A computer big data wireless connection device

By using a detachable electric push rod and a precisely matched slide rail slider structure, the problem of difficult disassembly of the wear-resistant block in the computer big data wireless connection device is solved, enabling convenient replacement of the wear-resistant block and improving the stability of the equipment.

CN224503704UActive Publication Date: 2026-07-14SCHOOL OF SCI & LITERATURE JIANGSU NORMAL UNIV

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SCHOOL OF SCI & LITERATURE JIANGSU NORMAL UNIV
Filing Date
2025-07-31
Publication Date
2026-07-14

AI Technical Summary

Technical Problem

The wear-resistant blocks of existing wireless connection devices for computer big data are difficult to disassemble and replace easily, resulting in cumbersome operation and potential damage to the device itself, which consumes time and manpower costs.

Method used

The first and second auxiliary mechanisms, which feature a detachable design, include components such as electric push rods, slide rails, sliders, T-blocks, and cylinders. The slider is driven to rise by the electric push rods, enabling convenient disassembly and replacement of the wear-resistant blocks. The anti-slip texture and precisely matched slide rail and slider structure enhance stability.

Benefits of technology

This allows for easy replacement of wear-resistant blocks, preventing device wear, ensuring equipment stability and smooth operation, and improving maintenance convenience and equipment lifespan.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model relates to wireless connection device technical field, concretely is a kind of computer big data wireless connection device, including body, first auxiliary mechanism and second auxiliary mechanism, the first auxiliary mechanism includes first connecting shell, first wear block, first electric push rod, first connecting block, first slide rail, first sliding block, first cylinder and T block, the first connecting block with the body side surface outer wall contact, the first wear block with first connecting shell bottom connection, first electric push rod one end with first connecting shell top connection, first electric push rod other end with first connecting block one end connection, the other end of first connecting block with first slide rail connection, first sliding block one end extends into first slide rail, first sliding block other end with T block one end connection, a kind of computer big data wireless connection device of the utility model, solve the problem of current equipment inconvenient disassembly.
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Description

Technical Field

[0001] This utility model relates to the field of wireless connection device technology, specifically a computer big data wireless connection device. Background Technology

[0002] As is well known, computer big data wireless connection devices are a type of equipment used to realize the wireless transmission of massive amounts of data (such as TB-level business data and real-time monitoring data). The core function is to establish stable "terminal-server" and "terminal-terminal" data links through wireless communication technologies (such as 5G, Wi-Fi 6, LoRa, etc.) to support high-bandwidth, low-latency big data interaction (such as real-time data synchronization between remote servers and local terminals, and data aggregation of multi-terminal clusters).

[0003] Existing wireless computer big data connection devices typically have wear-resistant blocks at the bottom. The core function of these blocks is to isolate the bottom of the device from the contact surface by allowing direct contact with the ground, desktop, or other flat surfaces, thus preventing wear and tear and extending the device's lifespan. However, most of these wear-resistant blocks are currently connected to the device body via direct fixing methods (such as adhesive or one-piece molding). While this connection structure ensures stability during daily use, it presents significant disassembly challenges. When the wear-resistant blocks need replacement due to aging or severe wear after long-term use, the lack of a convenient disassembly mechanism often requires workers to forcibly peel them off with tools. This is not only cumbersome but may also cause accidental damage to the device body during disassembly, while also wasting considerable time and manpower. Utility Model Content

[0004] (a) Technical problems to be solved

[0005] To address the shortcomings of existing technologies, this utility model provides a wireless connection device for computer big data.

[0006] (II) Technical Solution

[0007] To achieve the above objectives, this utility model provides the following technical solution: A wireless connection device for computer big data, comprising a main body, a first auxiliary mechanism, and a second auxiliary mechanism. The first auxiliary mechanism includes a first connecting shell, a first wear-resistant block, a first electric push rod, a first connecting block, a first slide rail, a first slider, a first cylinder, and a T-shaped block. The first connecting block contacts the outer wall of the side of the main body. The first wear-resistant block is connected to the bottom of the first connecting shell. One end of the first electric push rod is connected to the top of the first connecting shell, and the other end of the first electric push rod is connected to one end of the first connecting block. The other end of the first connecting block is connected to the first slide rail. One end of the first slider extends into the first slide rail, and the other end of the first slider is connected to one end of the T-shaped block. One end of the first cylinder is connected to the top of the main body. The first cylinder is connected to the second slider at one end. The second auxiliary mechanism includes a second connecting shell, a second wear-resistant block, a second electric push rod, a second connecting block, a second slide rail, a second slider, a second cylinder, and a T-slot. The second connecting block contacts the outer wall of the side of the main body. The second wear-resistant block is connected to the bottom of the second connecting shell. One end of the second electric push rod is connected to the top of the second connecting shell. The other end of the second electric push rod is connected to one end of the second connecting block. The other end of the second connecting block is connected to the second slide rail. One end of the second slider extends into the second slide rail. The T-slot is opened at the other end of the second slider. The other end of the T-block extends into the T-slot. One end of the second cylinder is connected to the top of the main body. The other end of the second cylinder passes through the second slider.

[0008] To improve the anti-slip effect, the present invention is improved by providing anti-slip patterns on the bottom of both the first wear-resistant block and the second wear-resistant block, wherein the anti-slip patterns are provided in multiple strips.

[0009] To improve stability, the present invention is improved in that the first slide rail is matched with the first slider, and the second slide rail is matched with the second slider.

[0010] To improve stability, this invention is improved by matching the T-shaped block with the T-shaped groove.

[0011] To improve stability, the present invention is improved in that the first auxiliary mechanism and the second auxiliary mechanism are arranged symmetrically.

[0012] To improve the connection effect, the present invention is improved in that both the first cylinder and the second cylinder are welded to the body.

[0013] (III) Beneficial Effects

[0014] Compared with the prior art, the present invention provides a wireless connection device for computer big data, which has the following advantages:

[0015] This wireless connection device for computer big data features a structure where the first and second wear-resistant blocks contact the placement surface, effectively isolating the bottom of the device body from the contact surface, preventing direct wear on the bottom of the body, and extending the device's service life. The wear-resistant blocks are detachable; when they need to be replaced due to aging, the controller activates an electric push rod to raise the slider, separating the T-block from the T-slot, allowing the wear-resistant block to be removed. This solves the problems of traditional fixed wear-resistant blocks being difficult to disassemble and time-consuming to replace. Furthermore, the high degree of matching between components, with precise fit between the slide rail and slider, and between the T-block and T-slot, along with symmetrically arranged auxiliary mechanisms and welded fixation between the cylinder and the body, ensures stable device support and smooth operation, preventing loosening or jamming of components. The anti-slip textured design on the bottom of the wear-resistant blocks further enhances the stability of the device placement. The overall structure balances protection and ease of maintenance, making it highly practical. Attached Figure Description

[0016] Figure 1 This is a schematic diagram of the structure of this utility model;

[0017] Figure 2 This utility model Figure 1 A magnified schematic diagram of the local structure at point A;

[0018] Figure 3 This utility model Figure 1 A magnified view of the structure at point B in the middle;

[0019] Figure 4 This utility model Figure 1 A magnified schematic diagram of the local structure at point C;

[0020] In the figure: 1. Main body; 2. First auxiliary mechanism; 3. First connecting shell; 4. First wear-resistant block; 5. First electric push rod; 6. First connecting block; 7. First slide rail; 8. First slider; 9. First cylinder; 10. T-slot; 11. Second auxiliary mechanism; 12. Second connecting block; 13. Second wear-resistant block; 14. Second electric push rod; 15. Second connecting block; 16. Second slide rail; 17. Second slider; 18. Second cylinder; 19. T-slot. Detailed Implementation

[0021] 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.

[0022] Please see Figure 1-4A wireless connection device for computer big data includes a main body 1, a first auxiliary mechanism 2, and a second auxiliary mechanism 11. The first auxiliary mechanism 2 includes a first connecting shell 3, a first wear-resistant block 4, a first electric push rod 5, a first connecting block 6, a first slide rail 7, a first slider 8, a first cylinder 9, and a T-shaped block 10. The first connecting block 6 contacts the outer side wall of the main body 1. The first wear-resistant block 4 is connected to the bottom of the first connecting shell 3. One end of the first electric push rod 5 is connected to the top of the first connecting shell 3, and the other end of the first electric push rod 5 is connected to one end of the first connecting block 6. The other end of the first connecting block 6 is connected to the first slide rail 7. One end of the first slider 8 extends into the first slide rail 7, and the other end of the first slider 8 is connected to one end of the T-shaped block 10. One end of the first cylinder 9 is connected to the top of the main body 1, and the other end of the first cylinder 9 passes through the first slider 8. The second auxiliary mechanism 11 includes a second connecting shell 12, a second wear-resistant block 13, a second electric push rod 14, a second connecting block 15, a second slide rail 16, a second slider 17, a second cylinder 18, and a T-slot 19. The second connecting block 15 contacts the outer side wall of the main body 1. The second wear-resistant block 13 is connected to the bottom of the second connecting shell 12. One end of the second electric push rod 14 is connected to the top of the second connecting shell 12, and the other end of the second electric push rod 14 is connected to one end of the second connecting block 15. The other end of the second connecting block 15 is connected to the second slide rail 16. One end of the second slider 17 extends into the second slide rail 16. The T-slot 19 is formed at the other end of the second slider 17. The other end of the T-block 18 extends into the T-slot 19. One end of the second cylinder 18 is connected to the top of the main body 1, and the other end of the second cylinder 18 passes through the second slider 17.

[0023] Working principle

[0024] When using the device, first place it in the designated position. The first wear-resistant block 4 and the second wear-resistant block 13 will provide stable support for the main body 1. Then connect the main body 1 to the external data cable, etc. The main body 1 is a conventional computer big data wireless connection device on the market. It contains a power supply mechanism, a data processing module, a wireless communication module, an antenna module, a heat dissipation module, and a protective shell, etc. (Specific details may vary slightly depending on the application scenario, and will not be explained here).

[0025] During normal operation, the first wear-resistant block 4 and the second wear-resistant block 13 are in direct contact with the ground or other flat surfaces, which can isolate the bottom of the body 1 from the contact surface and effectively prevent the bottom of the body 1 from being worn due to direct contact.

[0026] When the first wear-resistant block 4 and the second wear-resistant block 13 need to be replaced due to aging or wear after long-term use, the operation procedure is as follows:

[0027] The staff can simultaneously activate the first electric push rod 5 and the second electric push rod 14 through the controller on the main body 1;

[0028] The first electric push rod 5 drives the first connecting block 6 to move upward, and the second electric push rod 14 drives the second connecting block 15 to move upward, thereby driving the first slider 8 and the second slider 17 to rise synchronously until the first slider 8 separates from the first cylinder 9 and the second slider 17 separates from the second cylinder 18.

[0029] The first slider 8 is pushed to slide within the first slide rail 7, while the second slider 17 is pushed to slide within the second slide rail 16, causing the T-block 10 to disengage from the T-slot 19;

[0030] Pulling the first connecting shell 3 and the second connecting shell 12 can completely separate them from the main body 1. Since the first wear-resistant block 4 is fixed to the bottom of the first connecting shell 3 and the second wear-resistant block 13 is fixed to the bottom of the second connecting shell 12, the first wear-resistant block 4 and the second wear-resistant block 13 can be disassembled.

[0031] When replacing, simply reverse the steps described above to complete the reset. New parts can be purchased from the manufacturer. The installation steps are standard procedures in this technical field and will not be explained in detail here.

[0032] It should be noted that both the first slide rail 7 and the second slide rail 16 adopt a T-shaped structure, and the parts of the first slider 8 and the second slider 17 that extend into the slide rail are also designed to be T-shaped. This structural matching method can ensure that the slider will not fall off when sliding in the slide rail, further improving the stability of the operation process.

[0033] To further improve the anti-slip effect when the equipment is placed, in this embodiment, the bottom of both the first wear-resistant block 4 and the second wear-resistant block 13 are specially provided with anti-slip patterns, and the anti-slip patterns adopt a design of several parallel (or staggered) distributions. This multi-pattern anti-slip structure can increase the friction between the first wear-resistant block 4, the second wear-resistant block 13 and the placement surface (such as the ground or tabletop), effectively reducing the possibility of displacement of the equipment due to external force contact, vibration, etc. during use, thereby further improving the stability of the equipment placement while ensuring the wear-resistant function.

[0034] To further improve the overall stability of the equipment structure, especially the fitting accuracy of components during relative movement, in this embodiment, the first slide rail 7 and the first slider 8 adopt a precisely matched structural design, and the second slide rail 16 and the second slider 17 also adopt a corresponding matching structural design. Specifically, the groove size and inner wall flatness of the slide rail are perfectly matched with the outer dimensions and contact surface accuracy of the slider. This matching relationship ensures that when the first slider 8 slides in the first slide rail 7 and the second slider 17 slides in the second slide rail 16, there will be no loosening, shaking, or jamming. Whether it is the support and fixation of the wear-resistant block in daily use or the sliding operation when replacing the wear-resistant block, stable relative movement can be achieved through this precise matching, avoiding structural displacement caused by excessive gaps in component fitting, thereby effectively improving the stability of the equipment during operation and maintenance.

[0035] To further improve the stability of the equipment structure, especially the connection reliability between the first auxiliary mechanism and the second auxiliary mechanism, in this embodiment, the T-block 10 and the T-slot 19 adopt a precisely matched structural design. Specifically, the size and shape of the protrusion of the T-block 10 correspond perfectly to the size and shape of the groove of the T-slot 19, and the gap between the two is controlled within a reasonable range. This matching relationship ensures that after the T-block 10 is embedded in the T-slot 19, there will be no lateral or longitudinal loosening or shaking. During normal use of the equipment, the first auxiliary mechanism and the second auxiliary mechanism can be firmly connected through their tight cooperation, avoiding the connection from falling off due to external vibration or other factors. In the operation of replacing the wear-resistant block, when it is necessary to separate the two, they can also be smoothly separated along the mating surface without jamming due to structural misalignment. Thus, the precise matching of the T-block 10 and the T-slot 19 improves the overall stability of the equipment in terms of both connection stability and operational smoothness.

[0036] To improve the overall stability of the equipment, in this embodiment, the first auxiliary mechanism 2 and the second auxiliary mechanism 11 are arranged symmetrically, with the two distributed in a mirror image with the main body 1 as the center. This symmetrical structure allows the first auxiliary mechanism 2 and the second auxiliary mechanism 11 to form a balanced support force on the main body 1, avoiding tilting or shaking of the main body 1 due to uneven force on both sides. At the same time, when the T-block 10 and the T-slot 19 are fitted together, the symmetrical distribution can keep the force on both sides of the main body 1 balanced, preventing loosening of the connection on one side from affecting the overall fixation effect. In addition, in the subsequent replacement of wear-resistant blocks, the symmetrical arrangement can also ensure that the actions of the mechanisms on both sides (such as the driving of the first electric push rod 5 and the second electric push rod 14, and the sliding of the first slider 8 and the second slider 17) are more easily synchronized, reducing structural jamming or misalignment problems caused by deviation of actions on both sides, thereby improving the stability of the equipment from multiple aspects such as support, connection and operation.

[0037] To improve the stability and structural strength of component connections, in this embodiment, both the first cylinder 9 and the second cylinder 18 are fixedly connected to the body 1 by welding. The welding process allows the first cylinder 9, the second cylinder 18, and the body 1 to form an integral structure, avoiding the loosening and displacement problems that may occur with traditional detachable connections. When the first slider 8 slides along the first cylinder 9 and the second slider 17 slides along the second cylinder 18, the welded cylinders provide stable guiding support, preventing the slider's sliding trajectory from deviating due to a loose connection between the cylinder and the body 1. At the same time, during daily use of the equipment or the replacement of wear blocks, this welded connection can withstand the force of the slider and the impact force from external vibrations, ensuring that there will be no gaps or detachment in the connection between the cylinder and the body 1. Through welding, the connection effect between the first cylinder 9 and the second cylinder 18 and the body 1 is significantly improved, providing a reliable guarantee for the structural stability of the entire device.

[0038] 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 wireless connection device for computer big data, comprising a main body (1), a first auxiliary mechanism (2), and a second auxiliary mechanism (11), characterized in that: The first auxiliary mechanism (2) includes a first connecting shell (3), a first wear-resistant block (4), a first electric push rod (5), a first connecting block (6), a first slide rail (7), a first slider (8), a first cylinder (9), and a T-shaped block (10). The first connecting block (6) contacts the outer side wall of the body (1). The first wear-resistant block (4) is connected to the bottom of the first connecting shell (3). One end of the first electric push rod (5) is connected to the top of the first connecting shell (3). The other end of the first electric push rod (5) is connected to one end of the first connecting block (6). The other end of the first connecting block (6) is connected to the first slide rail (7). One end of the first slider (8) extends into the first slide rail (7). The other end of the first slider (8) is connected to one end of the T-shaped block (10). One end of the first cylinder (9) is connected to the top of the body (1). The other end of the first cylinder (9) passes through the first slider (8). The second auxiliary mechanism (11) includes a second connecting shell. (12), second wear-resistant block (13), second electric push rod (14), second connecting block (15), second slide rail (16), second slider (17), second cylinder (18) and T-slot (19), the second connecting block (15) is in contact with the outer wall of the side of the body (1), the second wear-resistant block (13) is connected to the bottom of the second connecting shell, one end of the second electric push rod (14) is connected to the top of the second connecting shell, the other end of the second electric push rod (14) is connected to one end of the second connecting block (15), the other end of the second connecting block (15) is connected to the second slide rail (16), one end of the second slider (17) extends into the second slide rail (16), the T-slot (19) is opened at the other end of the second slider (17), the other end of the T-block (10) extends into the T-slot (19), one end of the second cylinder (18) is connected to the top of the body (1), and the other end of the second cylinder (18) passes through the second slider (17).

2. The computer big data wireless connection device according to claim 1, characterized in that: The bottom of both the first wear-resistant block (4) and the second wear-resistant block (13) is provided with anti-slip texture, and the anti-slip texture has several strips.

3. The computer big data wireless connection device according to claim 2, characterized in that: The first slide rail (7) is matched with the first slider (8), and the second slide rail (16) is matched with the second slider (17).

4. The computer big data wireless connection device according to claim 3, characterized in that: The T-block (10) matches the T-slot (19).

5. A computer big data wireless connection device according to claim 4, characterized in that: The first auxiliary mechanism (2) and the second auxiliary mechanism (11) are symmetrically arranged.

6. A computer big data wireless connection device according to claim 5, characterized in that: Both the first cylinder (9) and the second cylinder (18) are welded to the body (1).