CN211236783U - High-performance multi-hard-disk network management machine - Google Patents

Abstract

The utility model discloses a high-performance multi-hard-disk network management machine, which comprises a shell, and a mainboard, a power supply, a memory card, a first hard disk, a second hard disk and a third hard disk which are arranged in the shell; the shell comprises a bottom shell and a cover plate which is detachably covered above the bottom shell; the first hard disk is provided with a plurality of first hard disks forming a first hard disk module, the front side of the bottom shell is provided with a first spacing frame, and the first spacing frame divides the front side of the accommodating space into a first upper accommodating cavity and a first lower accommodating cavity; a support frame is detachably arranged in the first upper accommodating cavity, and the first hard disk module is arranged on the support frame; the support frame is provided with a plurality of mounting cavities, each mounting cavity is internally provided with a guide rail, and each first hard disk is slidably mounted on the guide rail; borrow this, it has realized the detachable setting of hard disk, provides convenience to the hard disk and dismantlement, is favorable to the function upgrade and the extension of server, has strengthened the functionality.

Description

High-performance multi-hard-disk network management machine

Technical Field

The utility model relates to a communication equipment field technique especially indicates a many hard disks of high performance network management machine.

Background

The communication manager is also called as a DPU or a gateway, and has a plurality of downlink communication interfaces and one or more uplink network interfaces, and is equivalent to a front-end processor, i.e. a monitoring computer, and is used for organizing and aggregating the communication data of all the intelligent monitoring/protection devices in a substation, and then sending the communication data to an upper-level main station system (a monitoring center background machine and a DCS) to complete remote communication and remote measurement functions. On the other hand, the remote control system receives commands issued by a background machine or a DCS and forwards the commands to an intelligent series unit in a substation, completes remote control of opening and closing of each switching device in a station or parameter setting of the device, and realizes remote control and remote regulation functions. Meanwhile, a plurality of serial interfaces are provided to facilitate communication among other intelligent devices in the plant station. The communication management machine is generally applied to a substation and a dispatching station, the communication management machine controls downlink equipment through a control platform to realize acquisition of information such as remote signaling, remote measurement and remote control, the information is fed back to a dispatching center, and then a control center administrator selects a command to be executed through processing and analysis of the information to achieve the aim of outputting the dispatching command.

The existing communication management machine is usually designed on structures and elements aiming at enhancing various places, various applicable requirements and performances, such as adding expansion cards, hard disks and the like; however, the existing communication management machine usually arranges the hard disk in the host machine, and the hard disk is inconvenient to disassemble and assemble after being assembled, so that when the communication management machine encounters an emergency in the use process, the communication management machine can only take measures of shutting down and then replacing and maintaining, thereby affecting the normal work; and the number of internal hard disks is limited, so that more functional requirements and expansion cannot be met.

Therefore, a new technology needs to be developed to solve the above problems.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model discloses to the disappearance that prior art exists, its main objective is to improve a many hard disks of high performance network management machine, and it has realized the detachable setting of hard disk, and the dismantlement that provides convenience to hard disk and is favorable to the function upgrade and the extension of server, has strengthened the functionality.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a high-performance multi-hard-disk network management machine comprises a shell, and a main board, a power supply, a memory card, a first hard disk, a second hard disk and a third hard disk which are arranged in the shell;

the shell comprises a bottom shell and a cover plate which is detachably covered above the bottom shell; the bottom shell is provided with an accommodating space, the mainboard is positioned in the right lower side area of the middle part of the accommodating space, the memory card is arranged above the mainboard, the first hard disk is positioned at the front side of the accommodating space, and the second hard disk is positioned in the left rear side area of the accommodating space; the third hard disk is positioned at the left front side of the accommodating space and below the first hard disk;

the first hard disk is provided with a plurality of first hard disks forming a first hard disk module, the front side of the bottom shell is provided with a first spacing frame, and the first spacing frame divides the front side of the accommodating space into a first upper accommodating cavity and a first lower accommodating cavity; a support frame is detachably arranged in the first upper accommodating cavity, and the first hard disk module is arranged on the support frame; the support frame is provided with a plurality of mounting cavities, each mounting cavity is internally provided with a guide rail, each first hard disk is slidably mounted on the guide rail, a PCB back plate is vertically arranged at the rear side of the support frame, the PCB back plate is provided with a first interface end corresponding to each mounting cavity, each first hard disk is provided with a second interface end, and the second interface end is connected with the corresponding first interface end in a pluggable manner; the third hard disk is positioned on the left side of the first lower accommodating cavity; the PCB back plate is connected with the main plate and is connected with the left end and the right end of the bottom shell through a cross beam;

the second hard disks are arranged in parallel in sequence along the front-back direction, a second partition frame is arranged on the left back side of the bottom shell, the left back side of the accommodating space is divided into a second upper accommodating cavity and a second lower accommodating cavity by the second partition frame, the second hard disks are located in the second upper accommodating cavity, and the power supply is located in the second lower accommodating cavity.

As a preferred scheme, the two ends of the cross beam are respectively connected to the left side and the right side of the bottom shell, the lower end of the cross beam is connected with a vertical positioning plate, and the PCB backboard is vertically positioned at the front side of the vertical positioning plate.

As a preferred scheme, a fan mounting frame is arranged on the rear side of the vertical positioning plate, and a first cooling fan is arranged on the fan mounting frame.

As a preferred scheme, a plurality of expansion cards are arranged on the right side of the first lower accommodating cavity, the expansion cards are arranged in a left-right side-by-side manner, and the third hard disk is located on the left side of the leftmost expansion card.

Preferably, the left side of the second partition frame is connected to the left side wall of the bottom case, the right side of the second partition frame integrally extends to the outside to form a front side extension and a rear side extension, and the upper side and the lower side of the front side extension and the lower side of the rear side extension are respectively provided with an upper connecting part and a lower connecting part which are protruded upwards and downwards.

As a preferred scheme, a supporting plate is arranged on the bottom shell, the front end and the rear end of the supporting plate are respectively connected to the rear side walls of the cross beam and the bottom shell, the upper connecting part is connected to the supporting plate, and the lower connecting part is connected to the inner bottom of the bottom shell.

As a preferable scheme, a second heat dissipation fan is disposed at a rear side of the second hard disk, and the second heat dissipation fan is located in an upper left area of a rear side wall of the bottom case.

Preferably, a third heat dissipation fan is disposed at a rear side of the main board, and the third heat dissipation fan is located in a lower right area of the rear sidewall of the bottom case.

As a preferred scheme, the heat dissipation modules are further arranged above the main board, the number of the heat dissipation modules is two, and the two heat dissipation modules are arranged at left and right intervals.

As a preferable scheme, 12 first hard disks are provided, the 12 first hard disks are arranged in three rows and stacked up and down, correspondingly, 12 mounting cavities are provided, and the 12 mounting cavities are arranged in three rows and stacked up and down.

Compared with the prior art, the utility model has obvious advantages and beneficial effects, concretely speaking, according to the technical scheme, the first hard disk module is detachably arranged in the first upper holding cavity by forming a plurality of first hard disks into the first hard disk module, and the first hard disk module is arranged on the support frame, thereby realizing the modular design of the hard disks, and simultaneously realizing the overall detachable arrangement of the hard disk module, and facilitating the assembly and later maintenance of the hard disk module; particularly, the support frame is provided with the mounting cavity, and the guide rail is arranged in the mounting cavity, so that the first hard disk can be slidably mounted on the guide rail, the first hard disk is detachably arranged, and the hard disk is convenient to detach; and through the combined design of the first hard disk, the second hard disk and the third hard disk, the function upgrading and the function expansion of the server are facilitated, and the functionality is enhanced.

To more clearly illustrate the structural features and technical means of the present invention and the specific objects and functions achieved thereby, the present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

Drawings

FIG. 1 is a schematic diagram of the overall structure of an embodiment of the present invention;

FIG. 2 is an exploded view of an embodiment of the present invention;

FIG. 3 is another exploded view of an embodiment of the present invention;

FIG. 4 is a further exploded view of an embodiment of the present invention;

fig. 5 is a schematic structural diagram of a second spacer according to an embodiment of the present invention.

The attached drawings indicate the following:

10. casing 11, bottom shell

12. Cover plate 20 and main board

30. Power supply 40 and memory card

50. First hard disk 60 and second hard disk

70. Third hard disk 80, PCB backboard

101. A first upper accommodating cavity

102. First lower accommodating cavity 103 and support frame

1031. Mounting cavity 1032 and guide rail

201. First spacer 202 and second spacer

2021. Front side extension 2022, rear side extension

2023. Upper connection part 2024, lower connection part

301. Crossbeam 302, vertical locating plate

303. Fan mounting frame 401 and first cooling fan

402. A second heat dissipation fan 403 and a third heat dissipation fan

404. Fourth radiator fan 501, support plate

502. And a heat dissipation module.

Detailed Description

Please refer to fig. 1 to 5, which show the specific structure of the embodiment of the present invention; the computer comprises a shell 10, a mainboard 20, a power supply 30, a memory card 40, a first hard disk 50, a second hard disk 60 and a third hard disk 70, wherein the mainboard 20, the power supply 30, the memory card 40, the first hard disk 50, the second hard disk 60 and the third hard disk 70 are arranged in the shell 10; wherein:

the shell 10 comprises a bottom shell 11 and a cover plate 12 which is detachably covered on the bottom shell 11; the bottom case 11 has an accommodating space, the main board 20 is located in a right lower area of the middle of the accommodating space, the memory card 40 is disposed above the main board 20, the first hard disk 50 is located in a front side of the accommodating space, and the second hard disk 60 is located in a left rear area of the accommodating space; the third hard disk 70 is located at the left front side of the accommodating space and below the first hard disk 50.

Specifically, the first hard disk 50 has a plurality of first hard disks 50, the plurality of first hard disks 50 form a first hard disk module, a first partition frame 201 is disposed on the front side of the bottom case 11, and the first partition frame 201 divides the front side of the accommodating space into a first upper accommodating cavity 101 and a first lower accommodating cavity 102; a support frame 103 is detachably arranged in the first upper accommodating cavity 101, and the first hard disk module is arranged on the support frame 103; the supporting frame 103 has a plurality of mounting cavities 1031, each mounting cavity 1031 is internally provided with a guide rail 1032, each first hard disk 50 is slidably mounted on the guide rail 1032, a PCB back plate 80 is vertically arranged at the rear side of the supporting frame 103, the PCB back plate 80 is provided with a first interface end corresponding to each mounting cavity 1031, each first hard disk 50 is provided with a second interface end, and the second interface end is connected with the corresponding first interface end in a pluggable manner; the third hard disk 70 is positioned at the left side of the first lower accommodating cavity 102; the PCB backplate 80 is connected to the main board 20, and the PCB backplate 80 is connected to the left and right ends of the bottom case 11 through a cross beam 301; the second hard disks 60 are plural, the plural second hard disks 60 are sequentially arranged side by side along the front-back direction, a second spacer 202 is arranged on the left back side of the bottom case 11, the left back side of the accommodating space is divided into a second upper accommodating cavity and a second lower accommodating cavity by the second spacer 202, the plural second hard disks 60 are located in the second upper accommodating cavity, and the power supply 30 is located in the second lower accommodating cavity.

Two ends of the cross beam 301 are respectively connected to the left side and the right side of the bottom case 11, the lower end of the cross beam 301 is connected with a vertical positioning plate 302, and the PCB backboard 80 is vertically positioned at the front side of the vertical positioning plate 302; in addition, in the embodiment, the cross beam 301 is provided with a plurality of connecting holes for positioning the cover plate 12 above the cross beam 301, so as to ensure the stable positioning of the cover plate 12.

A fan mounting rack 303 is arranged at the rear side of the vertical positioning plate 302, and a first cooling fan 401 is arranged on the fan mounting rack 303; a second heat dissipation fan 402 is disposed at the rear side of the second hard disk 60, and the second heat dissipation fan 402 is located in the upper left area of the rear sidewall of the bottom case 11; a third heat dissipation fan 403 is disposed at the rear side of the main board 20, and the third heat dissipation fan 403 is located in a lower right area of the rear sidewall of the bottom case 11; in addition, in the present embodiment, a fourth heat dissipation fan 404 is also disposed at the rear side of the power supply 30; therefore, through the combination design of the first heat dissipation fan 401, the second heat dissipation fan 402, the third heat dissipation fan 403 and the fourth heat dissipation fan 404, the different internal structures can be subjected to dispersive heat dissipation, the purpose of targeted heat dissipation is achieved, and meanwhile, the overall heat dissipation performance is improved.

A plurality of expansion cards are arranged on the right side of the first lower accommodating cavity 102, the expansion cards are arranged in a left-right side-by-side manner, and the third hard disk 70 is positioned on the left side of the leftmost expansion card; the overall performance of the expansion card can be improved by arranging the expansion cards.

The left side of the second partition frame 202 is connected to the left side wall of the bottom case 11, the right side of the second partition frame 202 integrally extends a front extension 2021 and a rear extension 2022 outward, and the upper and lower sides of the front extension 2021 and the rear extension 2022 are respectively provided with an upper connecting portion 2023 and a lower connecting portion 2024 protruding upward and downward; the bottom case 11 is provided with a supporting plate 501, the front end and the rear end of the supporting plate 501 are respectively connected to the cross beam 301 and the rear side wall of the bottom case 11, the upper connecting portion 2023 is connected to the supporting plate 501, and the lower connecting portion 2024 is connected to the inner bottom of the bottom case 11. Therefore, the second spacer 202 is assembled on the bottom case 11 and the supporting plate 501, so that the positioning is more stable, and the second hard disk 60 is stably supported. Preferably, in this embodiment, three second hard disks 60 are provided, and the three second hard disks 60 are sequentially arranged in a front-back side-by-side manner.

Preferably, in this embodiment, two heat dissipation modules 502 are further disposed above the motherboard 20, and the two heat dissipation modules 502 are disposed at a left-right interval; with the setting through heat dissipation module 502, reach and effectively dispel the heat to mainboard 20, guarantee the purpose of the operation of mainboard 20 normal work.

Preferably, in this embodiment, 12 first hard disks 50 are provided, 12 first hard disks 50 are arranged in three rows and stacked up, and correspondingly, 12 mounting chambers 1031 are provided, and 12 mounting chambers 1031 are arranged in three rows and stacked up.

To sum up, the design of the utility model is characterized in that a plurality of first hard disks are formed into a first hard disk module, a support frame is detachably arranged in a first upper accommodating cavity, and the first hard disk module is arranged on the support frame, so that the modular design of the hard disks is realized, and meanwhile, the overall detachable arrangement of the hard disk module is realized, thereby facilitating the assembly and later maintenance of the hard disk module; particularly, the support frame is provided with the mounting cavity, and the guide rail is arranged in the mounting cavity, so that the first hard disk can be slidably mounted on the guide rail, the first hard disk is detachably arranged, and the hard disk is convenient to detach; and through the combined design of the first hard disk, the second hard disk and the third hard disk, the function upgrading and the function expansion of the server are facilitated, and the functionality is enhanced.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the technical scope of the present invention, so that any slight modifications, equivalent changes and modifications made by the technical spirit of the present invention to the above embodiments are all within the scope of the technical solution of the present invention.

Claims (10)

1. A high-performance multi-hard-disk network management machine is characterized in that: the computer comprises a shell, and a mainboard, a power supply, a memory card, a first hard disk, a second hard disk and a third hard disk which are arranged in the shell;

the shell comprises a bottom shell and a cover plate which is detachably covered above the bottom shell; the bottom shell is provided with an accommodating space, the mainboard is positioned in the right lower side area of the middle part of the accommodating space, the memory card is arranged above the mainboard, the first hard disk is positioned at the front side of the accommodating space, and the second hard disk is positioned in the left rear side area of the accommodating space; the third hard disk is positioned at the left front side of the accommodating space and below the first hard disk;

the first hard disk is provided with a plurality of first hard disks forming a first hard disk module, the front side of the bottom shell is provided with a first spacing frame, and the first spacing frame divides the front side of the accommodating space into a first upper accommodating cavity and a first lower accommodating cavity; a support frame is detachably arranged in the first upper accommodating cavity, and the first hard disk module is arranged on the support frame; the support frame is provided with a plurality of mounting cavities, each mounting cavity is internally provided with a guide rail, each first hard disk is slidably mounted on the guide rail, a PCB back plate is vertically arranged at the rear side of the support frame, the PCB back plate is provided with a first interface end corresponding to each mounting cavity, each first hard disk is provided with a second interface end, and the second interface end is connected with the corresponding first interface end in a pluggable manner; the third hard disk is positioned on the left side of the first lower accommodating cavity; the PCB back plate is connected with the main plate and is connected with the left end and the right end of the bottom shell through a cross beam;

the second hard disks are arranged in parallel in sequence along the front-back direction, a second partition frame is arranged on the left back side of the bottom shell, the left back side of the accommodating space is divided into a second upper accommodating cavity and a second lower accommodating cavity by the second partition frame, the second hard disks are located in the second upper accommodating cavity, and the power supply is located in the second lower accommodating cavity.

2. The high-performance multi-hard-disk network manager according to claim 1, wherein: the two ends of the cross beam are connected to the left side and the right side of the bottom shell respectively, the lower end of the cross beam is connected with a vertical positioning plate, and the PCB backboard is vertically positioned at the front side of the vertical positioning plate.

3. The high-performance multi-hard-disk network manager according to claim 2, wherein: the rear side of the vertical positioning plate is provided with a fan mounting frame, and a first cooling fan is arranged on the fan mounting frame.

4. The high-performance multi-hard-disk network manager according to claim 1, wherein: the right side of the first lower accommodating cavity is provided with a plurality of expansion cards, the expansion cards are arranged in a left-right side-by-side mode, and the third hard disk is located on the left side of the leftmost expansion card.

5. The high-performance multi-hard-disk network manager according to claim 1, wherein: the left side of the second partition frame is connected to the left side wall of the bottom shell, a front side extension portion and a rear side extension portion integrally extend outwards from the right side of the second partition frame, and an upper connecting portion and a lower connecting portion are respectively arranged on the upper side and the lower side of the front side extension portion and the lower side of the rear side extension portion in a protruding mode upwards and downwards.

6. The high-performance multi-hard-disk network manager according to claim 5, wherein: the bottom shell is provided with a supporting plate, the front end and the rear end of the supporting plate are respectively connected to the rear side walls of the cross beam and the bottom shell, the upper connecting portion is connected to the supporting plate, and the lower connecting portion is connected to the inner bottom of the bottom shell.

7. The high-performance multi-hard-disk network manager according to claim 1, wherein: and a second heat radiation fan is arranged at the rear side of the second hard disk and is positioned in the upper left area of the rear side wall of the bottom shell.

8. The high-performance multi-hard-disk network manager according to claim 1, wherein: the rear side of mainboard is provided with the third radiator fan, third radiator fan is located the right downside region of the back side wall of drain pan.

9. The high-performance multi-hard-disk network manager according to claim 1, wherein: the heat dissipation module is arranged above the mainboard, the number of the heat dissipation modules is two, and the two heat dissipation modules are arranged at the left and right intervals.

10. The high-performance multi-hard-disk network manager according to claim 1, wherein: the number of the first hard disks is 12, the 12 first hard disks are arranged in a three-row up-down stacked mode, correspondingly, the number of the installation cavities is 12, and the 12 installation cavities are arranged in a three-row up-down stacked mode.

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