CN210244283U

CN210244283U - Node distributed device

Info

Publication number: CN210244283U
Application number: CN201921635339.3U
Authority: CN
Inventors: Jinchang Han; 韩金倡; Wei Chen; 陈威
Original assignee: Hangzhou Jiuzhou Fang Yuan Technology Co ltd
Current assignee: Hangzhou Jiuzhou Fang Yuan Technology Co ltd
Priority date: 2019-09-26
Filing date: 2019-09-26
Publication date: 2020-04-03
Anticipated expiration: 2029-09-26

Abstract

The utility model provides a pair of node distributing type device, including a plurality of servers, a plurality of switch and a plurality of pile fold line, every server includes quick-witted case, hard disk, network card equipment, disk array card and treater, quick-witted case is the cuboid, quick-witted incasement is provided with a plurality of positions in a storehouse, the treater is located quick-witted incasement, the hard disk is connected in quick-witted incasement position in a storehouse, network card equipment is connected in quick-witted incasement position in a storehouse, disk array card is connected in quick-witted incasement position in a storehouse, the hard disk network card equipment disk array card all with the treater communication, a plurality of switches pass through a plurality of pile fold lines are piled up, every server all with every switch communication, the device has optimized resource distribution, has reduced the fortune dimension cost.

Description

Node distributed device

Technical Field

The utility model relates to the field of communication, especially, relate to a node distributing type device.

Background

Currently, in some data centers, the architecture of a traditional storage, switch network, server, or a distributed architecture like that implemented based on installing corresponding storage virtualization software in an operating system is also adopted. The traditional architectures of storage, switch networks and servers cannot flexibly realize the unified allocation and management of storage, networks and computing resources and the reasonable integration and utilization of resources to achieve the reasonable utilization of the resources, and the capacity expansion capability of the traditional architectures is limited by multiple parties when the resources are insufficient in the future. The class distributed architecture realizes software definition of storage only through storage virtualization software, the technology only realizes pooling of storage, and as a matter of fact, the technology has the defects of unreasonable resource distribution and separation of management and computing resources as conventional storage, only frees storage on a conventional server, reduces corresponding cost and difficulty of capacity expansion, and if the performance requirement of an application system is burst and the network load is increased rapidly, the load capacity and the processing capacity of software are influenced to a certain extent, and future development of a data center cannot be met.

SUMMERY OF THE UTILITY MODEL

The utility model provides a pair of node distributing type device aims at solving among the prior art resource allocation unreasonable, the higher weak point of fortune dimension cost.

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

the utility model discloses a node distributing type device, including a plurality of servers, a plurality of switches and a plurality of pile folded line, every server includes quick-witted case, hard disk, network card equipment, disk array card and treater, quick-witted case is the cuboid, quick-witted incasement is provided with a plurality of positions in a storehouse, the treater is located quick-witted incasement, the hard disk is connected in quick-witted incasement position in a storehouse, network card equipment is connected in quick-witted incasement position in a storehouse, disk array card is connected in quick-witted incasement position in a storehouse, the hard disk network card equipment the disk array card all with the treater communication, a plurality of switches pass through a plurality of pile folded lines pile up, every server all with every switch communication.

The distributed technology has the capacity of unified management and free allocation of storage, network and computing resources, the simplification of each resource management and the improvement of capacity expansion capacity are realized, the operation and maintenance pressure and the capacity expansion cost can be greatly reduced, and the resources can be allocated more reasonably by integrating the storage equipment into the server.

Preferably, each bin in the case is provided with at least four screw holes, and the hard disk, the network card device and the disk array card are all connected in the bin in the case through at least four screws.

The screw can firmly connect the hard disk, the network card equipment and the disk array card in the bin, and prevent the equipment from displacing and damaging.

Preferably, the hard disk comprises a solid state disk and a mechanical hard disk, and the solid state disk is provided with metal cooling fins.

The solid state disk and the mechanical hard disk are used for different storage layers, storage performance is improved, and the radiating fins can accelerate heat dissipation, so that the solid state disk can work more stably.

Preferably, the case is provided with heat dissipation holes, and the case is internally provided with a fan radiator which dissipates heat through the heat dissipation holes.

The heat dissipation holes and the fan radiator can better dissipate heat, and damage caused by overheating of equipment is prevented.

Preferably, a press-down type heat sink is arranged on the processor, and the press-down type heat sink is connected to the processor through a buckle.

The press-down radiator can quickly radiate heat generated by the processor, and is connected in a buckling mode, so that the replacement is convenient.

Preferably, the solid state disk is provided with an outer rail, the outer rail is provided with a groove, the metal heat sink is provided with an inner rail, and the outer rail is connected with the inner rail in a sliding mode through the groove.

The solid state disk and the radiating fins are connected through the inner rail and the outer rail, and the radiating fins are convenient to detach and replace.

Preferably, a layer of dust screen is arranged on the heat dissipation holes, and the dust screen is adsorbed on the heat dissipation holes through magnets.

Dust is easily accumulated on the heat dissipation holes, the dust screen is used for preventing dust accumulation, and the magnetic type dust screen is easy to disassemble and convenient to clean.

Preferably, the buckle includes pin thread and box, the pin thread is connected on the lower pressure formula radiator, the box is connected on the treater, the pin thread with the box all has the direction oblique angle, pin thread elastic arm warp to impress the box, the elastic arm warp and intensity is enough, the pin thread with the box laminating.

The buckle can fix the radiator on the treater, and convenient dismantlement, maintenance are again simultaneously.

The utility model discloses following beneficial effect has:

through setting up the radiator, dispel the heat fast to equipment, prevent that equipment from overheating from producing the damage, distributed technology itself has the unified management and the free allocation ability to storage, network, computational resource, has realized the simplification of each resource management and the promotion of dilatation ability, can greatly reduced fortune dimension pressure and dilatation cost, sets up different hard disks and is used for the storage aspect, rationally distributes the resource, promotes equipment operation performance.

Drawings

The following drawings are only for the purpose of enabling those skilled in the art to better understand the technical solution of the present invention, and are not intended to limit the scope of the present invention.

Fig. 1 is a front view of a node distributed device server according to the present invention;

fig. 2 is an exemplary diagram of a node distributed apparatus according to the present invention;

fig. 3 is a schematic diagram illustrating connection between inner rails and outer rails of a node-distributed apparatus according to the present invention;

fig. 4 is the utility model discloses a node distributing type device buckle sketch map.

Detailed Description

The invention will be further described with reference to the drawings and the detailed description, wherein the following examples are given by way of illustration only and are not intended to limit the invention.

Before introducing the present invention, an exemplary scenario in which the present invention may be applied is introduced.

The following are exemplary: the traditional architectures of storage, switch networks and servers cannot flexibly realize the unified allocation and management of storage, networks and computing resources and the reasonable integration and utilization of resources to achieve the reasonable utilization of the resources, the capacity expansion capacity of the traditional architectures is limited by multiple parties when the resources are insufficient in the future, and the requirements of the traditional architectures on the resources cannot be met in a future data center.

The similar distributed architecture realizes software definition of storage only through storage virtualization software, the technology only realizes pooling of storage, and the technology has the defects of unreasonable resource distribution and separation of management and computing resources as in the conventional storage, only frees the storage on the conventional server, reduces corresponding cost and difficulty of capacity expansion, and if the performance requirement of an application system is outburst and the network load is increased sharply, the load capacity and the processing capacity of the software are influenced to a certain extent, so that the future development of a data center cannot be met.

Combine foretell suitable scene right the utility model discloses further introduce:

illustratively, as shown in fig. 1 and fig. 2, a node distribution apparatus includes a plurality of servers 1, a plurality of switches 10 and a plurality of stacking lines 9, each server 1 comprises a case 16, a hard disk, a network card device 4, a disk array card 5 and a processor 7, the case 16 is a cuboid, a plurality of bins are arranged in the case 16, the processor 7 is positioned in the case 16, the hard disk is connected in the bin in the case 16, the network card device 4 is connected in the bin in the case 16, the disk array card 5 is connected in a bin in the case 16, the hard disk, the network card device 4 and the disk array card 5 are all communicated with the processor 7, the plurality of switches 10 are stacked by the plurality of stacking lines 9, and each server 1 communicates with each switch 10.

One possible embodiment: four servers 1 which are commonly used in the market; configuring a certain number of hard disks, tera network cards, disk array cards 5 and processors 7; each of the two commercially available ten-gigabit switches 10 is provided with four modules and two stacking lines 9, so that the two switches 10 are stacked; the installation of a bottom operating system, a virtualized system popular in the market and at least three nodes; the memory of the single-node host is not lower than 8 GB; the single node host needs at least one solid state disk 2 as a cache layer device; the single node host needs at least one mechanical hard disk 3 as capacity layer equipment; the single node host computer at least needs a disk controller, a direct connection mode or a just a bunch of disks (JBOD) mode; the single node host needs at least one trillion network card device 4 with two ports.

The software definition of storage, calculation and network is realized on the bottom operating system level, and the compatibility test with various hardware manufacturers on the market is wide, so that the wide hardware platform selection is achieved. The distributed technology has the capacity of unified management and free allocation of storage, network and computing resources, the simplification of each resource management and the improvement of capacity expansion capacity are realized, and the operation and maintenance pressure and the capacity expansion cost can be greatly reduced.

In an exemplary node-distributed apparatus, each bay in the chassis 16 is at least provided with four screw holes, and the hard disk, the network card device 4, and the disk array card 5 are all connected in the bay in the chassis 16 by at least four screws.

One possible embodiment: four positions of each bin are respectively provided with a screw hole, and the hard disk, the network card equipment 4 and the disk array card 5 are fixed on the bin by four screws.

The screw can firmly connect the hard disk, the network card device 4 and the disk array card 5 to the bin position, and prevent each device from displacing, thereby causing damage.

Illustratively, the hard disks comprise a solid state disk 2 and a mechanical hard disk 3, and the solid state disk 2 is provided with a metal heat sink 11.

One possible embodiment: the solid state disk 2 is used as a cache level device, and the mechanical hard disk 3 is used as a capacity level device.

Different hard disks are configured to serve as storage devices on different layers, the running performance of the system can be improved, and the radiating fins can radiate heat for the solid state disk 2, so that the solid state disk 2 can continuously and stably work.

In an exemplary node distribution type device, the chassis 16 is provided with heat dissipation holes, the chassis 16 is provided with a fan radiator 8 therein, and the fan radiator 8 radiates heat through the heat dissipation holes.

Because equipment needs to work for a long time, can produce more heat, if not in time dispel the heat, in case equipment high temperature can cause equipment to damage, so need set up louvre and fan and dispel the heat, a possible embodiment: the host is provided with heat dissipation holes, the fan is aligned to the heat dissipation holes, wind power generated by the fan dissipates heat generated by the equipment through the heat dissipation holes, and the size and the shape of the heat dissipation holes are not limited.

Set up louvre and fan, can in time dispel the heat that equipment produced, guarantee that equipment lasts the operation steadily, set up the louvre and be favorable to the fan to dispel the heat better.

In an exemplary node distribution device, the processor 7 is provided with a push-down heat sink 6, and the push-down heat sink 6 is connected to the processor 7 through a snap.

The lower pressure type radiator 6 can quickly dissipate heat of the processor 7, timely dissipates heat generated by the processor 7, prevents overheating from influencing normal work of the processor 7, and is connected through a buckle to facilitate disassembly and maintenance.

Illustratively, as shown in fig. 3, in the node distributed device, an outer rail 12 is disposed on the solid state disk 2, a groove is disposed on the outer rail 12, an inner rail 13 is disposed on the metal heat sink 11, and the outer rail 12 and the inner rail 13 are slidably connected through the groove.

One possible embodiment: the solid state disk 2 and the metal heat sink 11 are connected through an inner rail 12 and an outer rail 12, the inner rail 13 is connected with a groove on the outer rail 12, and the inner rail 13 and the outer rail 12 can slide relatively.

The solid state disk 2 can generate a large amount of heat in the working process, so that the heat is dissipated by the radiator, the radiating fins are connected to the hard disk through the inner rail 12 and the outer rail 12, the hard disk can be better dissipated, and meanwhile, the disassembly and the maintenance are convenient.

The node distributed device is characterized in that a layer of dust screen is arranged on the heat dissipation holes, and the dust screen is adsorbed on the heat dissipation holes through magnets.

One possible embodiment: choose for use magnetism to inhale the formula dust screen, adsorb on the host computer, the dust screen covers on the louvre.

The dust is saved easily to the louvre, and the dust screen can prevent that the louvre from piling up the dust, does not influence the louvre heat dissipation simultaneously again, adsorbs on the louvre through magnet, conveniently dismantles and clears up.

Illustratively, as shown in fig. 4, the buckle comprises a male buckle 14 and a female buckle 15, the male buckle 14 is connected to the push-down heat sink 6, the female buckle 15 is connected to the processor 7, the male buckle 14 and the female buckle 15 both have a guiding bevel, the elastic arm of the male buckle 14 deforms and presses into the female buckle 15, the elastic arm deforms and has sufficient strength, and the male buckle 14 fits with the female buckle 15.

One possible embodiment: before buckling: the buckling direction is guided by the guide oblique angle, and the male buckle 14 and the female buckle 15 are both guided into the angle; in the buckling: the elastic arm of the male buckle 14 is deformed and pressed into the female buckle 15, the elastic arm is required to be deformed, the strength is enough, and the general deformation is more than or equal to the buckling amount; after buckling: the male buckle 14 and the female buckle 15 are attached to each other, the separation direction is not easy to take out, and the buckling surface or the buckling angle is required to be smaller than the guiding oblique angle.

The buckle is the plastic part and connects the structure commonly used of fixing, can replace the screw to be used for fixing under the not high condition of intensity requirement, and the buckle combines closely, conveniently dismantles again simultaneously.

The node distribution device is applied to a communication system and realizes information exchange or transmission.

The above is only the preferred embodiment of the present invention, which aims to embody the outstanding technical effects and advantages of the present invention, and is not the limitation of the technical solution of the present invention. It should be understood by those skilled in the art that all modifications, changes or alternative technical features made based on the technical contents of the present invention should be covered within the technical scope of the appended claims.

Claims

1. The utility model provides a node distributing type device, its characterized in that includes a plurality of servers, a plurality of switch and a plurality of pile line, every server includes quick-witted case, hard disk, network card equipment, disk array card and treater, quick-witted case is the cuboid, be provided with a plurality of positions in the machine case, the treater is located quick-witted incasement, the hard disk is connected in the position in the machine case, network card equipment is connected in the position in the machine case, disk array card is connected in the position in the machine case, the hard disk the network card equipment the disk array card all with the treater communication, a plurality of switches pass through a plurality of pile lines pile up, every server all with every switch communication.

2. The node-distributed apparatus according to claim 1, wherein each bay in the chassis is provided with at least four screw holes, and the hard disk, the network card device, and the disk array card are all connected to the bay in the chassis by at least four screws.

3. The node distribution device of claim 1, wherein the hard disk comprises a solid state disk and a mechanical hard disk, and the solid state disk is provided with metal heat sinks.

4. The distributed node apparatus according to claim 1, wherein the casing is provided with heat dissipation holes, and a fan radiator is provided in the casing, and the fan radiator radiates heat through the heat dissipation holes.

5. The distributed node apparatus of claim 1, wherein said processor is configured with a push-down heat sink, said push-down heat sink being connected to said processor by a snap-fit connection.

6. The node distribution type device according to claim 3, wherein an outer rail is disposed on the solid state disk, a groove is disposed on the outer rail, an inner rail is disposed on the metal heat sink, and the outer rail and the inner rail are slidably connected through the groove.

7. The distributed node apparatus according to claim 4, wherein a layer of dust screen is disposed on the heat dissipation holes, and the dust screen is attached to the heat dissipation holes through magnets.

8. The distributed node apparatus of claim 5, wherein said fastener comprises a male buckle and a female buckle, said male buckle is connected to said heat sink, said female buckle is connected to said processor, said male buckle and said female buckle both have a guiding bevel, said male buckle elastic arm deforms and presses into said female buckle, said elastic arm deforms and has sufficient strength, and said male buckle fits into said female buckle.