CN214847737U - Server and solid state disk thereof - Google Patents

Abstract

A server and a solid state disk thereof are provided, wherein the solid state disk comprises a ruler-shaped shell, a solid state disk module, an end cover and a handle. The solid state disk module is fixed in the ruler-shaped shell, and an electric connection part of the solid state disk module extends out of one end of the ruler-shaped shell. The end cover covers the other end of the ruler-shaped shell. The handle comprises a pivot part and a hook. The pivot part enables the handle to be pivoted to the end cover, and the clamping hook is positioned on the handle and in the end cover. Therefore, when the handle rotates to one surface of the end cover corresponding to the scale-shaped shell, the clamping hook rotates out of the end cover along with the handle. Therefore, see through above framework, the utility model discloses not only provide quicker and convenient mounting means, realize exempting from the purpose of instrument equipment function, more can reduce the equipment degree of difficulty, structure complexity and its corresponding cost.

Description

Server and solid state disk thereof

Technical Field

The present invention relates to a solid state disk, and more particularly to a server and a solid state disk thereof.

Background

Nowadays, server technology is rapidly growing at a fast pace, and the development trend is mainly toward powerful computing functions, high speed and small volume, so that a plurality of removable hard disks can be loaded on a server case. These removable hard disks store a relatively large amount of data, thereby extending the functionality of the server. The removable hard disks have the characteristic of being removable on the server case so as to be used for hot plugging of the removable hard disks by a user.

However, the current fixing method of the removable hard disk is not easy to assemble or disassemble, which not only increases the difficulty of disassembling and assembling, but also increases the structural complexity and the corresponding cost.

Therefore, it is obvious that the above-mentioned technologies have inconveniences and disadvantages, and further improvements are needed to solve the inconveniences and disadvantages, which belong to one of the important research and development issues currently, and are a great need for improvement in the related art.

SUMMERY OF THE UTILITY MODEL

An object of the present invention is to provide a server and a solid state disk thereof, for solving the above mentioned difficulties of the prior art.

An embodiment of the utility model provides a solid state hard drives. The solid state disk comprises a ruler-shaped shell, a solid state disk module, an end cover and a handle. The ruler-shaped shell is provided with an inner space, a first end and a second end. The first end and the second end are opposite to each other. The solid state disk module is fixed in the inner space and is provided with a first electric connection part. The first electrical connection portion extends from the second end of the ruler-shaped housing. The end cap covers the first end of the scale-shaped housing. The handle comprises a bracket body, a pivot part and a first hook. The pivot portion enables the support body to be pivoted to the end cover, and the first clamping hook is located on the support body and located in the end cover. Therefore, when the bracket body rotates to one surface of the end cover corresponding to the scale-shaped shell, the first clamping hook rotates out of the end cover along with the bracket body.

According to one or more embodiments of the present invention, in the solid state disk, the handle further includes a first torsion spring. The first torsion spring is respectively abutted against the end cover and the bracket body and used for providing elastic force for enabling the bracket body to rotate away from the end cover.

According to one or more embodiments of the present invention, in the above-mentioned solid state disk, the end cap further comprises a buckle. The buckle comprises a buckle body, a pivot part and a second hook. The button body is relative to the pivot part of the handle. The pivoting part is used for pivoting the buckle body to the end cover. The second hook is located on the buckle body and used for directly stopping the support body to prevent the support body from rotating away from the end cover.

According to one or more embodiments of the present invention, in the above-mentioned solid state disk, the buckle further comprises a second torsion spring. The second torsion spring is respectively abutted against the end cover and the buckle body and used for providing elasticity for returning the buckle body to the original position.

According to the utility model discloses one or more embodiments, among the foretell solid state hard drive, the support body has a through-hole, and the end cover has one and goes up the storage tank. Therefore, when the bracket body rotates to the surface of the end cover, the upper accommodating groove is communicated with the inner space and the through hole.

According to one or more embodiments of the present invention, in the solid state disk, the end cap has a light guide portion. The light guide part is positioned on the surface of the end cover and connected with a signal lamp of the solid state disk module. Therefore, when the bracket body rotates to the surface of the end cover, the light guide part penetrates through the through hole so as to output light of the signal lamp from the through hole.

According to one or more embodiments of the present invention, in the solid state disk, the light guide portion includes a projection and at least one light guide pillar. The projection protrudes from the face of the end cap. One end face of the light guide column directly contacts the signal lamp, and the other end face of the light guide column is exposed out of the surface of the bump. Therefore, when the bracket body rotates to the surface of the end cover, the surface of the lug is exposed from the through opening.

According to one or more embodiments of the present invention, in the solid state disk, an outer side of the end cap has a limiting frame, and an outer side of the ruler-shaped casing has a heat dissipating fin set.

An embodiment of the utility model provides a server. The server comprises a shell, a circuit board, a second electric connection part and the solid state disk. The housing has at least one slot and at least one stop opening. The stop opening is communicated with the long and narrow slot. The circuit board is positioned in the shell. The second electric connection part is arranged on the circuit board. The solid state disk is removably positioned in the long and narrow slot and is electrically connected with the second electric connection part through the first electric connection part. Therefore, when the bracket body rotates to the surface of the end cover, the first clamping hook moves into the stopping port, and the solid state disk is limited on the shell.

According to one or more embodiments of the present invention, when there are two long and narrow slots in the server, the solid state disk is located in one of the long and narrow slots. The solid state disk further comprises a limiting frame and a radiating fin group, the radiating fin group is fixedly arranged on one outer side of the ruler-shaped shell, and the limiting frame is fixedly arranged on one outer side of the end cover. The limit frame and the radiating fin group are both positioned in the other long and narrow slot.

So, see through above each embodiment the framework, the utility model discloses a solid state hard drives not only provides quicker and convenient mounting means, realizes exempting from the purpose of instrument equipment function, more can reduce the equipment degree of difficulty, structure complexity and its corresponding cost.

The above description is only for the purpose of illustrating the problems to be solved, the technical means for solving the problems, the efficacy of the invention, and the like, and the details of the present invention will be described in detail in the following embodiments and the related drawings.

Drawings

In order to make the aforementioned and other objects, features, advantages and embodiments of the invention more comprehensible, the following description is given:

fig. 1 is a partially exploded view of a server according to an embodiment of the present invention;

FIG. 2 is an exploded view of the solid state drive of FIG. 1;

FIG. 3 is a cross-sectional view taken along line AA in FIG. 1;

FIG. 4 is a diagram illustrating operation of the solid state drive of FIG. 1;

FIG. 5 is a diagram of the operation of the server of FIG. 1; and

fig. 6 is a schematic diagram of a solid state disk according to an embodiment of the present invention.

[ notation ] to show

10 server

100 casing

110 front side

120: slotting

130 narrow and long slot

140 stopping opening

150 circuit board

151 second electrical connection portion

200. 201 solid state disk

300 ruler-shaped shell

301 outer side

310 first end

320 second end

330 inner space

340 radiating fin group

341 fin

342 an air gap

400 solid state disk module

410 circuit body

420: signal lamp

430 first electrical connection portion

500 end cap

501 outer side

510 end cover surface

520 upper accommodation groove

530 lower accommodating groove

540 light guiding part

541, bump

542 light guide column

550 limiting frame

551: frame body

552 air inlet

600: handle

610 support body

611 first part

612 second part

613 through hole

620 pivoting part

630 the first hook

640 first torsion spring

700: fastener

710 button body

720 pivoting part

730 the second hook

740 second torsion spring

AA line segment

B1, B2 pivot

L is the major axis direction

R is a rotating axis

M is a region

Detailed Description

In the following description, for purposes of explanation, numerous implementation details are set forth in order to provide a thorough understanding of the various embodiments of the invention. It should be understood, however, that these implementation details should not be used to limit the invention. That is, in the embodiments of the present invention, these practical details are not necessary. In addition, for the sake of simplicity, some conventional structures and elements are shown in the drawings in a simple schematic manner.

Unless defined otherwise, all words (including technical and scientific terms) used herein have their ordinary meaning as is understood by those skilled in the art. Furthermore, the definitions of the above words and phrases in general dictionary should be read in the content of the present specification to be consistent with the meaning and meaning of the relevant fields of the present invention. Unless specifically defined otherwise, these terms are not to be interpreted in an idealized or overly formal sense.

Fig. 1 is a partially exploded view of a server 10 according to an embodiment of the present invention, and a partially enlarged view of a region M thereof. Fig. 2 is an exploded view of solid state drive 200 of fig. 1. Fig. 3 is a cross-sectional view taken along line AA of fig. 1. As shown in fig. 1 to 3, the server 10 includes a casing 100 and a plurality of Solid-state disks (SSD) 200. The housing 100 includes a slot 120, a plurality of slots 130 and a plurality of stopping openings 140. The slot 120 is formed in the front side 110 of the chassis 100. The slots 130 are formed in the slot 120 in parallel and connected to the front side 110 of the housing 100. Each elongated slot 130 is used for inserting one of the solid state disks 200. The stopping openings 140 are arranged at intervals on the inner side surfaces of the casing 100 facing the slots 120, respectively located in the elongated slots 130, and connect with the corresponding elongated slots 130. Each stopper opening 140 penetrates the inner side surface of the casing 100. The server 10 further includes a circuit board 150 and a plurality of second electrical connectors 151. The circuit board 150 is located in the slot 120, and the second electrical connection portions 151 are disposed on the circuit board 150 side by side, and respectively correspond to the elongated slots 130 one by one. In the present embodiment, the solid state disk 200 is not limited to the size, for example, the length is 300 cm or 400 cm, or the width is 18 cm, 9.5 cm, etc., however, the present invention is not limited thereto.

As shown in fig. 2, each solid state disk 200 includes a ruler-shaped housing 300, a solid state disk module 400, an end cap 500 and a handle 600. The ruler-shaped housing 300 has a first end 310, a second end 320 and an inner space 330. The first end 310 and the second end 320 are opposite to each other, and the inner space 330 is located between the first end 310 and the second end 320. The solid state disk module 400 has a circuit body 410, at least one signal lamp 420 and a first electrical connection portion 430. The circuit body 410 is fixed in the inner space 330, and the signal lamp 420 is located at one end of the circuit body 410 and faces the end cap 500. The first electrical connection portion 430 is located at the other end of the circuit body 410, and extends outward from the second end 320 of the ruler-shaped housing 300. The end cap 500 is fixedly connected to the first end 310 of the ruler-shaped housing 300, and covers the first end 310 of the ruler-shaped housing 300 and the inner space 330.

One surface of the end cap 500 (hereinafter referred to as the end cap surface 510) opposite to the housing 300 has an upper receiving groove 520, a lower receiving groove 530 and a light guide portion 540. The light guide part 540 is disposed between the upper receiving groove 520 and the lower receiving groove 530, and is connected to the signal lamp 420 to output light of the signal lamp 420. The upper receiving groove 520 and the lower receiving groove 530 are both communicated with the inner space 330.

The handle 600 includes a support body 610, a pivot portion 620 and a first hook 630. The stent body 610 is L-shaped, for example, and the stent body 610 includes a first portion 611 and a second portion 612. The first portion 611 extends into the lower receiving groove 530, and the second portion 612 is connected to the first portion 611 and located outside the lower receiving groove 530. The first hook 630 is located at an end of the first portion 611 opposite to the second portion 612. The pivot 620 is located on the first portion 611 and is between the second portion 612 and the first hook 630. The pivot portion 620 allows the holder body 610 to be pivotally connected to the end cap 500 via the pivot B1, such that the handle 600 can rotate relative to the end cap 500 to move the second portion 612 of the holder body 610 to the end cap surface 510 of the end cap 500 or away from the end cap surface 510. The rotation axis R of the pivot 620 (or the pivot B1) is orthogonal to the long axis direction L of the ruler-shaped case 300.

Thus, as shown in fig. 2 and 3, when a user inserts one of the solid state disks 200 into one of the elongated slots 130 until the first electrical connection portion 430 is inserted into the second electrical connection portion 151, the user rotates the bracket body 610 of the handle 600, so that the second portion 612 of the bracket body 610 covers the end cover surface 510 of the end cover 500. At this time, the first hook 630 rotates out of the end cap 500 and rotates into one of the stop openings 140 along with the rotation of the bracket body 610, so that the solid state disk 200 is limited on the chassis 100.

Fig. 4 is a usage operation diagram of the solid state disk 200 of fig. 1. Fig. 5 is a use operation diagram of the server 10 of fig. 1. As shown in fig. 4 and fig. 5, conversely, when the user rotates the bracket body 610 of the grip 600 to make the second portion 612 of the bracket body 610 far away from the end cover surface 510 of the end cover 500, the first hooks 630 rotate into the end cover 500 and rotate out of the corresponding stopping openings 140 along with the rotation of the bracket body 610, so that the solid state disk 200 can be pulled out of the elongated slot 130 and the first electrical connection portions 430 are pulled away from the second electrical connection portions 151.

More specifically, in the present embodiment, as shown in fig. 2 and 3, the grip 600 further includes a first torsion spring 640. The first torsion spring 640 is disposed in the lower receiving groove 530, sleeved on the pivot B1, and respectively abutting against the end cap 500 and the first portion of the bracket body 610. As such, when the user rotates the grip 600 such that the second portion 612 of the holder body 610 is away from the end cap surface 510 of the end cap 500, the first torsion spring 640 starts to store the elastic force for rotating the holder body 610 away from the end cap 500, so as to subsequently return the grip 600 to the end cap surface 510 of the end cap 500.

In addition, in the present embodiment, the end cap 500 further includes a buckle 700. The buckle 700 includes a buckle body 710, a pivot portion 720 and a second hook 730. The button body 710 is disposed in the upper receiving groove 520, and the button body 710 is disposed opposite to the pivot portion 620 of the handle 600. The hinge portion 720 is disposed on the buckle body 710 for pivotally connecting the buckle body 710 to the end cap 500 via a pivot B2. The pivot 720 (or pivot B2) has a rotation axis R perpendicular to the longitudinal direction L of the ruler-shaped case 300. The second hook 730 is located on the buckle body 710 for directly stopping the bracket body 610 to prevent the bracket body 610 from rotating away from the end cap 500. The latch 700 further includes a second torsion spring 740. The second torsion spring 740 is disposed in the upper receiving groove 520 and abuts against the end cap 500 and the buckle body 710, respectively. Thus, when the user pulls the buckle 700 to move the buckle body 710 away from the second portion 612 of the bracket body 610, the second torsion spring 740 starts to store the elastic force for returning the buckle body 710 to the original position, so as to subsequently return the buckle body 710 to the end cover surface 510 of the end cover 500.

The grip 600 has a through opening 613, and the through opening 613 is formed in the second portion 612 of the bracket body 610. When the holder body 610 rotates to the end cap surface 510 of the end cap 500, the upper receiving groove 520 connects the inner space 330 of the ruler-shaped housing 300 and the through hole 613 of the grip 600. The light guide part 540 includes a bump 541 and at least one light guide pillar 542. The projections 541 protrude from the end cap face 510 of the end cap 500. The light guide pillar 542 is disposed in the bump 541, one end surface of the light guide pillar directly contacts the signal lamp 420, and the other end surface of the light guide pillar is exposed on the surface of the bump 541. Therefore, when the bracket body 610 rotates to the end cover surface 510 of the end cover 500, the surface of the protrusion 541 is exposed from the through hole 613. Thus, when the bracket body 610 rotates to the end cover surface 510 of the end cover 500, the protrusion 541 just extends into the through hole 613, so that the light of the signal lamp 420 is exposed from the light guide pillar 542 to the through hole 613 for the user to observe.

Fig. 6 is a schematic diagram of a solid state disk 201 according to an embodiment of the present invention. As shown in fig. 1 and 6, the end cap 500 has a retaining frame 550. The spacing frame 550 is located at the outer side 501 of the end cap 500 opposite to the upper receiving groove 520. The limiting frame 550 includes a frame body 551 and a plurality of air inlets 552. An air inlet 552 is formed in the frame body 551. The ruler-shaped housing 300 has a heat-dissipating fin set 340. The heat dissipating fin set 340 is located on the outer side 301 of the ruler-shaped shell 300 opposite to the inner space 330. The heat dissipating fin group 340 includes a plurality of fins 341. An air gap 342 is formed between any two fins 341. The air gap 342 communicates with these air inlets 552, and the long axis direction L of the air gap 342 is parallel to the long axis direction L of the scale-shaped housing 300.

Thus, when the solid state disk 201 is located in one of the elongated slots 130 and no other solid state disk 201 is placed in the adjacent elongated slot 130, since the limiting frame 550 and the heat dissipation fin set 340 of the solid state disk 201 are both located in the adjacent elongated slot 130, the limiting frame 550 can stop a user, and the user is prevented from mistakenly touching the second electrical connection portion 151 in the housing 100. In addition, the heat dissipating airflow can enter the air gaps 342 of the heat dissipating fin set 340 through the air inlets 552 to take away the heat of the heat dissipating fin set 340.

So, see through above each embodiment the framework, the utility model discloses a solid state hard drives not only provides quicker and convenient mounting means, realizes exempting from the purpose of instrument equipment function, more can reduce the equipment degree of difficulty, structure complexity and its corresponding cost.

Finally, the above-described embodiments are not intended to limit the present invention, and those skilled in the art can make various changes and modifications without departing from the spirit and scope of the present invention. Therefore, the protection scope of the present invention should be determined by the scope of the appended claims.

Claims (10)

1. A solid state disk, comprising:

a ruler-shaped shell, which is provided with an inner space, a first end and a second end, wherein the first end and the second end are opposite to each other;

the solid state disk module is fixed in the inner space and is provided with a first electric connection part which extends out of the second end of the ruler-shaped shell;

an end cap covering the first end of the ruler-shaped shell; and

a handle, comprising a bracket body, a pivot part and a first hook, wherein the pivot part enables the bracket body to be pivoted on the end cover, the first hook is positioned on the bracket body and positioned in the end cover,

when the bracket body rotates to one surface of the end cover opposite to the ruler-shaped shell, the first clamping hook rotates out of the end cover along with the bracket body.

2. The solid state disk of claim 1, wherein the holder body has a through opening, the end cap has an upper receiving groove,

when the bracket body rotates to the surface of the end cover, the upper accommodating groove is communicated with the inner space and the through hole.

3. The solid state disk of claim 2, wherein the end cap has a light guide portion, the light guide portion is located on the side of the end cap, and is connected to a signal lamp of the solid state disk module,

when the bracket body rotates to the surface of the end cover, the light guide part penetrates through the through hole so as to output light of the signal lamp from the through hole.

4. The solid state disk of claim 3, wherein the light guide portion comprises:

a projection protruding from the surface of the end cap; and

at least one light guide column, one end face of the light guide column directly contacts the signal lamp, the other end face of the light guide column is exposed out of the surface of the projection,

when the bracket body rotates to the surface of the end cover, the surface of the convex block is exposed from the through hole.

5. The solid state disk of claim 1, wherein the handle further comprises a first torsion spring, the first torsion spring abutting against the end cap and the holder body respectively for providing a resilient force for rotating the holder body to the end cap.

6. The solid state disk of claim 1, wherein the end cap further comprises a snap, the snap comprising:

a buckle body opposite to the pivot part of the handle;

a pivoting part for pivoting the buckle body to the end cover; and

the second hook is positioned on the buckle body and used for directly stopping the bracket body so as to prevent the bracket body from rotating away from the end cover.

7. The solid state disk of claim 6, wherein the latch further comprises a second torsion spring, the second torsion spring abutting against the cap and the latch respectively for providing a resilient force to return the latch to the original position.

8. The solid state disk of claim 1, wherein an outer side of the end cap has a retaining frame, and an outer side of the ruler-like housing has a set of heat dissipating fins.

9. A server, comprising:

a housing having at least one elongated slot and at least one stopping opening, the stopping opening communicating with the elongated slot;

a circuit board located in the casing;

the second electric connection part is arranged on the circuit board; and

the solid state disk of claim 1, removably positioned within the elongated slot and electrically connected to the second electrical connection through the first electrical connection,

when the bracket body rotates to the surface of the end cover, the first clamping hook moves into the stopping port, so that the solid state disk is limited on the shell.

10. The server according to claim 9, wherein when there are two slots, the solid state disk is located in one of the slots, the solid state disk further comprises a limiting frame and a set of heat dissipation fins, the set of heat dissipation fins is fixed on an outer side of the ruler-shaped casing, the limiting frame is fixed on an outer side of the end cover, and the limiting frame and the set of heat dissipation fins are located in the other slot.

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