CN215932234U - Channel for micro-module data center - Google Patents

Abstract

The utility model relates to a channel for a micro-module data center, which comprises an optical fiber channel assembly for laying optical fibers; the cable channel assembly comprises a cable track assembly used for laying cables, a first supporting piece and a second supporting piece, wherein the first supporting piece is fixedly connected with the optical fiber channel assembly and is used for supporting the optical fiber channel assembly; the upper end of the second supporting piece is fixedly connected with the optical fiber channel assembly, and the lower end of the second supporting piece is fixedly connected with the cable routing frame assembly and used for supporting the optical fiber channel assembly. According to the utility model, the optical fibers and the cables are separately arranged through the optical fiber channel assembly and the cable chute assembly, so that the optical fibers and the cables are separately arranged, the overall arrangement is regular, and the later maintenance is convenient; when the cable is short-circuited and the like, the optical fiber is not affected, the safety of the optical fiber is greatly ensured, and the cost for maintaining the optical fiber is reduced.

Description

Channel for micro-module data center

Technical Field

The utility model relates to a channel for a micro-module data center, and belongs to the technical field of optical fiber channels for providing optical fiber routing and cable protection, storage and management in the micro-module data center.

Background

With the continuous increase and perfection of equipment facilities and function configuration of the micro-module data center, the number of optical cables and cables for wiring is correspondingly increased, and the arrangement of micro-module data center lines is disordered due to the fact that the optical cables and the cables are added in the original design space, so that the difficulty of later maintenance is increased; and often can appear arranging cable and optical cable in same wire casing, this also can lead to the cable wire casing to appear laying cable too much and lead to the degree of depth that highly is higher than the wire casing of in-line cable, just so can appear following problem: when a short circuit is not found in time when a cable in the wire slot is overloaded and generates heat, the cable and the optical fiber are laid together, so that the optical fiber is easily damaged, the potential safety hazard of the optical cable and the cable in the whole wire slot is caused, and the maintenance cost after the damage is very high.

Disclosure of Invention

The utility model aims to provide a channel for a micro-module data center, which has a reasonable and compact structure, can improve the utilization rate and accuracy of optical fiber resources and improve the operation level and safety and reliability of an optical fiber network by respectively arranging cables and optical cables.

The technical scheme for achieving the aim of the utility model is as follows: a channel for a micromodule data center, comprising: comprises that

A fiber channel assembly for routing an optical fiber;

a cable run rack assembly for cabling;

a first support member fixedly connected to the fiber channel assembly for supporting the fiber channel assembly;

the upper end of the second supporting piece is fixedly connected with the optical fiber channel assembly, and the lower end of the second supporting piece is fixedly connected with the cable routing frame assembly and used for supporting the optical fiber channel assembly.

Wherein: the optical fiber channel assembly comprises a first optical fiber channel, a bus channel and a bus tee joint, wherein the bus tee joint comprises a bus connecting end and a bus lower line port, and two ends of the bus channel are respectively connected with the bus connecting end of the bus tee joint;

the second optical fiber groove comprises a branch channel and a branch tee; the branch tee joint comprises a branch connecting end and a branch lower line port, and is positioned at the lower part of the branch tee joint through the branch connecting end and the branch channel;

one end of the inward-bent channel is connected with the second optical fiber groove, and the other end of the inward-bent channel is connected with the bus down-line port, so that the first optical fiber groove is positioned above the second optical fiber groove;

the first supporting piece is fixedly connected with the second optical fiber groove and used for supporting the second optical fiber groove; the upper end of the second supporting piece is fixedly connected with the first optical fiber groove.

The second supporting piece comprises an adjusting screw rod and a supporting plate, and the supporting plate is fixedly connected to the upper end of the adjusting screw rod; the fixed support is fixedly connected to the lower end of the adjusting screw rod; and the position of the supporting plate and the fixed bracket can be adjusted on the adjusting screw rod.

The supporting plate is provided with a plurality of first mounting waist-shaped holes connected with the second optical fiber grooves, and the fixing support is provided with a plurality of second mounting waist-shaped holes fixedly connected with the cable routing frame assembly.

And the first supporting piece is provided with a plurality of third mounting waist-shaped holes fixedly connected with the second optical fiber grooves.

The width of the first optical fiber groove is larger than that of the second optical fiber groove, and the minimum curvature radius R of the inward-bent groove is larger than or equal to 37.5 mm.

The cable chute subassembly includes the laying frame and support arm and butterfly board, the laying frame passes through butterfly board and support arm connection for the support arm supports the laying frame.

The channel for the micro-module data center adopts the optical fiber channel component, the cable routing frame component, the first supporting component and the second supporting component, is supported by the first supporting component and the second supporting component, and is separately distributed with the optical fibers and the cables by the optical fiber channel component and the cable routing frame component, so that the optical fibers and the cables can be separately distributed, the overall distribution is regular, the structure is reasonable and compact, the defects of disordered optical cable management, low construction operation and maintenance efficiency, unattractive distribution and the like caused by the use of the existing cable channel in the data center are overcome, the utilization rate and the accuracy of optical fiber resources are improved, the later maintenance is convenient, and the operation level and the safety and reliability of an optical fiber network are improved. The optical fiber and the cable are separately arranged, so that when the cable is short-circuited and the like, the optical fiber is not affected, the safety of the optical fiber is greatly ensured, the cost for maintaining the optical fiber can be reduced, and the problem of potential safety hazard of the optical fiber is solved.

Drawings

The utility model is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic diagram of a channel for a micromodule data center according to the present invention.

FIG. 2 is a schematic diagram of the construction of a fiber channel assembly of the present invention.

Fig. 3 is an enlarged schematic view of a structure at a in fig. 2.

Fig. 4 is an enlarged schematic view of B in fig. 2.

Fig. 5 is a schematic structural view of a cable run rack assembly of the present invention.

Fig. 6 is a schematic structural view of the first support member of the present invention.

Fig. 7 is a schematic structural view of a second support member of the present invention.

Wherein: 10-an optical fiber channel assembly, 12-a first optical fiber channel, 121-a bus channel, 122-a bus tee, 1221-a bus connection end, 1222-a bus drop port, 13-a second optical fiber channel, 131-a branch channel, 132-a branch tee, 1321-a branch connection end, 1322-a branch drop port, 133-an inward-bent channel, 20-a cable routing frame assembly, 21-a laying frame, 22-a support arm, 23-a butterfly plate, 30-a first support member, 31-a third installation kidney-shaped hole, 40-a second support member, 41-an adjusting screw rod, 42-a support plate, 421-a first installation kidney-shaped hole; 43-fixing bracket, 431-second installation kidney-shaped hole.

Detailed Description

The present invention will now be described in further detail with reference to the accompanying drawings. These drawings are simplified schematic views illustrating only the basic structure of the present invention in a schematic manner, and thus show only the constitution related to the present invention.

Referring to fig. 1-4, a channel for a micromodule data center of the present invention comprises a fiber channel assembly 10 for routing optical fibers, a cable rack assembly 20 for routing cables, a first support 30 and a second support 40, wherein the fiber channel assembly 10 comprises a first fiber channel 12, a second fiber channel 13 and an inner-bending channel 133, the first fiber channel 12 comprises a bus channel 121 and a bus tee 122, the bus tee 122 comprises a bus connection end 1221 and a bus lower line port 1222, two ends of the bus channel 121 are respectively connected with the bus connection end 1221 of the bus tee 122, the bus tee 122 is alternately connected with the bus channel 121 through the bus connection end 1221, the length of the first fiber groove 12 can be extended or shortened as required, the bus drop port 1222 faces downward, and port baffles are arranged at two ends of the first fiber groove 12 to seal the ports.

As shown in fig. 1-4, the second fiber groove 13 of the present invention includes a branch channel 131 and a branch tee 132; the branch tee 132 includes a branch connection end 1321 and a branch offtake port 1322, the branch tee 132 is alternately connected with the branch channel 131 through the branch connection end 1321, the length of the second optical fiber groove 13 can be extended or shortened as required, and the branch offtake port 1322 faces downward to output the optical fiber cable of the micro module data center equipment cabinet. One end of the inner-bent channel 133 of the utility model is connected with one end of the second optical fiber groove 13, the other end is connected with the bus lower line port 1222, and the first optical fiber groove 12 is higher than the second optical fiber groove 13, the channel width of the first optical fiber groove 12 is larger than the channel width of the second optical fiber groove 13, the minimum curvature radius R of the inner-bent channel 133 of the utility model is more than or equal to 37.5mm, the minimum curvature radius can be satisfied, and the first supporting piece 30 is fixedly connected with the second optical fiber groove 13 for supporting the second optical fiber groove 13. As shown in fig. 6, the first supporting member 30 of the present invention is fixedly connected to the branch channel 131, and the first supporting member 30 is provided with a plurality of third mounting kidney-shaped holes 31, so as to adjust the position of the first supporting member 30 when the first supporting member is mounted conveniently, wherein the first supporting member 30 includes a supporting plate and several types of supporting seats, two ends of the supporting plate are respectively connected to the several types of supporting seats, and the supporting plate is provided with the third mounting kidney-shaped holes 31; the upper end of the second support member 40 is fixedly attached to the first fiber channel 12 and the lower end of the second support member 40 is fixedly attached to the cable trough assembly 20 for supporting the fiber channel assembly 10.

As shown in fig. 7, the second supporting member 40 of the present invention includes an adjusting screw 41, a supporting plate 42 and a fixing bracket 43, one end of the supporting plate 42 is fixedly connected to the upper end of the adjusting screw 41, and the supporting plate 42 can be adjusted in the axial height of the adjusting screw 41 according to the height requirement, or the circumferential position of the supporting plate 42 on the adjusting screw 41 can be adjusted according to the position difference, and the supporting plate 42 is provided with a plurality of first mounting kidney-shaped holes 421 connected to the second fiber groove 13, so as to conveniently adjust the position relationship between the supporting plate 42 and the first fiber groove 12; the fixed bracket 43 is fixedly connected to the lower end of the adjusting screw rod 41; the position of the support plate 42 and the fixing bracket 43 can be adjusted on the adjusting screw 41, and the fixing bracket 43 is provided with a plurality of second waist-shaped mounting holes 431 fixedly connected with the cable rack assembly 20, where the "positional relationship" refers to the adjusting screw 41, and may be axial or axial.

Preferably, as shown in fig. 5, the cable chute assembly 20 of the present invention comprises a laying frame 21, a support arm 22 and a butterfly plate 23, the laying frame 21 being connected to the support arm 22 by the butterfly plate 23 so that the support arm 22 supports the laying frame 21. The channel for a micromodule data center includes a fiber channel assembly 10 for routing optical fibers, a cable rack assembly 20 for routing cables, a first support 30, and a second support 40. Below the fiber channel assembly 10 are disposed a first support 30 and a second support 40, and below the second support 40 is disposed a cable trough assembly 20. Wherein the first support 30 and the support arm 22 are each fixedly mounted to the top of the equipment cabinet.

The channel for the micro-module data center can be processed by adopting low-smoke halogen-free flame-retardant ABS materials, is laid by adopting a layered structure, is in a square loop shape, comprises a first optical fiber groove 12 and a second optical fiber groove 13 on the upper layer, the second optical fiber groove 13 is connected with a bus tee 122 through a wide joint, the bus tee 122 is used for switching the first optical fiber groove 12 and the second optical fiber groove 13, an inner-bent channel 133 is arranged below the bus tee 122, the channel width of the first optical fiber groove 12 is larger than that of the second optical fiber groove 13, the inner-bent channel 133 meets the condition that the minimum curvature radius R is larger than or equal to 37.5mm and is connected with the second optical fiber groove 13 through a narrow joint, a branch tee 132 is arranged beside the second optical fiber groove 13, the branch tee 132 is arranged above a wire outlet hole at the top of an equipment cabinet and is used for optical fiber cable outlet, a branch lower wire outlet is arranged below the branch tee 132, the transition fillet at the corner meets the condition that the minimum curvature radius R is larger than or equal to 37.5mm, and 1 equipment cabinet is configured with a set of branch tee joints 132 and branch offtake ports 1322, and the specific number is flexibly set according to the number of the cabinets.

In light of the foregoing description of the preferred embodiment of the present invention, many modifications and variations can be made by the worker in the light of the above teachings without departing from the spirit of the utility model. The technical scope of the present invention is not limited to the content of the specification, and must be determined according to the scope of the claims.

Claims (7)

1. A channel for a micromodule data center, comprising: comprises that

A fibre channel assembly (10) for laying an optical fibre;

a cable run rack assembly (20) for cabling;

a first support member (30), the first support member (30) being fixedly connected to the fiber channel assembly (10) for supporting the fiber channel assembly (10);

the upper end of the second supporting piece (40) is fixedly connected with the optical fiber channel assembly (10), and the lower end of the second supporting piece (40) is fixedly connected with the cable routing rack assembly (20) and is used for supporting the optical fiber channel assembly (10).

2. The channel for a micromodule data center of claim 1, wherein:

the fiber channel assembly (10) includes

The first optical fiber groove (12) comprises a bus channel (121) and a bus tee joint (122), the bus tee joint (122) comprises a bus connecting end (1221) and a bus lower line port (1222), and two ends of the bus channel (121) are respectively connected with the bus connecting end (1221) of the bus tee joint (122);

a second fiber groove (13) including a branch channel (131) and a branch tee (132); the branch tee joint (132) comprises a branch connecting end (1321) and a branch offline port (1322), and the branch tee joint (132) is alternately connected with the branch channel (131) through the branch connecting end (1321), so that the branch offline port (1322) is positioned at the lower part of the branch tee joint (132);

an inward-bent channel (133), one end of the inward-bent channel (133) is connected with the second optical fiber groove (13), and the other end of the inward-bent channel is connected with the bus down port (1222), so that the first optical fiber groove (12) is positioned above the second optical fiber groove (13);

the first supporting piece (30) is fixedly connected with the second optical fiber groove (13) and is used for supporting the second optical fiber groove (13); the upper end of the second supporting piece (40) is fixedly connected with the first optical fiber groove (12).

3. The channel for a micromodule data center of claim 2, wherein: the second supporting piece (40) comprises an adjusting screw rod (41) and a supporting plate (42), and the supporting plate (42) is fixedly connected to the upper end of the adjusting screw rod (41); the fixing support (43), the said fixing support (43) is fixedly connected to the bottom end of the adjusting screw (41); and the supporting plate (42) and the fixing bracket (43) can be adjusted in position on the adjusting screw rod (41).

4. The channel for a micromodule data center of claim 3, wherein: the supporting plate (42) is provided with a plurality of first installation waist-shaped holes (421) connected with the second optical fiber grooves (13), and the fixing support (43) is provided with a plurality of second installation waist-shaped holes (431) fixedly connected with the cable routing frame assembly (20).

5. The channel for a micromodule data center of claim 2, wherein: the first supporting piece (30) is provided with a plurality of third mounting kidney-shaped holes (31) fixedly connected with the second optical fiber grooves (13).

6. The channel for the micromodule data center according to claim 2, wherein the channel width of the first fiber channel (12) is larger than the channel width of the second fiber channel (13), and the minimum curvature radius R of the inward-bent channel (133) is not less than 37.5 mm.

7. The channel for a micromodule data center of claim 1, wherein: the cable routing frame assembly (20) comprises a laying frame (21), a supporting arm (22) and a butterfly plate (23), wherein the laying frame (21) is connected with the supporting arm (22) through the butterfly plate (23) so that the supporting arm (22) supports the laying frame (21).

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