of image analysis, realizes the remote full-automatic monitoring, can effectively reduce the dependence on the traditional smoke sensing system, is suitable for completing fire monitoring independently through a monitoring component or combining the traditional smoke sensing system, and effectively improves the fire alarm accuracy.

Description

Data center system

Technical Field

The utility model relates to the technical field of data center manufacturing, in particular to a data center system.

Background

The existing data machine room generally comprises a plurality of large-sized cabinets, a large number of IT devices such as servers and network devices are installed in each large-sized cabinet, each cabinet is generally divided into a plurality of installation intervals for installing different types of IT devices, the cabinet is generally provided with a metal door or a transparent door, after the installation of each IT device is finished, a safety door is locked, and a user cannot directly or effectively observe the conditions in the cabinet from outside.

Because the data machine room is generally in high-intensity operation, a patrol personnel is required to periodically patrol and record the operation state and the safety state of each cabinet. If necessary, the cabinet door of the machine can be opened, and IT equipment in the cabinet can be checked. The existing data center often has thousands of cabinets, so that the two work steps are time-consuming and labor-consuming, the accuracy of personnel is seriously depended, and a large amount of waste is easily caused.

The data computer lab is interior generally to be provided with smoke sensing system, when having the smog of certain concentration in conflagration or computer lab, smoke sensing system can send alarm signal, and at the time, smoke sensing system has the condition of misinformation or alarm delay, and misinformation can cause unexpected panic, and alarm delay can delay the opportunity of fighting fires, causes the serious loss of data computer lab easily.

Disclosure of Invention

The utility model aims to provide a data center system which effectively reduces the manual inspection cost, is easy to analyze the running state and the safety state of any cabinet by means of image analysis so as to realize remote full-automatic monitoring, can effectively reduce the dependence on a traditional smoke sensing system, is suitable for completing fire monitoring independently through a monitoring component or combining the traditional smoke sensing system, and effectively improves the fire alarm accuracy.

In order to achieve the above purpose, the utility model discloses a data center system, which comprises a monitoring component, a monitoring terminal and a plurality of cabinets, wherein each cabinet is provided with an independent code, the monitoring component is in communication connection with the monitoring terminal, the monitoring component can movably acquire independent code images and state image information of any cabinet and sends the independent code images and state image information to the monitoring terminal, and the monitoring terminal positions the current cabinet according to the independent code images and monitors the running state and the safety state of the current cabinet according to the state image information.

Compared with the prior art, each cabinet is provided with an independent code, independent code image and state image information of any cabinet are movably acquired through the monitoring component, and the independent code image and the state image information are sent to the monitoring terminal, so that the monitoring terminal can selectively monitor the running state and the safety state of any cabinet in real time, the manual inspection cost is effectively reduced, the running state and the safety state of any cabinet are easily analyzed by means of image analysis, the remote full-automatic monitoring is realized, the dependence on a traditional smoke sensing system is effectively reduced, and the system is suitable for completing fire monitoring independently through the monitoring component or combining the traditional smoke sensing system, and the fire alarm accuracy is effectively improved.

Preferably, the monitoring assembly comprises a sliding rail assembly and a camera assembly, and the camera assembly can freely move in an X-Y plane through the sliding rail assembly.

Specifically, the sliding rail assembly comprises a first rail and a second rail, one of the first rail and the second rail is arranged along the X-axis direction, the other one of the first rail and the second rail is arranged along the Y-axis direction, the second rail is connected with the first rail in a sliding manner through a first sliding block, the camera assembly is connected with the second rail in a sliding manner through a second sliding block, and the first rail and the second rail jointly form a rail frame.

Preferably, the monitoring component is arranged outside the cabinet, and the independent code is arranged on the outer wall of the cabinet and faces the track frame.

Preferably, the data center system comprises a plurality of monitoring components, each monitoring component corresponds to one cabinet, the monitoring components are arranged in the cabinets, and the independent codes are arranged in the cabinets and face the track frames.

Preferably, the track frame is mounted on the inner wall of a cabinet door of the cabinet.

Specifically, the track frame is embedded in the inner wall of a cabinet door of the cabinet.

Preferably, the monitoring assembly further comprises a connecting wire harness and a storage box, the connecting wire harness is wound in the storage box in an elastically telescopic mode, one end of the connecting wire harness is electrically connected with the camera assembly, and the other end of the connecting wire harness is electrically connected with the power supply.

Preferably, the independent codes comprise independent two-dimensional codes or code bars.

Preferably, the operation state of the cabinet comprises a start-up state and a stop state, and the safety state of the cabinet comprises a fire state and a smoke state.

Drawings

FIG. 1 is a schematic diagram of the data center system of the present utility model;

FIG. 2 is a schematic illustration of the locations of all cabinets and monitoring assemblies of the present utility model with all cabinets arranged in a single row in sequence;

FIG. 3 is a schematic view of the locations of each row of cabinets and corresponding monitoring assemblies when all of the cabinets of the present utility model are arranged in a plurality of rows in sequence;

FIG. 4 is a schematic structural view of the monitoring assembly of the present utility model;

fig. 5 is a block diagram of a data center system of the present utility model.

Detailed Description

In order to describe the technical content, the constructional features, the achieved objects and effects of the present utility model in detail, the following description is made in connection with the embodiments and the accompanying drawings.

Referring to fig. 1-5, the data center system of the present embodiment includes a monitoring assembly 10, a monitoring terminal 20 and a plurality of cabinets 30, all cabinets 30 may be distributed in the data center system according to a preset arrangement rule, in this embodiment, all cabinets 30 are illustrated as an array arrangement of a plurality of rows and a plurality of columns, each cabinet 30 has a corresponding number, and the monitoring terminal 20 can position any cabinet 30 according to the number.

Each cabinet 30 has an independent code 40, and preferably, the independent code 40 includes independent two-dimensional codes or code bars, each two-dimensional code or code bar stores the number of the current cabinet 30, and of course, each two-dimensional code or code bar may also store information such as the model number, position information, electrical parameters, etc. of the current cabinet 30.

The monitoring component 10 is in communication connection with the monitoring terminal 20, the monitoring component 10 can movably acquire independent coding images and state image information of any cabinet 30, and send the independent coding images and the state image information to the monitoring terminal 20, and the monitoring terminal 20 locates the current cabinet 30 according to the independent coding images and monitors the running state and the safety state of the current cabinet 30 according to the state image information. Preferably, the operation state of the cabinet 30 includes, but is not limited to, a start-up state and a stop state, and the safety state of the cabinet 30 includes, but is not limited to, a fire state and a smoke state.

Preferably, the monitoring assembly 10 includes a slide rail assembly and a camera assembly 12, the camera assembly 12 being freely movable in the X-Y plane by the slide rail assembly. Specifically, the sliding rail assembly includes a first rail 111 and a second rail 112, one of the first rail 111 and the second rail 112 is arranged along the X-axis direction, the other is arranged along the Y-axis direction, the second rail 112 is slidably connected to the first rail 111 through a first slider, the camera assembly 12 is slidably connected to the second rail 112 through a second slider, and the first rail 111 and the second rail 112 together form a rail frame.

Preferably, the camera module 12 may be connected to the second slider through an electric universal ball (not shown), and the electric universal ball is communicatively connected to the monitor terminal 20, so that the monitor terminal 20 can remotely control the shooting angle of the camera module 12, so as to monitor a specific portion of the cabinet 30 more flexibly.

Specifically, in order to overcome the power supply problem and the wire harness winding problem in the moving process of the camera module 12, the monitoring module 10 of the embodiment further comprises a connecting wire harness 13 and a storage box 14, the connecting wire harness 13 is wound in the storage box 14 in an elastically telescopic mode, one end of the connecting wire harness 13 is electrically connected with the camera module 12, and the other end of the connecting wire harness is electrically connected with a power supply, so that the camera module 12 is not exposed in a data center system in the current moving process, and the camera module 12 is effectively prevented from moving failure due to wire clamping.

Preferably, the monitoring assembly 10 is disposed outside the cabinet 30 as shown in FIGS. 1-3, and the independent code 40 is disposed on the outer wall of the cabinet 30 and facing the track frame. For only a single row of sequential cabinets 30, the track frame generally faces the front of all cabinets 30, and preferably, the front projection of all cabinets 30 should fall entirely within the projection of the track frame to ensure that movement of camera assembly 12 covers all cabinets 30.

For a plurality of rows of cabinets 30 arranged in sequence, a plurality of monitoring assemblies 10 should be provided, and each monitoring assembly 10 corresponds to a row of cabinets 30 arranged in sequence, and the arrangement mode is the same as that when a single row of cabinets 30 are arranged in sequence, and will not be described herein.

Further, since the monitoring assembly 10 is photographed from the outside of the cabinet 30, in order to effectively obtain the situation inside the cabinet 30, the door of the cabinet 30 is preferably a transparent door, so that the image data inside the cabinet 30 can be directly obtained for the monitoring terminal 20 to perform image analysis during photographing.

In other preferred forms, each cabinet 30 may also be monitored independently. Specifically, the data center system includes a plurality of monitoring assemblies 10, each monitoring assembly 10 corresponding to one of the racks 30, the monitoring assemblies 10 being disposed within the racks 30, and independent codes 40 being disposed within the racks 30 and facing the track frames. Preferably, the track frame is mounted on the inner wall of the cabinet door 1 of the cabinet 30, preferably embedded in the inner wall of the cabinet door 1 of the cabinet 30, but of course the track frame may also be mounted in other parts of the cabinet 30. At this time, the monitoring assembly 10 directly photographs the respective IT devices inside the cabinet 30 to more precisely obtain the specific operation state and the safety state of each IT device.

Of course, in other preferred manners, a group of monitoring assemblies 10 may be disposed outside each row of the cabinets 30 that are sequentially arranged, and a group of monitoring assemblies 10 may be disposed in each cabinet 30, so as to complete simultaneous monitoring of the outside of the cabinets 30 and the inside of the cabinets 30, which is not described herein.

It should be noted that the monitoring terminal 20 is a remote terminal, and the monitoring terminal 20 locates the specific location of the current cabinet 30 after receiving the independent coded image. After receiving the status image information, the monitoring terminal 20 converts the status image information into an analog quantity that can be identified by the hardware circuit, and monitors the operation status analysis and the safety status of the cabinet 30 through the hardware circuit built by the electronic components. Of course, the monitoring terminal 20 may also have a certain computing capability, and process the state image information according to the image analysis software, for example, analyze the indication lamps, the control lamps and the environment inside and outside the cabinet 30, so as to complete the operation state analysis and the safety state analysis of the cabinet 30, and the operation state analysis and the safety state analysis by the image analysis software may be implemented by calling, which is not described herein.

Referring to fig. 1-5, each cabinet 30 of the present utility model has an independent code 40, which can movably acquire independent code image and status image information of any cabinet 30 through the monitoring component 10, and send the independent code image and status image information to the monitoring terminal 20, so that the monitoring terminal 20 can selectively monitor the operation status and the safety status of any cabinet 30 in real time, thereby effectively reducing the cost of manual inspection, and analyzing the operation status and the safety status of any cabinet 30 easily by means of image analysis, so as to realize remote full-automatic monitoring, effectively reduce the dependence on the traditional smoke sensing system, and be suitable for completing fire monitoring independently through the monitoring component 10 or combining the traditional smoke sensing system, and effectively improving the fire alarm accuracy.

The foregoing description of the preferred embodiments of the present utility model is not intended to limit the scope of the claims, which follow, as defined in the claims.

Claims

1. A data center system, characterized by: the intelligent cabinet monitoring system comprises a monitoring assembly, a monitoring terminal and a plurality of cabinets, wherein each cabinet is provided with an independent code, the monitoring assembly is in communication connection with the monitoring terminal, the monitoring assembly can movably acquire independent code images and state image information of any cabinet, the independent code images and the state image information are sent to the monitoring terminal, and the monitoring terminal positions the current cabinet according to the independent code images and monitors the running state and the safety state of the current cabinet according to the state image information.

2. The data center system of claim 1, wherein: the monitoring assembly comprises a sliding rail assembly and a camera assembly, and the camera assembly can freely move in an X-Y plane through the sliding rail assembly.

3. The data center system of claim 2, wherein: the sliding rail assembly comprises a first rail and a second rail, one of the first rail and the second rail is arranged along the X-axis direction, the other one of the first rail and the second rail is arranged along the Y-axis direction, the second rail is connected with the first rail in a sliding manner through a first sliding block, the camera assembly is connected with the second rail in a sliding manner through a second sliding block, and the first rail and the second rail jointly form a rail frame.

4. The data center system of claim 3, wherein: the monitoring assembly is arranged outside the cabinet, and the independent codes are arranged on the outer wall of the cabinet and are opposite to the track frame.

5. The data center system of claim 3, wherein: the monitoring system comprises a plurality of monitoring assemblies, wherein each monitoring assembly corresponds to one cabinet, the monitoring assemblies are arranged in the cabinets, and the independent codes are arranged in the cabinets and are opposite to the track frames.

6. The data center system of claim 5, wherein: the track frame is installed on the inner wall of a cabinet door of the cabinet.

7. The data center system of claim 6, wherein: the track frame is embedded into the inner wall of the cabinet door of the cabinet.

8. The data center system of claim 3, wherein: the monitoring assembly further comprises a connecting wire harness and a storage box, the connecting wire harness is wound in the storage box in an elastically telescopic mode, one end of the connecting wire harness is electrically connected with the camera assembly, and the other end of the connecting wire harness is electrically connected with a power supply.

9. The data center system of claim 1, wherein: the independent codes comprise independent two-dimensional codes or code bars.

10. The data center system of claim 1, wherein: the operation state of the cabinet comprises a starting state and a stopping state, and the safety state of the cabinet comprises a fire state and a smoke state.