CN111757651A - Elastic distribution system for power load of data center - Google Patents

Abstract

The invention discloses a data center power load elastic distribution system which comprises a controller, a first cross beam and a second cross beam, wherein two ends of the first cross beam are respectively connected with an upright post, two ends of the second cross beam are respectively connected with an upright post, slide rails are respectively connected between the two upright posts of the first cross beam and between the two upright posts of the second cross beam, a first movable beam is connected between the two slide rails, two ends of the first movable beam are respectively connected with a first moving unit which is matched with the slide rails and can slide at the slide rails, and two cooling units are also arranged at the first movable beam; a plurality of bus ducts are fixed between the first cross beam and the second cross beam, one end of each bus duct is provided with a first sliding block connected with the first cross beam, and the other end of each bus duct is provided with a second sliding block connected with the second cross beam. The distribution system can realize flexible distribution and has stronger adaptability to the arrangement of the data center cabinets.

Description

Elastic distribution system for power load of data center

Technical Field

The invention relates to the field of data centers, in particular to a data center power load elastic distribution system.

Background

A data center is a globally collaborative network of devices that is used to communicate, accelerate, present, compute, store data information over an internet network infrastructure. The generation of data centers has led to the introduction of people's awareness from the quantitative, structured world to the uncertain and unstructured world, which, like traffic and network communications, will gradually become part of the infrastructure of modern society, thus positively affecting many industries. In data center's power transmission, mainly use the bus duct to carry out power transmission, it has many advantages compared with the cable, but current data center, the mounted position of bus duct is fixed, and the adjustment of the installation of the rack in the data center faces, and the difference of the specification of different data center racks, make fixed bus duct can not carry out the elastic distribution of electric power, thereby it is inconvenient to use, and current bus duct is collocation jack box use usually, generate heat easily in the plug position, and the bus duct also generates heat easily on the whole, when local region suddenly generates heat appears, current data center can not carry out the pertinence heat dissipation to it.

Disclosure of Invention

The purpose of the invention is as follows: the invention aims to overcome the defects of the prior art and provides a data center power load flexible distribution system.

The technical scheme is as follows: the utility model provides a data center electric power load elasticity distribution system, includes controller, first crossbeam and second crossbeam, the both ends of first crossbeam are connected with a stand respectively, and the both ends of second crossbeam are connected with a stand respectively, all are connected with the slide rail between two stands of first crossbeam and between two stands of second crossbeam, are connected with first walking beam between two slide rails, the both ends of first walking beam be connected with one respectively with the slide rail cooperation can be in the gliding first mobile unit of slide rail department, first walking beam department still has two cooling units, cooling unit includes can be in the gliding second mobile unit of first walking beam department, the fly leaf of being connected with the expansion end of second mobile unit, through the link with the fly leaf of being connected of first cylinder, the fly leaf top has the stock solution container, the fly leaf below has first intubate, The first, second and third insertion tubes are respectively provided with a valve, the liquid storage container is connected with a connecting pipe, the first insertion tube and the third insertion tube are respectively connected with the connecting pipe, the second insertion tube is connected with the liquid storage container, the connecting pipe is provided with a liquid pump, the liquid pump is positioned between the liquid storage container and the first insertion tube, and a corrugated pipe is connected between the liquid storage containers of the two cooling units; a plurality of bus ducts are fixed between the first cross beam and the second cross beam, one end of each bus duct is provided with a first sliding block connected with the first cross beam, the other end of each bus duct is provided with a second sliding block connected with the second cross beam, the first sliding block locks the relative position of the first sliding block and the first cross beam through a first locking bolt, the second sliding block locks the relative position of the second sliding block and the second cross beam through a second locking bolt, each bus duct comprises a bottom plate, a cover plate and two side plates connected with the bottom plate and the cover plate, the bottom plate is provided with a bottom insulating gasket, the cover plate is provided with a top insulating gasket, a plurality of conductors are installed between the bottom insulating gasket and the top insulating gasket, each bus duct is provided with a plurality of plugging positions for installing a plugging box, each plugging position is provided with a plurality of temperature sensors, and each plugging position is at least provided with one temperature sensor, the two ends of the bus duct are respectively provided with a first pipe orifice, each splicing position is provided with two second pipe orifices, a first cooling channel is arranged in the cover plate, the two ends of the first cooling channel are respectively communicated with the first pipe orifices, each splicing position is provided with a second cooling channel positioned in the cover plate, and the two ends of the second cooling channel are respectively communicated with one second pipe orifice of the splicing position corresponding to the second cooling channel.

Further, the number of bus ducts connected between the first cross beam and the second cross beam is more than or equal to 5; each bus duct has more than 2 grafting position.

Therefore, the arrangement of the plurality of bus ducts and the plurality of plugging positions of each bus duct enables the whole system to supply power for more cabinets.

Further, the first pipe orifice and the second pipe orifice are both provided with step parts, and sealing gaskets are arranged at the step parts; the ends of the first, second and third cannulae each have a plug unit.

The plug is fitted to the stepped portion, thereby preventing leakage.

Furthermore, the cover plate is provided with 3 mutually parallel first cooling channels, the 3 first cooling channels are distributed in a parallel mode, and two ends of each first cooling channel are respectively communicated with one first pipe orifice; each inserting position is provided with 2 second cooling channels which are parallel to each other and distributed in a parallel mode, and two ends of each second cooling channel are respectively communicated with one second pipe orifice of the inserting position corresponding to the second cooling channel.

Thereby the second cooling channel of first cooling channel and same grafting position all has a plurality ofly to when the cooling, can cool off the bigger region of the apron of bus duct, the cooling effect is better.

Further, a plurality of accommodating grooves for accommodating the conductors are formed in the bottom insulating gasket and the top insulating gasket. Thereby achieving the fixation of the conductors parallel to each other with a gap between adjacent conductors.

Further, the side plate is provided with a side plate fin; the liquid storage container is provided with a plurality of liquid storage container radiating fins. Thereby be favorable to the heat dissipation of bus duct to and the heat dissipation of coolant liquid in stock solution container.

Furthermore, the first movable beam is also provided with a plurality of auxiliary sliding blocks, the auxiliary sliding blocks are connected with a limiting ring through vertical rods, the auxiliary sliding blocks are positioned between two second moving units, an elastic pull rope is connected between every two adjacent auxiliary sliding blocks, and an elastic pull rope is connected between each second moving unit and the auxiliary sliding block closest to the moving unit; the bellows passes through all the stop collars.

Thereby when two cooling unit are close to each other, perhaps when two cooling unit keep away from each other, the spacing ring can be spacing with the bellows to the bellows can not hang etc. under the excessive, the bellows of own just has certain elasticity of stretching out and drawing back, under the cooperation of a plurality of spacing rings, can provide bigger elasticity of stretching out and drawing back, thereby makes things convenient for two cooling unit's nimble removal.

Further, still be connected with the second walking beam between two slide rails, the both ends of second walking beam be connected with respectively one with the slide rail cooperation can be along the third mobile unit of slide rail removal, second walking beam department has the fourth mobile unit, and fourth mobile unit department installs the second cylinder, and the expansion end of second cylinder is installed and is removed the liquid unit, it includes air pump, air cock and heating unit to remove the liquid unit.

Further, the two first moving units have independent driving mechanisms, the two third moving units have independent driving mechanisms, the two second moving units have independent driving mechanisms, and the fourth moving unit has independent driving mechanisms.

Therefore, the first mobile unit, the second mobile unit, the third mobile unit and the fourth mobile unit are independently controlled, and certainly, in the actual operation process, the two first mobile units synchronously operate and the two third mobile units synchronously operate.

Further, the first, second, third and fourth moving units may be selected as a moving cart.

Further, each first pipe orifice and each second pipe orifice are provided with a valve.

Therefore, when the first nozzle and the second nozzle are not inserted with the cannula, the valve can be closed, and the liquid is prevented from influencing the humidity of the air.

Further, under the drive of the first and second moving units and the first cylinder, the first and second insertion tubes of the same cooling unit can be simultaneously and respectively inserted into the two second tube openings of the same plugging position, and under the drive of the first and second moving units and the first cylinder, the third insertion tubes of the two cooling units can be simultaneously and respectively inserted into the two first tube openings of the same bus duct.

Has the advantages that: according to the data center, the installation position of the bus duct can be adaptively adjusted and modified, so that corresponding adjustment can be realized when cabinets are added or the positions of the cabinets are adjusted, and the bus duct for standby use can be taken care of in the construction process of the data center to deal with the expansion of the data center at any time. And aiming at the condition of heat dissipation of the bus duct of the data center, heat dissipation can be performed on a single plugging position, heat dissipation can be performed on the whole bus duct, and heat dissipation is more flexible and efficient.

Drawings

FIG. 1 is a first angle schematic of a dispensing system;

FIG. 2 is a second perspective view of the dispensing system;

FIG. 3 is a third schematic view of a dispensing system;

fig. 4 is a fourth angle schematic of the dispensing system.

In the figure, for simplicity and convenience in illustration, only two plugging positions are drawn on each bus duct, actually, each bus duct can be provided with a plurality of plugging positions, and the specific number is set as required. In addition, in order to illustrate the internal structure of the bus duct, a cross section is illustrated at one of the plugging positions.

Detailed Description

Reference numerals: 1.1 a first beam; 1.2 a second beam; 1.3 upright posts; 1.4 a third mobile unit; 1.5 a second movable beam; 1.6 a fourth mobile unit; 1.7 a second cylinder; 1.8 air pump; 1.9 air tap; 1.10 slide rail; 2, a bus duct; 2.1 covering plate; 2.2, a bottom plate; 2.3 top insulating pad; 2.4 bottom insulating pad; 2.5 side plates; 2.6 a conductor; 2.7 first cooling channels; 2.8 second cooling channels; 2.10 first slide block; 3, inserting a jack box; 3.1, 3.2 second orifice; 3.3, 3.4 first orifice; 4.1 a first mobile unit; 4.2 a first walking beam; 5.1 a second mobile unit; 5.2 a first cylinder; 5.3 connecting the bracket; 5.4 moving plates; 5.5 a liquid storage container; 5.6 connecting pipes; 5.7 a first cannula; 5.8 a second cannula; 5.9 a third cannula; 6.1 auxiliary slide block; 6.2 vertical rods; 6.3 a limit ring; 7 a corrugated tube; 8 elastic pull rope.

The following detailed description is made with reference to the accompanying drawings: a data center electric power load elastic distribution system comprises a controller, a first beam 1.1 and a second beam 1.2, wherein two ends of the first beam 1.1 are respectively connected with a stand column 1.3, two ends of the second beam 1.2 are respectively connected with a stand column 1.3, slide rails 1.10 are respectively connected between the two stand columns 1.3 of the first beam 1.1 and between the two stand columns 1.3 of the second beam 1.2, a first movable beam 4.2 is connected between the two slide rails 1.10, two ends of the first movable beam 4.2 are respectively connected with a first movable unit 4.1 which is matched with the slide rails 1.10 and can slide at the slide rails 1.10, two cooling units are also arranged at the first movable beam 4.2, each cooling unit comprises a second movable unit 5.1 which can slide at the first beam 4.2, a first air cylinder 5.2 connected with the second movable unit 5.1, and a movable plate 4.2 connected with the movable end of the first air cylinder 5.2 through a connecting frame 5.3, a liquid storage container 5.5 is arranged above the movable plate 5.4, a first insertion pipe 5.7, a second insertion pipe 5.8 and a third insertion pipe 5.9 are arranged below the movable plate 5.4, valves are arranged at the first insertion pipe, the second insertion pipe and the third insertion pipe, the liquid storage container 5.5 is connected with a connecting pipe 5.6, the first insertion pipe 5.7 and the third insertion pipe 5.9 are connected with the connecting pipe 5.6, the second insertion pipe 5.8 is connected with the liquid storage container 5.5, a liquid pump is arranged at the connecting pipe 5.6 and located between the liquid storage container and the first insertion pipe 5.7, and a corrugated pipe 7 is connected between the liquid storage containers 5.5 of the two cooling units; a plurality of bus ducts 2 are fixed between a first cross beam 1.1 and a second cross beam 1.2, one end of each bus duct 2 is provided with a first sliding block 2.10 connected with the first cross beam, the other end of each bus duct is provided with a second sliding block connected with the second cross beam, the first sliding block locks the relative position of the first sliding block and the first cross beam through a first locking bolt, the second sliding block locks the relative position of the second sliding block and the second cross beam through a second locking bolt, each bus duct comprises a bottom plate 2.2, a cover plate 2.1 and two side plates 2.5 connecting the bottom plate 2.2 and the cover plate 2.1, the bottom plate 2.2 is provided with a bottom insulating gasket 2.4, the cover plate 2.1 is provided with a top insulating gasket 2.3, a plurality of conductors 2.6 are arranged between the bottom insulating gasket 2.4 and the top insulating gasket 2.3, each bus duct 2 is provided with a plurality of plugging positions for installing plugging boxes, a plurality of temperature sensors are arranged at each plugging position, at least one temperature sensor is arranged at each plugging position, two ends of the bus duct are respectively provided with a first pipe orifice 3.3 and a first pipe orifice 3.4, each splicing position is provided with two second pipe orifices 3.1 and 3.2, the cover plate is internally provided with a first cooling channel 2.7, two ends of the first cooling channel 2.7 are respectively communicated with the first pipe orifices 3.3 and 3.4, each splicing position is provided with a second cooling channel 2.8 positioned in the cover plate, and two ends of the second cooling channel 2.8 are respectively communicated with one second pipe orifice 3.1 and 3.2 of the splicing position corresponding to the second cooling channel 2.8.

The number of bus ducts 2 connected between the first cross beam 1.1 and the second cross beam 1.2 is more than or equal to 5; each bus duct 2 has more than 2 plug positions. The first pipe orifices 3.3 and 3.4 and the second pipe orifices 3.1 and 3.2 are provided with step parts, and the step parts are provided with sealing gaskets; the ends of the first cannula 5.7, the second cannula 5.8 and the third cannula 5.9 each have a plug unit. The cover plate is provided with 3 mutually parallel first cooling channels 2.7, the 3 first cooling channels 2.7 are distributed in a parallel mode, and two ends of each first cooling channel 2.7 are respectively communicated with one first pipe orifice 3.3 and one first pipe orifice 3.4; each plug-in position is provided with 2 second cooling channels 2.8 which are parallel to each other and distributed in a parallel mode, and two ends of each second cooling channel 2.8 are respectively communicated with one second pipe orifice 3.1 and one second pipe orifice 3.2 of the plug-in position corresponding to the second cooling channel. The bottom insulating spacer 2.4 and the top insulating spacer 2.3 each have a plurality of receiving grooves for receiving the conductors 2.6. The side plate 2.5 is provided with a side plate fin; the liquid storage container 5.5 is provided with a plurality of liquid storage container radiating fins. The first movable beam 1.1 is also provided with a plurality of auxiliary sliding blocks 6.1, the auxiliary sliding blocks 6.1 are connected with a limiting ring 6.3 through vertical rods 6.2, the plurality of auxiliary sliding blocks 6.1 are positioned between two second moving units 5.1, an elastic pull rope 8 is connected between every two adjacent auxiliary sliding blocks 6.1, and an elastic pull rope 8 is connected between each second moving unit 5.1 and the auxiliary sliding block 6.1 closest to the moving unit; the bellows passes through all the stop collars 6.3. Still be connected with second walking beam 1.5 between two slide rails 1.10, the both ends of second walking beam 1.5 be connected with one respectively with slide rail 1.10 cooperation can be along the third mobile unit 1.4 of slide rail removal, and second walking beam 1.5 department has fourth mobile unit 1.6, and fourth mobile unit 1.6 department installs second cylinder 1.7, and the expansion end of second cylinder 1.7 is installed and is removed the liquid unit, it includes air pump 1.8, air cock 1.9 and heating unit to remove the liquid unit. The two first movement units 4.1 have independent drive mechanisms, the two third movement units 1.4 have independent drive mechanisms, and the second movement unit 5.1 and the fourth movement unit 1.6 each have independent drive mechanisms. Valves are mounted at each first orifice 3.3, 3.4 and at each second orifice 3.1, 3.2.

The power load distribution system is as shown in the figure, the installation positions of a plurality of bus ducts can be adjusted (the ends of the bus ducts can be connected with power supply equipment through electric connection parts), unused bus ducts can be reserved, the adjustment of cabinet installation can be met at any time, the position of a cabinet can be adjusted, and the first locking bolt and the second locking bolt can be locked after the adjustment is finished, so that the fixation of the bus duct position can be met.

In addition, in the use process, along with the difference of equipment operation conditions in the cabinet, the bus duct can generate heat, can possibly generate heat of the whole bus duct, and also can generate heat of a certain plugging position, all valves, temperature sensors, cooling units, liquid removing units and the like are controlled by a controller, and whether the whole bus duct generates heat or the certain plugging position generates heat can be judged through a plurality of temperature sensors installed at the bus. Under the drive of the second mobile unit and the first cylinder, the first insertion tube and the second insertion tube of the same cooling unit can be simultaneously and respectively inserted into the two second tube orifices of the same insertion position, and under the drive of the second mobile unit and the first cylinder, the third insertion tubes of the two cooling units can be simultaneously and respectively inserted into the two first tube orifices of the same bus duct.

When it is determined that a certain plugging position generates heat, the first cannula and the second cannula of one cooling unit are respectively inserted into the two second ports of the plugging position under the driving of the second moving unit and the first cylinder, the valves of the first cannula and the second cannula of the cooling unit are opened, the valve of the third cannula is closed, and the liquid pump is started, so that the circulation of the cooling liquid is realized, and the cooling position is cooled.

When judging for it is that whole bus duct generates heat, can make two cooling unit's third intubate insert respectively in a first mouth of pipe of this bus duct, and two cooling unit's the first this moment, the valve of two intubate departments is closed, the valve of third intubate department is opened, thereby start two liquid pumps, the coolant liquid circulates in first cooling channel, thereby realize the heat dissipation to whole bus duct, when the heat dissipation to whole bus duct, the flow of coolant liquid in the bellows, because the bellows is very long, can further natural cooling to the coolant liquid. The first pipe orifice and the second pipe orifice at the bus duct are opened only when a plug is inserted, and are closed in other time.

In addition, when the cannula and the pipe orifice are pulled out and separated, cooling liquid (the residual quantity is less) possibly remains at the first pipe orifice and the second pipe orifice, and hot air can be slowly blown by the air nozzle of the liquid removing unit for drying, so that liquid is removed, and adverse effects caused by the residual cooling liquid are avoided. In addition, only one first movable beam is arranged, and a plurality of first movable beams can be arranged according to needs (for example, the number of the bus ducts is large), so that the splicing positions on different bus ducts can be cooled simultaneously.

While the invention has been shown and described with respect to the preferred embodiments, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the scope of the invention as defined in the following claims.

Claims (10)

1. The utility model provides a data center electric power load elasticity distribution system, its characterized in that, includes controller, first crossbeam and second crossbeam, the both ends of first crossbeam are connected with a stand respectively, and the both ends of second crossbeam are connected with a stand respectively, all are connected with the slide rail between two stands of first crossbeam and between two stands of second crossbeam, are connected with first walking beam between two slide rails, the both ends of first walking beam be connected with respectively one with the slide rail cooperation can be in the gliding first mobile unit of slide rail department, first walking beam department still has two cooling units, cooling unit includes can be in gliding second mobile unit of first walking beam department, the first cylinder of being connected with second mobile unit, the fly leaf of being connected with the expansion end of first cylinder through the link, the fly leaf top has the stock solution container, the fly leaf below has first intubate, The first, second and third insertion tubes are respectively provided with a valve, the liquid storage container is connected with a connecting pipe, the first insertion tube and the third insertion tube are respectively connected with the connecting pipe, the second insertion tube is connected with the liquid storage container, the connecting pipe is provided with a liquid pump, the liquid pump is positioned between the liquid storage container and the first insertion tube, and a corrugated pipe is connected between the liquid storage containers of the two cooling units; a plurality of bus ducts are fixed between the first cross beam and the second cross beam, one end of each bus duct is provided with a first sliding block connected with the first cross beam, the other end of each bus duct is provided with a second sliding block connected with the second cross beam, the first sliding block locks the relative position of the first sliding block and the first cross beam through a first locking bolt, the second sliding block locks the relative position of the second sliding block and the second cross beam through a second locking bolt, each bus duct comprises a bottom plate, a cover plate and two side plates connected with the bottom plate and the cover plate, the bottom plate is provided with a bottom insulating gasket, the cover plate is provided with a top insulating gasket, a plurality of conductors are installed between the bottom insulating gasket and the top insulating gasket, each bus duct is provided with a plurality of plugging positions for installing a plugging box, each plugging position is provided with a plurality of temperature sensors, and each plugging position is at least provided with one temperature sensor, the two ends of the bus duct are respectively provided with a first pipe orifice, each splicing position is provided with two second pipe orifices, a first cooling channel is arranged in the cover plate, the two ends of the first cooling channel are respectively communicated with the first pipe orifices, each splicing position is provided with a second cooling channel positioned in the cover plate, and the two ends of the second cooling channel are respectively communicated with one second pipe orifice of the splicing position corresponding to the second cooling channel.

2. The data center electrical load elastic distribution system of claim 1, wherein the number of bus ducts connected between the first beam and the second beam is greater than or equal to 5; each bus duct has more than 2 grafting position.

3. The data center electrical load elastic distribution system of claim 1, wherein said first and second nozzles each have a step, said step having a gasket thereon; the ends of the first, second and third cannulae each have a plug unit.

4. The data center electrical load elastic distribution system of claim 1, wherein the cover plate has 3 first cooling channels parallel to each other, the 3 first cooling channels are distributed in parallel, and two ends of each first cooling channel are respectively communicated with one first nozzle; each inserting position is provided with 2 second cooling channels which are parallel to each other and distributed in a parallel mode, and two ends of each second cooling channel are respectively communicated with one second pipe orifice of the inserting position corresponding to the second cooling channel.

5. The data center electrical load elastic distribution system of claim 1, wherein said bottom insulating spacer and said top insulating spacer each have a plurality of receiving grooves for receiving said conductors.

6. The data center electrical load elastic distribution system of claim 1, wherein said side panels have side panel fins at said side panels; the liquid storage container is provided with a plurality of liquid storage container radiating fins.

7. The elastic data center power load distribution system according to claim 1, wherein the first movable beam further comprises a plurality of auxiliary sliding blocks, the auxiliary sliding blocks are connected with limiting rings through vertical rods, the plurality of auxiliary sliding blocks are located between two second movable units, an elastic pull rope is connected between every two adjacent auxiliary sliding blocks, and an elastic pull rope is connected between each second movable unit and the auxiliary sliding block closest to the movable unit; the bellows passes through all the stop collars.

8. The elastic distribution system for the electric load of the data center according to claim 1, wherein a second movable beam is further connected between the two slide rails, a third moving unit is connected to each of two ends of the second movable beam and is capable of moving along the slide rails in cooperation with the slide rails, a fourth moving unit is provided at the second movable beam, a second air cylinder is installed at the fourth moving unit, a liquid removing unit is installed at a movable end of the second air cylinder, and the liquid removing unit comprises an air pump, an air faucet and a heating unit.

9. The data center electrical load elastic distribution system of claim 1, wherein two first mobile units have independent drive mechanisms, two third mobile units have independent drive mechanisms, two second mobile units have independent drive mechanisms, and a fourth mobile unit has independent drive mechanisms.

10. The data center electrical load elastic distribution system of claim 1, wherein a valve is installed at each first pipe orifice and each second pipe orifice.

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