A general-purpose installation device for big data servers

By using a perforated mounting plate and an adjustable mounting mechanism, the problem of poor compatibility of traditional server installation equipment is solved, enabling adaptation and precise positioning to cabinets of different sizes, thus improving the flexibility and stability of installation.

CN224439422UActive Publication Date: 2026-06-30ZHONGCHENG YOUXUAN (TIANJIN) TECHNOLOGY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
ZHONGCHENG YOUXUAN (TIANJIN) TECHNOLOGY CO LTD
Filing Date
2025-08-04
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

Traditional server installation equipment suffers from insufficient compatibility and struggles to adapt to the installation requirements of cabinets of different sizes and specifications. In particular, wall-mounted installations require precise positioning and drilling, leading to installation difficulties.

Method used

The system employs a multi-hole mounting plate, an adjustable mounting mechanism, and positioning and fixing components, including an adjusting slide, adjusting screw, fixing slider, and positioning rod, to achieve stepless adjustment of the horizontal position and fine-tuning of the height of the server frame, ensuring installation flexibility and stability.

Benefits of technology

It enables adaptation to cabinets of different depths, improving the flexibility, precision, stability, and ease of maintenance during installation, and solving the problem of traditional installation equipment being unable to adjust.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model discloses a universal installation device for big data servers, including a mounting plate with multiple positioning holes and embedded bolts in the holes. A server mounting frame is connected to one side of the mounting plate. The server mounting frame is a rectangular frame, and at least one pair of mounting rods are provided on one side of the server mounting frame. This utility model relates to the field of installation equipment technology. This device achieves stepless adjustment of the horizontal position of the server frame through an adjustable screw-slider mechanism, adapting to cabinets of different depths. The densely overlapping through holes on the mounting rods, combined with the positioning rods, provide stepless height fine-tuning and secure positioning. The T-shaped slider and groove matching, the integrated molding structure, and the triangular reinforcing ribs ensure high load-bearing rigidity and deformation resistance. The rectangular limit block enhances the anti-loosening safety, completely solving the problems of poor compatibility and inability to adjust after wall mounting in traditional installations, significantly improving installation flexibility, accuracy, stability, and maintenance convenience.
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Description

Technical Field

[0001] This utility model relates to the field of installation equipment technology, specifically a general installation device for big data servers. Background Technology

[0002] With the rapid development of big data technology, the installation and deployment efficiency, compatibility, and security of big data servers, as core data processing equipment, have become crucial aspects of data center construction. However, traditional server installation equipment often adopts a fixed rack structure, using bolts or pre-set guide rails for server positioning. This design generally suffers from insufficient compatibility, often only adapting to specific server models and failing to meet the installation needs of cabinets of different sizes. For example, while some existing technologies have lifting functions, they do not solve the size adjustment problem, resulting in limited applicability. Especially when wall-mounted, more precise positioning and drilling are required. Once the wall-mounted installation is completed, it becomes impossible to adjust, easily leading to difficulties in installing big data servers. In view of this, this case study was developed to address the above problems. Utility Model Content

[0003] In view of the shortcomings of the existing technology, this utility model provides a general installation device for big data servers, which solves the existing background technology problems.

[0004] To achieve the above objectives, this utility model is implemented through the following technical solution: a general installation device for big data servers, including an installation plate, the installation plate having multiple installation holes, bolts embedded in the installation holes, and a server installation frame connected to one side of the installation plate;

[0005] The server mounting frame is a rectangular frame, and at least one pair of mounting rods are provided on one side of the server mounting frame.

[0006] The mounting plate is provided with an adjustment mounting mechanism, which includes at least two pairs of adjustment slides. The two pairs of adjustment slides are provided on the mounting plate. An adjustment shaft is provided in the adjustment slide, and an adjustment screw is provided on the adjustment shaft. An adjustment slider is threadedly connected to the adjustment screw, and the adjustment slider matches the adjustment slide.

[0007] The adjustment and installation mechanism also includes a fixed slider. A fixed slider is provided on one side of the adjustment slider, and a mounting slot is provided on one side of the fixed slider. The mounting rod is assembled on the mounting slot, and a positioning and fixing component is provided on the fixed slider to cooperate with the mounting rod to fix the horizontal position of the server mounting frame.

[0008] Preferably, the end of the adjusting screw penetrates the side wall of the mounting plate, and the end of the adjusting screw is provided with an internal hexagonal groove.

[0009] Preferably, the adjusting slider is a T-shaped structural plate, and the adjusting groove matches the shape of the adjusting slider.

[0010] Preferably, the fixed slider and the adjusting slider are integrally formed, and the bottom surface of the adjusting slider is provided with triangular reinforcing ribs.

[0011] Preferably, the positioning and fixing component includes a positioning hole, the bottom of the mounting slot is provided with a positioning hole, and a plurality of through holes are continuously provided on the corresponding mounting rod. The plurality of through holes are arranged in an overlapping manner. A positioning rod is installed on the mounting hole, and the positioning rod passes through any of the through holes and is threadedly connected to the positioning hole.

[0012] Preferably, the top of the positioning rod is movably provided with a rectangular limiting block that matches the top opening of the mounting slot.

[0013] This utility model provides a universal installation device for big data servers. It offers the following advantages: The device achieves stepless horizontal adjustment of the server frame's position through an adjustable screw-slider mechanism, adapting to cabinets of varying depths; densely overlapping through-holes on the mounting rod, combined with positioning rods, provide stepless height fine-tuning and secure positioning; the T-shaped slider and groove matching, integrated molding structure, and triangular reinforcing ribs ensure high load-bearing rigidity and deformation resistance; rectangular limit blocks enhance anti-loosening safety, completely solving the problems of poor compatibility and inability to adjust after wall mounting in traditional installations, significantly improving installation flexibility, precision, stability, and ease of maintenance. Attached Figure Description

[0014] Figure 1 This is a three-dimensional structural diagram of a general installation device for a big data server as described in this utility model.

[0015] Figure 2 This is a partial three-dimensional structural diagram of a general installation device for a big data server according to the present invention.

[0016] Figure 3 This is a partial blasting structure diagram of a general installation device for a big data server according to the present invention.

[0017] In the diagram: 1. Mounting plate; 2. Mounting hole; 3. Server mounting frame; 4. Mounting rod; 5. Through hole; 6. Adjustment mounting mechanism; 61. Adjustment slide; 62. Adjustment shaft; 63. Adjustment screw; 64. Adjustment slider; 65. Fixed slider; 66. Mounting slot; 67. Positioning and fixing component; 671. Positioning hole; 672. Positioning rod; 673. Rectangular limit block. Detailed Implementation

[0018] 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.

[0019] Please see Figure 1-3 This utility model provides an implementation scheme: Traditional server installation equipment mostly adopts a fixed rack structure, which can only be adapted to specific models of servers and is difficult to meet the installation needs of cabinets of different sizes and specifications. At the same time, although the existing technology has a lifting function, it has not solved the size adjustment problem, resulting in limited applicability. Especially when wall-mounted, more precise positioning and drilling work are required. Once the installation is completed, the wall-mounted installation cannot be adjusted, which can easily lead to difficulties in the installation of big data servers.

[0020] To address the aforementioned issues, this application discloses a universal installation device for big data servers, including a mounting plate 1. The mounting plate 1 has multiple mounting holes 2, which provide precise insertion positions for embedded bolts, ensuring that the mounting plate 1 can be securely fixed to a wall or supporting structure, forming the basic anchoring points for the entire device. Embedded bolts, which are expansion bolts, are installed in the mounting holes 2, passing through the mounting holes 2 and penetrating deep into the wall to firmly anchor the mounting plate 1 in a predetermined position, bearing the entire weight of the server and frame. A server mounting frame 3 is connected to one side of the mounting plate 1. The server mounting frame 3 is the rigid main body that directly supports and fixes the big data server cabinet. Its structural strength must ensure the stability of the server during operation. The server mounting frame 3 is designed according to the server specifications and is a rectangular frame. The rectangular frame provides a sturdy support platform, ensuring the flatness and overall rigidity of the server installation and preventing deformation.

[0021] According to the instruction manual Figure 1-3 It is known that at least one pair of mounting rods 4 are provided on one side of the server mounting frame 3; the mounting rods 4, as the connecting bridge between the frame and the adjustment mechanism, extend perpendicularly to the mounting plate 1, and their position changes directly determine the position of the server frame, and are the key force-bearing components for realizing the adjustment function.

[0022] According to the instruction manual Figure 1-3As can be seen, the mounting plate 1 is equipped with an adjustment mounting mechanism 6. This adjustment mounting mechanism 6 is a core functional module, enabling the device to adapt to different server sizes and fine-tune its position after installation, solving the rigid fit problem of traditional solutions. The adjustment mounting mechanism 6 includes at least two pairs of adjustment slides 61. One pair of parallel adjustment slides 61 is fixed to the mounting plate 1, forming at least four precise guide tracks. This strictly limits the movement path and direction of subsequent moving parts, ensuring the straightness and stability of the adjustment process. The four pairs of adjustment slides 61 are symmetrically arranged on both sides of the mounting plate 1. An adjustment shaft 62 is installed within each adjustment slide 61 for adjustment... The rotating shaft 62 is located at the end of the slide groove, providing stable rotational support and ensuring concentricity. An adjusting screw 63 is installed on the adjusting shaft 62. The adjusting screw 63 is a precision drive element, and its rotational motion is converted into linear displacement through a threaded pair, providing controllable and precise position adjustment power. The threaded pair of the adjusting screw 63 is connected to the adjusting slider 64, which efficiently converts the rotational force of the screw into its own linear movement force. It is the direct execution component for position adjustment. The adjusting slider 64 matches the adjusting slide groove 61, ensuring that the slider can only slide precisely along the slide groove direction, effectively preventing offset, tilting, or derailment, and ensuring adjustment accuracy and load-bearing stability.

[0023] The adjustment and mounting mechanism 6 also includes a fixed slider 65. A fixed slider 65 is provided on one side of the adjustment slider 64. The fixed slider 65 serves as a rigid connector between the adjustment slider 64 and the server frame, and integrates a locking function. The fixed slider 65 is rigidly connected to the adjustment slider 64, ensuring synchronous movement and transmitting the adjustment action to the server frame without deviation. A mounting slot 66 is provided on one side of the fixed slider 65. The mounting slot 66 is an upward-opening U-shaped structure used to accommodate the mounting rod 4 of the server mounting frame 3, providing a convenient initial mounting interface and vertical support limit. The mounting rod 4 is mounted on the mounting slot 66 and embedded within it, allowing the server mounting frame 3 to suspend on the fixed slider 65. This allows for minor vertical position adjustments before final locking. A positioning and fixing component 67 is provided on the fixed slider 65, which works with the mounting rod 4 to fix the horizontal position of the server mounting frame 3. After adjustment, the mounting rod 4 and the fixed slider 65 are firmly locked, eliminating any possibility of loosening and ensuring absolute stability during server operation.

[0024] As a preferred option, the end of the adjusting screw 63 extends through the side wall of the mounting plate 1. This design exposes the screw drive end for easy operation. The end of the adjusting screw 63 is provided with an internal hexagonal slot, which is a standard interface that allows a universal internal hexagonal wrench to be inserted and rotated without relying on power tools.

[0025] As a preferred option, the adjusting slider 64 is further designed as a T-shaped structure plate, which provides a larger upper connecting surface and reliable anti-overturning capability.

[0026] As a preferred option, the fixed slider 65 and the adjusting slider 64 are integrally formed. The integral forming eliminates the connecting parts and potential loose points. The bottom surface of the adjusting slider 64 is provided with triangular reinforcing ribs. The triangular reinforcing ribs are welded or cast on the bottom surface of the slider, which significantly enhances the slider's ability to resist bending deformation, effectively copes with the long-term static load and dynamic load of the server, and prevents the positional inaccuracy or failure caused by deformation.

[0027] As a preferred embodiment, the positioning and fixing component 67 further includes a positioning hole 671, which is formed on the bottom fixing slider 65 of the mounting slot 66. This positioning hole 671 serves as a reference hole for locking. The bottom of the mounting slot 66 has the positioning hole 671, and the corresponding mounting rod 4 has a series of through holes 5. These through holes 5 are densely arranged along the length of the mounting rod 4, providing continuously selectable height fixing points. The overlapping arrangement of the through holes 5 eliminates adjustment gaps, allowing for near-stepless precise height positioning along the length of the mounting rod 4, meeting the extremely high levelness requirements of server installation. A positioning rod 672 is installed on the mounting hole. The positioning rod 672, a bolt, is the final locking actuator. The positioning rod 672 passes through any of the through holes 5 and is threaded into the positioning hole 671. By selecting a suitable through hole 5 on the mounting rod 4 and aligning it with the positioning hole 671 of the fixing slider 65, the positioning rod 672 is passed through the aligned hole and tightened, thus firmly locking the mounting rod 4 onto the fixing slider 65, achieving absolute fixation of the horizontal position.

[0028] As a preferred option, the top of the positioning rod 672 is movably provided with a rectangular limiting block 673 that matches the top opening of the mounting slot 66. After the positioning rod 672 is locked, the limiting block is rotated to lock it into the top opening of the mounting slot 66, forming a mechanical block, which effectively prevents the positioning rod 672 from loosening and rotating under vibration or accidental conditions, providing additional anti-loosening safety protection.

[0029] Working process: First, the mounting plate 1 is fixed to the wall with bolts. The mounting rods 4 on both sides of the server mounting frame 3 are initially suspended by inserting them into the mounting slots 66 of the corresponding fixed sliders 65. An Allen wrench is inserted into the Allen socket at the end of the adjusting screw 63 and rotated to drive the adjusting screw 63 to rotate. This causes the adjusting slider 64, which is threaded to it, to move linearly along the adjusting groove 61. The two pairs of fixed sliders 65 are arranged in an alternating manner, so that the pair of mounting rods 4 on the back of the server mounting frame 3 can be arranged vertically. This staggered distribution effectively disperses the load-bearing capacity of the installation. This allows for adjustment of the server mounting frame 3 to the horizontal plane to accommodate server cabinets of different sizes. After fine-tuning the server mounting frame 3 within the mounting slot 66 to the precise height, a specific overlapping through hole 5 on the mounting rod 4 is selected and aligned with the positioning hole 671 on the fixed slider 65. The positioning rod 672 is then passed through the aligned through hole 5 and positioning hole 671 and tightened. Finally, the rectangular limit block 673 at the top of the positioning rod 672 is rotated to lock into the top opening of the mounting slot 66, preventing the positioning rod 672 from loosening. After adjustment and locking, the server cabinet is installed onto the server mounting frame 3.

[0030] In summary, this device achieves stepless horizontal adjustment of the server frame's position through the adjusting screw 63 and slider mechanism, adapting to cabinets of different depths; the densely overlapping through holes 5 on the mounting rod 4, combined with the positioning rod 672, provide stepless height fine-tuning and secure positioning; the T-shaped slider and groove matching, the integrated molding structure, and the triangular reinforcing ribs ensure high load-bearing rigidity and resistance to deformation; the rectangular limit block 673 enhances anti-loosening safety, completely solving the problems of poor compatibility and inability to adjust after wall mounting in traditional installations, significantly improving installation flexibility, accuracy, stability, and ease of maintenance.

[0031] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. A general-purpose installation device for a big data server, comprising an installation plate (1) having a plurality of installation holes (2) formed therein, and a buried bolt provided in each installation hole (2), characterized in that, The mounting plate (1) is connected to a server mounting frame (3) on one side; The server mounting frame (3) is a rectangular frame, and at least one pair of mounting rods (4) are provided on one side of the server mounting frame (3); An adjustment mounting mechanism (6) is provided on the mounting plate (1). The adjustment mounting mechanism (6) includes at least two pairs of adjustment slides (61). The two pairs of adjustment slides (61) are provided on the mounting plate (1). An adjustment shaft (62) is provided in the adjustment slide (61). An adjustment screw (63) is provided on the adjustment shaft (62). An adjustment slider (64) is threadedly connected to the adjustment screw (63). The adjustment slider (64) matches the adjustment slide (61). The adjustment and installation mechanism (6) further includes a fixed slider (65). The fixed slider (65) is provided on one side of the adjustment slider (64), and the fixed slider (65) is provided on one side of the mounting slot (66). The mounting rod (4) is assembled on the mounting slot (66). The fixed slider (65) is provided with a positioning and fixing component (67) which cooperates with the mounting rod (4) to fix the horizontal position of the server mounting frame (3).

2. The general installation equipment for a big data server according to claim 1, characterized in that, The end of the adjusting screw (63) penetrates the side wall of the mounting plate (1), and the end of the adjusting screw (63) is provided with an internal hexagonal groove.

3. The general installation equipment for a big data server according to claim 2, characterized in that, The adjusting slider (64) is a T-shaped structure plate, and the adjusting groove (61) matches the shape of the adjusting slider (64).

4. The general installation equipment for a big data server according to claim 3, characterized in that, The fixed slider (65) and the adjusting slider (64) are integrally formed, and the bottom surface of the adjusting slider (64) is provided with triangular reinforcing ribs.

5. The general installation device for a big data server according to claim 4, characterized in that, The positioning and fixing component (67) includes a positioning hole (671). The bottom of the mounting slot (66) is provided with a positioning hole (671). A plurality of through holes (5) are continuously provided on the corresponding mounting rod (4). The plurality of through holes (5) are arranged in an overlapping manner. A positioning rod (672) is installed on the mounting hole. The positioning rod (672) passes through any of the through holes (5) and is threadedly connected to the positioning hole (671).

6. The general installation device for a big data server according to claim 5, characterized in that, The top of the positioning rod (672) is movably provided with a rectangular limiting block (673) that matches the top opening of the mounting slot (66).