CN218886513U - Server storage frame and storage server - Google Patents

Abstract

The utility model relates to a server field provides a server storage frame and storage server, include: a housing; the hard disk back plate is arranged in the shell; the tray is arranged in the first accommodating cavity along the horizontal direction of the first accommodating cavity; the hard board module is used for being electrically connected with the plurality of hard disks; and the heat dissipation mechanism is arranged in the second accommodating cavity and is electrically connected with the hard disk backboard. The utility model provides a server storage frame, through set up the hard disk backplate in the shell, utilize the hard disk backplate to separate into the first holding chamber and the second holding chamber of mutual intercommunication with the inner space of shell, set up the tray that sets up along the horizontal direction in first holding chamber, set up heat dissipation mechanism in second holding chamber, and utilize hardboard module intercommunication external hard disk and hard disk backplate, the mode that relies on the hardboard module to connect realizes the connection of many hard disks, improve space utilization, when hard disk concentration and scalability, heat dissipation risk and heat dissipation cost have been reduced.

Description

Server storage frame and storage server

Technical Field

The utility model relates to a server field especially relates to a server storage frame and storage server.

Background

With the development of science and technology, the application of artificial intelligence technology and big data analysis is more and more common. In parallel with this, the demand for the functions of storage products is continuously increasing. The number of hard disks of storage products is increasing, the density of the hard disks is increasing, the capacity of storing and calculating data is increasing, and the influence of the layout and the architecture inside the case on the performance of the case is also increasing obviously.

Although a few of existing high-disk storage cabinets are in vertical insertion array layout, the scheme of the vertical insertion array layout is convenient to disassemble and assemble, the density of hard disk layout is high, the structure processing is complex and high in cost, and the overall heat dissipation of the high-disk storage cabinet is also a severe test. And the hard disk vertical insertion has higher requirement on the shock absorption effect, and the gravity connector can be in close contact with the hard disk vertical insertion, so that the hard disk vertical insertion is very easy to damage if the shock absorption effect is poor. And the whole machine with the horizontal tray type layout has the same size, and the whole distribution density is smaller than that of the vertical insertion array type. However, the whole machine has a large heat dissipation bottleneck under the condition of arranging a plurality of hard disks, and if a special structure and a method are not used for solving the heat dissipation problem, the density of the hard disks is limited, so that the performance of the whole machine is limited.

SUMMERY OF THE UTILITY MODEL

The utility model provides a server storage frame and storage server, the complete machine of solving present horizontal tray formula overall arrangement sets up the heat dissipation problem of many hard disks.

In a first aspect, the present invention provides a server storage frame, including:

a housing;

the hard disk back plate is arranged in the shell and is suitable for dividing the inner space of the shell into a first accommodating cavity and a second accommodating cavity which are communicated with each other;

the tray is arranged in the first accommodating cavity along the horizontal direction of the first accommodating cavity and is used for accommodating a plurality of hard disks;

the hardboard module includes: a connection line and a plurality of first connectors; the first end of the connecting line extends to the hard disk backboard, the second end of the connecting line extends to the tray and is connected with the plurality of first connectors, and the first connectors are used for connecting the hard disks;

and the heat dissipation mechanism is arranged in the second accommodating cavity and is electrically connected with the hard disk backboard.

According to the utility model provides a pair of server storage frame, highly being less than of first connector the thickness of hard disk, the hardboard module still includes: a second connector; the second connector is connected with the connecting line and used for connecting the hard disk and the hard disk backboard.

According to the utility model provides a pair of server storage frame, the hardboard module is equipped with a plurality ofly interconnecting link, each interconnecting link interval in proper order sets up on the tray.

According to the utility model provides a pair of server storage frame, the hardboard module still includes:

and the host single board is arranged on the tray, a first end of the host single board is electrically connected with the hard disk backboard, and a second end of the host single board is electrically connected with the second connectors on the connecting lines.

According to the utility model provides a pair of server storage frame, the tray is equipped with a plurality ofly, each the tray is followed the direction of height in first holding chamber sets up, every with spacing each other all be equipped with on the tray the hardboard module.

According to the utility model provides a server storage frame, the first holding chamber is provided with the opening, the tray is suitable for switching between the first position and the second position relative to the first holding chamber; in the first position, the tray is arranged in the first accommodating cavity, and the first end of the hard board module is electrically connected with the hard disk backboard; in the second position, the tray is suitable for penetrating through the opening, at least part of the tray is arranged outside the first accommodating cavity, and the first end of the hard board module is disconnected with the hard disk backboard.

According to the utility model provides a pair of server storage frame, the shell the tray with at least one among the hard disk backplate is equipped with the louvre.

According to the utility model provides a pair of server storage frame, server storage frame still includes: the power supply is arranged in the first accommodating cavity or the second accommodating cavity and is electrically connected with the hard disk backboard.

According to the utility model provides a pair of server storage frame, heat dissipation mechanism includes: and the induced draft fan is arranged in the second accommodating cavity.

In a second aspect, according to the present invention, a storage server is provided, comprising:

the server storage frame;

and the hard disks are all arranged on the tray, and each hard disk is electrically connected with the second end of the hard board module.

The utility model provides a pair of server storage frame and storage server, through set up the hard disk backplate in the shell, utilize the hard disk backplate to separate into the first holding chamber and the second holding chamber of mutual intercommunication with the inner space of shell, set up the tray that sets up along the horizontal direction in first holding chamber, set up heat dissipation mechanism in second holding chamber, and utilize hardboard module intercommunication external hard disk and hard disk backplate, rely on the mode that hardboard module is connected to realize the connection of many hard disks, improve space utilization, when hard disk concentration and scalability, heat dissipation risk and heat dissipation cost have been reduced.

Drawings

In order to illustrate the technical solutions of the present invention or the prior art more clearly, the drawings used in the following embodiments or the description of the prior art will be briefly described, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

FIG. 1 is a schematic diagram of a server storage framework provided by an embodiment of the present application;

FIG. 2 is a schematic view of a tray provided by an embodiment of the present application;

fig. 3 is a schematic diagram of a hard board module according to an embodiment of the present disclosure;

FIG. 4 is a schematic diagram of a wind direction of an induced draft fan provided in an embodiment of the present application;

reference numerals:

10. a housing; 100. a first heat dissipation hole; 20. a hard disk backplane; 30. a tray; 40. a hard board module; 400. connecting a line; 401. a second connector; 402. a first connector; 403. a bolt; 404. i-shaped nails; 405. a host single board; 50. a heat dissipation mechanism; 60. a hard disk; 70. a power source.

Detailed Description

To make the objects, technical solutions and advantages of the present invention clearer, the drawings of the present invention are combined to clearly and completely describe the technical solutions of the present invention, and obviously, the described embodiments are some embodiments of the present invention, not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by a person skilled in the art without making creative efforts belong to the protection scope of the present invention.

The server storage frame provided by the present invention is described below with reference to fig. 1 to 3, and is used for installing a hard disk, and after the hard disk is set, the whole component provides calculation or application service, and has the capability of undertaking response service request, undertaking service, and ensuring service.

In this embodiment, the server storage framework includes: the hard disk drive comprises a shell 10, a hard disk back plate 20, a tray 30, a hard disk module 40 and a heat dissipation mechanism 50.

The whole server storage frame is of a box structure, the shell 10 is a chassis shell, and a hollow internal space is arranged in the shell 10 and used for accommodating the hard disk back plate 20, the tray 30, the hard disk module 40, the heat dissipation mechanism 50 and other components. The hard disk back plate 20 is disposed in the housing 10, the hard disk back plate 20 separates the inner space of the housing into a first accommodating cavity and a second accommodating cavity which are communicated with each other, that is, heat dissipation holes are disposed on the hard disk back plate 20, or a gap is disposed between the hard disk back plate 20 and the housing 10, and the first accommodating cavity is communicated with the second accommodating cavity through the heat dissipation holes or the gap.

The whole server storage frame adopts a horizontal tray type layout, that is, the tray 30 is arranged along the horizontal direction of the first accommodating cavity, in this embodiment, the tray 30 is arranged in the first accommodating cavity along the horizontal direction, at least one mounting position for mounting the hard disk 60 is arranged on the tray 30, and one or more hard disks 60 can be arranged as required.

In order to improve the space utilization rate, the direct connection between the hard disk backplane 20 and the hard disk 60 is eliminated, the hard disk module 40 is arranged on the tray 30, and the hard disk module 40 is connected in a manner of reducing the area of a single board. The first end of the hard board module 40 extends to the hard disk backplane 20, the first end of the hard board module 40 is electrically connected to the hard disk backplane 20, the second end of the hard board module 40 extends to the tray 30, and the hard board module 40 is used for electrically connecting to the plurality of hard disks 60. Specifically, the hard board module 40 includes: a connection line 400 and a plurality of first connectors 402. The first end of the connection line 400 extends to the hard disk backplane 20, the second end of the connection line 400 extends to the tray 30 to be connected with the plurality of first connectors 402, and the first connectors 402 are used for connecting the hard disk 60, so that the hard disk module 40 is connected with the plurality of hard disks 60.

Therefore, the hard board module 40 is communicated with the hard board back plate 20 and the external hard disk 60, and the space utilization rate, the hard disk density and the expandability are improved. The heat dissipation mechanism 50 is electrically connected with the hard disk back plate 20, the heat dissipation mechanism 50 is arranged in the second accommodating cavity, and the first accommodating cavity is communicated with the second accommodating cavity, so that direct connection of the hard disk back plate 20 is eliminated, sufficient clearance is reserved for the hard disk 60, and a good space is created for heat dissipation, so that more hard disks 60 can be accommodated under the condition of unchanged volume, the density of the hard disks 60 is improved, the influence of the hard disk back plate 20 directly connected with the hard disks 60 on heat dissipation is reduced, and the heat dissipation cost is reduced.

The embodiment of the utility model provides a pair of server storage frame, through set up the hard disk backplate in the shell, utilize the hard disk backplate to become first holding chamber and the second holding chamber of mutual intercommunication with the inner space of shell, set up the tray that sets up along the horizontal direction in first holding chamber, set up heat dissipation mechanism in second holding chamber, and utilize hardboard module intercommunication external hard disk and hard disk backplate, rely on the mode that the hardboard module is connected to realize the connection of many hard disks, improve space utilization, when hard disk concentration and scalability, heat dissipation risk and heat dissipation cost have been reduced. A hard board module (a soft and hard combination board) is combined with a tray type storage hard disk layout to solve the heat dissipation problem of high-disk equipment.

It should be noted that, by using the hard board module 40, the height of the tray 30 can be reduced, and more hard disks 60 can be accommodated without changing the total height of the apparatus, thereby increasing the density of hard disks 60. Meanwhile, the area of a single board and the size of structural components are reduced to the minimum, the gap between the hard disk 60 and the surrounding structural components is increased, the contact area between wind and the hard disk 60 is increased, the influence of each structural component on air flow is reduced to the maximum extent, and therefore the heat dissipation cost is reduced.

In one example, as shown in fig. 1 to 3, the hard board module 40 includes: the line 400 is connected. The connection line 400 is a flat cable, the connection line 400 is disposed on the tray 30, the connection line 400 extends on the tray 30, and a second connector 401 and a plurality of first connectors 402 are disposed on the connection line 400. The second connector 401 and the plurality of first connectors 402 are each connected to the connection line 400.

The second connector 401 is an opposite insertion connector, the second connector 401 is connected to one end of the connection line 400 close to the hard disk backplane 20, and the second connector 401 is used for simultaneously connecting the hard disk 60 and the hard disk backplane 20. The first connector 402 employs a Serial Advanced Technology Attachment (SATA) interface board for connecting the hard disk 60. The hard disk 60 is fixed on the tray 30 through a bracket, and the hard disk 60 is connected with the SATA connector through the self-contained connector of the hard disk 60 with a certain gap from the bottom of the tray 30.

In this embodiment, the SATA connector is of a rectangular parallelepiped structure, and has the following specific dimensions: length, width, and height: 63 x 15.5 x 0.8mm. The hard disk 60 is a standard component, the thickness is 26mm, the height of the SATA connector is smaller than that of the hard disk, and the air channels formed on the tray 30 by the SATA connector are mutually compensated. So that the air duct on the tray 30 is more unobstructed to facilitate the heat dissipation of the hard disk 60.

In addition, the SATA connector is integrally connected to the connection line 400 by soldering, and the docking connector is also integrally connected to the connection line 400 by soldering. One side of the SATA connector is provided with a chute for mounting the hard disk 60, and the other side of the SATA connector is provided with a screw fixing hole for fixing by a bolt 403. The plurality of hard disks 60 are connected by the SATA connector, and the gap between the hard disks 60 is enlarged to dissipate heat without changing the overall size of the apparatus.

In this embodiment, a single connection wire 400 is provided with a second connector 401 and two first connectors 402, and the first connectors 402 are fixed on the tray 30 by bolts 403 and i-shaped nails 404. The two first connectors 402 are connected by the connection line 400, and the second connector 401 is also connected with the two first connectors 402 by the connection line 400, whereby the second connector 401, the first connector 402 and the connection line 400 are integrated. By providing one second connector 401 and two first connectors 402, the second connector 401 and the two first connectors 402 are sequentially provided at intervals on the tray 30, thereby being divided into three rows for connecting the hard disks 60. The three hard disks 60 are connected by using a single connecting line, and the three hard disks are electrically connected with the hard disk backplane 20 by only using one second connector 401, so that the space utilization rate, the density of the hard disks and the expandability of the hard disks are improved.

Further, the hard board module 40 is provided with a plurality of connection lines 400, and the connection lines are sequentially arranged on the tray 30 at intervals. Since the hard disk backplane 20 does not need to be directly connected to the whole hard disk 60, the hard disk backplane 20 only needs to be connected to the second connector 401, and thus a plurality of connection lines 400 can be connected to the hard disk backplane 20 at the same time, and can be connected to more hard disks 60 without changing the device.

In this embodiment, there are four connection lines 400, which are the first connection line, the second connection line, the third connection line and the fourth connection line. All be equipped with second connector 401 and two first connectors 402 on first connecting circuit, second connecting circuit, third connecting circuit and the fourth connecting circuit to 12 hard disks 60 can be set up simultaneously on single tray 30, space utilization, hard disk concentration and scalability have been promoted by a wide margin.

In the case where the hard board module 40 is provided with the plurality of connection lines 400, the hard board module 40 further includes: host board 405. The host board 405 is mounted on the tray 30 by bolts. A first end of the host board 405 is electrically connected to the hard disk backplane 20, and a second end of the host board 405 is electrically connected to the second connectors 401 on the plurality of connection lines 400 at the same time. Therefore, when the second connector 401 and the first connector 402 are both connected with the hard disks 60, the single host board 405 can electrically connect the plurality of hard disks 60 and the hard disk backplane 20, and the single hard disk backplane 20 and the plurality of hard disks 60 can communicate simultaneously.

As shown in fig. 1 to fig. 3, according to the number of the hard disks 60 required to be arranged, a plurality of trays 30 may be arranged, each tray 30 is arranged in the first accommodating cavity along the horizontal direction, and the trays 30 are arranged at intervals along the height direction of the first accommodating cavity, that is, the whole server storage frame adopts a layered design. Each tray 30 is provided with a hard plate module 40.

Wherein, tray 30 is installed in first holding intracavity by layer, and every tray 30 height is less than 1U, and five layers of tray 30 overall heights are 4U, and every layer of tray 30 all is connected the communication with hard disk backplate 20. Each layer of trays 30 is used to install a plurality of hard disks 60 simultaneously.

Specifically, each tray 30 is provided with a hard board module 40, a first end of the hard board module 40 extends to be electrically connected with the hard disk backplane 20, a second end of the hard board module 40 extends to the tray 30, and the hard board module 40 is used for being electrically connected with the plurality of hard disks 60. Therefore, the hard board module 40 is communicated with the hard board back plate 20 and the external hard disk 60, and the space utilization rate, the hard disk density and the expandability are improved. The heat dissipation mechanism 50 is electrically connected with the hard disk backboard 20, the heat dissipation mechanism 50 is arranged in the second accommodating cavity, the first accommodating cavity is communicated with the second accommodating cavity, direct connection of the hard disk backboard 20 is eliminated, enough clearance is reserved for the hard disks 60, a good space is created for heat dissipation, the single heat dissipation mechanism 50 can dissipate heat of the plurality of hard disks 60 on the multilayer tray 30, more hard disks 60 can be accommodated, the density of the hard disks 60 is improved, the influence of the hard disk backboard 20 directly connected with the hard disks 60 on heat dissipation is reduced, and therefore the heat dissipation cost is reduced.

To facilitate the placement of the hard disk 60, in one embodiment provided herein, as shown in fig. 1 to 3, the first receiving chamber is provided with an opening, a rail for sliding the tray 30 is provided on a side wall of the first receiving chamber, and the tray 30 is provided on the rail, so that the tray 30 is adapted to move between a first position and a second position relative to the first receiving chamber.

In the case where the tray 30 is provided with a plurality of hard disks 60, the second end of the hard disk module 40 extends to the tray 30, and the second end of the hard disk module 40 is electrically connected to the hard disks 60.

When the tray 30 is pushed into the first accommodating cavity, the tray 30 moves to the first position under the action of external force, the tray 30 is completely arranged in the first accommodating cavity, and the first end of the hard board module 40 is electrically connected with the hard board back board 20, so that the plurality of hard disks 60 are electrically connected with the hard board back board 20. The direct connection of the hard disk back plate 20 is cancelled, enough clearance is reserved for the hard disk 60, and a good space is created for heat dissipation, so that more hard disks 60 can be accommodated under the condition of unchanged volume, the density of the hard disks 60 is improved, the influence of the direct connection of the hard disk back plate 20 and the hard disks 60 on the heat dissipation is reduced, and the heat dissipation cost is reduced.

When the tray 30 is pulled out of the first accommodating cavity, the tray 30 moves to the second position under the action of external force, the tray 30 is suitable for penetrating through the opening, at least part of the tray 30 is arranged outside the first accommodating cavity, at the moment, the first end of the hard board module 40 is disconnected from the hard disk backboard 20, and the hard disk 60 can be directly detached from the tray 30.

Based on the above embodiments, in one embodiment, as shown in fig. 1 to fig. 3, at least one of the housing 10, the tray 30 and the hard disk backplane 20 is provided with heat dissipation holes, and the heat dissipation effect of the server storage frame is improved by providing the heat dissipation holes on the housing 10, the tray 30 and the hard disk backplane 20.

Specifically, the top surface, the side surfaces and the bottom surface of the housing 10 may be provided with first heat dissipation holes 100 for dissipating heat from the first accommodation cavity and the second accommodation cavity of the inner space. Be equipped with the second louvre on the tray 30, the second louvre sets up in the clearance department of hard disk 60, and many trays 30 establish ties each other through the second heat dissipation trompil of tray 30, have improved the hard disk 60 quantity of every layer of tray 30, have avoided the inconsistent problem of shell 10 with inside hard disk heat dissipation environment. The hard disk back plate 20 is provided with a third heat dissipation hole for communicating the first accommodation cavity with the second accommodation cavity. Through setting up first louvre 100, second louvre and third louvre for different trays 30 constitute a heat dissipation space through first louvre 100, second louvre and third louvre.

Based on the above embodiments, in one embodiment, as shown in fig. 1 to 3, the server storage framework further includes: a power supply 70. The power supply 70 is used to supply power to the entire server storage frame and the hard disk 60, and the power supply 70 may be a battery module or a rectified power supply. The power supply 70 is disposed in the first receiving cavity or the second receiving cavity, and the power supply 70 is electrically connected to the hard disk backplane 20. After the hard disk 60 is disposed in the server storage frame, the power supply 70 may be used to supply power to the entire server storage frame and the hard disk 60.

As shown in fig. 1 to 3, the heat dissipation mechanism 50 includes: an induced draft fan. The induced draft fan sets up in the second holding chamber. As shown in fig. 4, the induced draft fan works in the second accommodating chamber for inducing air from the second accommodating chamber toward the first accommodating chamber.

In the process of induced air, the induced draft fan can be from second holding chamber induced air towards in the first holding chamber. Under the condition that a plurality of trays 30 are arranged, heat in air channels formed by different trays 30 can be effectively taken away, the air channels formed by different trays 30 are mutually compensated, and the whole server storage frame is kept within a preset temperature range.

In addition, the induced draft fan can also be arranged outside the whole shell 10 according to the needs, and the temperature is reduced by an external induced draft mode.

In one particular embodiment, the host board 405 is first secured to the bottom of the tray 30. The first connector 402 (SATA connector) in the hard board module 40 is fixed to the tray 30. The connection line 400 in the hard board module 40 is attached to the tray 30 by an adhesive tape or the like, and the second connector 401 (mating connector) is connected to the interface of the host board 405. The hard disk 60 is then sequentially mounted, and the interface of the hard disk 60 is aligned with the first connector 402 and fixed to the tray 30 by the bracket. The steps are repeated again, the five layers of trays 30 are assembled, and then the hard disk backboard 20 is installed in the shell 10. After completion, the trays 30 are installed inside the housing 10 in order from the bottom up. Finally, the heat dissipation mechanism 50 and the power supply 70 are installed inside the housing 10.

An embodiment of the present application further provides a storage server, as shown in fig. 1 to fig. 3, where the storage server includes: a server storage frame and a plurality of hard disks 60. The server storage framework includes: the hard disk drive comprises a shell 10, a hard disk back plate 20, a tray 30, a hard disk module 40 and a heat dissipation mechanism 50.

The whole server storage frame is of a box structure, the shell 10 is a chassis shell, and a hollow internal space is arranged in the shell 10 and used for accommodating the hard disk back plate 20, the tray 30, the hard disk module 40, the heat dissipation mechanism 50 and other components. Hard disk backplate 20 board sets up in shell 10, and hard disk backplate 20 becomes first holding chamber and second holding chamber of mutual intercommunication with the inner space partition of shell, is also to be equipped with the louvre on the hard disk backplate 20, or has the clearance between hard disk backplate 20 and the shell 10, and first holding chamber passes through louvre or clearance and second holding chamber intercommunication.

The whole server storage frame adopts a horizontal tray type layout, that is, the tray 30 is arranged along the horizontal direction of the first accommodating cavity, and in this embodiment, the tray 30 is arranged in the first accommodating cavity along the horizontal direction.

In order to improve the space utilization rate, the direct connection between the hard disk backboard 20 and the hard disk 60 is cancelled, the hard disk module 40 is arranged on the tray 30, the first end of the hard disk module 40 extends to be electrically connected with the hard disk backboard 20, the second end of the hard disk module 40 extends to the tray 30, each hard disk 60 is arranged on the tray 30, and each hard disk 60 is electrically connected with the second end of the hard disk module 40. Therefore, the hard board module 40 is communicated with the hard board back plate 20 and the external hard disk 60, and the space utilization rate, the hard disk density and the expandability are improved. The heat dissipation mechanism 50 is electrically connected with the hard disk back plate 20, the heat dissipation mechanism 50 is arranged in the second accommodating cavity, and the first accommodating cavity is communicated with the second accommodating cavity, so that direct connection of the hard disk back plate 20 is eliminated, sufficient clearance is reserved for the hard disk 60, and a good space is created for heat dissipation, so that more hard disks 60 can be accommodated under the condition of unchanged volume, the density of the hard disks 60 is improved, the influence of the hard disk back plate 20 directly connected with the hard disks 60 on heat dissipation is reduced, and the heat dissipation cost is reduced.

The embodiment of the utility model provides a pair of storage server, through set up the hard disk backplate in the shell, utilize the hard disk backplate to separate into the first holding chamber and the second holding chamber of mutual intercommunication with the inner space of shell, set up the tray that sets up along the horizontal direction in first holding chamber, set up heat dissipation mechanism in second holding chamber, and utilize hardboard module intercommunication external hard disk and hard disk backplate, rely on the mode that hardboard module is connected to realize the connection of many hard disks, improve space utilization, when hard disk concentration and scalability, heat dissipation risk and heat dissipation cost have been reduced.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art will understand that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention in its corresponding aspects.

Claims (10)

1. A server storage framework, comprising:

a housing;

the hard disk back plate is arranged in the shell and is suitable for dividing the inner space of the shell into a first accommodating cavity and a second accommodating cavity which are communicated with each other;

the tray is arranged in the first accommodating cavity along the horizontal direction of the first accommodating cavity and is used for accommodating a plurality of hard disks;

the hardboard module includes: a connection line and a plurality of first connectors; the first end of the connecting line extends to the hard disk backboard, the second end of the connecting line extends to the tray and is connected with the plurality of first connectors, and the first connectors are used for connecting the hard disks;

and the heat dissipation mechanism is arranged in the second accommodating cavity and is electrically connected with the hard disk backboard.

2. The server storage frame of claim 1, wherein the height of the first connector is less than the thickness of the hard disk, the hard disk module further comprising: a second connector; the second connector is connected with the connecting line and used for connecting the hard disk and the hard disk backboard.

3. The server storage frame of claim 2, wherein the hard board module is provided with a plurality of the connection lines, each of the connection lines being spaced apart on the tray.

4. The server storage frame of claim 3, wherein the hardboard module further comprises:

and the host single board is arranged on the tray, a first end of the host single board is electrically connected with the hard disk backboard, and a second end of the host single board is electrically connected with the second connectors on the connecting lines.

5. The server storage frame according to any one of claims 1 to 4, wherein a plurality of trays are provided, the trays are arranged at intervals in a height direction of the first receiving cavity, and the hard board module is provided on each tray.

6. The server storage frame of any one of claims 1-4, wherein the first housing cavity is provided with an opening, the tray adapted to switch between a first position and a second position relative to the first housing cavity; in the first position, the tray is arranged in the first accommodating cavity, and the first end of the hard board module is electrically connected with the hard disk backboard; in the second position, the tray is suitable for penetrating through the opening, at least part of the tray is arranged outside the first accommodating cavity, and the first end of the hard board module is disconnected with the hard disk backboard.

7. The server storage frame of any one of claims 1-4, wherein at least one of the housing, the tray, and the hard disk backplane is provided with heat dissipation holes.

8. The server storage frame according to any one of claims 1-4, further comprising:

the power supply is arranged in the first accommodating cavity or the second accommodating cavity and is electrically connected with the hard disk backboard.

9. The server storage frame of any of claims 1-4, wherein the heat dissipation mechanism comprises:

and the induced draft fan is arranged in the second accommodating cavity.

10. A storage server, comprising:

the server storage framework of any one of claims 1-9;

and each hard disk is arranged on the tray and electrically connected with the second end of the hard plate module.

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