CN111857271B - Rack-mounted server and vibration damping and buffering mounting structure thereof - Google Patents

Abstract

The invention discloses a vibration damping buffering mounting structure which comprises a mounting frame, a plurality of elastic support components arranged at the bottom of the mounting frame and a mounting plate which is connected with the top ends of the elastic support components and used for mounting server nodes, wherein each elastic support component comprises a support block vertically arranged on the bottom surface of the mounting frame, an elastic part sleeved on the outer surface of the support block in a sleeving manner, and a sliding sleeve which can be vertically and slidably sleeved on the outer surface of the support block and abutted against the top end of the elastic part, the top of the sliding sleeve is connected with the bottom surface of the mounting plate, and the elastic expansion direction of the elastic part is vertical. So, when installing additional or dismantling the server node on the mounting panel, the impact vibration that the mounting panel received is through the slip compression elastic component of slip cap on the supporting shoe surface, and elastic deformation through the elastic component absorbs impact vibration energy, avoids causing the impact influence to server rack and all the other electronic components. The invention also discloses a rack server, which has the beneficial effects as described above.

Description

Rack-mounted server and vibration damping and buffering mounting structure thereof

Technical Field

The invention relates to the technical field of servers, in particular to a vibration damping and buffering mounting structure. The invention also relates to a rack server.

Background

With the development of the electronic technology in China, more and more electronic devices have been widely used.

Servers are important components in electronic devices, and are devices that provide computing services. Since the server needs to respond to and process the service request, the server generally has the capability of assuming and securing the service. The server is divided into a file server, a database server, an application program server, a WEB server and the like according to different service types provided by the server. The main components of the server include a processor, a hard disk, a memory, a system bus, etc., similar to a general computer architecture.

In the big data era, a large number of IT devices are centrally placed in racks of a data center. These data centers include various types of servers, storage, switches, and a large number of cabinets and other infrastructure. Each type of IT equipment is composed of various hardware boards, such as a computing module, a memory module, a chassis, a fan module, and the like.

The specifications of the rack server are 1U, 2U, 4U and the like, and the rack server is generally installed in a standard 19-inch cabinet and is mostly a functional server. At present, a server cabinet is generally integrally arranged in a machine room, and due to the requirement of performance expansion or adjustment, a server and other related electronic components are often required to be additionally arranged on or detached from the server cabinet, so that the overall weight of the server cabinet is generally in an irregular change. When an operator carries out server dismounting operation on a server cabinet, due to the fact that the weight of the server is large and the size of the server is large, collision and impact on the cabinet body can often occur in the process of putting the server on or off the shelf, the bottom of the cabinet body directly impacts the ground of a machine room, the bottom of the cabinet body or the whole structure is damaged, meanwhile, impact influence can be caused on electronic components such as the installed server in the cabinet body, and performance and economic loss are caused.

Therefore, how to reduce the impact vibration influence on the cabinet body in the process of assembling and disassembling the server, prevent the cabinet body and the internal structure thereof from being damaged, and prolong the service life of the server is a technical problem for technicians in the field.

Disclosure of Invention

The invention aims to provide a vibration damping and buffering mounting structure which can reduce impact vibration influence on a cabinet body in the process of assembling and disassembling a server, prevent the cabinet body and the internal structure thereof from being damaged and prolong the service life of the server. Another object of the present invention is to provide a rack server.

In order to solve the technical problems, the invention provides a vibration damping buffer mounting structure, which comprises a mounting frame, a plurality of elastic support components arranged at the bottom of the mounting frame, and a mounting plate connected with the top ends of the elastic support components and used for mounting a server node, wherein each elastic support component comprises a support block vertically arranged on the bottom surface of the mounting frame, an elastic part sleeved on the outer surface of the support block in a sleeved mode, and a sliding sleeve which is sleeved on the outer surface of the support block in a vertically sliding mode and abutted against the top end of the elastic part, the top of the sliding sleeve is connected with the bottom surface of the mounting plate, and the elastic expansion direction of the elastic part is vertical.

Preferably, the outer surface of the supporting block is provided with a plurality of slideways distributed along the circumferential direction along the vertical direction, and the inner wall of the sliding sleeve is provided with a plurality of balls which are matched with the slideways to roll.

Preferably, the supporting block is conical, the sliding sleeve is in a shape of a reduced cylinder, and the elastic element is a conical helical spring spirally wound on the outer surface of the supporting block.

Preferably, a plurality of mounting boxes distributed along the circumferential direction are arranged on the inner wall of the sliding sleeve, pre-tightening springs are mounted in the mounting boxes, the balls are mounted on the surfaces of the corresponding mounting boxes respectively, and the extending ends of the pre-tightening springs are connected with the corresponding balls.

Preferably, the elastic expansion direction of each pre-tightening spring is perpendicular to the outer surface of the supporting block, a pressing plate is further arranged in the mounting box, the outer extending end of each pre-tightening spring is connected to one side surface of the pressing plate, and the ball bearings are arranged on the other side surface of the pressing plate in a rolling manner.

Preferably, an inward extending edge which extends inwards for a preset length and is used for being abutted with the top end of the elastic piece is arranged on the bottom end face of the sliding sleeve along the horizontal direction.

Preferably, the top end of the supporting block is provided with a stopper plate which is expanded outward in the circumferential direction by a predetermined radius for preventing the balls from coming out of the top end of the slide way.

Preferably, a cooling box is arranged on the surface of the mounting plate, and a plurality of fans are arranged in the cooling box; the surface of the cooling box is used for installing the server nodes, and a plurality of positioning plates used for indicating the correct installation positions of the server nodes are arranged on the surface of the cooling box.

Preferably, the bottom of installation frame is connected with the dust removal case, install the dust removal motor in the dust removal case, just be connected with on the output of dust removal motor and be used for cleaning the subassembly that cleans of installation frame bottom.

The invention also provides a rack server, which comprises a cabinet and a vibration damping and buffering mounting structure arranged in the cabinet, wherein the vibration damping and buffering mounting structure is specifically any one of the vibration damping and buffering mounting structures.

The invention provides a vibration-damping buffering mounting structure which mainly comprises a mounting frame, an elastic supporting assembly and a mounting plate. The mounting frame is a main body structure of the mounting structure and is mainly used for mounting the server nodes and other parts. The elastic support component is generally provided with a plurality of and all set up in the bottom of installation frame, mainly used provides stable support and cushions the damping through elastic deformation to the server node. The mounting panel sets up on each elastic support subassembly's top, mainly used installation server node. Each elastic supporting component mainly comprises a supporting block, an elastic piece and a sliding sleeve. The supporting block is vertically arranged on the bottom surface of the installation frame, the elastic piece is sleeved on the outer surface of the supporting block in a sleeved mode, and the sliding sleeve is sleeved on the outer surface of the supporting block but can vertically slide on the sliding sleeve. Simultaneously, the top of sliding sleeve links to each other with the bottom surface of mounting panel, and the bottom of sliding sleeve and the top butt of elastic component to the flexible direction of elasticity of elastic component is vertical. So, when installing additional or dismantling the server node on the mounting panel, the impact vibration that the mounting panel received transmits to the slip sheathe in, later can be through the slip compression elastic component of slip cap on the supporting shoe surface, absorb the impact vibration energy who transmits through elastic component elastic deformation in vertical, avoid causing the impact influence to server rack and all the other electronic components. Therefore, the vibration reduction buffering mounting structure provided by the invention can reduce the impact vibration influence on the cabinet body in the server dismounting process, prevent the cabinet body and the internal structure thereof from being damaged, and prolong the service life of the server.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the provided drawings without creative efforts.

Fig. 1 is a schematic overall structure diagram of an embodiment of the present invention.

Fig. 2 is a partial structural view of the elastic support assembly shown in fig. 1.

Wherein, in fig. 1-2:

a server node-a;

the device comprises an installation frame-1, an elastic supporting component-2, an installation plate-3, a cooling box-4, a fan-5, a positioning plate-6, a dust removal box-7, a dust removal motor-8, a cleaning component-9, a lengthened connecting rod-10, a guide sliding rod-11 and an anti-falling connecting rod-12;

the device comprises a supporting block-21, an elastic piece-22, a sliding sleeve-23, balls-24, a mounting box-25, a pre-tightening spring-26, a pressing plate-27, an inward extending edge-28 and a stop plate-29.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, fig. 1 is a schematic overall structure diagram of an embodiment of the present invention.

In one embodiment of the present invention, the damping buffer mounting structure mainly comprises a mounting frame 1, an elastic support component 2 and a mounting plate 3.

The mounting frame 1 is a main structure of the mounting structure and is mainly used for mounting the server node a and other parts. Generally, the mounting frame 1 may be a rectangular frame, and has an opening opened on a top surface thereof for the server node a to enter and exit.

The elastic support component 2 is generally provided in plurality and is disposed at the bottom of the mounting frame 1, and is mainly used for providing stable support for the server node a and damping vibration through elastic deformation. Considering that the server nodes a are generally rectangular, in order to improve the support stability and prevent the server nodes a from being unstable in inclination, the respective elastic support members 2 may be formed in an array of a predetermined size, such as a 3 × 3 array, on the bottom surface of the mounting frame 1.

The mounting plate 3 is arranged at the top end of each elastic support component 2 and is mainly used for mounting the server node a. In general, the mounting plate 3 may be embodied as a rectangular plate having a certain thickness and structural strength, and the surface area thereof may be equivalent to the bottom area of the server node a.

Each elastic support member 2 mainly includes a support block 21, an elastic member 22, and a sliding sleeve 23.

Wherein, the supporting block 21 is erected on the bottom surface of the mounting frame 1, the elastic member 22 is sleeved on the outer surface of the supporting block 21, and the sliding sleeve 23 is sleeved on the outer surface of the supporting block 21 but can slide vertically on the sliding sleeve 23. Meanwhile, the top of the sliding sleeve 23 is connected with the bottom surface of the mounting plate 3, the bottom of the sliding sleeve 23 is abutted against the top end of the elastic member 22, and the elastic expansion direction of the elastic member 22 is vertical.

So, when installing additional or dismantling server node a on mounting panel 3, the impact vibration that mounting panel 3 received transmits sliding sleeve 23 on, later can be through sliding sleeve 23 sliding compression elastic component 22 on the supporting shoe 21 surface, absorb the impact vibration energy that the transmission comes through elastic component 22 at vertical ascending elastic deformation, avoid causing the impact influence to server rack and all the other electronic components.

Therefore, the damping buffering mounting structure that this embodiment provided can reduce the impact vibration influence to the cabinet body production at server dismouting in-process, prevents to produce the damage to the cabinet body and inner structure, improves server life.

In order to facilitate the sliding of the sliding sleeve 23 on the outer surface of the supporting block 21, in this embodiment, a plurality of sliding ways are formed on the outer surface of the supporting block 21 along the vertical direction, and a plurality of balls 24 are arranged on the inner wall of the sliding sleeve 23, and each ball 24 is mainly used for being matched with each sliding way and rolling in the corresponding sliding way. Specifically, each slide way can be uniformly distributed along the circumferential direction of the supporting block 21, for example, 4 slide ways can be provided, and the included angle between the circle centers of two adjacent 2 slide ways is 90 °. Of course, more runners may be used. Meanwhile, the balls 24 are distributed on the inner wall of the sliding sleeve 23 in the same manner as the slide ways are distributed on the outer surface of the supporting block 21, i.e., uniformly distributed in the circumferential direction. Furthermore, each slide way can correspond to a plurality of balls 24 which are distributed in parallel along the vertical direction (or axial direction), so that a plurality of (for example, 3) balls 24 roll on the same slide way at the same time.

In a preferred embodiment with respect to the supporting block 21 and the sliding sleeve 23, the supporting block 21 is particularly cylindrical while the sliding sleeve 23 is particularly cylindrical, and the elastic member 22 may be a typical coil spring.

In another preferred embodiment of the supporting block 21 and the sliding sleeve 23, in order to improve the stability of the sliding sleeve 23 during sliding and prevent the balls 24 from coming off the slide way during rolling, in this embodiment, the supporting block 21 is conical, the sliding sleeve 23 is reduced cylindrical, and the elastic member 22 is a conical coil spring spirally wound on the outer surface of the supporting block 21. With such an arrangement, when the sliding sleeve 23 slides on the outer surface of the supporting block 21, the vertical downward pressure from the server node a will generate a positive pressure component perpendicular to the inner wall of the sliding sleeve 23 and the outer surface of the supporting block 21, and the sliding sleeve 23 can be pressed on the outer surface of the supporting block 21 by using the positive pressure component, thereby ensuring that the balls 24 can press the surface of the slideway to prevent the sliding sleeve from being accidentally pulled out of the slideway.

Further, in the present embodiment, a plurality of mounting boxes 25 are provided on the inner wall of the sliding sleeve 23, and a pre-tightening spring 26 is mounted in each mounting box 25. Specifically, the mounting boxes 25 are distributed on the inner wall of the sliding sleeve 23 along the circumferential direction, and the distribution form is the same as that of the slideway on the outer surface of the supporting block 21. Meanwhile, the balls 24 are respectively mounted on the surfaces of the corresponding mounting boxes 25, and the outward extending ends of the pre-tightening springs 26 in the respective mounting boxes 25 are respectively connected with the respective balls 24, so that the balls 24 are ensured to be smoothly rolled while being pressed against the surface of the slideway by the elastic deformation of the pre-tightening springs 26 when subjected to the positive pressure component.

To facilitate the installation of the balls 24 on the mounting box 25 and the connection with the pre-tightening springs 26, the present embodiment adds a pressing plate 27 in the mounting box 25, the pressing plate 27 is specifically installed at the distal end of the mounting box 25, one end of the pre-tightening springs 26 is connected to the inner wall of the sliding sleeve 23, while the other end (overhanging end) of the pre-tightening springs 26 is connected to one side surface of the pressing plate 27, and the balls 24 are rollably installed on the other side surface of the pressing plate 27. With this arrangement, the preload spring 26 can press the balls 24 against the slide surface via the pressing plate 27 when it is elastically deformed. In general, the elastic deformation direction of each pre-tightening spring 26 is perpendicular to the outer surface of the support block 21.

In addition, in order to ensure that the bottom of the sliding sleeve 23 can stably press the elastic member 22 during sliding, the embodiment provides an inward extending edge 28 on the bottom end surface of the sliding sleeve 23. Specifically, the inwardly extending edge 28 extends inwardly along the bottom end face of the sliding sleeve 23 for a certain length and is horizontally distributed, and is mainly used for abutting against the top end of the elastic member 22. With this arrangement, the inwardly extending lip 28, which has a large surface area, can be used to maintain contact and compression against the top end of the resilient member 22.

Furthermore, considering that the sliding sleeve 23 will rise vertically along the supporting block 21 under the elastic reaction force of the elastic member 22 after the server node a is detached, in order to prevent the sliding sleeve 23 from falling off the supporting block 21 accidentally, the embodiment provides a stop plate 29 at the top end of the supporting block 21. Specifically, the stopper plate 29 is expanded outward from the top center of the supporting block 21 in the circumferential direction by a certain radius, and effectively blocks the respective mounting boxes 25 and the respective balls 24.

To facilitate the connection between the mounting plate 3 and the sliding sleeves 23, the embodiment further connects the extension link 10 on the top of each sliding sleeve 23, so that the specific mounting height of the server node a in the mounting frame 1 can be adjusted by the length of the extension link 10.

In order to prevent the mounting plate 3 from tilting or shaking when sliding vertically along the sliding sleeve 23, a plurality of guide sliding rods 11 are also vertically arranged at the bottom of the mounting frame 1. Specifically, each guide slide bar 11 extends vertically, the top end of each guide slide bar can be connected with a turned-over edge at the top of the installation frame 1, and each guide slide bar 11 penetrates through the installation plate 3, so that a vertical guide effect is formed in the vertical sliding process of the installation plate 3. Further, this embodiment has still set up a plurality of anticreep connecting rods 12 on the surface of mounting panel 3 immediately, and each anticreep connecting rod 12 can be followed vertical extension and worn to establish on the top turn-ups of installation frame 1 to be provided with the limiting plate on the top of anticreep connecting rod 12, the biggest downtake height of mounting panel 3 is restricted to the limiting plate of accessible anticreep connecting rod 12 and the turn-ups's of the top butt of installation frame 1.

In addition, in order to improve the heat dissipation performance of the server node a, the present embodiment further provides a cooling box 4 on the surface of the mounting plate 3, and a plurality of fans 5 are installed inside the cooling box 4. In this manner, the server nodes a can be mounted on the surface of the cooling box 4 while being radiated by the respective fans 5. In order to ensure that the server nodes a are stably and properly installed on the surface of the cooling box 4, in the embodiment, a plurality of positioning plates 6 are arranged on the surface of the cooling box 4, so that the correct installation positions of the server nodes a are indicated through the installation spaces encircled by the positioning plates 6.

Considering that the bottom of the rack server is easy to collect dust, the present embodiment further installs a dust box 7 at the bottom of the installation frame 1, and installs a dust removing motor 8 in the dust box 7, wherein the output shaft of the dust removing motor 8 extends out of the dust box 7, and the end of the output shaft is connected with a cleaning assembly 9. So, through the drive of dust removal motor 8 to cleaning subassembly 9, can effectively clean the dust of rack-mounted server bottom to accomodate the clearance through dust removal case 7.

The embodiment further provides a rack server, which mainly includes a cabinet and a vibration damping and buffering mounting structure disposed in the cabinet, wherein specific contents of the vibration damping and buffering mounting structure are the same as those of the vibration damping and buffering mounting structure, and are not described herein again.

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

Claims (7)

1. The damping and buffering mounting structure is characterized by comprising a mounting frame (1), a plurality of elastic support components (2) arranged at the bottom of the mounting frame (1), and a mounting plate (3) connected with the top ends of the elastic support components (2) and used for mounting a server node (a), wherein each elastic support component (2) comprises a support block (21) vertically arranged on the bottom surface of the mounting frame (1), an elastic part (22) sleeved on the outer surface of the support block (21) in a sleeved mode, and a sliding sleeve (23) which is sleeved on the outer surface of the support block (21) in a vertically sliding mode and abutted to the top end of the elastic part (22), the top of the sliding sleeve (23) is connected with the bottom surface of the mounting plate (3), and the elastic expansion direction of the elastic part (22) is vertical;

a plurality of slideways distributed along the circumferential direction are arranged on the outer surface of the supporting block (21) along the vertical direction, and a plurality of balls (24) which are matched with the slideways to roll are arranged on the inner wall of the sliding sleeve (23);

the supporting block (21) is conical, the sliding sleeve (23) is in a necking cylinder shape, and the elastic element (22) is a conical spiral spring spirally wound on the outer surface of the supporting block (21);

the inner wall of the sliding sleeve (23) is provided with a plurality of mounting boxes (25) distributed along the circumferential direction, each mounting box (25) is internally provided with a pre-tightening spring (26), each ball (24) is respectively mounted on the surface of the corresponding mounting box (25), and the extending end of each pre-tightening spring (26) is connected with the corresponding ball (24).

2. The vibration damping and buffering mounting structure according to claim 1, wherein the elastic expansion and contraction direction of each pre-tightening spring (26) is perpendicular to the outer surface of the support block (21), a pressing plate (27) is further arranged in the mounting box (25), the outward extending end of the pre-tightening spring (26) is connected to one side surface of the pressing plate (27), and the ball (24) is rollably mounted on the other side surface of the pressing plate (27).

3. The vibration-damping cushion mounting structure according to claim 2, wherein an inwardly extending edge (28) extending a predetermined length inward for abutting against a top end of the elastic member (22) is provided on a bottom end surface of the sliding sleeve (23) in a horizontal direction.

4. The vibration-damping cushion mounting structure according to claim 3, wherein the top end of the support block (21) is provided with a stopper plate (29) which is expanded outward in the circumferential direction by a predetermined radius for preventing the balls (24) from coming out of the top end of the runner.

5. The vibration damping and buffering mounting structure according to any one of claims 1 to 4, wherein a cooling box (4) is provided on the surface of the mounting plate (3), and a plurality of fans (5) are installed inside the cooling box (4); the surface of the cooling box (4) is used for installing the server nodes (a), and a plurality of positioning plates (6) used for indicating the correct installation positions of the server nodes (a) are arranged on the surface of the cooling box (4).

6. The vibration damping and buffering mounting structure according to claim 5, wherein a dust removing box (7) is connected to the bottom of the mounting frame (1), a dust removing motor (8) is installed in the dust removing box (7), and a cleaning assembly (9) for cleaning the bottom of the mounting frame (1) is connected to an output end of the dust removing motor (8).

7. A rack-mounted server, comprising a cabinet and a vibration-damping and buffering mounting structure arranged in the cabinet, wherein the vibration-damping and buffering mounting structure is specifically the vibration-damping and buffering mounting structure of any one of claims 1 to 6.

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