A product remote inspection identification device

By introducing shock-absorbing components into the product remote inspection and identification device, and using guide posts, magnetic blocks, and spring structures to eliminate vibration energy, the problem of image blurring caused by shaking is solved, and the stability and real-time performance of the identification components are improved.

CN224397008UActive Publication Date: 2026-06-23CHINA CERTIFICATION & INSPECTION GRP SHANDONG CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
CHINA CERTIFICATION & INSPECTION GRP SHANDONG CO LTD
Filing Date
2025-07-07
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

Existing remote inspection and identification devices are prone to blurring of the detection image under shaking conditions, affecting image clarity and recognition accuracy. Conventional methods are difficult to completely eliminate the shaking effect, affecting detection efficiency and real-time performance.

Method used

The system employs a shock-absorbing component, including guide posts, magnetic blocks, and a spring structure. The pre-compression state of the spring is adjusted via a screw knob, and the vibration energy is eliminated by combining magnetic repulsion and friction, ensuring the stability and cushioning performance of the identification component.

Benefits of technology

It effectively reduces the impact of jitter on the recognition component, ensuring the stable operation of the recognition component in a severely jittery environment, and improving detection efficiency and real-time performance.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN224397008U_ABST
    Figure CN224397008U_ABST
Patent Text Reader

Abstract

The utility model provides a product remote inspection identification device, include: identification subassembly, the identification subassembly lower end is equipped with the shock attenuation component that is used for shock attenuation detection blurred picture to identification subassembly, identification subassembly includes adjusting seat no.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This utility model belongs to the field of remote inspection and identification technology, and specifically relates to a product remote inspection and identification device. Background Technology

[0002] Existing remote inspection and identification devices are prone to vibration during operation due to equipment or environmental factors, leading to blurred detection images and misjudgments. This vibration may originate from mechanical instability, vibrations during transportation, or improper operation by personnel. When the image acquisition system cannot stably capture the target object due to vibration, the acquired image may exhibit dynamic blur or focus shift, directly reducing image clarity and detail recognition capabilities. Ultimately, this causes the recognition algorithm to misjudge target features, resulting in false positives or false negatives.

[0003] To address this issue, conventional methods typically employ hardware ruggedization, such as adding shock absorption devices or using high-precision mounting brackets to reduce the impact of external vibrations. Simultaneously, image enhancement techniques or motion compensation algorithms are introduced at the software level to improve the restoration of blurred images. However, these methods have limitations: hardware measures increase equipment cost and complexity and are difficult to completely eliminate jitter effects in complex environments; software processing is limited by algorithm performance, showing limited effectiveness in the face of severe jitter and potentially causing system response delays, affecting overall detection efficiency and real-time performance. Therefore, we aim to design a welding device with a novel structure to solve this problem. Utility Model Content

[0004] In view of the shortcomings of the existing technology, the purpose of this utility model is to provide a remote product inspection and identification device to solve the problems mentioned in the background technology.

[0005] This utility model is achieved through the following technical solution: a remote product inspection and identification device, comprising: an identification component, wherein a shock-absorbing component for shock absorption and preventing blurring of the detection image is installed at the lower end of the identification component, the identification component includes an adjustment seat two for driving the detection and identification camera to rotate, an adjustment seat one for adjusting the left and right movement of the detection and identification camera is fixed on the upper side of the adjustment seat two, and a detection and identification camera is movably installed on the upper side of the adjustment seat one;

[0006] The shock absorption assembly includes a base plate, a guide post is provided in the middle of the upper side of the base plate, a magnetic block is provided at the top of the guide post, the upper side of the guide post is movably inserted into the lower end of the sleeve, and a magnetic block is fixed at the top of the inside of the sleeve for shock absorption and buffering.

[0007] In a preferred embodiment, the identification component further includes a mounting base, the upper side of which is fixedly connected to the lower end of the adjustment base.

[0008] In a preferred embodiment, the shock-absorbing assembly includes guide rods. Four extension plates, each at a 90-degree angle, are provided outward from the outer wall of the base plate. A guide rod is welded to the upper side of the end of each extension plate. A screw knob is threaded to the end of each guide rod. In actual use, the screw knob can be used to adjust the pre-compression state of the four springs, so that the shock-absorbing effect of the four springs can be adjusted, making the entire shock-absorbing assembly flexible in use.

[0009] In a preferred embodiment, the shock absorption assembly further includes a spring, with a spring fitted on the outer wall of each guide rod, the lower end of the spring abutting against the upper surface of the extension plate.

[0010] In a preferred embodiment, the shock absorption assembly further includes a pressure frame, a sleeve is provided in the middle of the pressure frame, the lower end of the sleeve passes through the middle of the pressure frame and extends to its lower side, and four guide plates are provided on the side of the pressure frame, with the four guide plates all positioned directly above the four extension plates.

[0011] In a preferred embodiment, the four guide plates are slidably connected to the upper sides of the four guide rods, and the upper ends of the four springs are movably abutting against the lower ends of the four guide plates.

[0012] In a preferred embodiment, both magnetic block one and magnetic block two are cylindrical structures, with the N pole of magnetic block one facing upwards and the N pole of magnetic block two facing downwards. The maximum distance between magnetic block one and magnetic block two is less than the maximum compression of the four springs. The arrangement of magnetic block one and magnetic block two can work together with the four springs to achieve the purpose of buffering and shock absorption, which helps to improve the shock absorption effect of the shock absorption assembly.

[0013] After adopting the above technical solution, the beneficial effects of this utility model are as follows: 1. By setting up a shock-absorbing component, since the spring is pre-compressed by the screw knob, the spring can quickly offset small vibrations, avoiding large vertical vibration amplitudes of the pressure frame and sleeve, thereby ensuring the stability of the identification component operation. Similarly, when the base plate encounters vibration, the four springs on it cooperate with the guide rod, guide post, sleeve, magnetic block one, and magnetic block two to ensure that the identification component located on it can greatly reduce the impact of vibration and make it work stably.

[0014] 2. The arrangement of the sleeve, guide post, magnetic block one, and magnetic block two allows the sleeve and guide post to generate friction during relative sliding, thereby eliminating some vibration energy. When magnetic block one and magnetic block two approach each other, the magnetic repulsion force they generate gradually increases, which in turn eliminates some vibration energy. This helps to improve the buffering performance of the shock absorption component, thereby ensuring the normal and stable operation of the identification component. It solves the problem that the existing technology has limited effectiveness when facing severe vibrations and may cause system response delays, affecting the overall detection efficiency and real-time performance. Attached Figure Description

[0015] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0016] Figure 1 This is a schematic diagram of the overall structure of a remote product inspection and identification device according to the present invention.

[0017] Figure 2 This is a schematic diagram of the shock absorption component structure of a remote product inspection and identification device according to this utility model.

[0018] In the diagram, 100-shock absorber assembly, 110-base plate, 120-guide rod, 130-spring, 140-pressure frame, 150-guide post, 160-sleeve, 170-mounting plate;

[0019] 200 - Identification component, 210 - Detection and identification camera, 220 - Adjustment seat one, 230 - Adjustment seat two, 240 - Mounting seat. Detailed Implementation

[0020] 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.

[0021] As the first embodiment of this utility model:

[0022] Please see Figures 1 to 2 This utility model provides a technical solution: a remote product inspection and identification device, including: an identification component 200, a shock-absorbing component 100 for shock absorption and preventing blurring of the detection image at the lower end of the identification component 200, the identification component 200 including an adjustment seat 230 for driving the detection and identification camera 210 to rotate, an adjustment seat 220 for adjusting the left and right movement of the detection and identification camera 210 fixed on the upper side of the adjustment seat 230, and the detection and identification camera 210 is movably installed on the upper side of the adjustment seat 220;

[0023] The shock absorption assembly 100 includes a base plate 110, a guide post 150 is provided in the middle of the upper side of the base plate 110, a magnetic block 1 is provided at the top of the guide post 150, the upper side of the guide post 150 is movably inserted into the lower end of the sleeve 160, and a magnetic block 2 is fixed at the top of the sleeve 160 for shock absorption and buffering.

[0024] The identification component 200 also includes a mounting base 240, the upper side of which is fixedly connected to the lower end of the adjustment base 230.

[0025] The shock absorption assembly 100 includes guide rods 120. The outer wall of the base plate 110 has four extension plates, each at a 90-degree angle, extending outward. Each extension plate has a guide rod 120 welded to its upper end. Each guide rod 120 has a screw knob threaded to its end. In actual use, the screw knob can be used to adjust the pre-compression state of the four springs 130, so that the shock absorption effect of the four springs 130 can be adjusted, making the entire shock absorption assembly 100 flexible in use.

[0026] The shock absorption assembly 100 also includes a spring 130, with a spring 130 fitted on the outer wall of each guide rod 120, and the lower end of the spring 130 abutting against the upper surface of the extension plate.

[0027] The shock absorption assembly 100 also includes a pressure frame 140, with a sleeve 160 in the middle of the pressure frame 140. The lower end of the sleeve 160 passes through the middle of the pressure frame 140 and extends to its lower side. Four guide plates are provided on the side of the pressure frame 140, and the four guide plates are all placed directly above the four extension plates.

[0028] The four guide plates are slidably connected to the upper side of the four guide rods 120, and the upper ends of the four springs 130 are in movable contact with the lower ends of the four guide plates.

[0029] Specifically, by setting the damping component 100, in actual use, since the identification component 200 is installed on the upper side of the damping component 100, when the adjustment seat 230 or adjustment seat 220 on the identification component 200 is running, the vibration generated by it will be transmitted to the mounting plate 170 through the mounting seat 240. The mounting plate 170 will then transmit the vibration to the sleeve 160 and the pressure frame 140, causing the entire sleeve 160 and pressure frame 140 to vibrate. At this time, the vibration causes the sleeve 160 and the pressure frame 140 to press down the springs on the four guide posts 150. 130. Because spring 130 is pre-compressed by the screw knob, spring 130 can quickly cancel out small vibrations, preventing the pressure frame 140 and sleeve 160 from having large vertical vibration amplitudes, thereby ensuring the stability of the identification component 200. Similarly, when the base plate 110 encounters vibration, the four springs 130 on it, together with the guide rod 120, guide post 150, sleeve 160, magnetic block one, and magnetic block two, cooperate to ensure that the identification component 200 located on it can greatly reduce the impact of vibration and enable it to work stably.

[0030] As a second embodiment of this utility model:

[0031] Please see Figures 1 to 2 Both magnetic block one and magnetic block two are cylindrical structures, with the N pole of magnetic block one facing upwards and the N pole of magnetic block two facing downwards. The maximum distance between magnetic block one and magnetic block two is less than the maximum compression of the four springs 130. The arrangement of magnetic block one and magnetic block two can work together with the four springs 130 to achieve the purpose of buffering and shock absorption, which helps to improve the shock absorption effect of the shock absorption component 100.

[0032] Based on the first embodiment described above, further, with the arrangement of sleeve 160, guide post 150, magnetic block one, and magnetic block two, friction is generated when sleeve 160 and guide post 150 slide relative to each other, thereby eliminating some vibration energy. At the same time, when sleeve 160 presses down on guide post 150, since the N pole of magnetic block one faces upward and the N pole of magnetic block two faces downward, based on the principle of like poles repelling each other, the magnetic repulsive force generated by magnetic block one and magnetic block two when they approach each other will gradually increase, thereby eliminating some vibration energy. This helps to improve the buffering performance of the shock absorption component 100, thereby ensuring the normal and stable operation of the identification component 200. This solves the problem that the existing technology has limited effectiveness when facing severe vibrations and may cause system response delay, affecting the overall detection efficiency and real-time performance.

[0033] The above description is only a preferred embodiment of the present utility model and is not intended to limit the present utility model. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present utility model should be included within the protection scope of the present utility model.

Claims

1. A remote product inspection and identification device, comprising: The identification component (200) is characterized in that a shock-absorbing component (100) for shock absorption and preventing blurring of the detection image is installed at the lower end of the identification component (200), the identification component (200) includes an adjustment seat two (230) for driving the detection and identification camera (210) to rotate, and an adjustment seat one (220) for adjusting the left and right movement of the detection and identification camera (210) is fixed on the upper side of the adjustment seat two (230), and the detection and identification camera (210) is movably installed on the upper side of the adjustment seat one (220). The shock absorption assembly (100) includes a base plate (110), a guide post (150) is provided in the middle of the upper side of the base plate (110), a magnetic block is provided at the top of the guide post (150), the upper side of the guide post (150) is movably inserted into the lower end of the sleeve (160), and a magnetic block is fixed at the top of the sleeve (160) for shock absorption and buffering.

2. The product remote inspection and identification device as described in claim 1, characterized in that: The identification component (200) also includes a mounting base (240), the upper side of which is fixedly connected to the lower end of the adjustment base (230).

3. The product remote inspection and identification device as described in claim 1, characterized in that: The shock absorption assembly (100) includes a guide rod (120). The outer wall of the base plate (110) is provided with four extension plates, each at a 90-degree angle. A guide rod (120) is welded to the upper side of the end of each extension plate. A screw knob is threaded to the end of each guide rod (120).

4. The product remote inspection and identification device as described in claim 3, characterized in that: The shock absorption assembly (100) also includes a spring (130), and a spring (130) is fitted on the outer wall of each guide rod (120), with the lower end of the spring (130) abutting against the upper surface of the extension plate.

5. The product remote inspection and identification device as described in claim 4, characterized in that: The shock absorption assembly (100) also includes a pressure frame (140), a sleeve (160) is provided in the middle of the pressure frame (140), the lower end of the sleeve (160) passes through the middle of the pressure frame (140) and extends to its lower side, and four guide plates are provided on the side of the pressure frame (140), and the four guide plates are all placed directly above the four extension plates.

6. The product remote inspection and identification device as described in claim 5, characterized in that: The four guide plates are slidably connected to the upper side of the four guide rods (120), and the upper ends of the four springs (130) are movably abutting against the lower ends of the four guide plates.

7. The product remote inspection and identification device as described in claim 6, characterized in that: Both magnetic block one and magnetic block two are cylindrical structures, with the N pole of magnetic block one facing upwards and the N pole of magnetic block two facing downwards. The maximum distance between magnetic block one and magnetic block two is less than the maximum compression of the four springs (130).