CN112099582B

CN112099582B - Unlocking mechanism for hard disk cage

Info

Publication number: CN112099582B
Application number: CN202010951120.5A
Authority: CN
Inventors: 余梦斌
Original assignee: Fiberhome Telecommunication Technologies Co Ltd
Current assignee: Fiberhome Telecommunication Technologies Co Ltd
Priority date: 2020-09-11
Filing date: 2020-09-11
Publication date: 2022-03-25
Anticipated expiration: 2040-09-11
Also published as: CN112099582A

Abstract

The invention discloses a hard disk cage unlocking mechanism, which comprises: the spring bolt comprises a panel, a first elastic piece and a spring bolt, wherein an accommodating groove is formed in the panel, the spring bolt is arranged in the accommodating groove, one end of the first elastic piece is fixed on the panel, the other end of the first elastic piece is connected with the spring bolt, and the spring bolt is provided with a first position and a second position relative to the first elastic piece; when the lock tongue is in a first position relative to the first elastic piece, the tail end of the lock tongue protrudes out of the accommodating groove; when the spring bolt receives external force, the spring bolt compresses the first elastic piece, the tail end of the spring bolt enters the accommodating groove, and the spring bolt is switched from a first position to a second position relative to the first elastic piece. According to the unlocking mechanism for the hard disk cage, the structure is simple, and compared with an industry common structure, the unlocking mechanism for the hard disk cage has the advantages that the material quantity is reduced, and the material cost is reduced. In actual use, the unlocking mechanism of the hard disk cage can be automatically locked by directly inserting the unlocking mechanism of the hard disk cage into the server, so that quick locking can be realized, and the user operation is greatly simplified.

Description

Unlocking mechanism for hard disk cage

Technical Field

The invention belongs to the field of hard disk cages, and particularly relates to an unlocking mechanism of a hard disk cage.

Background

The quantity of the hard disks installed on the server is large, and the hard disks are extremely large in plugging and unplugging workload in installation and maintenance of the hard disks of the server. The existing unlocking mechanism for the hard disk cage is complex in structure and multiple in structural material, a hard disk handle is required to be opened when a hard disk is installed, a server clamping groove is pushed after the hard disk is installed, then the hard disk cage is locked by pressing the handle, the operation is troublesome, and time and labor are wasted when the hard disk is installed under the condition of serving dozens of hard disks of single equipment.

Disclosure of Invention

Aiming at the defects or the improvement requirements of the prior art, the invention provides a hard disk cage unlocking mechanism, which aims to simplify the structure of the hard disk cage unlocking mechanism, reduce the material cost, realize self-locking by directly inserting the hard disk cage unlocking mechanism into a server, realize quick locking and greatly simplify the user operation, thereby solving the technical problems of complex structure, troublesome unlocking operation and time and labor consumption in the unlocking process of the conventional hard disk cage unlocking mechanism.

To achieve the above object, according to an aspect of the present invention, there is provided a hard disk cage unlocking mechanism, including: the bolt-locking mechanism comprises a panel 1, a first elastic piece 2 and a bolt 3, wherein an accommodating groove 11 is formed in the panel 1, the bolt 3 is arranged in the accommodating groove 11, one end of the first elastic piece 2 is fixed on the panel 1, the other end of the first elastic piece 2 is connected with the bolt 3, and the bolt 3 has a first position and a second position relative to the first elastic piece 2;

when the bolt 3 is located at the first position relative to the first elastic element 2, the tail end of the bolt 3 protrudes out of the accommodating groove 11;

when the bolt 3 receives an external force, the bolt 3 compresses the first elastic piece 2, the tail end of the bolt 3 enters the accommodating groove 11, and the bolt 3 is switched from the first position to the second position relative to the first elastic piece 2.

Preferably, the tail end of the lock tongue 3 is provided with an inclined surface 31, when the hard disk cage unlocking mechanism is pushed into a server, a limiting structure on the server applies external force to the inclined surface 31 of the lock tongue 3, and the lock tongue 3 compresses the first elastic element 2 so as to push the tail part of the lock tongue 3 into the accommodating groove 11;

after the locking tongue 3 is pushed through the limiting structure, the first elastic piece 2 rebounds to withdraw the tail of the locking tongue 3 from the accommodating groove 11, and the locking tongue 3 is switched from the second position to the first position relative to the first elastic piece 2 to realize self-locking of the hard disk cage.

Preferably, a limiting portion 32 is disposed at a front end of the locking tongue 3, and the limiting portion 32 is used for preventing the locking tongue 3 from sliding out of the accommodating groove 11 in a rebounding process of the first elastic element 2.

Preferably, the unlocking mechanism of the hard disk cage further comprises a handle 4 and a second elastic member 5, one end of the second elastic member 5 is connected with the panel 1, and the other end of the second elastic member 5 is connected with the handle 4;

the handle 4 is provided with a rotating shaft 41, the panel 1 is provided with a shaft hole 12, and the rotating shaft 41 and the shaft hole 12 form a shaft joint;

the second elastic element 5 is used for driving the handle 4 to rotate around the rotating shaft 41.

Preferably, a shift lever 42 is arranged on the handle 4, a force receiving part 33 is arranged on the bolt 3, and the shift lever 42 abuts against the force receiving part 33;

when the second elastic element 5 drives the handle 4 to rotate around the rotating shaft 41, the shift lever 42 applies an external force to the stressed portion 33 to push the latch 3 to compress the first elastic element 2, so that the tail end of the latch 3 is pushed into the accommodating groove 11, and the hard disk cage is unlocked.

Preferably, the accommodating groove 11 is provided with a fixing portion 111, and the other end of the second elastic member 5 is connected to the fixing portion 111;

the accommodating groove 11 is provided with an opening 112, and the force-receiving portion 33 moves along the opening 112 under the action of an external force.

Preferably, the hard disk cage unlocking mechanism further comprises a rebounder 6, two locking hooks 601 and a lock cylinder 602 are arranged on the rebounder 6, an accommodating cavity 13 is arranged on the panel 1, the rebounder 6 is accommodated in the accommodating cavity 13, and in an initial state, the locking hooks 601 protrude out of the accommodating cavity 13;

the handle 4 is provided with a locking block 43;

when the lock block 43 is pressed for the first time, the lock block 43 applies external force to the lock cylinder 602, the locking hooks 601 are pushed into the accommodating cavity 13, and the two locking hooks 601 lock the lock block 43, so that the handle 4 and the panel 1 are locked together;

when the lock block 43 is pressed for the second time, the lock block 43 applies an external force to the lock cylinder 602, the locking hook 601 is ejected out of the accommodating cavity 13, and the locking hook 601 releases the lock block 43, so that the handle 4 is separated from the panel 1.

Preferably, the rebounder 6 comprises a pull rod 62 and a locking body 60, the locking hook 601 and the lock cylinder 602 are disposed on the locking body 60, a guide groove 603 is disposed on the locking body 60, and a groove 6031 is disposed on the guide groove 603;

when the locking block 43 is pressed for the first time, the locking block 43 applies an external force to the lock cylinder 602, the locking body 60 moves downward, and the pull rod 62 moves along the guide groove 603 until the pull rod 62 hooks the groove 6031, so that the locking hook 601 is maintained in the accommodating cavity 13;

when the locking block 43 is pressed for the second time, the locking block 43 applies an external force to the lock cylinder 602, the locking body 60 continues to move downwards, the pull rod 62 exits the groove 6031, and after the external force is released, the locking body 60 moves upwards, so that the locking hook 601 is ejected out of the accommodating cavity 13.

Preferably, the rebounder 6 further includes a bottom case 63 and a third elastic member 64, one end of the third elastic member 64 is connected to the bottom case 63, and the other end of the third elastic member 64 is connected to the locking body 60;

in the process of pressing the locking block 43 for the first time and pressing the locking block 43 for the second time, the third elastic member 64 is compressed, and after the pull rod 62 exits the groove 6031 and releases the external force, the third elastic member 64 recovers deformation to drive the locking body 60 to move upwards.

Preferably, the hard disk cage unlocking mechanism further comprises a hard disk bracket 7, and the panel 1 is connected with the hard disk bracket 7.

Generally, compared with the prior art, the technical scheme of the invention has the following beneficial effects: the invention provides a hard disk cage unlocking mechanism, which comprises: the spring bolt comprises a panel, a first elastic piece and a spring bolt, wherein an accommodating groove is formed in the panel, the spring bolt is arranged in the accommodating groove, one end of the first elastic piece is fixed on the panel, the other end of the first elastic piece is connected with the spring bolt, and the spring bolt is provided with a first position and a second position relative to the first elastic piece; when the lock tongue is located at the first position relative to the first elastic piece, the tail end of the lock tongue protrudes out of the accommodating groove; when the spring bolt receives external force, the spring bolt compresses the first elastic piece, the tail end of the spring bolt enters the accommodating groove, and the spring bolt is switched from the first position to the second position relative to the first elastic piece.

According to the unlocking mechanism for the hard disk cage, the structure is simple, and compared with an industry common structure, the unlocking mechanism for the hard disk cage has the advantages that the material quantity is reduced, and the material cost is reduced. In actual use, the unlocking mechanism of the hard disk cage can be automatically locked by directly inserting the unlocking mechanism of the hard disk cage into the server, so that quick locking can be realized, and the user operation is greatly simplified.

Furthermore, when the hard disk needs to be maintained, automatic rebounding unlocking can be achieved only by pressing down the lock block on the handle, the operation is simple, and the maintenance efficiency can be improved.

Drawings

Fig. 1 is a schematic structural diagram of an unlocking mechanism of a hard disk cage according to an embodiment of the present invention;

FIG. 2 is an exploded view of a disk cage unlocking mechanism according to an embodiment of the present invention;

fig. 3 is a schematic structural diagram of a lock tongue according to an embodiment of the present invention;

fig. 4 is a schematic structural diagram of a rebounder provided in an embodiment of the present invention;

figure 5 is an exploded view of a bouncer provided in accordance with an embodiment of the present invention;

fig. 6 is a schematic structural diagram of the locking tongue provided in the embodiment of the present invention, which is located at a first position relative to the first elastic member;

fig. 7 is a schematic structural diagram of the locking tongue provided in the embodiment of the present invention, which is located at a second position relative to the first elastic member;

fig. 8 is a schematic view of the position relationship between the lock block and the rebounder when the lock tongue is located at the first position relative to the first elastic member according to the embodiment of the present invention;

fig. 9 is a schematic diagram illustrating a positional relationship between the lock block and the rebounder when the latch tongue is located at the second position relative to the first elastic member according to the embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention. In addition, the technical features involved in the embodiments of the present invention described below may be combined with each other as long as they do not conflict with each other.

Example 1:

this embodiment provides a hard disk cage release mechanism, hard disk cage release mechanism includes: panel 1, first elastic component 2 and spring bolt 3, be provided with storage tank 11 on the panel 1, spring bolt 3 sets up in the storage tank 11, the one end of first elastic component 2 is fixed on the panel 1, the other end of first elastic component 2 with spring bolt 3 is connected, wherein, panel 1 with all be provided with a fixed column (not mark) on the spring bolt 3, the both ends of first elastic component 2 are fixed respectively on the fixed column. In practical applications, the first elastic member 2 may be a spring or other elastic device.

The lock tongue 3 has a first position and a second position relative to the first elastic member 2, when the lock tongue 3 is located at the first position relative to the first elastic member 2, the tail end of the lock tongue 3 protrudes out of the accommodating groove 11, when the lock tongue 3 receives an external force, the lock tongue 3 compresses the first elastic member 2, the tail end of the lock tongue 3 enters the accommodating groove 11, and the lock tongue 3 is switched from the first position to the second position relative to the first elastic member 2.

In order to facilitate pushing the hard disk cage unlocking mechanism into the server, an inclined plane 31 is arranged at the tail end of the lock tongue 3, when the hard disk cage unlocking mechanism is pushed into the server, an external force is applied to the inclined plane 31 of the lock tongue 3 by a limiting structure on the server, a horizontal component of the external force received by the inclined plane 31 drives the lock tongue 3 to compress the first elastic part 2 so as to push the tail part of the lock tongue 3 into the accommodating groove 11, when the lock tongue 3 is pushed through the limiting structure, the first elastic part 2 rebounds to withdraw the tail part of the lock tongue 3 from the accommodating groove 11, and the lock tongue 3 is switched to the first position from the second position relative to the first elastic part 2 so as to realize the self-locking of the hard disk cage.

Further, the front end of the lock tongue 3 is provided with a limiting portion 32, and the limiting portion 32 is used for preventing the lock tongue 3 from sliding out of the accommodating groove 11 in the rebounding process of the first elastic element 2. Wherein, spacing portion 32 has elasticity, can be formed by the plastic material preparation, and in actual assembly process, spacing portion 32 is compressed, thereby will spring bolt 3 is packed into in the storage tank 11, spacing portion 32 roll-off resume deformation behind the storage tank 11, spacing portion 32 is higher than the notch of storage tank 11, in order to place 3 roll-offs of spring bolt the storage tank 11.

In this embodiment, the unlocking mechanism of the hard disk cage further comprises a handle 4 and a second elastic member 5, one end of the second elastic member 5 is connected with the panel 1, and the other end of the second elastic member 5 is connected with the handle 4; the handle 4 is provided with a rotating shaft 41, the panel 1 is provided with a shaft hole 12, and the rotating shaft 41 and the shaft hole 12 form a shaft joint; the second elastic element 5 is used for driving the handle 4 to rotate around the rotating shaft 41.

A shift lever 42 is arranged on the handle 4, a stress part 33 is arranged on the bolt 3, and the shift lever 42 is abutted against the stress part 33; when the second elastic element 5 drives the handle 4 to rotate around the rotating shaft 41, the shift lever 42 applies an external force to the stressed portion 33 to push the latch 3 to compress the first elastic element 2, so that the tail end of the latch 3 is pushed into the accommodating groove 11, and the hard disk cage is unlocked.

Specifically, the accommodating groove 11 is provided with a fixing portion 111, and the other end of the second elastic member 5 is connected to the fixing portion 111; the accommodating groove 11 is provided with an opening 112, and the force-receiving portion 33 moves along the opening 112 under the action of an external force.

The hard disk cage unlocking mechanism further comprises a hard disk bracket 7, the panel 1 is connected with the hard disk bracket 7, and the hard disk bracket 7 is used for bearing a hard disk.

In this embodiment, the hard disk cage unlocking mechanism further includes an elastic device 6, two locking hooks 601 and a lock cylinder 602 are arranged on the elastic device 6, an accommodating cavity 13 is arranged on the panel 1, the elastic device 6 is accommodated in the accommodating cavity 13, and in an initial state, the locking hooks 601 protrude from the accommodating cavity 13. The locking hook 601 has elasticity and can be made of plastic.

The handle 4 is provided with a locking block 43, the locking block 43 comprises two wing edges and a protrusion located between the two wing edges, wherein the locking block 43 can be in a triangular shape or a U-shaped shape.

In practical use, when the lock block 43 is pressed for the first time, the lock block 43 applies an external force to the lock cylinder 602, the locking hooks 601 are pushed into the accommodating cavity 13, and the two locking hooks 601 lock the lock block 43, so that the handle 4 and the panel 1 are locked together.

Specifically, the protrusion of the lock block 43 applies an external force to the lock cylinder 602, the locking hooks 601 are pushed into the receiving cavity 13, the distance between the two locking hooks 601 is reduced, the two locking hooks 601 respectively clamp the two wing edges, and the lock block 43 is locked, so that the handle 4 and the panel 1 are locked together. When the lock block 43 is pressed for the second time, the lock block 43 applies an external force to the lock cylinder 602, the locking hook 601 is ejected out of the accommodating cavity 13, and the locking hook 601 releases the lock block 43, so that the handle 4 is separated from the panel 1.

The rebounder 6 further comprises a pull rod 62 and a locking body 60, the locking hook 601 and the lock cylinder 602 are arranged on the locking body 60, a guide groove 603 is formed in the locking body 60, and a groove 6031 is formed in the guide groove 603.

The rebounder 6 further comprises a bottom shell 63 and a third elastic member 64, wherein one end of the third elastic member 64 is connected with the bottom shell 63, and the other end of the third elastic member 64 is connected with the locking body 60.

In actual use, when the locking block 43 is pressed for the first time, the locking block 43 applies an external force to the lock cylinder 602, the locking body 60 moves downward, and the pull rod 62 moves along the guide groove 603 until the pull rod 62 hooks the groove 6031, so that the locking hook 601 is maintained in the accommodating cavity 13.

Specifically, in the process of pressing the locking block 43 for the first time and pressing the locking block 43 for the second time, the third elastic member 64 is compressed, after the pull rod 62 exits the groove 6031 and releases the external force, the third elastic member 64 recovers deformation to drive the locking body 60 to move upwards, so that the locking hook 601 is ejected out of the accommodating cavity 13, and the handle 4 continues to move upwards under the drive of the second elastic body, so that the locking block 43 of the handle 4 is separated from the locking hook 601, and the unlocking function of the handle 4 and the panel 1 is realized.

In the present embodiment, the locking structure between the panel 1 and the handle 4 is simple and easy to operate.

In this embodiment, hard disk cage release mechanism's simple structure compares in the structure that the trade is commonly used, has reduced material quantity, has reduced material cost. In actual use, the unlocking mechanism of the hard disk cage can be automatically locked by directly inserting the unlocking mechanism of the hard disk cage into the server, so that quick locking can be realized, and the user operation is greatly simplified.

Furthermore, when the hard disk needs to be maintained, the automatic rebounding unlocking can be realized only by pressing the locking block 43 on the handle 4, the operation is simple, and the maintenance efficiency can be improved.

The self-locking mechanism and the unlocking mechanism of the hard disk cage of the present embodiment are specifically described below.

The self-locking working mechanism is as follows: after the hard disk is loaded into the hard disk bracket 7, the handle 4 is locked with the panel 1 by pressing the locking block 43, and in the process, the second elastic member 5 is compressed. Then, the hard disk cage unlocking mechanism is pushed into a server, an external force is applied to an inclined surface 31 of the lock tongue 3 by a limiting structure on the server, a horizontal component of the external force received by the inclined surface 31 drives the lock tongue 3 to compress the first elastic piece 2 so as to push the tail part of the lock tongue 3 into the accommodating groove 11, after the lock tongue 3 is pushed through the limiting structure, the first elastic piece 2 rebounds, the tail part of the lock tongue 3 is withdrawn from the accommodating groove 11, and the tail part of the lock tongue 3 abuts against the limiting structure on the server so as to realize self-locking of the hard disk cage. That is, the relationship between the locking piece 41 and the rebounder 6 is changed from fig. 8 to fig. 9, and the position of the latch tongue 3 with respect to the first elastic member 2 is changed from fig. 7 to fig. 6.

An unlocking working mechanism comprises: the locking block 43 is pressed again, the handle 4 is separated from the panel 1, the second elastic piece 5 recovers deformation to drive the handle 4 to rotate around the rotating shaft 41, in the rotating process, the deflector rod 42 applies external force to the stress part 33 of the spring bolt 3 to drive the spring bolt 3 to compress the first elastic piece 2 so as to push the tail part of the spring bolt 3 into the accommodating groove 11, the tail part of the spring bolt 3 is separated from the limiting structure on the server, and then the hard disk cage unlocking mechanism can be taken down from the server to unlock the hard disk cage. That is, the relationship between the locking piece 41 and the rebounder 6 is changed from fig. 9 to fig. 8, and the position of the latch tongue 3 with respect to the first elastic member 2 is changed from fig. 6 to fig. 7.

It will be understood by those skilled in the art that the foregoing is only a preferred embodiment of the present invention, and is not intended to limit the invention, and that any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the scope of the present invention.

Claims

1. The utility model provides a hard disk cage release mechanism which characterized in that, hard disk cage release mechanism includes: the bolt comprises a panel (1), a first elastic piece (2) and a bolt (3), wherein an accommodating groove (11) is formed in the panel (1), the bolt (3) is arranged in the accommodating groove (11), one end of the first elastic piece (2) is fixed on the panel (1), the other end of the first elastic piece (2) is connected with the bolt (3), and the bolt (3) has a first position and a second position relative to the first elastic piece (2);

when the bolt (3) is located at the first position relative to the first elastic piece (2), the tail end of the bolt (3) protrudes out of the accommodating groove (11);

when the bolt (3) receives external force, the bolt (3) compresses the first elastic piece (2), the tail end of the bolt (3) enters the accommodating groove (11), and the bolt (3) is switched from the first position to the second position relative to the first elastic piece (2);

the unlocking mechanism of the hard disk cage further comprises a handle (4) and a second elastic piece (5), one end of the second elastic piece (5) is connected with the panel (1), and the other end of the second elastic piece (5) is connected with the handle (4); a rotating shaft (41) is arranged on the handle (4), a shaft hole (12) is arranged on the panel (1), and the rotating shaft (41) is in shaft connection with the shaft hole (12); the second elastic piece (5) is used for driving the handle (4) to rotate around the rotating shaft (41).

2. The unlocking mechanism for the hard disk cage according to claim 1, wherein the tail end of the locking tongue (3) is provided with an inclined surface (31), when the unlocking mechanism for the hard disk cage is pushed into a server, a limiting structure on the server applies external force to the inclined surface (31) of the locking tongue (3), and the locking tongue (3) compresses the first elastic member (2) so as to push the tail part of the locking tongue (3) into the accommodating groove (11);

when the lock tongue (3) is pushed through the limiting structure, the first elastic piece (2) rebounds, the tail portion of the lock tongue (3) is made to exit from the accommodating groove (11), and the lock tongue (3) is switched to the first position from the second position relative to the first elastic piece (2) so as to achieve self-locking of the hard disk cage.

3. The mechanism of claim 2, wherein a limiting part (32) is arranged at the front end of the locking tongue (3), and the limiting part (32) is used for preventing the locking tongue (3) from sliding out of the accommodating groove (11) in the process of rebounding of the first elastic piece (2).

4. The hard disk cage unlocking mechanism according to claim 1, wherein a shift lever (42) is provided on the handle (4), a force receiving portion (33) is provided on the latch tongue (3), and the shift lever (42) abuts against the force receiving portion (33);

when the second elastic piece (5) drives the handle (4) to rotate around the rotating shaft (41), the shifting lever (42) applies external force to the stress part (33) to push the lock tongue (3) to compress the first elastic piece (2), and then the tail end of the lock tongue (3) is pushed into the accommodating groove (11) to unlock the hard disk cage.

5. The unlocking mechanism of a hard disk cage according to claim 4, wherein the accommodating groove (11) is provided with a fixed portion (111), and the other end of the second elastic member (5) is connected with the fixed portion (111);

an opening (112) is formed in the accommodating groove (11), and the stress part (33) moves along the opening (112) under the action of external force.

6. The mechanism of claim 1, further comprising an elastic device (6), wherein the elastic device (6) is provided with two locking hooks (601) and a lock cylinder (602), the panel (1) is provided with a receiving cavity (13), the elastic device (6) is received in the receiving cavity (13), and in an initial state, the locking hooks (601) protrude from the receiving cavity (13);

a locking block (43) is arranged on the handle (4);

when the locking block (43) is pressed for the first time, the locking block (43) applies external force to the lock cylinder (602), the locking hooks (601) are pushed into the accommodating cavity (13), and the two locking hooks (601) lock the locking block (43) so that the handle (4) and the panel (1) are locked together;

when the locking block (43) is pressed for the second time, the locking block (43) applies external force to the lock cylinder (602), the locking hook (601) pops out of the accommodating cavity (13), and the locking hook (601) releases the locking block (43) so as to separate the handle (4) from the panel (1).

7. The hard disk cage unlocking mechanism according to claim 6, wherein the rebounder (6) includes a pull rod (62) and a locking body (60), the locking hook (601) and the lock cylinder (602) are provided on the locking body (60), a guide groove (603) is provided on the locking body (60), and a groove (6031) is provided on the guide groove (603);

when the locking block (43) is pressed for the first time, the locking block (43) applies external force to the lock cylinder (602), the locking body (60) moves downwards, the pull rod (62) moves along the guide groove (603) until the pull rod (62) hooks the groove (6031), so that the locking hook (601) is maintained in the accommodating cavity (13);

when pressing locking piece (43) for the second time, locking piece (43) to lock core (602) applys external force, locking body (60) continues the downstream, pull rod (62) withdraw from recess (6031), and after releasing external force, locking body (60) upward movement, so that locking hook (601) pop out accept cavity (13).

8. The device according to claim 7, wherein said rebounder (6) further comprises a bottom shell (63) and a third elastic member (64), one end of said third elastic member (64) is connected to said bottom shell (63), and the other end of said third elastic member (64) is connected to said locking body (60);

the locking block (43) is pressed for the first time, the locking block (43) is pressed for the second time, the third elastic piece (64) is compressed, and after the pull rod (62) exits the groove (6031) and releases external force, the third elastic piece (64) restores to deform and drives the locking body (60) to move upwards.

9. The mechanism of claim 1, further comprising a hard disk tray (7), wherein the panel (1) is connected to the hard disk tray (7).