CN219370620U - Quick detach formula solid state hard drives - Google Patents

Abstract

The utility model discloses a quick-dismantling type solid state disk, which relates to the field of solid state disks and comprises a bottom shell, a chip body arranged in the bottom shell and a top cover arranged at the top of the bottom shell, wherein locking openings are formed in four corners of the top of the bottom shell, the bottom of each locking opening is communicated with a locking cavity, a locking clamping block is connected to the inner wall of each locking cavity in a sliding manner, and a spring I is fixed on one side of each locking clamping block.

Description

Quick detach formula solid state hard drives

Technical Field

The utility model relates to the technical field of solid state disks, in particular to a quick-disassembly solid state disk.

Background

Solid state hard drives, also known as solid state drives, are hard drives made from arrays of solid state electronic memory chips.

The shell of the solid state disk is usually a plastic shell or a metal shell, so that the whole shell is often required to be divided into two parts for facilitating the assembly and subsequent maintenance of the hard disk, and important chips are placed into the shell and then the two shells are combined, locked and fixed by using screws. Just like the published patent in China: "CN211879016U, a solid state disk", mention is made of: the top of the top cover 11 is provided with two mounting openings 13, the inner wall of the mounting opening 13 is movably connected with a gasket 14, the top of the gasket 14 is movably connected with a fixing bolt 15, the purpose that the solid state disk is convenient to maintain can be achieved, and workers can rapidly detach and mount the top cover 11". Although the shell can be detached by the mode, a screwdriver or other tools are needed to be arranged in actual use, the shell can be detached normally only after a plurality of bolts are screwed by the screwdriver, the operation is troublesome, the efficiency is low, and once the screwdriver which is not arranged with the bolts is not arranged, the solid state disk is difficult to detach, so that the later maintenance of the solid state disk is not facilitated.

Therefore, aiming at the technical problem that the shell of the solid state disk in the prior art needs to be provided with a tool to detach, a quick-disassembly solid state disk is designed.

Disclosure of Invention

The utility model aims to overcome the defects of the prior art and provides a technical scheme capable of solving the problems.

In order to achieve the above purpose, the present utility model provides the following technical solutions: a quick-dismantling solid state disk comprises a bottom shell, a chip body arranged in the bottom shell and a top cover arranged on the top of the bottom shell; locking ports are formed in four corners of the top of the bottom shell, the bottom of each locking port is communicated with a locking cavity, a locking clamping block is connected to the inner wall of each locking cavity in a sliding mode, and a first spring is fixed on one side of each locking clamping block; the bottom four corners homogeneous body shaping of top cap has the locking post, and has seted up the locking card hole on the locking post, the locking post activity runs through to locking cavity in.

As a further scheme of the utility model: the inside of locking chamber still sliding connection has ejecting piece, and the one end of ejecting piece runs through outside the lateral wall of drain pan, the both sides of ejecting piece one end all are fixed with the fixed plate, and two the fixed plate is located the front and back both sides of locking post and laminating on locking fixture block.

As a further scheme of the utility model: limiting sliding grooves are formed in the side wall of the bottom shell and located at the top and the bottom of each ejection block, an unlocking plug block is connected to each two limiting sliding grooves in a sliding mode, and a spring thimble is arranged in an inner cavity of the unlocking plug block; and a limiting hole is further formed in the side wall of the bottom shell and close to the side surface of each ejection block, and the needle head of the spring thimble is matched with the limiting hole.

As a further scheme of the utility model: the inside of the first spring is also provided with a telescopic part, the telescopic part comprises an outer cylinder and an inner rod sliding in the inner cavity of the outer cylinder, the outer cylinder is fixed on the inner wall of the locking cavity, and the inner rod is fixed on the locking clamping block.

As a further scheme of the utility model: the top four corners of drain pan and the position department that keeps away from every locking mouth all activity peg graft there is an ejector rod, the bottom of ejector rod runs through and extends to seting up in the ejecting chamber of drain pan inner wall, the interior bottom wall in ejecting chamber is fixed with the spring two, the top of spring two is fixed with the sliding plate, the top of sliding plate is laminated with the bottom of ejector rod.

As a further scheme of the utility model: one side at the top of the locking clamping block and one side at the bottom of the locking column are designed into a round corner structure, and the front side, the rear side, the upper side and the lower side of the locking clamping block are all attached to the inner wall of the locking cavity.

As a further scheme of the utility model: the bottom of top cap still is provided with the heat conduction silica gel pad, and this heat conduction silica gel pad is arranged in the drain pan laminating on the chip body and flush with the top of drain pan, the inseparable laminating in the top of drain pan of bottom of top cap.

Compared with the prior art, the utility model has the following beneficial effects:

according to the utility model, the chip body is protected and a complete solid state disk is formed by the bottom shell and the top cover, and the connecting and locking structure is a locking clamping block, a locking column and other structures, so that automatic locking can be realized when the bottom shell is attached to the top cover, assembly of the two shells can be rapidly completed, unlocking of the ejection block can be completed by moving the designed unlocking plug block in later disassembly, the locking column can be rapidly unlocked by pushing the ejection block, the two shells can be rapidly separated, and the solid state disk is disassembled.

Drawings

FIG. 1 is a schematic perspective view of the bottom shell and top cover of the present utility model after separation;

FIG. 2 is an enlarged schematic view of the structure of FIG. 1 according to the present utility model;

FIG. 3 is a schematic cross-sectional elevation view of the locking chamber of the present utility model;

FIG. 4 is a schematic elevational cross-sectional view of an ejection chamber of the present utility model;

FIG. 5 is a schematic view of a right side cross-sectional structure of the locking chamber of the present utility model;

FIG. 6 is a schematic elevational cross-sectional view of an unlocking insert of the present utility model;

FIG. 7 is a schematic perspective view of a locking latch of the present utility model;

FIG. 8 is a schematic perspective view of an ejector block of the present utility model;

fig. 9 is a schematic perspective view of the bottom case and the top cover combined in the present utility model.

Reference numerals and names in the drawings are as follows:

1. a bottom case; 2. a top cover; 201. a thermally conductive silicone pad; 3. a chip body; 4. locking the column; 401. locking the clamping hole; 5. a locking port; 6. an ejector rod; 7. limiting sliding grooves; 8. unlocking the plug block; 801. a spring thimble; 9. an ejection block; 901. a fixing plate; 10. a limiting hole; 11. a locking cavity; 12. locking the clamping block; 1201. a first spring; 13. an ejection cavity; 14. a second spring; 15. and a sliding plate.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-9, a quick-release solid state disk includes a bottom case 1, a chip body 3 disposed inside the bottom case 1, and a top cover 2 mounted on top of the bottom case 1; the four corners at the top of the bottom shell 1 are provided with locking openings 5, the bottom of each locking opening 5 is communicated with a locking cavity 11, the locking openings 5 are communicated with the locking cavities 11, the effects of facilitating the positioning and the entering and exiting of a locking column 4 are achieved, a locking clamping block 12 is slidably connected to the inner wall of each locking cavity 11, a first spring 1201 is fixed on one side of each locking clamping block 12, a telescopic piece is further arranged in the first spring 1201 and comprises an outer cylinder and an inner rod sliding in an inner cavity of the outer cylinder, the outer cylinder is fixed on the inner wall of each locking cavity 11, the inner rod is fixed on each locking clamping block 12, and the stability of each locking clamping block 12 in moving can be improved through the design of the telescopic piece; locking columns 4 are uniformly formed at four corners of the bottom of the top cover 2, locking clamping holes 401 are formed in the locking columns 4, and the locking columns 4 movably penetrate into the locking cavities 11.

In this embodiment, the inside of the locking cavity 11 is further slidably connected with an ejector block 9, and one end of the ejector block 9 penetrates through the side wall of the bottom shell 1, two sides of one end of the ejector block 9 are both fixed with fixing plates 901, and the two fixing plates 901 are located on the front side and the rear side of the locking column 4 and are attached to the locking clamping blocks 12.

Specifically, through the ejecting piece 9 of design, can be when follow-up needs dismantle top cap 2 quick use pushing means can realize, and two fixed plates 901 are located the both sides of locking post 4, and the purpose is in order not to influence the normal upper and lower activity of locking post 4, and also is favorable to the synchronous propulsion that applies pressure in the both sides of locking fixture block 12, more is favorable to the activity of locking fixture block 12.

In the embodiment, limit sliding grooves 7 are formed in the side wall of the bottom shell 1 and located at the top and bottom of each ejection block 9, an unlocking insert block 8 is slidably connected to each two limit sliding grooves 7, and a spring thimble 801 is installed in an inner cavity of the unlocking insert block 8; a limiting hole 10 is also formed in the side wall of the bottom shell 1 and close to the side surface of each ejection block 9, and the needle head of the spring thimble 801 is matched with the limiting hole 10.

Specifically, when drain pan 1 and top cap 2 are closed together, unblock inserted block 8 can be regarded as the barrier between ejecting piece 9 and the drain pan 1, can avoid ejecting piece 9 to receive the effect of external force to drive fixed plate 901 and want the inside activity of locking chamber 11, guaranteed locking fixture block 12's stability, and when needing drain pan 1 and top cap 2 to tear open, can move unblock inserted block 8 again to thereby can promote ejecting piece 9 thereby make fixed plate 901 be close to locking fixture block 12 and promote locking fixture block 12.

In this embodiment, an ejector rod 6 is movably inserted into four corners of the top of the bottom shell 1 and at positions far away from each locking opening 5, the bottom of the ejector rod 6 extends into an ejector cavity 13 formed in the inner wall of the bottom shell 1 in a penetrating manner, a second spring 14 is fixed on the inner bottom wall of the ejector cavity 13, a sliding plate 15 is fixed on the top of the second spring 14, and the top of the sliding plate 15 is attached to the bottom of the ejector rod 6.

Specifically, considering that the top cover 2 is quickly separated from the bottom shell 1 during disassembly, an ejector rod 6 is arranged between the top cover 2 and the bottom shell 1, and the ejector rod 6 can quickly push the top cover 2 to be separated from the bottom shell 1 by using the restoring force of the second spring 14; when the top cover 2 is attached to the bottom shell 1, the second spring 14 always pushes the ejector rod 6, namely the ejector rod 6 always pushes the top cover 2 outwards, and the top cover 2 is clamped with the locking clamping block 12 through the locking column 4, so that the top cover 2 can be better locked and fastened on the bottom shell 1.

In this embodiment, one side of the top of the locking fixture block 12 and one side of the bottom of the locking column 4 are designed with rounded structures, and the front, rear, upper and lower four sides of the locking fixture block 12 are attached to the inner wall of the locking cavity 11.

Specifically, the contact points of the locking clamping block 12 and the locking column 4 are designed in a round corner structure, so that the locking clamping block 12 can be conveniently contacted and touched, the locking clamping block 12 is conveniently pushed by the locking column 4 to move, the locking clamping block 12 is completely attached to the inner wall of the locking cavity 11, and the stability of the locking clamping block 12 during movement is ensured.

In this embodiment, the bottom of the top cover 2 is further provided with a heat-conducting silica gel pad 201, and the heat-conducting silica gel pad 201 is disposed in the bottom shell 1 and attached to the chip body 3 and flush with the top of the bottom shell 1, and the bottom of the top cover 2 is tightly attached to the top of the bottom shell 1.

Specifically, the heat-conducting silica gel pad 201 can better conduct heat and dissipate heat to the chip body 3, so that the service life of the chip body 3 is prolonged, and in order to enable the top cover 2 and the bottom shell 1 to be more sealed, structures such as sealant can be added at the joint to seal.

During installation, the four locking columns 4 at the bottom of the top cover 2 are aligned with the four locking openings 5 on the bottom shell 1, the locking columns 4 enter the locking openings 5 and slowly press down the whole top cover 2, when the top cover 2 presses down the locking columns 4, round corners of the locking columns 4 are contacted with round corners of the locking clamping blocks 12, the whole locking clamping blocks 12 are pushed to be far away from one side of the locking columns 4 until the bottom of the locking columns 4 is attached to the inner bottom wall of the locking cavity 11, at the moment, the locking clamping blocks 12 are subjected to the action of restoring force of the first spring 1201 and the end parts of the locking clamping blocks 12 are pushed into the locking clamping holes 401 of the locking columns 4, and finally, the effect that the top cover 2 and the bottom shell 1 are installed and tightly attached together is achieved (in the process that the top cover 2 is continuously close to the bottom shell 1, the top rod 6 is synchronously pressed down, and the second spring 14 is compressed through the ejection rod 6 and the sliding plate 15);

the unlocking insert block 8 is slid, so that the unlocking insert block 8 slides along the limiting chute 7, and the unlocking insert block 8 is coated on the upper side and the lower side of the ejection block 9 until the needle heads of the spring ejector pins 801 on the unlocking insert block 8 enter the limiting holes 10, so that the effect of limiting the positions of the ejection block 9 and the fixing plate 901 is realized;

when the top cover 2 is dismounted from the bottom shell 1, only the unlocking insert block 8 is required to slide in the opposite direction, the unlocking insert block 8 is far away from the ejection block 9, the spring thimble 801 on the unlocking insert block 8 is pulled, retraction is generated, namely the unlocking insert block 8 can be separated from the limiting hole 10, then the two ejection blocks 9 are respectively pressed by two hands, the ejection block 9 at the moment can push the locking clamping block 12 through the fixing plate 901, the end head of the locking clamping block 12 gradually withdraws from the locking clamping hole 401, after the end head of the locking clamping block 12 is withdrawn from the locking clamping hole 401, the locking column 4 loses the constraint of the locking clamping block 12, so that the second spring 14 at the moment has no downward pressure, reversion can be generated, and the whole top cover 2 is quickly pushed upwards through the ejection rod 6, so that the top cover 2 and the bottom shell 1 are separated, and the top cover 2 of the solid hard disk can be quickly separated from the bottom shell 1 under the condition that an external tool is not utilized.

It will be evident to those skilled in the art that the utility model is not limited to the details of the foregoing illustrative embodiments, and that the present utility model may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (7)

1. The quick-dismantling type solid state disk is characterized by comprising a bottom shell (1), a chip body (3) arranged in the bottom shell (1) and a top cover (2) arranged at the top of the bottom shell (1);

locking ports (5) are formed in four corners of the top of the bottom shell (1), the bottom of each locking port (5) is communicated with a locking cavity (11), a locking clamping block (12) is connected to the inner wall of each locking cavity (11) in a sliding mode, and a first spring (1201) is fixed on one side of each locking clamping block (12);

the locking column (4) is uniformly formed at four corners of the bottom of the top cover (2), locking clamping holes (401) are formed in the locking column (4), and the locking column (4) movably penetrates into the locking cavity (11).

2. The quick-release solid state disk of claim 1, wherein the inside of the locking cavity (11) is further slidably connected with an ejector block (9), one end of the ejector block (9) penetrates through the side wall of the bottom shell (1), fixing plates (901) are fixed on two sides of one end of the ejector block (9), and the two fixing plates (901) are located on the front side and the rear side of the locking column (4) and are attached to the locking clamping blocks (12).

3. The quick-release solid state disk according to claim 1, wherein limiting sliding grooves (7) are formed in the side wall of the bottom shell (1) and located at the top and bottom of each ejection block (9), an unlocking insert block (8) is slidably connected to each two limiting sliding grooves (7), and a spring thimble (801) is arranged in an inner cavity of the unlocking insert block (8);

and a limiting hole (10) is further formed in the side wall of the bottom shell (1) and close to the side surface of each ejection block (9), and the needle head of the spring thimble (801) is matched with the limiting hole (10).

4. The quick-release solid state disk of claim 1, wherein the spring one (1201) is further provided with a telescopic member, the telescopic member comprises an outer cylinder and an inner rod sliding in an inner cavity of the outer cylinder, the outer cylinder is fixed on an inner wall of the locking cavity (11), and the inner rod is fixed on the locking clamping block (12).

5. The quick-release solid state disk of claim 1, wherein an ejector rod (6) is movably inserted into four corners of the top of the bottom shell (1) and is far away from each locking opening (5), the bottom of the ejector rod (6) extends into an ejector cavity (13) formed in the inner wall of the bottom shell (1), a second spring (14) is fixed on the inner bottom wall of the ejector cavity (13), a sliding plate (15) is fixed on the top of the second spring (14), and the top of the sliding plate (15) is attached to the bottom of the ejector rod (6).

6. The quick-release solid state disk of claim 1, wherein one side of the top of the locking fixture block (12) and one side of the bottom of the locking column (4) are designed to be round-corner structures, and the front side, the rear side, the upper side and the lower side of the locking fixture block (12) are attached to the inner wall of the locking cavity (11).

7. The quick-release solid state disk of claim 1, wherein a heat-conducting silica gel pad (201) is further arranged at the bottom of the top cover (2), the heat-conducting silica gel pad (201) is arranged in the bottom shell (1) and is attached to the chip body (3) and is flush with the top of the bottom shell (1), and the bottom of the top cover (2) is tightly attached to the top of the bottom shell (1).