CN220214286U - Data center measurement monitoring component - Google Patents

Abstract

The utility model discloses a data center metering and monitoring assembly, which comprises an energy consumption monitoring cabinet, a dust collecting and guiding mechanism and a split type dust removing mechanism, wherein the dust collecting and guiding mechanism is arranged on one side of the energy consumption monitoring cabinet, the dust collecting and guiding mechanism comprises a collecting and guiding box, a drainage tube is connected in the collecting and guiding box and communicated with the energy consumption monitoring cabinet, a negative pressure fan is connected in the drainage tube, the split type dust removing mechanism is arranged in the energy consumption monitoring cabinet, the split type dust removing mechanism comprises a pair of dust removing filter bags, two ends of each dust removing filter bag are fixedly connected with fixing blocks, and a dust removing communicating pipe is connected between each fixing block and the drainage tube. According to the utility model, through the arrangement of the corresponding mechanism, the data center metering and monitoring assembly has an automatic dust removing function, so that dust accumulation of the data center metering and monitoring assembly in the use process is reduced, and the use safety and stability of the data center metering and monitoring assembly are improved.

Description

Data center measurement monitoring component

Technical Field

The present utility model relates to data centers, and more particularly to a data center metering and monitoring assembly.

Background

Data centers are a specific type of network equipment used for transmitting, accelerating, displaying, calculating and storing data information on the internet, and with the popularization and development of artificial intelligence, the application of the data centers is also becoming wider and wider.

As is well known, the data center can process huge data in the operation process, correspondingly, the energy consumption in the operation process of the data center is far higher than that of a common computer server, and in order to reduce the operation energy consumption of the data center, the operation energy consumption of the data center is metered and monitored by mainly adopting a data center metering and monitoring component at present, so that the energy consumption of the data center is conveniently and reasonably planned.

The data center metering and monitoring assembly in the prior art mainly comprises hardware equipment such as an energy consumption monitoring controller, an electric quantity metering device, a control coding module, a communication module, a temperature and humidity transmitter, an energy consumption monitoring cabinet and an energy consumption monitoring software system, wherein the hardware equipment such as the energy consumption monitoring controller, the electric quantity metering device, the control coding module, the communication module, the temperature and humidity transmitter are uniformly assembled in the energy consumption monitoring cabinet, the energy consumption monitoring cabinet is distributed in a data center machine room in the use process, and metering and monitoring are carried out on a data center through the mutual cooperation of the hardware equipment and the software system.

However, most of the data center metering and monitoring components at present do not have the function of automatic dust removal, and in the actual use process, because of the electrostatic adsorption effect of electric component equipment such as an energy consumption monitoring controller, an electric quantity metering device, a control coding module, a communication module, a temperature and humidity transmitter and the like on dust in the environment, the dust accumulation condition of the data center metering and monitoring components after a period of use can be caused, and the dust accumulation causes the electric component in the data center metering and monitoring components to have the damage condition such as electrostatic breakdown and the like, so that the use safety and the stability of the data center metering and monitoring components are poor.

Disclosure of Invention

The utility model aims to provide a data center metering and monitoring assembly which can solve the problem that the existing data center metering and monitoring assembly does not have an automatic dust removal function.

To achieve the above object, the present utility model provides a data center metering monitoring assembly, comprising: the dust collection and guide device comprises an energy consumption monitoring cabinet, a dust collection and guide mechanism and a split dust removal mechanism;

the dust collection flow guide mechanism is arranged on one side of the energy consumption monitoring cabinet and comprises a collection flow guide box, a drainage tube is connected in the collection flow guide box and is communicated with the energy consumption monitoring cabinet, and a negative pressure fan is connected in the drainage tube;

the split type dust removing mechanism is arranged in the energy consumption monitoring cabinet and comprises a pair of dust removing filter bags, two ends of each dust removing filter bag are fixedly connected with fixing blocks, and a dust removing communicating pipe is connected between each fixing block and the drainage tube.

In one or more embodiments, one end of the drainage tube in the energy consumption monitoring cabinet is connected with a flow expansion tube, so that the flow expansion tube can conveniently conduct flow and transport to the gas in the energy consumption monitoring cabinet.

In one or more embodiments, a diverter cone is connected to one side of the drainage tube away from the diffuser tube, and the diverter cone is used for diverting and conveying air flow generated in the operation process of the negative pressure fan.

In one or more embodiments, the outside of dust removal filter bag is equipped with spacing fixed frame, spacing fixed frame is connected with the lateral wall of energy consumption monitoring rack, plays the spacing effect of support through spacing fixed frame to the fixed block, set up in the dust removal filter bag with fixed block assorted remove spout, be convenient for carry out the block spacing to the fixed block through the mutually supporting of remove spout and fixed block to be convenient for carry out dismouting change to the dust removal filter bag.

In one or more embodiments, the both sides of dust removal filter bag are equipped with a plurality of evenly distributed spacing member bars, a plurality of spacing member bars all with spacing fixed frame fixed connection, be convenient for play the spacing effect of separation to the dust removal filter bag through a plurality of spacing member bars, reduced the circumstances that appears dust removal filter bag receives the air current effect and the electrical components contact in the energy consumption monitoring rack.

In one or more embodiments, the fixed block is internally provided with a via hole, and the via hole is communicated with the dust collection communicating pipe, so that the via hole is convenient for conducting the dust collection filter bag and the dust collection communicating pipe, and gas in the drainage tube is convenient for being conveyed into the dust collection filter bag under the action of the dust collection communicating pipe and the via hole.

Compared with the prior art, the automatic dust removal device has the advantages that through the arrangement of the corresponding mechanism, the data center metering and monitoring assembly has an automatic dust removal function, dust accumulation of the data center metering and monitoring assembly in the using process is reduced, and the using safety and stability of the data center metering and monitoring assembly are improved.

Drawings

Fig. 1 is a front cross-sectional view according to an embodiment of the present utility model.

Fig. 2 is a schematic diagram of the structure at a in fig. 1.

Fig. 3 is a schematic diagram of the structure at B in fig. 1.

Fig. 4 is a perspective view of an embodiment according to the present utility model.

The main reference numerals illustrate:

the device comprises a 1-energy consumption monitoring cabinet, a 2-dust collecting and guiding mechanism, a 201-collecting and guiding box, a 202-drainage tube, a 203-negative pressure fan, a 204-flow expansion tube, a 205-flow dividing cone, a 3-split dust removing mechanism, a 301-dust removing filter bag, a 302-fixed block, a 303-dust removing communicating pipe, a 304-limit fixed frame, a 305-limit rod piece and a 306-through hole.

Detailed Description

The following detailed description of embodiments of the utility model is, therefore, to be taken in conjunction with the accompanying drawings, and it is to be understood that the scope of the utility model is not limited to the specific embodiments.

Throughout the specification and claims, unless explicitly stated otherwise, the term "comprise" or variations thereof such as "comprises" or "comprising", etc. will be understood to include the stated element or component without excluding other elements or components.

As shown in fig. 1 to 4, according to an embodiment of the present utility model, the dust collection and guide device comprises an energy consumption monitoring cabinet 1, a dust collection and guide mechanism 2 and a split dust removal mechanism 3.

As shown in fig. 1 to 2, the dust collecting and guiding mechanism 2 is arranged on one side of the energy consumption monitoring cabinet 1, so that dust in the energy consumption monitoring cabinet 1 is conveniently gathered and conveyed through the dust collecting and guiding mechanism 2, and convenience is provided for subsequent dust removal.

As shown in fig. 1 to 2, the dust collection diversion mechanism 2 includes a collection diversion box 201. The drainage tube 202 and the dedusting communicating tube 303 are limited and protected through the collecting guide box 201.

As shown in fig. 1 to 2, a drainage tube 202 is connected in the collection and diversion box 201, and the drainage tube 202 is communicated with the energy consumption monitoring cabinet 1, so that the dust-containing gas in the energy consumption monitoring cabinet 1 can be conveniently conducted and conveyed through the drainage tube 202.

As shown in fig. 1 to 2, a negative pressure fan 203 is connected to the draft tube 202. The operation of the negative pressure fan 203 is controlled so that dust in the energy consumption monitoring cabinet 1 is conveyed into the drainage tube 202 along with gas by the flow expansion tube 204.

As shown in fig. 1 to 2, one end of the drainage tube 202 located in the energy consumption monitoring cabinet 1 is connected with a flow expansion tube 204, so that the flow expansion tube 204 can conveniently conduct and convey the gas in the energy consumption monitoring cabinet 1.

As shown in fig. 1 to 2, a diverter cone 205 is connected to one side of the drainage tube 202 away from the diffuser tube 204, and the diverter cone 205 is used for diverting and conveying the airflow generated in the operation process of the negative pressure fan 203.

As shown in fig. 1 to 3, the split type dust removing mechanism 3 is disposed in the energy consumption monitoring cabinet 1, so that dust filtering treatment is performed on dust-containing gas through the split type dust removing mechanism 3, and the energy consumption monitoring cabinet 1 is convenient to remove dust.

As shown in fig. 1 to 3, the split dust removing mechanism 3 includes a pair of dust removing filter bags 301, and the dust-containing gas is filtered through the pair of dust removing filter bags 301. Meanwhile, the filtered gas is conveniently discharged from the dedusting filter bag 301, so that not only can the electrical components in the energy consumption monitoring cabinet 1 be cooled, but also dust attached to the electrical components in the energy consumption monitoring cabinet 1 can be cleaned.

As shown in fig. 1 to 3, both ends of a pair of dust-removing filter bags 301 are fixedly connected with fixing blocks 302, the dust-removing filter bags 301 are fixed and limited by the fixing blocks 302, and meanwhile, the dust-removing filter bags 301 are conveniently detached and fixed in a mode of fixing and limiting the fixing blocks 302.

As shown in fig. 1 to 3, a dust-removing communicating pipe 303 is connected between the fixing block 302 and the drainage tube 202, and the dust-removing communicating pipe 303 plays a role in communicating the through hole 306 with the drainage tube 202. The dust-containing gas in the drainage tube 202 is conveniently conveyed into the dust-removing filter bag 301 under the action of the dust-removing communicating tube 303 and the through hole 306.

As shown in fig. 1 to 3, a limiting fixing frame 304 is arranged on the outer side of the dedusting filter bag 301, and the limiting fixing frame 304 is connected with the side wall of the energy consumption monitoring cabinet 1. The limiting fixing frame 304 plays a role in supporting and limiting the fixing block 302.

Wherein, the dust removing filter bag 301 is internally provided with a movable chute matched with the fixed block 302, so that the fixed block 302 is conveniently clamped and limited by the mutual matching of the movable chute and the fixed block 302. Thereby facilitating the disassembly, assembly and replacement of the dust removing filter bag 301.

As shown in fig. 1 to 3, a plurality of uniformly distributed limit bars 305 are disposed on two sides of the dust removing filter bag 301, and the plurality of limit bars 305 are fixedly connected with the limit fixing frame 304. The plurality of limit rods 305 are convenient to separate and limit the dust removing filter bags 301, and the condition that the dust removing filter bags 301 are contacted with electrical elements in the energy consumption monitoring cabinet 1 under the action of air flow is reduced.

In addition, a via hole 306 is formed in the fixed block 302, and the via hole 306 is communicated with the dust collection communicating pipe 303. The through holes 306 are convenient to conduct the dust collection filter bag 301 and the dust collection communicating pipe 303, so that the gas in the drainage tube 202 is convenient to be conveyed into the dust collection filter bag 301 under the action of the dust collection communicating pipe 303 and the through holes 306.

When the device is specifically used, the operation of the negative pressure fan 203 is controlled to extract the gas in the energy consumption monitoring cabinet 1, so that dust attached to the surfaces of electrical components in the energy consumption monitoring cabinet 1 enters the drainage tube 202 along with the operation of the negative pressure fan 203 under the action of air flow. The dust-containing gas is conveyed into the dust-removing filter bag 301 through the fixed block 302 and the through hole 306 under the split flow action of the split flow cone 205, and the dust-containing gas is filtered through the dust-removing filter bag 301, and meanwhile, the dust-filtered gas is discharged from the dust-removing filter bag 301, so that the auxiliary collection of dust attached to electrical components in the energy consumption monitoring cabinet 1 can be realized, and the cooling treatment of the electrical components in the energy consumption monitoring cabinet 1 can be realized.

In addition, in the use, the dust removing filter bag 301 can be replaced in a movable and detachable mode through the fixing block 302, so that the dust removing filter bag has strong use convenience.

The foregoing descriptions of specific exemplary embodiments of the present utility model are presented for purposes of illustration and description. It is not intended to limit the utility model to the precise form disclosed, and obviously many modifications and variations are possible in light of the above teaching. The exemplary embodiments were chosen and described in order to explain the specific principles of the utility model and its practical application to thereby enable one skilled in the art to make and utilize the utility model in various exemplary embodiments and with various modifications as are suited to the particular use contemplated. It is intended that the scope of the utility model be defined by the claims and their equivalents.

Claims (8)

1. A data center metering monitoring assembly, comprising:

an energy consumption monitoring cabinet;

the dust collection and flow guide mechanism is arranged on one side of the energy consumption monitoring cabinet and comprises a collection flow guide box, a drainage tube is connected in the collection flow guide box, the drainage tube is communicated with the energy consumption monitoring cabinet, and a negative pressure fan is connected in the drainage tube;

the split type dust removing mechanism is arranged in the energy consumption monitoring cabinet and comprises a pair of dust removing filter bags, two ends of each dust removing filter bag are fixedly connected with fixing blocks, and a dust removing communicating pipe is connected between each fixing block and the drainage tube.

2. The data center metering monitoring assembly of claim 1 wherein a diffuser tube is connected to an end of the draft tube located within the energy consumption monitoring cabinet.

3. The data center metering monitoring assembly of claim 2 wherein a shunt cone is connected to a side of the draft tube remote from the draft tube.

4. The data center metering and monitoring assembly of claim 1, wherein a limiting fixed frame is arranged on the outer side of the dedusting filter bag and is connected with the side wall of the energy consumption monitoring cabinet.

5. The data center metering and monitoring assembly of claim 4, wherein the dust collection filter bag is internally provided with a movable chute matched with the fixed block.

6. The data center metering monitoring assembly of claim 5, wherein a plurality of evenly distributed spacing bars are provided on both sides of the dust collection filter bag.

7. The data center metering monitoring assembly of claim 6 wherein a plurality of the limit bars are fixedly connected to a limit fixed frame.

8. The data center metering and monitoring assembly of claim 1, wherein the fixed block is internally provided with a via, and the via is communicated with a dust collection communicating pipe.