CN114461024B - Double-row hard disk server - Google Patents

Abstract

The invention discloses a double-row hard disk server.A part of the rear end of an outer hard disk frame can be inserted into the front end of a chassis shell and positioned, and the front end of the outer hard disk frame can extend out of the chassis shell; the inner hard disk frame and the outer hard disk frame are respectively and independently arranged in rows for inserting hard disks, and two rows of hard disks can be installed; the outer hard disk frame is detachably connected with the chassis shell, the outer hard disk frame is fixedly installed in normal use, and the outer hard disk frame is detached from the chassis shell when the hard disk is required to be disassembled and assembled, so that the hard disk in the inner hard disk frame can be operated; the lower surface of outer hard disk frame, the upper surface of interior hard disk frame, the upper surface of chassis shell set up respectively and are used for dodging the breach of dodging of cable, and when outer hard disk frame took out, the cable of its connection can stretch into dodging the breach, and outer hard disk frame can be placed on the chassis shell. The invention adopts a detachable external hard disk frame structure, additionally increases a row of hard disk installation space and improves the total hard disk installation amount of the server.

Description

Double-row hard disk server

Technical Field

The invention relates to the field of servers, in particular to a double-row hard disk server.

Background

In the big data age, the data traffic of industries such as the Internet, artificial intelligence, communication and the like shows explosive growth, which tends to increase the demand on a server; the storage capacity of the server is an important index, and at present, the common practice is that the front window of the server is fully covered with hard disks, for example, the front window of a 19-inch 2U rack type server can be fully covered with 25 hot plug hard disks of 2.5 inches at most, and along with the continuous increase of storage requirements, the storage capacity of the hard disks is continuously improved, and the information storage density of the server needs to be further improved.

How to increase the number of hard disks of a server is a technical problem to be solved at present for those skilled in the art.

Disclosure of Invention

The invention provides a double-row hard disk server, which adopts a detachable outer hard disk frame to additionally increase the installation quantity of hard disks, and the specific scheme is as follows:

the double-row hard disk server comprises a case shell, an inner hard disk frame and an outer hard disk frame, wherein the inner hard disk frame is arranged in the front end of the case shell, and a part of the rear end of the outer hard disk frame can be inserted into the front end of the case shell; the inner hard disk frame and the outer hard disk frame are respectively and independently inserted into the hard disk in rows;

the outer hard disk frame is detachably connected to the chassis shell, and the outer hard disk frame can be detached from the chassis shell;

the lower surface of the outer hard disk frame, the upper surface of the inner hard disk frame and the upper surface of the chassis shell are respectively provided with an avoidance notch for avoiding cables.

Optionally, the outer hard disk frame and the chassis shell are fixedly connected through tightening bolts.

Optionally, the rear edges of the upper surface and the lower surface of the outer hard disk frame are respectively provided with an outer frame positioning clamping groove, and the outer frame positioning clamping groove can be matched with a positioning I-shaped nail protruding from the inner wall of the chassis shell for clamping and positioning.

Optionally, the inner hard disk frame is slidably mounted to the chassis housing, and the inner hard disk frame can translate in a front-rear direction.

Optionally, the upper surface and the lower surface of interior hard disk frame set up inside casing location draw-in groove respectively, inside casing location draw-in groove is through with the cooperation clamping location of the location I-shaped nail that the protrusion of chassis outer wall set up.

Optionally, the inner frame positioning clamping groove comprises an inner frame open clamping groove arranged at the front edge and the rear edge of the inner hard disk frame and an inner frame closed clamping groove arranged in the middle of the inner hard disk frame; the width in the middle of the inner frame closed clamping groove is larger than the width at two ends, and the inner frame closed clamping groove is matched with the positioning I-shaped nails to limit the moving range of the inner hard disc frame.

Optionally, the inner hard disk frame and the outer hard disk frame are connected with each other through a connecting piece, and when the outer hard disk frame moves out, the inner hard disk frame can be pulled outwards through the connecting piece.

Optionally, the connecting piece includes two sections of articulated member, the both ends of connecting piece rotate respectively connect in outer hard disk frame and interior hard disk frame.

Optionally, one end of the connecting piece is hinged to a connecting lug arranged on the inner hard disk frame, and the other end of the connecting piece is matched and assembled with the waist hole of the outer hard disk frame in a sliding manner through a pin shaft;

and the side wall of the outer hard disk frame is provided with a position avoiding groove for avoiding the connecting lug.

Optionally, the inner hard disk frame is a cylindrical square frame which is penetrated from front to back, and the outer hard disk frame is a cuboid with a side wall at the rear end; and the rear side wall of the outer hard disk frame is provided with a vent hole.

Optionally, the cross section of the rear end of the outer hard disk frame is suddenly changed to form a positioning boss.

Optionally, the avoidance notch arranged on the upper surface of the chassis shell is provided with two flexible stop blocks relatively to realize shielding.

The invention provides a double-row hard disk server, wherein an inner hard disk frame is completely positioned in a case shell, a part of the rear end of an outer hard disk frame can be inserted into the front end of the case shell and positioned, and the front end of the outer hard disk frame can extend out of the case shell; the inner hard disk frame and the outer hard disk frame are respectively and independently arranged in rows for inserting hard disks, and two rows of hard disks can be installed; the outer hard disk frame is detachably connected with the chassis shell, the outer hard disk frame is fixedly installed in normal use, and the outer hard disk frame is detached from the chassis shell when the hard disk is required to be disassembled and assembled, so that the hard disk in the inner hard disk frame can be operated; the lower surface of outer hard disk frame, the upper surface of interior hard disk frame, the upper surface of chassis shell set up respectively and are used for dodging the breach of dodging of cable, and when outer hard disk frame took out, the cable of its connection can stretch into dodging the breach, and outer hard disk frame can be placed on the chassis shell. The invention adopts a detachable external hard disk frame structure, additionally increases a row of hard disk installation space and improves the total hard disk installation amount of the server.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1A is an overall block diagram of a dual-row hard disk server of the present invention in a normal use state;

FIG. 1B is a front end partial structure diagram of a dual-row hard disk server of the present invention in a normal use state;

FIG. 2 is a schematic view of the structure of the chassis housing after disassembly;

FIG. 3 is a schematic diagram of the structure of a chassis housing;

FIG. 4 is a schematic diagram of an external hard disk frame;

fig. 5 is a schematic structural diagram of an inner hard disk frame.

The drawings include:

the machine case comprises a machine case shell 1, positioning I-shaped nails 11, an inner hard disk frame 2, an inner frame positioning clamping groove 21, an inner frame opening clamping groove 211, an inner frame closing clamping groove 212, a connecting lug 22, an outer hard disk frame 3, an outer frame positioning clamping groove 31, a waist hole 32, a position avoiding groove 33, a vent hole 34, a position avoiding notch 4, a connecting piece 5 and a tightening bolt 6.

Detailed Description

The core of the invention is to provide a double-row hard disk server, wherein the number of the hard disks is additionally increased by adopting a detachable outer hard disk frame.

In order to make those skilled in the art better understand the technical solution of the present invention, the following detailed description of the double-row hard disk server of the present invention will be given with reference to the accompanying drawings and the specific embodiments.

As shown in fig. 1A, which is an overall structure diagram of a dual-row hard disk server in a normal use state of the present invention, fig. 1B is a front-end partial structure diagram of the dual-row hard disk server in a normal use state of the present invention; the double-row hard disk server comprises a case shell 1, an inner hard disk frame 2, an outer hard disk frame 3 and other structures. The inner hard disk frame 2 is arranged in the front end of the chassis shell 1, and the inner hard disk frame 2 is completely positioned in the chassis shell 1; a part of the rear end of the outer hard disk frame 3 can be inserted into the front end of the chassis housing 1, and the front end of the outer hard disk frame 3 is exposed to the chassis housing 1. The hard disk is usually installed at the front end of the chassis, and external air flows from the front end through the hard disk and then flows into the chassis.

The inner hard disk frame 2 and the outer hard disk frame 3 are respectively and independently arranged in rows to insert hard disks, namely the inner hard disk frame 2 can accommodate a row of hard disks, and the outer hard disk frame 3 can accommodate a row of hard disks; the hard disk socket corresponding to the inner hard disk frame 2 can be arranged on the inner hard disk frame 2 or in the case shell 1; the hard disk socket corresponding to the outer hard disk frame 3 is arranged on the outer hard disk frame 3 and is connected with the main board inside the chassis shell 1 through a cable connection signal.

The outer hard disk frame 3 is detachably connected to the chassis housing 1, and the outer hard disk frame 3 can be detached from the chassis housing 1; as shown in fig. 1, in a normal use state, the outer hard disk frame 3 is fixedly connected to the chassis housing 1, at this time, two rows of hard disks are mounted on the inner hard disk frame 2 and the outer hard disk frame 3 together, and an additional row of hard disks is added through the outer hard disk frame 3; when the hard disk in the inner hard disk frame 2 needs to be disassembled, the outer hard disk frame 3 is disassembled first, so that the front end of the inner hard disk frame 2 is exposed, and the hard disk placed in the inner hard disk frame 2 can be operated.

Referring to fig. 2, a schematic diagram of the structure of the chassis housing 1 after being disassembled is shown; the lower surface of outer hard disk frame 3, the upper surface of interior hard disk frame 2, the upper surface of shell 1 sets up respectively and is used for dodging the breach 4 of dodging of cable, the breach 4 position coincidence of dodging that interior hard disk frame 2 and shell 1 offered, after outer hard disk frame 3 takes off, can place the upper surface of shell 1, the breach 4 coincidence of dodging that outer hard disk frame 3, interior hard disk frame 2, shell 1 set up this moment, the pencil card that outer hard disk frame 3 connected is gone into dodges breach 4, outer hard disk frame 3 can be supported by shell 1 steadily.

Compared with the traditional server structure, the invention has the advantages that the number of the hard disks is increased by nearly one time under the condition that the external dimension of the case is unchanged, the total hard disk installation amount of the server is improved, and the storage capacity of the server is increased.

On the basis of the scheme, the outer hard disk frame 3 and the chassis shell 1 are fixedly connected through the tightening bolts 6, and as shown in the figure 1B, the tightening bolts 6 are respectively arranged on two opposite sides of the outer hard disk frame 3 and the chassis shell 1, openings for installing the tightening bolts 6 are respectively arranged at opposite positions of the outer hard disk frame 3 and the chassis shell 1, and threaded holes are arranged on the outer hard disk frame 3 and are in threaded fit with the tightening bolts 6; after the outer hard disk frame 3 is inserted in place, the outer hard disk frame 3 is fixed by tightening bolts 6 on both sides respectively. Other fixing modes, such as a buckle, can be adopted besides the mode of tightening the bolts 6 for connection and fixation, and the specific connection mode is included in the protection scope of the invention.

The rear edges of the upper surface and the lower surface of the outer hard disk frame 3 are respectively provided with an outer frame positioning clamping groove 31, and the outer frame positioning clamping groove 31 can be matched and clamped and positioned with positioning I-shaped nails 11 protruding from the inner wall of the chassis shell 1; referring to fig. 3, a schematic structural diagram of the chassis housing 1 is shown, and fig. 4 is a schematic structural diagram of the external hard disk frame 3; the inner sides of the upper surface and the lower surface of the chassis shell 1 are convexly provided with a plurality of positioning I-shaped nails 11, the upper surface and the lower surface of the outer hard disk frame 3 are respectively correspondingly provided with an outer frame positioning clamping groove 31, and when the outer hard disk frame 3 is assembled in place, the outer frame positioning clamping groove 31 and the positioning I-shaped nails 11 are mutually inserted, so that the maximum position of the inner insertion of the outer hard disk frame 3 can be limited.

On the basis of any one of the above technical schemes and the combination thereof, the inner hard disk frame 2 in the invention is slidably mounted on the chassis housing 1, and the inner hard disk frame 2 can translate along the front-rear direction; when the outer hard disk frame 3 is removed, the inner hard disk frame 2 can be moved forward, closer to the outside, so as to operate the hard disk in the inner hard disk frame 2.

Referring to fig. 5, a schematic structure of the inner hard disk frame 2 is shown; the upper surface and the lower surface of the inner hard disk frame 2 are respectively provided with an inner frame positioning clamping groove 21, the inner frame positioning clamping groove 21 is matched and clamped and positioned by positioning I-shaped nails 11 protruding from the inner wall of the chassis shell 1, and the moving range of the inner hard disk frame 2 is limited by the mutual matching of the inner frame positioning clamping groove 21 and the positioning I-shaped nails 11.

The inner frame positioning clamping groove 21 comprises an inner frame open clamping groove 211 arranged at the front edge and the rear edge of the inner hard disk frame 2 and an inner frame closed clamping groove 212 arranged in the middle of the inner hard disk frame 2; the inner frame open clamping groove 211 is not closed relative to the outside, the inner frame closed clamping groove 212 is closed relative to the outside, and the inner frame open clamping groove 211 and the outer frame positioning clamping groove 31 which are arranged towards the front are matched and clamped with the same-position positioning I-shaped nail 11.

The width of the middle of the inner frame closed clamping groove 212 is larger than the width of the two ends, the positioning I-shaped nail 11 is of a structure with big head and small root, and the head of the positioning I-shaped nail 11 can pass through the middle of the inner frame closed clamping groove 212. The inner frame closing clamping groove 212 cooperates with the positioning I-shaped nail 11 to limit the moving range of the inner hard disk frame 2, and the moving range of the inner hard disk frame 2 is the length of the inner frame closing clamping groove 212.

Further, the inner hard disk frame 2 and the outer hard disk frame 3 of the present invention are connected to each other by the connecting member 5, and when the outer hard disk frame 3 is moved out, the inner hard disk frame 2 can be pulled out by the connecting member 5, and the inner hard disk frame 2 is moved out while the outer hard disk frame 3 is removed.

Specifically, the connecting piece 5 of the present invention comprises two sections of rod pieces hinged to each other, the two ends of the connecting piece 5 are respectively rotatably connected to the outer hard disk frame 3 and the inner hard disk frame 2, the connecting piece 5 is stretched when the outer hard disk frame 3 is moved out, and the connecting piece 5 is folded when the outer hard disk frame 3 is fixed to the chassis housing 1.

Preferably, one end of the connecting piece 5 is hinged with the connecting lug 22 arranged on the inner hard disk frame 2, the connecting lug 22 protrudes forwards, and an opening is arranged on the connecting lug 22; the other end of the connecting piece 5 is matched and assembled with the waist hole 32 of the outer hard disk frame 3 in a sliding manner through a pin shaft, the length direction of the waist hole 32 is vertical as shown in the combination of fig. 4, the connecting piece 5 can slide vertically relative to the waist hole 32, and avoidance can be provided in the stretching and folding process.

The side wall of the outer hard disk frame 3 is provided with a clearance groove 33 for avoiding the connecting lug 22, and the outer hard disk frame 3 can be just contacted with the inner hard disk frame 2 when fixed, so that the clearance between the outer hard disk frame 3 and the inner hard disk frame in the front-rear direction is reduced.

Referring to fig. 5, the inner hard disk frame 2 is a cylindrical square frame penetrating from front to back, and the hard disk socket is arranged in the chassis housing 1; the outer hard disk frame 3 is a cuboid with a side wall arranged at the rear end, and the front end of the outer hard disk frame is communicated with the outside for inserting a hard disk. The rear side wall of the outer hard disk frame 3 is provided with a hard disk socket for connecting a hard disk, and the rear side wall of the outer hard disk frame 3 is provided with a vent hole 34 for air flow.

As shown in fig. 4, the rear end cross section of the outer hard disk frame 3 is abruptly changed to form a positioning boss, which can be brought into contact with the front end edge of the chassis housing 1 as shown in fig. 4 a.

The avoidance notch 4 arranged on the upper surface of the chassis housing 1 is provided with two opposite flexible stop blocks to realize shielding, the flexible stop blocks can be made of rubber, silica gel and other materials, the two flexible stop blocks are mutually contacted to form a slit, dust can be prevented from entering, deformation occurs when a wire harness is clamped, and avoidance is provided for the wire harness.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (10)

1. The double-row hard disk server is characterized by comprising a case shell (1), an inner hard disk frame (2) and an outer hard disk frame (3), wherein the inner hard disk frame (2) is arranged inside the front end of the case shell (1), and a part of the rear end of the outer hard disk frame (3) can be inserted into the front end of the case shell (1); the inner hard disk frame (2) and the outer hard disk frame (3) are respectively and independently inserted into a row of hard disks;

the outer hard disk frame (3) is detachably connected to the chassis housing (1), and the outer hard disk frame (3) can be detached from the chassis housing (1);

an avoidance notch (4) for avoiding cables is respectively arranged on the lower surface of the outer hard disk frame (3), the upper surface of the inner hard disk frame (2) and the upper surface of the chassis shell (1);

the inner hard disk frame (2) and the outer hard disk frame (3) are connected with each other through a connecting piece (5), and when the outer hard disk frame (3) is moved out, the inner hard disk frame (2) can be pulled outwards through the connecting piece (5);

the connecting piece (5) comprises two sections of rod pieces which are hinged with each other, and two ends of the connecting piece (5) are respectively connected with the outer hard disk frame (3) and the inner hard disk frame (2) in a rotating mode.

2. The double-row hard disk server according to claim 1, wherein the outer hard disk frame (3) and the chassis housing (1) are fixedly connected by tightening bolts (6).

3. The double-row hard disk server according to claim 2, wherein outer frame positioning clamping grooves (31) are respectively formed in the rear edges of the upper surface and the lower surface of the outer hard disk frame (3), and the outer frame positioning clamping grooves (31) can be matched and clamped with positioning I-shaped nails (11) protruding from the inner wall of the chassis shell (1).

4. A dual row hard disk server as claimed in any one of claims 1 to 3, wherein the inner hard disk frame (2) is slidably mounted to the chassis housing (1), the inner hard disk frame (2) being translatable in a front-rear direction.

5. The double-row hard disk server according to claim 4, wherein inner frame positioning clamping grooves (21) are respectively formed in the upper surface and the lower surface of the inner hard disk frame (2), and the inner frame positioning clamping grooves (21) are clamped and positioned in a matched manner through positioning I-shaped nails (11) protruding from the inner wall of the chassis outer shell (1).

6. The double-row hard disk server according to claim 5, wherein the inner frame positioning clamping groove (21) comprises an inner frame open clamping groove (211) arranged at the front and rear edges of the inner hard disk frame (2) and an inner frame closed clamping groove (212) arranged in the middle of the inner hard disk frame (2); the width in the middle of the inner frame sealing clamping groove (212) is larger than the width at two ends, and the inner frame sealing clamping groove (212) and the positioning I-shaped nails (11) are matched to limit the moving range of the inner hard disc frame (2).

7. The double-row hard disk server according to claim 4, wherein one end of the connecting piece (5) is hinged to a connecting lug (22) arranged on the inner hard disk frame (2), and the other end of the connecting piece is matched and slidingly assembled with a waist hole (32) of the outer hard disk frame (3) through a pin shaft;

the side wall of the outer hard disk frame (3) is provided with a avoidance groove (33) for avoiding the connecting lug (22).

8. The double-row hard disk server according to claim 4, wherein the inner hard disk frame (2) is a cylindrical square frame penetrating front and back, and the outer hard disk frame (3) is a cuboid with a side wall at the rear end; and the rear side wall of the outer hard disk frame (3) is provided with a vent hole (34).

9. The double-row hard disk server according to claim 8, wherein the rear end cross section of the outer hard disk frame (3) is abrupt-changed to form a positioning boss.

10. The double-row hard disk server according to claim 4, wherein the avoidance notch (4) arranged on the upper surface of the chassis housing (1) is provided with two flexible stoppers relatively to realize shielding.

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