CN114272534A - Network equipment room mounting structure - Google Patents

Abstract

The invention provides a network equipment room installation structure which comprises a data hall, a room unit, a lead unit and a fire unit, wherein the room unit is arranged in the data hall, and a cold channel is arranged in the room unit; the lead unit is arranged at the top of the electric cabinet; the fire-fighting unit comprises a mixed gas fire-fighting assembly and spraying assemblies distributed outside the machine room. According to the network equipment room installation structure provided by the invention, the plurality of cold channels are arranged in the room unit to install the electrical cabinet, so that the abnormity caused by overlarge heat of electrical elements is avoided, the normal operation of the equipment is ensured, the lead unit is arranged above the cold channels, cables in the electrical cabinet are gathered into the lead unit from the top, the reasonable arrangement of the cables is realized, the mixed gas fire extinguishing system can carry out fire protection on the area in the cold channels, the damage of the electrical elements caused by spray fire extinguishing is avoided, the spray fire extinguishing is adopted in other areas, and the overall cost is reduced.

Description

Network equipment room mounting structure

Technical Field

The invention belongs to the technical field of data halls, and particularly relates to a network equipment room installation structure.

Background

With the rapid development of network technology, data center construction is often required in city construction. Traditional internet data center is simply setting up a plurality of computer rooms that are used for installing the regulator cubicle, because there are a large amount of regulator cubicles in the computer room, can give off a large amount of heats in the use, so there are equipment in current data hall in use and lay, the circuit arranges, environmental temperature control, equipment fire prevention a great deal of problem.

Disclosure of Invention

The invention aims to provide a network equipment room installation structure, which can enable a data hall to meet various requirements such as temperature control, wiring and fire protection, and ensure the normal operation of the data hall.

In order to achieve the purpose, the invention adopts the technical scheme that: there is provided a network equipment room mounting structure including:

a data hall;

the equipment room unit is arranged in the data hall, a plurality of cold channels are arranged in the equipment room unit, and the cold channels are internally provided with electric cabinets;

the lead unit is arranged at the top of the electric cabinet, is positioned in the cold channel and is used for bearing the cable led out from the electric cabinet;

and the fire-fighting unit comprises mixed gas fire-extinguishing components distributed in the cold channel and spraying components distributed outside the machine room.

In a possible implementation, be equipped with antistatic insulation floor in the data hall, antistatic insulation floor is located the cold passageway outside, and antistatic insulation floor includes:

the heat insulation base layer is laid on the floor slab and comprises a plurality of parallel bearing strips and a heat insulation plate arranged between every two adjacent bearing strips;

the mounting frame comprises a plurality of supporting columns arranged on the bearing strips and a frame arranged above the supporting columns, the frame comprises longitudinal strips arranged along the extending direction of the bearing strips and transverse strips arranged perpendicular to the extending direction of the bearing strips, and the supporting columns are supported below the intersection points of the longitudinal strips and the transverse strips;

the antistatic floor is laid above the frame;

the frame is provided with a mounting hole for mounting the electrical cabinet, and the antistatic floor is distributed on the periphery of the electrical cabinet.

In some embodiments, the bottom of the frame is provided with a plurality of connecting sleeves extending in the up-down direction, and the supporting column comprises:

the bottom plate is positioned on the bearing strip;

the landing leg is connected on the bottom plate along upper and lower direction, and is located the center of bottom plate, the upper end and the connecting sleeve threaded connection of landing leg.

In some embodiments, the heat insulation board comprises a heat insulation layer and a rigid shell coated outside the heat insulation layer, the rigid shell is a galvanized steel sheet material component, and the thickness of the rigid shell is 0.5-1 mm; the heat-insulating layer is made of rubber-plastic heat-insulating cotton and has a thickness of 20-30 mm; the antistatic floor is a calcium sulfate component, and the thickness of the antistatic floor is 25-35 mm;

the antistatic heat-insulation floor further comprises transparent observation plates arranged between two adjacent antistatic floors at intervals, the antistatic floors are calcium sulfate members, and the thickness of each antistatic floor is 25-35 mm.

In one possible implementation, the fire fighting unit further comprises a detector and a controller, the detector is installed at the top of the data hall; the mixed gas fire extinguishing assembly is provided with a starting valve, and the spraying assembly is provided with a water inlet valve;

the controller is electrically connected with the detector, the starting valve and the water inlet valve respectively, and can receive detection parameters of the detector and send control instructions to the starting valve or the water inlet valve.

In some embodiments, a ceiling plate is arranged in the data hall, the detector is embedded in the ceiling plate, the upper end of the detector is connected with a cable extending into the floor plate, a metal hose is sleeved on the periphery of the cable between the ceiling plate and the floor plate, and a pre-buried steel pipe used for penetrating the cable is pre-buried in the floor plate.

In some embodiments, the spray assembly includes a water supply pipe mounted to a floor of the data hall by a guide bracket, the guide bracket including:

the top of the guide rail is connected with the bottom surface of the floor slab and extends along the horizontal direction;

the sliding block is connected below the guide rail in a sliding manner;

the upper half ring is connected to the bottom surface of the sliding block, and the opening of the upper half ring is downward;

and the lower half ring is connected below the upper half ring through a connecting piece and is used for being matched with the upper half ring to be encircled on the periphery of the water supply pipe.

In one possible implementation, the lead unit includes:

the supporting frame comprises two pillars arranged at the top of the electric cabinet and a supporting beam connected to the upper ends of the two pillars, and the supporting beam extends along the front-back direction of the electric cabinet;

the cable bracket is arranged on the supporting beam and used for supporting a cable, and the cable bracket extends from one side of the electric cabinet to the other side of the electric cabinet.

In some embodiments, the cable bracket is a mesh frame member formed by criss-cross steel bars, and two side edges of the cable bracket are bent upwards to extend and form side rails;

the electric cabinet is provided with a wire passing hole for leading out a cable, and the inner bottom surface of the cable bracket is provided with a guide plate which is bent downwards in an arc shape and corresponds to the wire passing hole up and down;

the bearing beam is provided with an upward opening, two side walls of the bearing beam bend outwards and downwards to extend and form a bearing part, and a plurality of clamping grooves which are communicated up and down and are in clamping fit with the steel bars of the cable bracket are arranged on the bearing part at intervals.

In a possible implementation, network equipment computer lab mounting structure is still including setting up in cold passageway top, and the unit of hanging that meets with the lead wire unit, hangs the unit and hoists in the top of computer lab unit, and it includes to hang the unit:

the upper end of the suspender is connected to the floor slab through an expansion bolt;

the hanging rack is connected to the lower end of the hanging rod and extends along the horizontal direction;

the wire arranging seat is arranged on the hanging frame, extends along the horizontal direction and is attached above the cables, and a plurality of separating parts protruding downwards to separate two adjacent cables are arranged on the bottom surface of the wire arranging seat;

and the at least two ground wires are respectively connected to the hanging rack and are connected with the grounding trunk line.

The shown scheme of this application embodiment, compared with the prior art, the shown scheme of this application embodiment, set up a plurality of cold passageways in order to carry out the installation of regulator cubicle in the unit of computer lab, cooling channel feeds into air conditioning through the lower part and makes electrical components be in low temperature environment, avoid the unusual that electrical components heat excessively caused, guarantee the normal operating of equipment, the cold passageway top is provided with the lead wire unit, the cable in the regulator cubicle gathers together to the lead wire unit in from the top, realize the reasonable laying of cable, mist fire extinguishing system can carry out the fire protection to the region in the cold passageway, avoid electrical components because of spraying the damage that the fire extinguishing caused, other regional adoption are sprayed and are put out a fire, the overall cost is reduced.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the embodiments or the prior art descriptions will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without inventive exercise.

Fig. 1 is a schematic top-view structural diagram of a network equipment room installation structure provided in an embodiment of the present invention;

FIG. 2 is a schematic sectional view of the antistatic insulation floor shown in FIG. 1;

FIG. 3 is a schematic top view of the frame of FIG. 2 according to an embodiment of the present invention;

FIG. 4 is a schematic cross-sectional view of the thermal insulation board shown in FIG. 2 according to an embodiment of the present invention;

fig. 5 is a schematic top view of an arrangement of a fire fighting unit in a network equipment room installation structure according to an embodiment of the present invention;

FIG. 6 is a schematic view of a mounting structure of a detector according to an embodiment of the present invention;

FIG. 7 is a schematic view of a front view of a water supply pipe and a guide bracket according to an embodiment of the present invention;

FIG. 8 is a left side cross-sectional structural view of the embodiment of FIG. 7;

fig. 9 is a schematic view of an electrical cabinet and a lead unit mounting structure provided in an embodiment of the invention;

FIG. 10 is a left side view of the structure of FIG. 9 according to the embodiment of the present invention;

FIG. 11 is a schematic structural view of the joist shown in FIG. 10 according to the embodiment of the present invention;

fig. 12 is a schematic view of an installation structure of a hanging unit according to an embodiment of the present invention.

Wherein, in the figures, the respective reference numerals:

1. a data hall; 11. a corridor; 2. a machine room unit; 21. a cold aisle; 22. an electrical cabinet; 3. a lead unit; 31. a support frame; 311. a pillar; 312. a support beam; 313. a bearing part; 314. a card slot; 32. a cable tray; 321. a side rail; 33. a guide plate; 4. a fire fighting unit; 41. a mixed gas fire suppression assembly; 42. a spray assembly; 43. a detector; 44. a metal hose; 45. pre-burying a steel pipe; 46. a water supply pipe; 5. antistatic heat-insulating floor; 51. a heat preservation base layer; 511. a support strip; 512. a thermal insulation board; 5121. a heat-insulating layer; 5122. a rigid shell; 52. a mounting frame; 521. a support pillar; 522. a frame; 523. a longitudinal strip; 524. a transverse strip; 525. a connecting sleeve; 53. an antistatic floor; 54. mounting holes; 55. a transparent viewing plate; 6. a guide bracket; 61. a guide rail; 62. a slider; 63. an upper half ring; 64. a lower half ring; 7. a hanging unit; 71. a boom; 72. a hanger; 73. a wire arranging base; 731. a partition portion; 74. a ground wire; 81. a ceiling plate; 82. and (7) a floor slab.

Detailed Description

In order to make the technical problems, technical solutions and advantageous effects to be solved by the present invention more clearly apparent, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

It will be understood that when an element is referred to as being "disposed on" another element, it can be directly on the other element or be indirectly on the other element. It will be understood that the terms "length," "width," "upper," "lower," "front," "rear," "top," "bottom," "inner," "outer," and the like are used in the orientation or positional relationship indicated in the drawings for ease of description and simplicity of description, and do not indicate or imply that the referenced device or element must have a particular orientation, be constructed in a particular orientation, and be constructed in a particular operation, and are therefore not to be considered limiting. The terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or several of that feature. In the description of the present invention, "a number" means two or more unless specifically limited otherwise.

Referring to fig. 1 to 12 together, a network equipment room installation structure provided by the present invention will now be described. The network equipment room installation structure comprises a data hall 1, a room unit 2, a lead unit 3 and a fire unit 4, wherein the room unit 2 is arranged in the data hall 1, a plurality of cold channels 21 are arranged in the room unit 2, and an electric cabinet 22 is arranged in the cold channels 21; the lead unit 3 is arranged at the top of the electrical cabinet 22, is positioned in the cold channel 21, and is used for supporting cables led out from the electrical cabinet 22; the fire fighting unit 4 comprises a mixed gas fire extinguishing assembly 41 distributed in the cold channel 21 and a spraying assembly 42 distributed outside the machine room.

The network equipment computer lab mounting structure that this embodiment provided, compared with the prior art, the network equipment computer lab mounting structure that this embodiment provided, set up a plurality of cold passageways 21 in order to carry out the installation of regulator cubicle 22 in unit 2 in the computer lab, cooling passageway feeds into air conditioning through the lower part and makes electrical components be in low temperature environment, avoid the too big anomaly that causes of electrical components heat, guarantee the normal operating of equipment, cold passageway 21 top is provided with lead wire unit 3, the cable in the regulator cubicle 22 gathers together to lead wire unit 3 in from the top, realize the reasonable laying of cable, mist fire extinguishing system can carry out fire protection to the region in the cold passageway 21, avoid electrical components because of spraying the damage that the fire extinguishing caused, other regional adoption are sprayed and are put out a fire, the overall cost is reduced.

In some possible implementations, the antistatic thermal insulation floor 5 with the above characteristics adopts the structure as shown in fig. 2 to 4. Referring to fig. 2 to 4, an antistatic heat-insulating floor 5 is arranged in the data hall, the antistatic heat-insulating floor 5 is located outside the cold channel 21, the antistatic heat-insulating floor 5 comprises a heat-insulating base layer 51, a mounting frame 52 and an antistatic floor 53, the heat-insulating base layer 51 is laid on the floor slab 82, and the heat-insulating base layer 51 comprises a plurality of bearing strips 511 arranged in parallel and a heat-insulating plate 512 arranged between two adjacent bearing strips 511; the mounting frame 52 comprises a plurality of supporting columns 521 arranged on the supporting strips 511 and a frame 522 arranged above the supporting columns 521, the frame 522 comprises longitudinal strips 523 arranged along the extending direction of the supporting strips 511 and transverse strips 524 arranged perpendicular to the extending direction of the supporting strips 511, and the supporting columns 521 are supported below the intersection points of the longitudinal strips 523 and the transverse strips 524; the antistatic floor 53 is laid above the frame 522;

the frame 522 is provided with a mounting hole 54 for mounting the electrical cabinet 22, and the antistatic floor 53 is distributed on the periphery of the electrical cabinet 22.

On heat preservation basic unit 51 laid floor 82, mounting bracket 52 maked somebody a mere figurehead antistatic floor 53 in heat preservation basic unit 51's top, support column 521 bears in frame 522's lower part angular point position, has guaranteed the structural stability of top component to lay antistatic floor 53, regulator cubicle 22 sets up in mounting hole 54, has saved antistatic floor 53's laying, has improved regulator cubicle 22's installation effectiveness, has saved manpower and financial resources and material resources.

In some embodiments, referring to fig. 2, the bottom of the frame 522 is provided with a plurality of connecting sleeves 525 extending in the up-down direction, and the supporting column 521 includes a bottom plate and a supporting leg, the bottom plate is located on the supporting strip 511; the landing leg is connected on the bottom plate along upper and lower direction, and is located the center of bottom plate, and the upper end and the connecting sleeve 525 threaded connection of landing leg.

Frame 522 bottom is provided with can with landing leg upper end threaded connection's connecting sleeve 525, connecting sleeve 525 sets up in the intersect below of vertical strip 523 and horizontal strip 524, and when the landing leg links to each other with connecting sleeve 525, can realize the connection effect through screw-thread fit, can also carry out the regulation of top frame 522 height, is convenient for guarantee the plane degree of frame 522 top surface, provides smooth plane for laying of follow-up antistatic floor 53.

In order to ensure that the bottom plate and the support legs have stable connection effect, rib plates are arranged between the bottom plate and the support legs to enhance the connection strength between the bottom plate and the support legs. Specifically, the plate surface of the rib plate extends along the vertical direction and is a triangular component. The rib plates are arranged on the periphery of the upper end of the supporting leg. The included angles between two adjacent rib plates are equal, so that the force between the supporting leg and the bottom plate is uniformly distributed.

In some embodiments, the above-described feature insulation board 512 may be configured as shown in fig. 4. Referring to fig. 4, the heat insulation board 512 includes an insulation layer 5121 and a rigid shell 5122 coated outside the insulation layer 5121, the rigid shell 5122 is a galvanized steel sheet member, and the thickness of the rigid shell 5122 is 0.5-1 mm; the heat insulation layer 5121 is made of rubber and plastic heat insulation cotton, and the thickness of the heat insulation layer 5121 is 20-30 mm; the antistatic floor 53 is a calcium sulfate member, and the thickness of the antistatic floor 53 is 25-35 mm;

the insulation board 512 is in a form of combining the insulation layer 5121 with the rigid shell 5122, the rigid shell 5122 can effectively protect the insulation board 512, and the overall service life of the insulation board 512 is prolonged.

In some embodiments, the rigid shell 5122 is a galvanized steel component, and the thickness of the rigid shell 5122 is 0.5-1 mm; the heat insulation layer 5121 is made of rubber and plastic heat insulation cotton, and the thickness of the heat insulation layer 5121 is 20-30 mm.

The heat preservation layer 5121 is made of rubber and plastic heat preservation cotton materials, the heat preservation layer 5121 is combined with the rigid shell 5122, the heat preservation effect is guaranteed, meanwhile, the heat preservation plate 512 has good structural rigidity, laying is facilitated, and construction efficiency is improved. The thickness of the heat insulation layer 5121 is 20-30mm, and the thickness value is selected to meet the heat insulation effect, reduce the cost of the structure and have good economical efficiency.

The rigid shell 5122 is made of galvanized steel sheets with good corrosion resistance, the thickness of each galvanized steel sheet is 0.5-1mm, the heat insulation layer 5121 can be effectively protected, and meanwhile, the heat insulation plate 512 has certain structural rigidity, and the stress performance of the heat insulation plate is improved.

On the basis of the structure, referring to fig. 3, the antistatic insulation floor 5 further comprises a transparent observation plate 55 arranged between two adjacent antistatic floors 53 at intervals, the transparent observation plate 55 is arranged on the mounting frame 52, and the top surface of the transparent observation plate 55 is flush with the antistatic floors 53. The antistatic floor 53 is a calcium sulfate member, and the thickness of the antistatic floor 53 is 25-35 mm. The transparent observation plate 55 is convenient for directly observing the condition of equipment below, helps to find abnormal conditions in time, improves the timeliness and effectiveness of maintenance, and has a good monitoring effect.

In some possible implementations, the fire fighting unit 4 described above is configured as shown in fig. 5. Referring to fig. 5, the fire fighting unit 4 further includes a detector 43 and a controller, the detector 43 being installed at the top of the data hall 1; the mixed gas fire extinguishing assembly 41 is provided with a starting valve, and the spraying assembly 42 is provided with a water inlet valve;

the controller is electrically connected with the detector 43, the starting valve and the water inlet valve respectively, and the controller can receive detection parameters of the detector 43 and send control instructions to the starting valve or the water inlet valve.

The detectors 43 are distributed in the data hall 1 in a plurality, some of the detectors 43 are distributed in the room unit 2, and some of the detectors are distributed outside the room unit 2. The machine room unit 2 is used for extinguishing fire in key areas with more electric elements by adopting mixed gas, conventional areas such as halls and corridors 11 are subjected to fire extinguishing operation by adopting the spraying fire extinguishing assembly, the overall cost of the fire extinguishing system is reduced, different areas in the data hall 1 are respectively monitored in real time by the aid of the detector 43, monitored parameters are fed back to the controller, the controller can conveniently start the water inlet valve or the starting valve according to a preset program, the spraying assembly 42 or the mixed gas fire extinguishing assembly 41 is correspondingly started, the processing speed when fire occurs is improved, the protection of important devices is realized, and the machine room unit has good economical efficiency.

In some embodiments, the feature detector 43 may be configured as shown in FIG. 6. Referring to fig. 6, a ceiling board 81 is arranged in the data hall 1, the detector 43 is embedded in the ceiling board 81, the upper end of the detector 43 is connected with a cable extending into the floor 82, a metal hose 44 is sleeved on the periphery of the cable between the ceiling board 81 and the floor 82, and a pre-buried steel pipe 45 for penetrating the cable is pre-buried in the floor 82.

In this embodiment, taking the data hall 1 as an example, the detector 43 is embedded in the ceiling plate 81 of the data hall 1, the cable above the detector 43 is inserted into the floor 82 through the embedded steel pipe 45, the cable is laid by the embedded steel pipe 45, and the embedded steel pipe 45 is used to protect the cable.

The cable above the detector 43, which is located between the ceiling plate 81 and the floor 82, can be protected by sleeving the metal hose 44 on the outer side of the cable, so that the cable is prevented from interfering with external components to cause damage, and the detector 43 can effectively monitor different positions.

In some embodiments, the above-described feature spray assembly 42 may be configured as shown in fig. 7 and 8. Referring to fig. 7 and 8, the shower assembly 42 includes a water supply pipe 46, the water supply pipe 46 being installed on a floor 82 of the data hall 1 through a guide bracket 6, the guide bracket 6 including a guide rail 61, a slider 62, an upper half ring 63, and a lower half ring 64, a top of the guide rail 61 being connected to a bottom surface of the floor 82 and extending in a horizontal direction; the slide block 62 is connected below the guide rail 61 in a sliding manner; the upper half ring 63 is connected to the bottom surface of the sliding block 62, and the opening of the upper half ring is arranged downwards; the lower half ring 64 is connected to the lower side of the upper half ring 63 through a connector and is used for being matched with the upper half ring 63 to be encircled around the water supply pipe 46.

The water supply pipe 46 is installed through the guide bracket 6, and the guide bracket 6 can enable the water supply pipe 46 to have axial displacement, so that the water supply pipe 46 can shift along the axial direction under the action of water pressure, and the damage of the water supply pipe 46 caused by rigid connection is avoided. The upper half ring 63 and the lower half ring 64 are encircled on the periphery of the water supply pipe 46 through a connecting piece, and are matched with the guide rail 61 in a sliding manner by utilizing the sliding block 62 above to match with the axial movement of the water supply pipe 46, so that the stability of the height of the water supply pipe 46 can be ensured, and the requirement of the axial movement can be met.

In some possible implementations, the above-mentioned characteristic lead unit 3 adopts the structure as shown in fig. 9 to 11. Referring to fig. 9 to 11, the lead unit 3 includes a support frame 31 and a cable tray 32, the support frame 31 includes two columns 311 disposed on the top of the electrical cabinet 22, and a support beam 312 connected to the upper ends of the two columns 311, the support beam 312 extends along the front-rear direction of the electrical cabinet 22; the cable tray 32 is disposed on the support beam 312 for supporting the cable, and the cable tray 32 extends from one side of the electrical cabinet 22 to the other side of the electrical cabinet 22.

Two pillars 311 of support frame 31 are with cable bracket 32 lifting take the altitude, the setting has cable bracket 32 at the supporting beam 312 bearing at two pillars 311 tops, cable bracket 32 can concentrate the bearing to crossing the downthehole cable of drawing forth of line, make cable bracket 32 make somebody a mere figurehead in support frame 31 top, make the interior cable of regulator cubicle 22 orderly draw in at regulator cubicle 22 top, the wiring mode of lead wire in the realization, be convenient for save occupation of exterior space, realize the maximize utilization of space, the security of circuit use has been improved.

In some embodiments, the cable tray 32 described above may be configured as shown in fig. 9-10. Referring to fig. 9 to 10, the cable bracket 32 is a mesh frame member formed by criss-cross steel bars, and two side edges of the cable bracket 32 are bent upwards to form side rails 321;

a wire passing hole for leading out a cable is formed in the electrical cabinet 22, and a guide plate 33 which is bent downwards in an arc shape and corresponds to the wire passing hole up and down is arranged on the inner bottom surface of the cable bracket 32;

the supporting beam 312 is provided with an upward opening, two side walls of the supporting beam 312 are bent outwards and downwards to extend and form a supporting part 313, and a plurality of clamping grooves 314 which are vertically communicated and are in clamping fit with the steel bars of the cable bracket 32 are arranged on the supporting part 313 at intervals.

The cable bracket 32 is a net frame member formed by combining criss-cross steel bars, so that the cable can be effectively supported, the cable can be conveniently cooled, and the consumption of materials can be greatly reduced by the cable bracket 32.

On this basis, the both sides edge of cable bracket 32 upwards bends and forms side rail 321, and side rail 321 can carry out effective spacing to the cable, makes the stable cable be in cable bracket 32, is convenient for keep the whole aesthetic property that the cable laid, avoids the cable to take place to bend the scheduling problem, the subsequent maintenance operation of being convenient for.

Be provided with on the bottom surface in the cable bracket 32 and lead the conveying board 33 to crossing the extension of line mouth position, lead the conveying board 33 can with the regulator cubicle 22 in the cable that upwards draws is smooth to lead to the cable bracket 32 in, the route of laying of the standard cable of being convenient for avoids the cable because of the local damage that the angle of bending is too little to cause, has guaranteed the security of cable laying process.

The openings of the support beams 312 are through in the direction of extension thereof, reducing material consumption while ensuring support strength. Two side walls of the supporting beam 312 are bent outwards to form a supporting part 313, and the reinforcing steel bars on the cable bracket 32 can be effectively clamped and limited by the clamping grooves 314 arranged on the supporting part 313, so that the stability of the cable bracket 32 is protected, and the cable is stably supported.

On this basis, the opening width of the support beam 312 gradually increases from bottom to top. The opening width of the bearing beam 312 gradually increases from bottom to top, namely the two side walls of the bearing beam extend upwards and outwards, the arrangement can enable the width of the upper part of the bearing beam 312 to be larger, the bearing effect on the cable bracket 32 is improved, and the stability of the bearing structure is ensured.

In some possible implementations, the characteristic hanging unit 7 is configured as shown in fig. 12. Referring to fig. 12, the network equipment room installation structure further includes a hanging unit 7 disposed above the cold channel 21 and connected to the lead unit 3, the hanging unit 7 is hung on the top of the room unit 2, the hanging unit 7 includes a hanger rod 71, a hanger bracket 72, a wire arranging base 73 and at least two ground wires 74, and the upper end of the hanger rod 71 is connected to a floor 82 through an expansion bolt; the hanger 72 is connected to the lower end of the boom 71 and extends in the horizontal direction; the wire arranging base 73 is arranged on the hanging rack 72, the wire arranging base 73 extends along the horizontal direction and is attached above the cables, and a plurality of separating parts 731 which are protruded downwards to separate two adjacent cables are arranged on the bottom surface of the wire arranging base 73; the ground line 74 is connected to the hanger 72 and to the ground rail.

When the cables are fed into the electrical cabinet 22 in the cold aisle 21, the cables are collectively led through the hanger unit 7. Hang unit 7 and hang on the floor 82 at computer lab unit 2 top, can adjust the height of hanging through jib 71, the stores pylon 72 is connected in jib 71 below, has ascending opening for the bearing cable. The wire arranging base 73 can comb the cables and keep the cables arranged to have good orderliness. The separating portion 731 disposed on the wire arranging seat 73 can separate the cables to be separated, so that the subsequent cables can be dispersed into the electrical cabinet 22. The ground wire 74 effectively connects the hanger 72 to the ground rail for good grounding.

The present invention is not limited to the above preferred embodiments, and any modifications, equivalent substitutions and improvements made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. Network equipment computer lab mounting structure, its characterized in that includes:

a data hall;

the computer room unit is arranged in the data hall, a plurality of cold channels are arranged in the computer room unit, and the electrical cabinets are arranged in the cold channels;

the lead unit is arranged at the top of the electrical cabinet, is positioned in the cold channel and is used for bearing the cable led out from the electrical cabinet;

and the fire-fighting unit comprises mixed gas fire-extinguishing components distributed in the cold channel and spraying components distributed outside the machine room.

2. The network equipment room mounting structure of claim 1, wherein an antistatic insulation floor is provided in the data hall, the antistatic insulation floor being located outside the cold aisle, the antistatic insulation floor comprising:

the heat insulation base layer is laid on the floor slab and comprises a plurality of parallel bearing strips and a heat insulation plate arranged between every two adjacent bearing strips;

the mounting frame comprises a plurality of supporting columns arranged on the bearing strips and a frame arranged above the supporting columns, the frame comprises longitudinal strips arranged along the extending direction of the bearing strips and transverse strips arranged perpendicular to the extending direction of the bearing strips, and the supporting columns are supported below the intersection points of the longitudinal strips and the transverse strips;

the antistatic floor is laid above the frame;

the frame is provided with mounting holes for mounting the electrical cabinet, and the antistatic floor is distributed on the periphery of the electrical cabinet.

3. The network equipment room mounting structure of claim 2, wherein the bottom of the frame is provided with a plurality of connecting sleeves extending in an up-down direction, and the supporting column comprises:

the bottom plate is positioned on the bearing strip;

the supporting legs are connected to the bottom plate in the up-down direction and located in the center of the bottom plate, and the upper ends of the supporting legs are in threaded connection with the connecting sleeves.

4. The network equipment room mounting structure of claim 3, wherein the heat insulation board comprises a heat insulation layer and a rigid shell covering the heat insulation layer, the rigid shell is a galvanized steel sheet member, and the thickness of the rigid shell is 0.5-1 mm; the heat-insulating layer is made of rubber and plastic heat-insulating cotton, and the thickness of the heat-insulating layer is 20-30 mm; the antistatic floor is a calcium sulfate component, and the thickness of the antistatic floor is 25-35 mm;

the antistatic heat-insulation floor further comprises transparent observation plates arranged between every two adjacent antistatic floors at intervals, the antistatic floors are calcium sulfate members, and the thickness of each antistatic floor is 25-35 mm.

5. The network equipment room mounting structure of claim 1, wherein the fire fighting unit further comprises a probe mounted at the top of the data hall and a controller; the mixed gas fire extinguishing assembly is provided with a starting valve, and the spraying assembly is provided with a water inlet valve;

the controller is electrically connected with the detector, the starting valve and the water inlet valve respectively, and can receive detection parameters of the detector and send control instructions to the starting valve or the water inlet valve.

6. The network equipment room installation structure of claim 5, wherein a ceiling plate is arranged in the data hall, the detector is embedded in the ceiling plate, the upper end of the detector is connected with a cable extending into a floor plate, a metal hose is sleeved on the periphery of the cable between the ceiling plate and the floor plate, and an embedded steel pipe for penetrating the cable is embedded in the floor plate.

7. The network equipment room mounting structure of claim 6, wherein the spray assembly includes a water supply pipe mounted on a floor of the data hall through a guide bracket, the guide bracket including:

the top of the guide rail is connected with the bottom surface of the floor slab and extends along the horizontal direction;

the sliding block is connected below the guide rail in a sliding manner;

the upper half ring is connected to the bottom surface of the sliding block, and an opening of the upper half ring is arranged downwards;

and the lower half ring is connected below the upper half ring through a connecting piece and is used for matching with the upper half ring to be embraced on the periphery of the water supply pipe.

8. The network equipment room mounting structure of any one of claims 1 to 7, wherein the lead wire unit includes:

the supporting frame comprises two supporting columns arranged at the top of the electric cabinet and a supporting beam connected to the upper ends of the two supporting columns, and the supporting beam extends along the front-back direction of the electric cabinet;

the cable bracket is arranged on the supporting beam and used for supporting a cable, and the cable bracket extends from one side of the electrical cabinet to the other side of the electrical cabinet.

9. The network equipment room mounting structure of claim 8, wherein the cable bracket is a mesh frame member formed by criss-cross steel bars, and two side edges of the cable bracket are bent upwards and extend to form side rails;

the electrical cabinet is provided with a wire passing hole for leading out the cable, and the inner bottom surface of the cable bracket is provided with a guide plate which is bent downwards in an arc shape and corresponds to the wire passing hole up and down;

the bearing beam is provided with an upward opening, the two side walls of the bearing beam bend towards the outer lower part and extend to form a bearing part, and a plurality of clamping grooves which are communicated up and down and are in clamping fit with the steel bars of the cable bracket are arranged on the bearing part at intervals.

10. The network equipment room mounting structure of any one of claims 1 to 7, further comprising a hanging unit disposed above the cold aisle and connected to the lead unit, wherein the hanging unit is hung on a top of the room unit, and the hanging unit comprises:

the upper end of the suspender is connected to the floor slab through an expansion bolt;

the hanging rack is connected to the lower end of the hanging rod and extends along the horizontal direction;

the wire arranging seat is arranged on the hanging rack, extends along the horizontal direction and is attached above the cables, and a plurality of separating parts protruding downwards to separate two adjacent cables are arranged on the bottom surface of the wire arranging seat;

and the at least two ground wires are respectively connected to the hanging rack and are connected with the grounding trunk line.

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