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CN109815211B - Data center wiring method, device and storage medium - Google Patents

Data center wiring method, device and storage medium Download PDF

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Publication number
CN109815211B
CN109815211B CN201811489124.5A CN201811489124A CN109815211B CN 109815211 B CN109815211 B CN 109815211B CN 201811489124 A CN201811489124 A CN 201811489124A CN 109815211 B CN109815211 B CN 109815211B
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cabinets
cabinet
wiring
wired
transverse
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CN109815211A (en
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邢晓坤
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Ping An Technology Shenzhen Co Ltd
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Ping An Technology Shenzhen Co Ltd
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    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02DCLIMATE CHANGE MITIGATION TECHNOLOGIES IN INFORMATION AND COMMUNICATION TECHNOLOGIES [ICT], I.E. INFORMATION AND COMMUNICATION TECHNOLOGIES AIMING AT THE REDUCTION OF THEIR OWN ENERGY USE
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Abstract

The invention belongs to the technical field of machine room management, and discloses a data center wiring method, which comprises the following steps: acquiring information of a cabinet to be wired in a machine room; constructing a wiring model, including a first wiring model and a second wiring model; selecting a wiring model according to a wiring position, wherein the first wiring model is selected when the wiring position is at the back of the cabinet, and the second wiring model is selected when the wiring position is at the front of the cabinet; determining a routing path between two cabinets to be routed according to the cabinet information to be routed; and determining the cable length between the two cabinets to be wired according to the cabinet information to be wired, the routing path and the selected routing model. According to the invention, the wiring length is accurately obtained through the constructed wiring model, the working efficiency is improved, the cable resources are reasonably utilized, the resource waste is reduced, the cost is saved, the risk brought by repeated work can be reduced, and the overall attractiveness of the machine room wiring is enhanced. The invention also discloses an electronic device and a storage medium.

Description

Data center wiring method, device and storage medium
Technical Field
The present invention relates to the field of machine room management technologies, and in particular, to a data center wiring method, a device, and a storage medium.
Background
Data centers are globally coordinated specific equipment networks used to transfer, accelerate, display, calculate, and store data information over an internet infrastructure, where the data center architecture requires connection to the data center equipment through multiple sets of cables. To meet the high requirements of the data center, wiring in the machine room generally uses finished jumpers. Although the length of the finished jumper wire has a plurality of specifications, if the cable length cannot be reasonably utilized, the following defects can occur: in daily work, the required cable length is difficult to accurately judge, and cable resources cannot be reasonably utilized; the cables are too short in the wiring process, short wires are required to be removed and re-wired, and a great amount of labor cost is wasted while the risk of repetitive work is borne; from the consumable resource aspect: the cable is too long in the wiring process, so that economic cost is wasted; from the aspect of machine room operation and maintenance: too long cables can cause a large number of cables to be piled up at the top of the cabinet or in the bridge, so that the life cycle of the wire slot of the data center is shortened, the heat dissipation of the cabinet is affected, and the integral aesthetic degree of the machine room is damaged; in terms of time cost: longer cables require longer time to finish and longer cables are more difficult to finish and aesthetically pleasing, the time spent in this process increases geometrically.
Disclosure of Invention
The invention provides a data center wiring method, a data center wiring device and a storage medium, which are used for accurately obtaining the length of a cable to be laid, improving the working efficiency, reducing the resource waste and saving the cost.
In order to achieve the above object, an aspect of the present invention provides a data center wiring method including:
constructing a cabinet information database, and acquiring cabinet information to be wired in a machine room from the cabinet information database;
constructing a wiring model, wherein the wiring model comprises a first wiring model and a second wiring model, and the first wiring model and the second wiring model are respectively shown in the following formula:
L 1 =n×h+m 1 ×D 1 +b+I 1 ×D 2 +I 2 ×D 3 +m 2 ×H+c
L 2 =n×h+H+m 1 ×D 1 +b+I 1 ×D 2 +I 2 ×D 3 +m 2 ×H+c
wherein L is 1 Representing the first cable length, L 2 Represents the length of the second cable, n represents the number of U bits in the cabinet, h represents the height of U bits in the cabinet, and m 1 Representing the number of longitudinal cabinets between the cabinet to be wired and the transverse trunking, D 1 Representing the width of the cabinet, b representing the distance from the cabinet to the longitudinal trunking, I 1 Representing the number of transverse cold channels between two cabinets to be wired, D 2 Indicating the width of the transverse cold aisle, I 2 Representing the number of transverse thermal channels between two cabinets to be wired, D 3 Represents the width of the transverse heat channel, m 2 Represents the number of transverse cabinets between two cabinets to be wired, and H represents the cabinetC represents the cable redundancy length;
selecting a wiring model according to a wiring position, wherein the first wiring model is selected when the wiring position is at the back of the cabinet, and the second wiring model is selected when the wiring position is at the front of the cabinet;
determining a routing path between two cabinets to be routed according to the cabinet information to be routed;
and determining the cable length between the two cabinets to be wired according to the cabinet information to be wired, the routing path and the selected routing model.
Preferably, a column of longitudinal wire slots is arranged at the top of each column of cabinets, a plurality of transverse wire slots are arranged between two adjacent columns of cabinets, and each transverse wire slot transversely penetrates through all the longitudinal wire slots.
Preferably, the determining a routing path between two cabinets to be wired according to the cabinet information to be wired includes: judging whether the two cabinets to be wired are positioned in the same column, if the two cabinets to be wired are positioned in different columns, selecting a transverse wire slot between the columns in which the two cabinets to be wired are positioned, and determining a wiring path according to the position of the selected transverse wire slot.
Preferably, the step of selecting a transverse wire chase comprises: determining the number of longitudinal cabinets between the cabinet to be wired and the selected transverse trunking according to the following:
Figure BDA0001895264560000021
wherein L represents the cable length between two cabinets to be wired, m 1 The number of longitudinal cabinets between the cabinets to be wired and the transverse trunking is represented.
Preferably, the data center wiring method further includes: the cables between the different cabinets to be wired use outer skins with different colors, and cable labels are arranged at two ends of the wired cables.
Preferably, the data center wiring method further includes: the outer surface of the cable is provided with a length mark, and the color of the length mark is different from that of the outer surface of the cable.
In order to achieve the above object, another aspect of the present invention provides an electronic device including:
a processor;
the memory comprises a data center wiring program, and the data center wiring program realizes the following steps when being executed by the processor:
constructing a cabinet information database, and acquiring cabinet information to be wired in a machine room from the cabinet information database;
constructing a wiring model, wherein the wiring model comprises a first wiring model and a second wiring model, and the first wiring model and the second wiring model are respectively shown in the following formula:
L 1 =n×h+m 1 ×D 1 +b+I 1 ×D 2 +I 2 ×D 3 +m 2 ×H+c
L 2 =n×h+H+m 1 ×D 1 +b+I 1 ×D 2 +I 2 ×D 3 +m 2 ×H+c
wherein L is 1 Representing the first cable length, L 2 Represents the length of the second cable, n represents the number of U bits in the cabinet, h represents the height of U bits in the cabinet, and m 1 Representing the number of longitudinal cabinets between the cabinet to be wired and the transverse trunking, D 1 Representing the width of the cabinet, b representing the distance from the cabinet to the longitudinal trunking, I 1 Representing the number of transverse cold channels between two cabinets to be wired, D 2 Indicating the width of the transverse cold aisle, I 2 Representing the number of transverse thermal channels between two cabinets to be wired, D 3 Represents the width of the transverse heat channel, m 2 The number of the transverse cabinets between two cabinets to be wired is represented, H represents the longitudinal depth of the cabinets, and c represents the redundant length of the cables;
selecting a wiring model according to a wiring position, wherein the first wiring model is selected when the wiring position is at the back of the cabinet, and the second wiring model is selected when the wiring position is at the front of the cabinet;
determining a routing path between two cabinets to be routed according to the cabinet information to be routed;
and determining the cable length between the two cabinets to be wired according to the cabinet information to be wired, the routing path and the selected routing model.
Preferably, the data center wiring program when executed by the processor further implements the steps of: judging whether the two cabinets to be wired are positioned in the same column, if the two cabinets to be wired are positioned in different columns, selecting a transverse wire slot between the columns in which the two cabinets to be wired are positioned, and determining a wiring path according to the position of the selected transverse wire slot.
Preferably, the electronic device further comprises a positioning device, wherein the positioning device is used for positioning the position of the cabinet to be wired.
In order to achieve the above object, still another aspect of the present invention is to provide a computer-readable storage medium including therein a data center wiring program which, when executed by a processor, implements the steps of the data center wiring method as described above.
Compared with the prior art, the invention has the following advantages and beneficial effects:
according to the invention, the cable length determined between two cabinets to be wired is output through the built wiring model, so that the wiring length is accurately obtained, the working efficiency is improved, the cable resources are reasonably utilized, the resource waste is reduced, the cost is saved, the life cycle of the transverse wire slot and the longitudinal wire slot arranged at the top of the data center cabinet is prolonged, and the cable length is accurately judged without removing short wires or rewiring, so that the risk brought by repeated work is reduced, and the overall aesthetic property of the machine room wiring is enhanced.
Drawings
FIG. 1 is a schematic flow chart of a data center wiring method according to the present invention;
FIG. 2 is a schematic diagram of a data center wiring structure in the present invention;
fig. 3 is a schematic block diagram of a data center wiring program according to the present invention.
The achievement of the objects, functional features and advantages of the present invention will be further described with reference to the accompanying drawings, in conjunction with the embodiments.
Detailed Description
Embodiments of the present invention will be described below with reference to the accompanying drawings. Those skilled in the art will recognize that the described embodiments may be modified in various different ways, or combinations thereof, without departing from the spirit and scope of the invention. Accordingly, the drawings and description are to be regarded as illustrative in nature, and not as restrictive. Furthermore, in the present specification, the drawings are not drawn to scale, and like reference numerals denote like parts.
Fig. 1 is a schematic flow chart of a data center wiring method according to the present invention, and as shown in fig. 1, the data center wiring method according to the present invention includes the following steps:
s1, constructing a cabinet information database;
s2, acquiring cabinet information to be wired in a machine room from the cabinet information database;
step S3, constructing a wiring model, wherein the wiring model comprises a first wiring model and a second wiring model, and the first wiring model and the second wiring model are respectively shown in the following formula:
L 1 =n×h+m 1 ×D 1 +b+I 1 ×D 2 +I 2 ×D 3 +m 2 ×H+c
L 2 =n×h+H+m 1 ×D 1 +b+I 1 ×D 2 +I 2 ×D 3 +m 2 ×H+c
wherein L is 1 Representing the first cable length, L 2 Represents the length of the second cable, n represents the number of U bits in the cabinet, h represents the height of U bits in the cabinet, and m 1 Representing the number of longitudinal cabinets between the cabinet to be wired and the transverse trunking, D 1 Representing the width of the cabinet, b representing the distance from the cabinet to the longitudinal trunking, I 1 Representing the number of transverse cold channels between two cabinets to be wired, D 2 Indicating the width of the transverse cold aisle, I 2 Representing the number of transverse thermal channels between two cabinets to be wired, D 3 Representing transverse heat fluxWidth of track, m 2 The number of the transverse cabinets between two cabinets to be wired is represented, H represents the longitudinal depth of the cabinets, c represents the redundant length of the cable, and the redundant length is used for meeting the operation standard that the cable is required to be horizontally and vertically arched when wired between the cabinets;
s4, selecting a wiring model according to a wiring position, wherein the wiring position is at the back of the cabinet, a first wiring model is selected, and the wiring position is at the front of the cabinet, a second wiring model is selected;
step S5, determining a routing path between two cabinets to be routed according to the cabinet information to be routed;
and S6, determining the cable length between the two cabinets to be wired according to the cabinet information to be wired, the routing path and the selected routing model.
The invention determines the cable length determined between the two cabinets through the constructed wiring model so as to accurately obtain the wiring length, improve the working efficiency, reasonably utilize cable resources, reduce the resource waste, save the cost, prolong the life cycle of the trunking arranged at the top of the cabinet of the data center, accurately judge the cable length without removing short wires or rewiring, reduce the risk brought by repeated work and enhance the overall aesthetic property of the wiring of the machine room.
The cabinet information database comprises cabinet information of each cabinet in the machine room, channel distance between two adjacent columns of cabinets, the number of transverse cabinets and longitudinal cabinets in the machine room, the position, the size and the number of transverse hot channels in the machine room, the position, the size and the number of transverse cold channels in the machine room, the cable redundancy length set according to wiring operation standards and the like, wherein the cabinet information comprises cabinet names, cabinet positions, cabinet sizes (comprising the lengths, the heights, the widths and the like of the cabinets) and the like.
In the invention, a column of longitudinal wire slots is arranged at the top of each column of cabinets, and a plurality of transverse wire slots are arranged between two adjacent columns of cabinets, wherein the transverse wire slots and the longitudinal wire slots are arranged at the top of the cabinet, and preferably, each transverse wire slot transversely penetrates through all the longitudinal wire slots so as to form complete wiring arrangement, thereby improving the convenience of wiring cables and facilitating cable routing.
And determining the routing paths in different manners according to different positions of the cabinets to be routed. Preferably, the determining a routing path between two cabinets to be wired according to the cabinet information to be wired includes: judging whether the two cabinets to be wired are positioned in the same column, if so, determining a routing path according to the longitudinal position of the cabinets to be wired; if the two cabinets to be wired are located in different columns, selecting transverse wire slots between the columns of the two cabinets to be wired, and determining a wiring path according to the positions of the selected transverse wire slots.
When two cabinets to be wired are positioned in different columns, a wiring path is determined according to the positions of the selected transverse wire grooves, and as a plurality of transverse wire grooves are arranged between the two columns of cabinets, the determination of the wiring path is mainly to determine the transverse wire grooves through which the wiring passes, namely, the number of the longitudinal cabinets between the cabinets to be wired and the transverse wire grooves is determined, so that the length of a cable between the two cabinets is shortest. Preferably, the step of selecting a transverse wire chase comprises: determining the number of longitudinal cabinets between the cabinet to be wired and the selected transverse trunking according to the following:
Figure BDA0001895264560000061
wherein L represents the cable length between two cabinets to be wired, m 1 Representing the number of longitudinal cabinets between the cabinet to be wired and the transverse trunking that minimizes the cable length L. According to the different wiring models, the calculation models of L are different and are respectively L 1 And L 2 Then get m 1 Nor is it the same.
In one embodiment of the invention, a signal generator and a signal receiver are arranged at each cabinet in a machine room, signals are transmitted between the two cabinets through the signal generator and the signal receiver, and the transmission distance between the two cabinets is determined through the transmission speed and the transmission time of the transmitted signals, so that the linear distance between the two cabinets is determined. And determining a plurality of routing paths according to different positions of the selected transverse wire grooves, and determining the approximate cable length required to be laid between two cabinets to be routed under a certain routing path according to the linear distance between the routing paths and the determined cabinets, so as to select the routing path with the minimum cable length, wherein the approximate cable length is different from the accurate cable length, and the routing path is determined only by the approximate cable length. For example, in fig. 2, when two cabinets to be wired are cabinet D01 and cabinet E01, two routing paths D01-D07-E01 and D01-D14-E01 (only the portion shown in fig. 2 is taken as an example) may be determined according to the positions of the transverse trunking, the distance between cabinet D01 and cabinet D07 is determined according to the signal transmission between cabinet D01 and cabinet D07 under the two routing paths, the distance between cabinet D07 and cabinet E07 is determined according to the signal transmission between cabinet D07 and E07, the distance between cabinet E07 and cabinet E01 is determined according to the signal transmission between cabinet E07 and cabinet E01, so that the approximate cable length required to be routed when the routing path is D01-D07-E01 is determined, similarly, the approximate cable length required to be routed when the routing path is D01-D14-E01 is determined, the actual routing path is determined according to the actual routing path of the routing of the cable.
In one embodiment of the invention, cables between different cabinets to be wired use outer skins of different colors, and cable labels are arranged at two ends of the wired cables. Further, the colors of the cable labels of the cable settings between the different cabinets to be wired are different, and the cable labels are used for recording basic information of the cables, and include: the use of the cable, the color of the outer surface of the cable, the length of the cable, cabinet information connected with two ends of the cable, the initial end position of the cable, the end position of the cable and the like, so that the cable is conveniently positioned and searched through the cable label, and confusion of a plurality of cables between cabinets is avoided.
Preferably, the outer surface of the cable is provided with a length mark, the color of the length mark can be the same as or different from that of the outer surface of the cable, and the length mark can be displayed once every 0.5 meter or 1 meter to accurately position the length of the cable.
The invention is further illustrated by taking two longitudinal columns where two cabinets to be wired are respectively located adjacent to each other as an example.
FIG. 2 is a schematic diagram of a data center wiring structure in the present invention; as shown in fig. 2, taking two column cabinets as an example, a longitudinal wire slot is disposed at the top of each column cabinet, three transverse wire slots are disposed between two adjacent column cabinets, each column includes a plurality of cabinets (only a portion is shown in fig. 2, and the cabinets D01-D14 and the cabinets E01-E14), longitudinal distances of the transverse wire slots relative to the cabinets D01 and E01 are 4.2m, 8.4m and 12.6m, respectively, and only two transverse wire slots are shown in fig. 2, and are respectively located between the cabinets D07 and E07, and between the cabinets D14 and E14.
According to the invention, according to the cabinet information database, the longitudinal depth H of the cabinet is 1m, the U-bit height H of the cabinet is 0.04445m, the length of the interior of each cabinet 47U is n x H, when the wiring position is positioned on the front of the cabinet, the longitudinal depth H of the cabinet is required to be added, and when the wiring position is positioned on the back of the cabinet, the longitudinal depth H of the cabinet is not required to be added. According to different cabinet models, the cabinet width D 1 Different, when the cabinet is a standard cabinet, D 1 0.6m, D when the cabinet is a network cabinet 1 When the cabinet is widened and is 0.8m, D 1 For example, 20 standard cabinets, or 15 network cabinets, or 15 widening cabinets and 1 standard cabinet can be arranged in each column. The distance b from the cabinet to the longitudinal trunking is 0.67m. Width D of transverse cold aisle 2 Width D of transverse thermal channel of 1.2m 3 The redundant length c of the cable is 0.5m, which is 1 m. If the cabinet to be wired is the cabinet D01 and the cabinet E01 respectively, wiring is carried out on the front surface of the cabinet, a wiring model is selected as a second wiring model according to the wiring position, a transverse wire slot between the cabinet D07 and the cabinet E07 is selected according to the position information of the cabinet D01 and the cabinet E01, and the wiring path is determined to be D01-D07-E07-E01 according to the selected transverse wire slot, so that the length of a cable laid between the cabinet D01 and the cabinet E01 is the shortest, and the cable resource is saved. Determining a cabinet D01 to be wired and a transverse wire slot according to the routing pathNumber of longitudinal cabinets m in between 1 Number of transverse cold channels I between two to-be-wired cabinets D01 and E01 of 7 1 1, the number I of transverse heat channels between two cabinets to be wired 2 2, the number of transverse cabinets m between two cabinets to be wired 2 Is 0. Finally, a cable length between cabinet D01 and cabinet E01 is determined according to the second wiring model.
The data center wiring method is applied to an electronic device, and the electronic device can be terminal equipment such as a television, a smart phone, a tablet personal computer, a computer and the like.
The electronic device includes: a processor; the memory is used for storing a data center wiring program, and the processor executes the data center wiring program to realize the following steps of the data center wiring method:
constructing a cabinet information database, and acquiring cabinet information to be wired in a machine room from the cabinet information database;
constructing a wiring model, wherein the wiring model comprises a first wiring model and a second wiring model, and the first wiring model and the second wiring model are respectively shown in the following formula:
L 1 =n×h+m 1 ×D 1 +b+I 1 ×D 2 +I 2 ×D 3 +m 2 ×H+c
L 2 =n×h+H+m 1 ×D 1 +b+I 1 ×D 2 +I 2 ×D 3 +m 2 ×H+c
wherein L is 1 Representing the first cable length, L 2 Represents the length of the second cable, n represents the number of U bits in the cabinet, h represents the height of U bits in the cabinet, and m 1 Representing the number of longitudinal cabinets between the cabinet to be wired and the transverse trunking, D 1 Representing the width of the cabinet, b representing the distance from the cabinet to the longitudinal trunking, I 1 Representing the number of transverse cold channels between two cabinets to be wired, D 2 Indicating the width of the transverse cold aisle, I 2 Representing the number of transverse thermal channels between two cabinets to be wired, D 3 Represents the width of the transverse heat channel, m 2 Representing the space between two cabinets to be wiredH represents the longitudinal depth of the cabinet and c represents the cable redundancy length;
selecting a wiring model according to a wiring position, wherein the first wiring model is selected when the wiring position is at the back of the cabinet, and the second wiring model is selected when the wiring position is at the front of the cabinet;
determining a routing path between two cabinets to be routed according to the cabinet information to be routed;
and determining the cable length between the two cabinets to be wired according to the cabinet information to be wired, the routing path and the selected routing model.
The electronic device also includes a network interface, a communication bus, and the like. The network interface may include, among other things, a standard wired interface, a wireless interface, and a communication bus for enabling connection communications between the various components.
The memory includes at least one type of readable storage medium, which may be a non-volatile storage medium such as a flash memory, a hard disk, an optical disk, or the like, or a plug-in hard disk, or the like, and may be any device that stores instructions or software and any associated data files in a non-transitory manner and provides instructions or software programs to a processor to enable the processor to execute the instructions or software programs. In the present invention, the software program stored in the memory includes a data center wiring program, and the data center wiring program may be provided to the processor, so that the processor may execute the data center wiring program to implement the steps of the data center wiring method.
The processor may be a central processing unit, a microprocessor or other data processing chip, etc., and may execute a stored program in memory, such as a data center wiring program in the present invention.
The electronic device may also comprise a display, which may also be referred to as a display screen or display unit. In some embodiments, the display may be an LED display, a liquid crystal display, a touch-sensitive liquid crystal display, an Organic Light-Emitting Diode (OLED) touch, or the like. The display is used for displaying information processed in the electronic device and for displaying a visual work interface.
The electronic device may also comprise a user interface, which may comprise an input unit (such as a keyboard), a speech output device (such as a sound box, a headset) etc.
Preferably, the electronic device further comprises a positioning device for positioning the cabinet to be wired so as to acquire the cabinet information to be wired.
In the invention, a column of longitudinal wire slots is arranged at the top of each column of cabinets, and a plurality of transverse wire slots are arranged between two adjacent columns of cabinets, wherein the transverse wire slots and the longitudinal wire slots are arranged at the top of the cabinet, and preferably, each transverse wire slot transversely penetrates through all the longitudinal wire slots so as to form complete wiring arrangement, thereby improving the convenience of wiring cables and facilitating cable routing.
Preferably, the data center wiring program when executed by the processor further implements the steps of: judging whether the two cabinets to be wired are positioned in the same column, if the two cabinets to be wired are positioned in different columns, selecting a transverse wire slot between the columns in which the two cabinets to be wired are positioned, and determining a wiring path according to the position of the selected transverse wire slot.
Further, the step of selecting the lateral slot includes: determining the number of longitudinal cabinets between the cabinet to be wired and the selected transverse trunking according to the following:
Figure BDA0001895264560000091
wherein L represents the cable length between two cabinets to be wired, m 1 The number of longitudinal cabinets between the cabinets to be wired and the transverse trunking is represented. According to the different wiring models, the calculation models of L are different and are respectively L 1 And L 2 Then get m 1 Nor is it the same.
The invention also provides a data center wiring system, comprising: the data center wiring method comprises the steps of arranging a plurality of longitudinal cabinets on the top of a cabinet, arranging a plurality of transverse trunks between two adjacent rows of longitudinal cabinets, wherein each transverse trunking transversely penetrates through all longitudinal trunking, and the wiring module is used for determining the length of a cable between two cabinets to be wired.
The transverse wire slot and the longitudinal wire slot both comprise a base and a clamping part, wherein the base is fixed with the top of the cabinet, and the clamping part is fixed on the base and is used for clamping a cable laid therein. The clamping part can be formed by butt joint of two arc-shaped plates, the cable is positioned between the two arc-shaped plates, and the cable is laid through opening and closing of the two arc-shaped plates. The cable comprises a plurality of cable cores, the plurality of cable cores are stranded together, and the adhesive tape layer is spirally wound outside the plurality of cable cores so as to ensure the overall aesthetic property of the laid cable.
In other embodiments, the data center cabling program may also be split into one or more modules, one or more modules stored in memory and executed by a processor to complete the invention. The invention may refer to a series of computer program instruction segments capable of performing a specified function. FIG. 3 is a schematic block diagram of a data center routing program according to the present invention, and as shown in FIG. 3, the data center routing program may be divided into: a database construction module 1, an acquisition module 2, a model construction module 3, a model selection module 4, a routing path determination module 5 and a cable length determination module 6. The functions or operational steps performed by the above modules are similar to those described above and will not be described in detail herein, for example, wherein:
the database construction module 1 is used for constructing a cabinet information database;
the acquisition module 2 acquires cabinet information to be wired in the machine room from the cabinet information database;
the model construction module 3 constructs a wiring model including a first wiring model and a second wiring model, the first wiring model and the second wiring model being respectively represented by the following formulas:
L 1 =n×h+m 1 ×D 1 +b+I 1 ×D 2 +I 2 ×D 3 +m 2 ×H+c
L 2 =n×h+H+m 1 ×D 1 +b+I 1 ×D 2 +I 2 ×D 3 +m 2 ×H+c
wherein L is 1 Representing the first cable length, L 2 Represents the length of the second cable, n represents the number of U bits in the cabinet, h represents the height of U bits in the cabinet, and m 1 Representing the number of longitudinal cabinets between the cabinet to be wired and the transverse trunking, D 1 Representing the width of the cabinet, b representing the distance from the cabinet to the longitudinal trunking, I 1 Representing the number of transverse cold channels between two cabinets to be wired, D 2 Indicating the width of the transverse cold aisle, I 2 Representing the number of transverse thermal channels between two cabinets to be wired, D 3 Represents the width of the transverse heat channel, m 2 The number of the transverse cabinets between two cabinets to be wired is represented, H represents the longitudinal depth of the cabinets, c represents the redundant length of the cable, and the redundant length is used for meeting the operation standard that the cable is required to be horizontally and vertically arched when wired between the cabinets;
the model selection module 4 selects a wiring model according to the wiring position, wherein the wiring position selects a first wiring model at the back of the cabinet, and the wiring position selects a second wiring model at the front of the cabinet;
the routing path determining module 5 determines a routing path between two cabinets to be routed according to the cabinet information to be routed;
and the cable length determining module 6 is used for determining the cable length between the two cabinets to be wired according to the cabinet information to be wired, the routing path and the selected wiring model.
In one embodiment of the invention, the computer readable storage medium may be any tangible medium that can contain, or store a program or instructions that can be executed to implement the corresponding functions in the hardware associated with the stored program instructions. For example, the computer readable storage medium may be a computer diskette, hard disk, random access memory, read-only memory, etc. The invention is not limited in this regard and may be any means for storing instructions or software and any associated data files or data structures in a non-transitory manner and which may be provided to a processor to cause the processor to execute programs or instructions therein. The computer readable storage medium includes a data center wiring program, which when executed by a processor, implements the steps of a data center wiring method as follows:
constructing a cabinet information database;
acquiring cabinet information to be wired in a machine room from the cabinet information database;
constructing a wiring model, wherein the wiring model comprises a first wiring model and a second wiring model, and the first wiring model and the second wiring model are respectively shown in the following formula:
L 1 =n×h+m 1 ×D 1 +b+I 1 ×D 2 +I 2 ×D 3 +m 2 ×H+c
L 2 =n×h+H+m 1 ×D 1 +b+I 1 ×D 2 +I 2 ×D 3 +m 2 ×H+c
wherein L is 1 Representing the first cable length, L 2 Represents the length of the second cable, n represents the number of U bits in the cabinet, h represents the height of U bits in the cabinet, and m 1 Representing the number of longitudinal cabinets between the cabinet to be wired and the transverse trunking, D 1 Representing the width of the cabinet, b representing the distance from the cabinet to the longitudinal trunking, I 1 Representing the number of transverse cold channels between two cabinets to be wired, D 2 Indicating the width of the transverse cold aisle, I 2 Representing the number of transverse thermal channels between two cabinets to be wired, D 3 Represents the width of the transverse heat channel, m 2 The number of the transverse cabinets between two cabinets to be wired is represented, H represents the longitudinal depth of the cabinets, c represents the redundant length of the cable, and the redundant length is used for meeting the operation standard that the cable is required to be horizontally and vertically arched when wired between the cabinets;
selecting a wiring model according to the wiring position, wherein the wiring position is at the back of the cabinet, a first wiring model is selected, and the wiring position is at the front of the cabinet, a second wiring model is selected;
determining a routing path between two cabinets to be routed according to the cabinet information to be routed;
and determining the cable length between the two cabinets to be wired according to the cabinet information to be wired, the routing path and the selected routing model.
The embodiment of the computer readable storage medium of the present invention is substantially the same as the embodiment of the data center wiring method and the electronic device, and will not be described herein.
It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, apparatus, article, or method that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, apparatus, article, or method. Without further limitation, an element defined by the phrase "comprising one … …" does not exclude the presence of other like elements in a process, apparatus, article or method that comprises the element.
The foregoing embodiment numbers of the present invention are merely for the purpose of description, and do not represent the advantages or disadvantages of the embodiments. From the above description of the embodiments, it will be clear to those skilled in the art that the above-described embodiment method may be implemented by means of software plus a necessary general hardware platform, but of course may also be implemented by means of hardware, but in many cases the former is a preferred embodiment. Based on such understanding, the technical solution of the present invention may be embodied essentially or in a part contributing to the prior art in the form of a software product stored in a storage medium (e.g. ROM/RAM, magnetic disk, optical disk) as described above, comprising instructions for causing a terminal device (which may be a mobile phone, a computer, a server, or a network device, etc.) to perform the method according to the embodiments of the present invention.
The foregoing description is only of the preferred embodiments of the present invention, and is not intended to limit the scope of the invention, but rather is intended to cover any equivalents of the structures or equivalent processes disclosed herein or in the alternative, which may be employed directly or indirectly in other related arts.

Claims (10)

1. A data center wiring method applied to an electronic device, comprising:
constructing a cabinet information database, and acquiring cabinet information to be wired in a machine room from the cabinet information database;
constructing a wiring model, wherein the wiring model comprises a first wiring model and a second wiring model, and the first wiring model and the second wiring model are respectively shown in the following formula:
L 1 =n×h+m 1 ×D 1 +b+I 1 ×D 2 +I 2 ×D 3 +m 2 ×H+c
L 2 =n×h+H+m 1 ×D 1 +b+I 1 ×D 2 +I 2 ×D 3 +m 2 ×H+c
wherein L is 1 Representing the first cable length, L 2 Represents the length of the second cable, n represents the number of U bits in the cabinet, h represents the height of U bits in the cabinet, and m 1 Representing the number of longitudinal cabinets between the cabinet to be wired and the transverse trunking, D 1 Representing the width of the cabinet, b representing the distance from the cabinet to the longitudinal trunking, I 1 Representing the number of transverse cold channels between two cabinets to be wired, D 2 Indicating the width of the transverse cold aisle, I 2 Representing the number of transverse thermal channels between two cabinets to be wired, D 3 Represents the width of the transverse heat channel, m 2 The number of the transverse cabinets between two cabinets to be wired is represented, H represents the longitudinal depth of the cabinets, and c represents the redundant length of the cables;
selecting a wiring model according to a wiring position, wherein the first wiring model is selected when the wiring position is at the back of the cabinet, and the second wiring model is selected when the wiring position is at the front of the cabinet;
determining a routing path between two cabinets to be routed according to the cabinet information to be routed;
and determining the cable length between the two cabinets to be wired according to the cabinet information to be wired, the routing path and the selected routing model.
2. The data center routing method of claim 1, wherein a column of longitudinal wire slots is provided at the top of each column of cabinets, and a plurality of transverse wire slots are provided between two adjacent columns of cabinets, each transverse wire slot extending transversely through all of the longitudinal wire slots.
3. The data center routing method according to claim 2, wherein determining a routing path between two racks to be routed according to the rack to be routed information comprises:
judging whether the two cabinets to be wired are positioned in the same column, if the two cabinets to be wired are positioned in different columns, selecting a transverse wire slot between the columns in which the two cabinets to be wired are positioned, and determining a wiring path according to the position of the selected transverse wire slot.
4. The data center routing method of claim 3, wherein the step of selecting a lateral slot comprises: determining the number of longitudinal cabinets between the cabinet to be wired and the selected transverse trunking according to the following:
Figure FDA0001895264550000021
wherein L represents the cable length between two cabinets to be wired, m 1 The number of longitudinal cabinets between the cabinets to be wired and the transverse trunking is represented.
5. The data center routing method of claim 1, wherein the data center routing method further comprises:
the cables between the different cabinets to be wired use outer skins with different colors, and cable labels are arranged at two ends of the wired cables.
6. The data center routing method of claim 5, further comprising:
the outer surface of the cable is provided with a length mark, and the color of the length mark is different from that of the outer surface of the cable.
7. An electronic device, comprising:
a processor;
the memory comprises a data center wiring program, and the data center wiring program realizes the following steps when being executed by the processor:
constructing a cabinet information database, and acquiring cabinet information to be wired in a machine room from the cabinet information database;
constructing a wiring model, wherein the wiring model comprises a first wiring model and a second wiring model, and the first wiring model and the second wiring model are respectively shown in the following formula:
L 1 =n×h+m 1 ×D 1 +b+I 1 ×D 2 +I 2 ×D 3 +m 2 ×H+c
L 2 =n×h+H+m 1 ×D 1 +b+I 1 ×D 2 +I 2 ×D 3 +m 2 ×H+c
wherein L is 1 Representing the first cable length, L 2 Represents the length of the second cable, n represents the number of U bits in the cabinet, h represents the height of U bits in the cabinet, and m 1 Representing the number of longitudinal cabinets between the cabinet to be wired and the transverse trunking, D 1 Representing the width of the cabinet, b representing the distance from the cabinet to the longitudinal trunking, I 1 Representing the number of transverse cold channels between two cabinets to be wired, D 2 Indicating the width of the transverse cold aisle, I 2 Representing the number of transverse thermal channels between two cabinets to be wired, D 3 Represents the width of the transverse heat channel, m 2 The number of the transverse cabinets between two cabinets to be wired is represented, H represents the longitudinal depth of the cabinets, and c represents the redundant length of the cables;
selecting a wiring model according to a wiring position, wherein the first wiring model is selected when the wiring position is at the back of the cabinet, and the second wiring model is selected when the wiring position is at the front of the cabinet;
determining a routing path between two cabinets to be routed according to the cabinet information to be routed;
and determining the cable length between the two cabinets to be wired according to the cabinet information to be wired, the routing path and the selected routing model.
8. The electronic device of claim 7, wherein the data center cabling program when executed by the processor further performs the steps of:
judging whether the two cabinets to be wired are positioned in the same column, if the two cabinets to be wired are positioned in different columns, selecting a transverse wire slot between the columns in which the two cabinets to be wired are positioned, and determining a wiring path according to the position of the selected transverse wire slot.
9. The electronic device of claim 7, further comprising a positioning device for positioning the location of the rack to be wired.
10. A computer readable storage medium, comprising a data center routing program therein, which when executed by a processor, implements the steps of the data center routing method of claim 1.
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