CN218918033U - Length-adjustable server casing tray structure - Google Patents

Abstract

The utility model provides a server casing tray structure of adjustable length, including a first carrier and a second carrier, first carrier has a bottom, and erects the lateral part in the bottom both sides respectively, and the second carrier is located the one end of the both sides joint direction of first carrier, and include a moving part, and erect the regulating plate in the moving part both sides respectively, the moving part stacks up in the bottom below of first carrier, and two regulating plates cooperate in the both sides inboard of first carrier respectively, and all have a bottom edge to correspond on the bottom of first carrier, first carrier and second carrier are with spout structure and can do the removal and connect; thereby adjusting the length direction to match with the server cabinet to be configured.

Description

Length-adjustable server casing tray structure

Technical Field

The present utility model relates to a server, and more particularly, to a tray structure of a server casing with adjustable length.

Background

According to the rapid development of network and cloud technologies, providing operation or requirements such as data access of network and cloud users through a server is an indispensable device.

Since the server is internally integrated by various electronic computing or access devices of different specifications, each manufacturer must be able to assemble and actually operate each other by the protocol of the specifications. However, other peripheral hardware, such as server enclosures or cabinets, are often assembled by merely dimensional coordination. Thus, different models, models or specifications are also derived.

However, for the server provider, in order to meet the needs of the customer, it is also necessary to provide more various or customized products, so that more models are required to be opened under the limitation of the above-mentioned size matching assembly. In order to solve the problem, the utility model provides a tray with adjustable length, which is used on a server casing.

Disclosure of Invention

The main objective of the present utility model is to provide a length-adjustable tray structure for a server enclosure, which can be adjusted in the length direction, so that the server enclosure can be adapted to more types or specifications of server cabinets.

In order to achieve the above-mentioned objective, the present utility model provides a server chassis tray structure with adjustable length, which includes a first carrier and a second carrier; the first carrier seat is provided with a bottom and side parts which are respectively erected on two sides of the bottom, the second carrier seat is positioned at one end of the two side parts of the first carrier seat in the common direction and comprises a moving part and adjusting plates which are respectively erected on two sides of the moving part, the moving part is overlapped below the bottom of the first carrier seat, and the two adjusting plates are respectively matched with the inner sides of the two side parts of the first carrier seat and are provided with a bottom edge which corresponds to the bottom of the first carrier seat; wherein the first carrier and the second carrier are movably connected by a chute structure. Thereby adjusting the length direction to match with the server cabinet to be configured.

The above-mentioned server chassis tray structure with adjustable length, wherein the sliding groove structure is provided with two first sliding grooves adjacent to the two side portions respectively on the bottom of the first carrier, and locking elements positioned on the first sliding grooves, the moving part of the second carrier is provided with a lower positioning hole respectively corresponding to the two first sliding grooves on the bottom, the bottom edge of the two adjusting plates of the second carrier is provided with an upper positioning hole and corresponds to the upper side of each first sliding groove respectively, and the locking elements penetrate into the upper positioning hole and then pass through the first sliding grooves to be locked in the lower positioning hole for fixing.

In the above-mentioned server casing tray structure with adjustable length, a downward protruding mating surface is formed at the bottom of the first carrier between the two first sliding grooves, and the moving member is stacked below the mating surface.

In the above-mentioned server chassis tray structure with adjustable length, the moving member has a plate shape.

In the above-mentioned server casing tray structure with adjustable length, the second carrier is provided with at least one second chute on the moving member, and the lower surface of the mating surface is provided with a lower slider protruding into the second chute corresponding to the second chute.

In the above-mentioned server casing tray structure with adjustable length, the second sliding groove has an enlarged through hole at one end adjacent to the first carrier, and the lower sliding block slides into the second sliding groove through the through hole.

In the above-mentioned server casing tray structure with adjustable length, a sliding surface protruding upward to contact with the mating surface is formed around the second chute.

In the above-mentioned server casing tray structure with adjustable length, the second carrier is provided with a second sliding groove on the two adjusting plates, and side sliding blocks respectively opposite to the second sliding groove are arranged on the inner surfaces of the two side portions of the first carrier, and each side sliding block respectively slides into the second sliding groove.

In the above-mentioned server casing tray structure with adjustable length, the second sliding groove has an enlarged through hole at an end far away from the first carrier, and the side sliding block slides into the second sliding groove through the through hole.

The second carrier is provided with second sliding grooves on the moving member and the two adjusting plates, and each second sliding groove is provided with an enlarged through hole, wherein the through hole of the second sliding groove on the moving member is positioned at one end of the second sliding groove, the through hole of the second sliding groove on the two adjusting plates is positioned at the other end of the second sliding groove, the lower surface of the matching surface is provided with a sliding-in matched lower sliding block in a protruding manner corresponding to the second sliding groove on the moving member, and the inner surfaces of the two side parts are provided with sliding-in matched side sliding blocks respectively corresponding to the second sliding groove on the two adjusting plates.

The utility model will now be described in more detail with reference to the drawings and specific examples, which are not intended to limit the utility model thereto.

Drawings

Fig. 1 is an exploded perspective view of the present utility model.

Fig. 2 is a perspective combined view of the present utility model.

Fig. 3 is an exploded perspective view of another view of the present utility model.

Fig. 4 is a perspective view of another perspective combination of the present utility model.

Fig. 5 is a partial schematic view of the length adjustment according to the present utility model.

FIG. 6 is a cross-sectional view taken along section 6-6 of FIG. 5.

FIG. 7 is a cross-sectional view taken at section 7-7 of FIG. 5.

FIG. 8 is a partial schematic view of the present utility model applied to a server rack.

Wherein, the reference numerals:

1 first carrier

10 bottom part

100 first chute

101 locking element

102 mating surface

102a lower slide block

11 side portion

110 side sliding block

12 pull rail

2 second carrier

20 moving part

200 lower locating hole

201 slip plane

21 adjusting plate

210 bottom edge

210a upper locating hole

22 second slide groove

220 through hole

23 interface plate

3 Server cabinet

Detailed Description

The structural and operational principles of the present utility model are described in detail below with reference to the accompanying drawings:

please refer to fig. 1 to 4, which are respectively a perspective exploded view, a perspective combined view, and a perspective exploded view and a perspective combined view of another view of the present utility model. The utility model provides a length-adjustable server casing tray structure, which can be additionally provided with an upper casing and other structures according to the requirements of server configuration, can be further configured on a server cabinet 3 (shown in fig. 8), and can be adjusted according to the length dimension of the server cabinet 3, so that the server casing can be applicable to server cabinets 3 of different models or specifications. The tray structure comprises a first carrier 1 and a second carrier 2; wherein:

the first carrier 1 is used for carrying a motherboard and related electronic components (not shown) in a server, and has a bottom 10 and side portions 11 respectively standing on two sides of the bottom 10, and the first carrier 1 is capable of positioning the second carrier 2 at one end of the two side portions 11 in a common direction, and is movably connected through a chute structure, so that the tray length is adjusted by relatively moving the second carrier 2 and the first carrier 1, as shown in fig. 5. The chute structure is disposed between the first carrier 1 and the second carrier 2; for example, two first sliding grooves 100 respectively adjacent to the two side portions 11 and a locking element 101 positioned on each first sliding groove 100 may be disposed on the bottom portion 10 of the first carrier 1, and a mating surface 102 protruding downward is formed between the two first sliding grooves 100, so as to provide the second carrier 2 capable of moving along the directions of the two first sliding grooves 100, thereby achieving the purpose of adjusting the tray length.

The second carrier 2 comprises a moving member 20 and adjusting plates 21 respectively erected on two sides of the moving member 20, wherein the moving member 20 can be plate-shaped and stacked under the matching surface 102 of the bottom 10 of the first carrier 1, and is respectively provided with a lower positioning hole 200 at two first sliding grooves 100 opposite to the bottom 10, the two adjusting plates 21 each have a bottom edge 210 and an upper positioning hole 210a at the bottom edge 210, and the two adjusting plates 21 respectively cooperate with the inner sides of two side portions 10 of the first carrier 1 and make the bottom edges 210 correspond to the upper positions of the first sliding grooves 100, so that the locking elements 101 positioned on the first sliding grooves 100 can penetrate into the upper positioning holes 210a and be locked in the lower positioning holes 200 through the first sliding grooves 100 for fixing, as shown in fig. 6.

Furthermore, the second carrier 2 may also be provided with a second chute 22 on the moving member 20 or the adjusting plate 21; taking the moving member 20 as an example, at least one second sliding groove 22 may be formed on the moving member 20, the second sliding groove 22 has an enlarged through hole 220 at an end adjacent to the first carrier 1, and a sliding surface 201 protruding upward to make friction contact with the mating surface 102 may be formed around the second sliding groove 22, so as to increase friction force between the sliding surface and the bottom 10 of the first carrier 1, and make the moving connection of the first carrier 1 and the second carrier 2 relatively stable in terms of structural strength. Referring to fig. 3 and fig. 4, the lower surface of the mating surface 102 is protruded with a lower slider 102a corresponding to the second sliding groove 22, and the lower slider 102a can be adjacent to the outer edge of the bottom 10 opposite to the second carrier 2 and can slide into the second sliding groove 22 through the through hole 220, i.e. as shown in fig. 7, so as to achieve the effect of moving connection between the first and second carriers 1 and 2.

Next, referring to fig. 1 and 2, taking the adjusting plate 21 as an example, the two adjusting plates 21 may be respectively provided with a second sliding groove 22, the second sliding groove 22 may also have an enlarged through hole 220 at an end far away from the first carrier 1, and the inner surfaces of the two side portions 11 of the first carrier 1 are respectively protruded with a side sliding block 110 corresponding to the second sliding groove 22 of the two adjusting plates 21, the side sliding blocks 110 may also be adjacent to the outer edge of the bottom 10 relative to the second carrier 2, and may slide into the second sliding groove 22 of the adjusting plate 21 through the through hole 220, as shown in fig. 7, so that the movable connection effect between the first and second carriers 1 and 2 may be achieved.

It is worth mentioning that: the present utility model can be used for providing the second sliding chute 22 on both the moving member 20 of the second carrier 1 and the adjusting plate 21, wherein the through hole 220 of the second sliding chute 22 on the moving member 20 is located at one end thereof, and the through hole 220 of the second sliding chute 22 on the adjusting plate 21 is located at the other end thereof, so that after the first and second carriers 1 and 2 are assembled, the through holes 220 of the moving member 20 and the second sliding chute 22 of the adjusting plate 21 are located at different ends respectively, thereby producing the effect of mutually restraining and preventing the lower sliding block 102a or the side sliding block 110 from exiting the through hole 220; for example, when the first and second carriers 1 and 2 are pulled toward each other (i.e., the tray length is shortened), the side slider 110 on the side portion 11 of the first carrier 1 corresponds to the through hole 220 of the second sliding slot 22 on the second adjusting plate 21, but at this time, the lower slider 102a on the lower surface of the bottom portion 10 of the first carrier 1 is just far away from the corresponding through hole 220, so that the side slider 110 is caught by the lower slider 102a and the first and second carriers 1 and 2 cannot be separated.

In addition, as shown in fig. 1 to 4, in order to facilitate the configuration with the server cabinet 3 in fig. 8, a pull rail 12 may be disposed outside the two side portions 11 of the first carrier 1, and the pull rail 12 is further combined with the inner side of the server cabinet 3, so that the server housing formed by the tray structure can be pulled out from the server cabinet 3, thereby facilitating the maintenance and other operations. Furthermore, in the embodiment of the present utility model, the second carrier 2 may have an interface board 23 erected on an end of the moving member 20 away from the first carrier 1, and the interface board 23 may be configured by providing various connectors (such as a network plug or a socket, etc.); of course, the first carrier 1 and the second carrier 2 are used for carrying the electronic components in the servers respectively, which is not limited, and the interface board 23 is not limited to be arranged on the second carrier 2 as the interface board can be changed or replaced according to the actual requirement.

Therefore, the length-adjustable server shell tray structure can be obtained by the structure.

Of course, the present utility model is capable of other various embodiments and its several details are capable of modification and variation in light of the present utility model, as will be apparent to those skilled in the art, without departing from the spirit and scope of the utility model as defined in the appended claims.

Claims (10)

1. A server chassis tray structure with adjustable length, comprising:

a first carrier having a bottom and side parts respectively erected on two sides of the bottom; and

the second carrier is positioned at one end of the two side parts of the first carrier in the same direction and comprises a moving part and adjusting plates respectively erected at the two sides of the moving part, the moving part is overlapped below the bottom of the first carrier, and the two adjusting plates are respectively matched with the inner sides of the two side parts of the first carrier and are provided with a bottom edge corresponding to the bottom of the first carrier;

wherein the first carrier and the second carrier are movably connected by a chute structure.

2. The tray structure of claim 1, wherein the sliding slot structure has two first sliding slots adjacent to the two side portions and locking elements positioned on the first sliding slots, respectively, the moving member of the second carrier has a lower positioning hole corresponding to the two first sliding slots on the bottom, and the bottom edge of the two adjusting plates of the second carrier has an upper positioning hole corresponding to the upper side of the first sliding slots, and the locking elements penetrate the upper positioning hole and then pass through the first sliding slots to be locked in the lower positioning hole for fixing.

3. The tray structure of claim 2, wherein the bottom of the first carrier has a downward protruding mating surface formed between the two first sliding grooves, and the moving member is stacked under the mating surface.

4. The server enclosure tray structure of claim 3, wherein the moving member is plate-shaped.

5. The server chassis tray structure according to claim 3, wherein the second carrier has at least one second sliding slot on the moving member, and the lower surface of the mating surface is protruded with a lower sliding block corresponding to the second sliding slot to slide into the second sliding slot.

6. The server chassis tray structure according to claim 5, wherein the second sliding slot has an enlarged through hole at an end adjacent to the first carrier, and the lower slider slides into the second sliding slot through the through hole.

7. The server chassis tray structure of claim 5, wherein the second runner is peripherally formed with a sliding surface protruding upward to contact the mating surface.

8. The server chassis tray structure according to claim 3, wherein the second carrier is provided with a second sliding slot on the two adjusting plates, and side sliding blocks corresponding to the second sliding slot are respectively arranged on the inner surfaces of the two side portions of the first carrier, and each side sliding block slides into the second sliding slot.

9. The server chassis tray structure of claim 8, wherein the second chute has an enlarged through hole at an end remote from the first carrier, and the side slider slides into the second chute through the through hole.

10. The server casing tray structure of claim 3, wherein the second carrier is provided with second sliding grooves on the moving member and the two adjusting plates, each second sliding groove is provided with an enlarged through hole, wherein the through hole of the second sliding groove on the moving member is located at one end of the second sliding groove, the through hole of the second sliding groove on the two adjusting plates is located at the other end of the second sliding groove, the lower surface of the matching surface is provided with a sliding-in matched lower sliding block in a protruding manner corresponding to the second sliding groove on the moving member, and the inner surfaces of the two side parts are provided with sliding-in matched side sliding blocks respectively corresponding to the second sliding grooves on the two adjusting plates.

Images