Anti-oscillation mounting for a computer component
By combining a U-shaped base and top cover with rubber buffer blocks and a snap-fit mechanism, the problem of poor anti-vibration performance of computer hard drives during shocks is solved, achieving stability and convenient disassembly and assembly. The rubber pads can be replaced in time after wear, ensuring the safety and reliability of the hard drive.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- GUANGZHOU PENGLONGJISUANJI TECH CO LTD
- Filing Date
- 2025-06-30
- Publication Date
- 2026-07-03
AI Technical Summary
Existing computer hard drive mounting brackets have poor anti-vibration performance during shocks, lack stability and shock absorption, and hard drives are easily damaged by high-frequency vibrations, which accelerates the wear of rubber pads and reduces the cushioning effect.
It adopts a U-shaped base, top cover, rubber buffer block, rubber pad and snap-fit mechanism, combined with automatic compensation component and indicator mechanism, to offset the shock force through rubber buffer and deformation, providing triple buffer effect, and the rubber pad is kept in contact with the hard drive by tension spring to prevent it from falling off after wear.
It significantly reduces hard drive vibration frequency, improves stability, ensures that the hard drive is not easily dislodged during vibration, and is easy to disassemble and assemble. The rubber sheet can be replaced in time after wear, maintaining a highly efficient shock absorption effect.
Smart Images

Figure CN224453526U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of computer component installation technology, specifically to an anti-vibration mounting bracket for computer components. Background Technology
[0002] A computer consists of two parts: a hardware system and a software system. Computer components generally refer to the hardware required to assemble a computer. Computer components can generally be divided into motherboards, power supplies, storage controllers, portable storage devices, internal memory, and hard drives, etc. These components are assembled into the computer's hardware system according to certain rules.
[0003] Currently, computer hard drives are typically fixed to mounting brackets with screws during installation, which makes installation and removal inconvenient. In addition, since the hard drive is directly fixed inside the computer case, it is easily damaged when the case is subjected to vibration.
[0004] Currently, an existing shockproof mounting bracket for computer components, with publication number (CN211207970U), includes a mounting bracket body. A fixing rod is fixedly connected inside the mounting bracket body, and the surface of the fixing rod abuts against the inner wall of a first sliding block. A connecting rod is fixedly connected to the side of the first sliding block away from the mounting bracket body, and a first clamping plate is fixedly connected to the end of the connecting rod away from the first sliding block. A first fixing compartment is fixedly connected to the top of the first clamping plate, and a first pulling rod is inserted inside the first fixing compartment. This invention features a first clamping plate and a second clamping plate. By moving the second clamping plate up and down, a hard drive can be fixed inside the mounting bracket body, facilitating the removal and installation of the hard drive. The first sliding block slides up and down on the surface of the fixing rod, providing cushioning when the mounting bracket body is subjected to shock, effectively preventing damage to the hard drive.
[0005] During the implementation of the existing technical solution, at least the following technical problems were found:
[0006] The existing device uses a fixed rod and a first sliding block in conjunction with the elasticity of the second spring to mitigate the vibration force, thereby protecting the hard drive when the mounting bracket body is subjected to vibration. While the spring does provide some cushioning, it increases the vibration frequency, causing the hard drive to vibrate at high frequency between the first and second clamping plates. If a mechanical hard drive is clamped between the first and second clamping plates, it is very easy to be damaged by vibration. Furthermore, the vibration process will accelerate the wear of the rubber pad, making its cushioning effect worse or even ineffective. Therefore, the existing device has poor anti-vibration effect and lacks stability and shock absorption.
[0007] Therefore, there is an urgent need for a shockproof mounting bracket for computer components to solve the above problems. Utility Model Content
[0008] The purpose of this invention is to provide an anti-vibration mounting bracket for computer components to solve the problems mentioned in the background art, such as poor anti-vibration effect, lack of stability and shock absorption effect of existing devices.
[0009] To achieve the above objectives, this utility model provides the following technical solution: a shockproof mounting bracket for computer components, comprising a U-shaped base 1 and a top cover 2. A first rubber pad 101 is detachably connected to the top surface of the U-shaped base 1, and the first rubber pad 101 is detachably connected to the top surface of the U-shaped base 1 by an adhesive. The top cover 2 is connected to a damping mechanism for damping the computer components. Rubber buffer blocks 102 are fixedly connected to the two opposite side walls of the U-shaped base 1. S-shaped bends 104 are fixedly connected to the bottom of the two rubber buffer blocks 102. A snap-fit mechanism is provided between the top cover 2 and the U-shaped base 1. The damping mechanism includes a connecting plate 3, and a second rubber sheet 301 is detachably connected to the bottom of the connecting plate 3 by an adhesive. The second rubber sheet 301 is detachably connected to the bottom of the connecting plate 3, and the connecting plate 3 is connected to the top of the top cover 2 by an automatic compensation component.
[0010] Preferably, the automatic compensation component includes four limiting holes 203 on the top of the top cover 2, each limiting hole 203 is fitted with a limiting rod 302, the lower end of the limiting rod 302 is fixedly connected to the connecting plate 3, the upper end of each limiting rod 302 is fixedly connected to an end plate 303, a reset component is provided between the end plate 303 and the top cover 2, and an indicator mechanism is provided on the top of the connecting plate 3.
[0011] Preferably, the reset component includes a tension spring 304, and both ends of the tension spring 304 are fixed to the end plate 303 and the top cover 2, respectively.
[0012] Preferably, the indicating mechanism includes a red fluorescent column 4 fixedly connected to the top of the connecting plate 3, and the top of the top cover 2 has a through hole 204, the red fluorescent column 4 is inserted into the through hole 204, and the top of the red fluorescent column 4 is provided with a shielding member.
[0013] Preferably, the shielding component includes a cover plate 401 fixedly connected to the top of the red fluorescent column 4.
[0014] Preferably, the snap-fit mechanism includes two symmetrically arranged arc-shaped plates 201 fixedly connected to both sides of the top cover 2, and two snap-fit blocks 202 fixedly connected to the two inner side walls of the top cover 2. Three snap-fit slots 103 are opened on the two outer side walls of the U-shaped base 1, and the snap-fit blocks 202 are adapted to the snap-fit slots 103.
[0015] Compared with the prior art, the beneficial effects of this utility model are:
[0016] 2. This utility model discloses an anti-vibration mounting bracket for computer components. When the U-shaped base of this application is subjected to vibration, the S-shaped bend connecting the U-shaped base to the chassis can deform to offset part of the vibration force. At the same time, the two rubber buffer blocks can also deform further to form a buffer, reducing the vibration force that the hard drive mounted on the U-shaped base can be subjected to. The first rubber pad and the second rubber sheet clamp the hard drive to further reduce the vibration force transmitted from the chassis, forming a triple buffering effect. Compared with spring buffering, buffering with rubber obviously has higher stability and can significantly reduce the vibration frequency of the hard drive. This solves the problem of poor anti-vibration effect, lack of stability and shock absorption effect of existing devices.
[0017] 3. The anti-vibration mounting bracket for a computer component of this utility model addresses the issue that after prolonged use, the first rubber pad and the second rubber sheet will wear down. Due to the arrangement of four tension springs, the tension springs pull the end plate, causing the end plate to constantly push the limiting rod to press against the connecting plate. This ensures that the connecting plate pushes the second rubber sheet to maintain constant contact with the hard drive, while simultaneously pushing the hard drive to press against the first rubber pad. This prevents a large gap from forming between the hard drive and either the first or second rubber pad after the first and second rubber pads wear down, making the hard drive less likely to fall off and giving this application high stability.
[0018] 4. This utility model discloses a shockproof mounting bracket for computer components. Before installing the hard drive, the arc-shaped plate is first pressed to separate the locking block from the slot, and the top cover along with the damping mechanism is disassembled. Then, the hard drive is placed on top of the first rubber pad, and the top cover is returned to its original position. The locking block can be engaged in different slots according to the actual thickness of the hard drive. Finally, the hard drive is clamped between the first rubber pad and the second rubber sheet. Both the first rubber pad and the second rubber sheet have a certain degree of extensibility to accommodate slight differences in the thickness of the hard drive. Compared with the existing installation method of fixing the hard drive with screws, this application uses the locking block and slot in conjunction with the U-shaped base and the top cover to fix the hard drive. It can be disassembled and installed by hand without tools, giving this application the advantage of easy disassembly and assembly. Attached Figure Description
[0019] Figure 1 This is a three-dimensional structural diagram of the present invention;
[0020] Figure 2 This is a schematic diagram of the exploded structure of this utility model;
[0021] Figure 3 This is a schematic diagram of the top cover and vibration damping mechanism of this utility model in a separated state.
[0022] Figure 4 This is a schematic diagram of the U-shaped base structure of this utility model;
[0023] Figure 5 This utility model Figure 3A magnified structural diagram at point A.
[0024] In the diagram: 1. U-shaped base; 2. Top cover; 3. Connecting plate; 4. Red fluorescent column; 101. First rubber pad; 102. Rubber buffer block; 103. Slot; 104. S-shaped bend; 201. Arc plate; 202. Slot; 203. Limiting hole; 204. Through hole; 301. Second rubber sheet; 302. Limiting rod; 303. End plate; 304. Tension spring; 401. Cover plate. Detailed Implementation
[0025] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0026] Please see Figure 1-5 This utility model provides a shockproof mounting bracket for computer components, including a U-shaped base 1 and a top cover 2. The top surface of the U-shaped base 1 is detachably connected to a first rubber pad 101. The top cover 2 is connected to a damping mechanism for damping the computer components. Rubber buffer blocks 102 are fixedly connected to the two opposite side walls of the U-shaped base 1. S-shaped bends 104 are fixedly connected to the bottom of the two rubber buffer blocks 102. A snap-fit mechanism is provided between the top cover 2 and the U-shaped base 1. The damping mechanism includes a connecting plate 3. The bottom of the connecting plate 3 is detachably connected to a second rubber sheet 301. The connecting plate 3 is connected to the top of the top cover 2 through an automatic compensation component.
[0027] The automatic compensation component includes four limiting holes 203 on the top of the top cover 2. Each limiting hole 203 is fitted with a limiting rod 302, and the lower end of the limiting rod 302 is fixedly connected to the connecting plate 3. The upper end of each limiting rod 302 is fixedly connected to an end plate 303. A reset component is provided between the end plate 303 and the top cover 2, and an indicator mechanism is provided on the top of the connecting plate 3.
[0028] The reset component includes a tension spring 304, and the two ends of the tension spring 304 are fixed to the end plate 303 and the top cover 2, respectively.
[0029] The indicating mechanism includes a red fluorescent column 4 fixedly connected to the top of the connecting plate 3, and the top of the top cover 2 has a through hole 204, the red fluorescent column 4 is inserted into the through hole 204, and the top of the red fluorescent column 4 is provided with a shielding component.
[0030] The shielding component includes a cover plate 401 that is fixedly connected to the top of the red fluorescent column 4.
[0031] The snap-fit mechanism includes two symmetrically arranged arc-shaped plates 201 fixedly connected to both sides of the top cover 2. The two inner side walls of the top cover 2 are fixedly connected with snap-fit blocks 202. The two outer side walls of the U-shaped base 1 are provided with three snap-fit slots 103. The snap-fit blocks 202 are adapted to the snap-fit slots 103.
[0032] U-shaped base 1: Used to support and fix the hard drive, connected to the chassis, and participates in buffering and shock absorption through the S-shaped bend 104, rubber buffer block 102, first rubber pad 101 and other structures. The surface has a slot 103 that cooperates with the slot 202 of the top cover 2 to fix the top cover 2.
[0033] Top cover 2: It works with the U-shaped base 1 to fix the hard drive. The surface has a limiting hole 203 and a through hole 204 for installing the vibration damping mechanism. The arc plates 201 at both ends are easy to disassemble. The card block 202 on the inner side wall is adapted to the card slot 103 of the U-shaped base 1 for fixing the top cover 2 and the U-shaped base 1.
[0034] Connecting plate 3: Connects the second rubber sheet 301, the limiting rod 302 and the red fluorescent column 4, and plays the role of fixing and transmitting force. Together with the tension spring 304, it ensures that the second rubber sheet 301 is always in contact with the hard disk.
[0035] Red fluorescent column 4: It moves through the through hole 204 as the first rubber pad 101 and the second rubber sheet 301 wear out, reminding the user of the wear condition of the first rubber pad 101 and the second rubber sheet 301, making it easy to replace. The top cover plate 401 prevents the fluorescent column from completely passing through the through hole 204.
[0036] First rubber pad 101: Adhesive is used to attach it to the top surface of the U-shaped base 1. It works with the second rubber pad 301 to clamp the hard drive. It is flexible and can adapt to slight differences in the thickness of the hard drive. It also participates in buffering and shock absorption.
[0037] Rubber buffer block 102: It is set at both ends of the U-shaped base 1 near the S-shaped bend 104. When the U-shaped base 1 is subjected to vibration, it further deforms to form a buffer and reduce the vibration force on the hard drive.
[0038] Card slot 103: It is formed on the two outer side walls of the U-shaped base 1 and is adapted to the card block 202 of the top cover 2. It is used to fix the top cover 2 and the U-shaped base 1. The card block 202 can be engaged in different card slots 103 according to the thickness of the hard drive.
[0039] S-shaped bend 104: Set at both ends of the U-shaped base 1, it deforms when the U-shaped base 1 is subjected to vibration, thus offsetting part of the vibration force.
[0040] Arc-shaped plate 201: It is set at both ends of the top cover 2, so as to facilitate the snapping of the locking block 202 and the locking groove 103, thereby removing the top cover 2.
[0041] Card block 202: Fixedly connected to the two inner side walls of the top cover 2, and adapted to the slot 103 of the U-shaped base 1, used to fix the top cover 2 and the U-shaped base 1.
[0042] Limiting hole 203: It is formed on the surface of the top cover 2 and slides with the limiting rod 302 to limit the position and ensure the accurate installation position of the vibration damping mechanism.
[0043] Through hole 204: It is opened on the surface of the top cover 2 for the red fluorescent column 4 to pass through, and the displacement of the red fluorescent column 4 reminds the user of the wear status of the first rubber pad 101 and the second rubber sheet 301.
[0044] The second rubber sheet 301 is bonded to the bottom of the connecting plate 3 by adhesive and works with the first rubber pad 101 to clamp the hard drive. It has elasticity and can adapt to slight differences in the thickness of the hard drive. It also participates in buffering and shock absorption. Its thickness is two-thirds of the thickness of the first rubber pad 101.
[0045] Limiting rod 302: It is fixedly connected to the top surface of the connecting plate 3 and slides in the limiting hole 203 of the top cover 2 to limit the position and ensure that the installation position of the connecting plate 3 is accurate. It works with the end plate 303 and the tension spring 304 to make the connecting plate 3 push the second rubber sheet 301 to always be in contact with the hard disk.
[0046] End plate 303: It is fixedly connected to the end of the four limit rods 302 away from the connecting plate 3 and is connected to the tension spring 304. Under the tension of the tension spring 304, it pushes the limit rods 302 to squeeze the connecting plate 3, so that the connecting plate 3 pushes the second rubber sheet 301 to always be in contact with the hard disk.
[0047] Tension spring 304: connects the end plate 303 to the top surface of the top cover 2. Through tension, the end plate 303 pushes the limiting rod 302 to squeeze the connecting plate 3, so that the connecting plate 3 pushes the second rubber sheet 301 to always be in contact with the hard drive, preventing the hard drive from falling off.
[0048] Cover plate 401: It is fixedly connected to the end of the red fluorescent column 4 away from the connecting plate 3. When the red fluorescent column 4 passes through the through hole 204, the cover plate 401 is located inside the through hole 204 and is used to block the light of the red fluorescent column 4.
[0049] Working principle:
[0050] In the first step, before installing the hard drive, the arc plate 201 is first pulled to separate the locking block 202 from the slot 103, and the top cover 2 along with the damping mechanism is disassembled. Then, the hard drive is placed on top of the first rubber pad 101, and then the top cover 2 is put back in place. The locking block 202 can be locked into different slots 103 according to the actual thickness of the hard drive. Finally, the hard drive is clamped between the first rubber pad 101 and the second rubber sheet 301. Both the first rubber pad 101 and the second rubber sheet 301 have a certain degree of extensibility to adapt to slight differences in the thickness of the hard drive.
[0051] The second step is that when the U-shaped base 1 of this application is subjected to vibration, the S-shaped bend 104 connecting the U-shaped base 1 to the chassis can deform to offset part of the vibration force. At the same time, the two rubber buffer blocks 102 can also deform further to form a buffer, reducing the vibration force that the hard drive installed on the U-shaped base 1 can be subjected to. The first rubber pad 101 and the second rubber sheet 301 clamp the hard drive to further reduce the vibration force transmitted from the chassis, forming a triple buffering effect.
[0052] Thirdly, after prolonged use, the first rubber pad 101 and the second rubber sheet 301 will wear out. Due to the setting of four tension springs 304, the tension springs 304 pull the end plate 303, so that the end plate 303 always pushes the limit rod 302 to squeeze the connecting plate 3, so that the connecting plate 3 pushes the second rubber sheet 301 to always be in contact with the hard drive, and at the same time pushes the hard drive to squeeze and contact the first rubber pad 101, preventing a large gap from forming between the hard drive and the first rubber pad 101 or the second rubber sheet 301 after the first rubber pad 101 and the second rubber sheet 301 wear out, so that the hard drive is not easy to fall off.
[0053] Fourthly, after the first rubber pad 101 and the second rubber sheet 301 continue to wear, the connecting plate 3 is constantly moved towards the hard drive by the tension spring 304, which causes the red fluorescent column 4 connected above to move towards the hard drive. Before the first rubber pad 101 and the second rubber sheet 301 wear to failure, the red fluorescent column 4 will first pass through the through hole 204, leaving only the cover plate 401 part above the through hole 204. At this time, when the user performs overall maintenance on the computer, it is easy to observe that the red fluorescent column 4 is blocked by the top cover 2 and the cover plate 401, which makes it easier for the user to understand the wear condition of the first rubber pad 101 and the second rubber sheet 301 and facilitates subsequent replacement.
[0054] It will be apparent to those skilled in the art that this invention is not limited to the details of the exemplary embodiments described above, and that it can be implemented in other specific forms without departing from the spirit or essential characteristics of this invention. Therefore, the embodiments should be considered illustrative and non-limiting in all respects, and the scope of this invention is defined by the appended claims rather than the foregoing description. Thus, it is intended that all variations falling within the meaning and scope of equivalents of the claims be included within this invention. No reference numerals in the claims should be construed as limiting the scope of the claims.
Claims
1. An anti-oscillation mounting for a computer component, comprising: The device includes a U-shaped base (1) and a top cover (2). The top surface of the U-shaped base (1) is detachably connected to a first rubber pad (101). The top cover (2) is connected to a damping mechanism for damping the computer components. Rubber buffer blocks (102) are fixedly connected to the two opposite side walls of the U-shaped base (1). S-shaped bends (104) are fixedly connected to the bottom of the two rubber buffer blocks (102). A snap-fit mechanism is provided between the top cover (2) and the U-shaped base (1). The vibration damping mechanism includes a connecting plate (3), and a second rubber sheet (301) is detachably connected to the bottom of the connecting plate (3), and the connecting plate (3) is connected to the top of the top cover (2) through an automatic compensation component.
2. The anti-oscillation mounting rack for computer components of claim 1, wherein: The automatic compensation component includes four limiting holes (203) on the top of the top cover (2). Each limiting hole (203) is fitted with a limiting rod (302), and the lower end of the limiting rod (302) is fixedly connected to the connecting plate (3). The upper end of each limiting rod (302) is fixedly connected to an end plate (303). A reset component is provided between the end plate (303) and the top cover (2), and an indicator mechanism is provided on the top of the connecting plate (3).
3. A shock mounting for a computer component according to claim 2, wherein: The reset component includes a tension spring (304), and the two ends of the tension spring (304) are fixed to the end plate (303) and the top cover (2) respectively.
4. The anti-oscillation mounting rack for computer components of claim 2, wherein: The indicating mechanism includes a red fluorescent column (4) fixedly connected to the top of the connecting plate (3), and the top of the top cover (2) is provided with a through hole (204), the red fluorescent column (4) is inserted into the through hole (204), and a shielding component is provided on the top of the red fluorescent column (4).
5. The shockproof mounting bracket for a computer component according to claim 4, characterized in that: The shielding component includes a cover plate (401) fixedly connected to the top of the red fluorescent column (4).
6. The anti-oscillation mounting rack for computer components of claim 1, wherein: The snap-fit mechanism includes two symmetrically arranged arc-shaped plates (201) fixedly connected to both sides of the top cover (2). The two inner side walls of the top cover (2) are fixedly connected with snap-fit blocks (202). The two outer side walls of the U-shaped base (1) are provided with three snap-fit slots (103). The snap-fit blocks (202) are adapted to the snap-fit slots (103).