A line-identification based visualization device
By adjusting the design of components and sensors, the problem of scanning errors caused by circuit board movement was solved, achieving stable fixation of the circuit board and effective identification of multi-layer circuits, thus improving the accuracy and efficiency of circuit identification.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- 洛阳万山电子科技有限公司
- Filing Date
- 2025-05-28
- Publication Date
- 2026-06-23
AI Technical Summary
Existing circuit identification visualization equipment lacks a device to fix the circuit board, which causes the circuit board to move, resulting in blurred or misaligned scanned images. The circuit identification algorithm may misjudge the location of components, open circuits, or short circuits, increasing the workload.
The adjustment assembly includes a bidirectional lead screw and ball screw driven by first and second motors, which, together with the fixing plate, clamp and fix the circuit board. The scanning angle is adjusted by sensors and electric telescopic rods to achieve stable fixation of circuit boards of different sizes and effective scanning of multi-layer circuits.
It achieves stable fixation of circuit boards of different sizes, avoids scanning errors, and can effectively scan the multi-layer layout of circuit boards and lines that are difficult to observe from a vertical perspective, thus improving recognition accuracy and efficiency.
Smart Images

Figure CN224401987U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of circuit identification technology, and in particular to a visualization device based on circuit identification. Background Technology
[0002] A visualization device based on line identification is an intelligent device that combines computer vision, image processing, and data visualization technologies. It aims to automatically identify and analyze line structures, such as circuit boards, power lines, and pipelines, and transform abstract line information into an intuitive graphical interface to help users quickly understand line layout, detect faults, or optimize designs.
[0003] However, existing circuit identification and visualization equipment lacks a device to fix the circuit board. During the circuit analysis process, the movement of the circuit board will cause the scanned image to be blurred or misaligned. The circuit identification algorithm may misjudge the component position, open circuit or short circuit, so multiple checks are required, which increases the workload. Utility Model Content
[0004] Given that existing circuit identification visualization devices lack a device for fixing the circuit board, the movement of the circuit board during circuit analysis can cause the scanned image to become blurred or misaligned. The circuit identification algorithm may misjudge the component position, open circuit, or short circuit, thus requiring multiple checks and increasing the workload. Therefore, this utility model is proposed.
[0005] To solve the above-mentioned technical problems, this utility model provides the following technical solution: a visualization device based on line identification, including a workbench and a base disposed at the lower end of the workbench. An adjustment component is provided on the upper end of the workbench. The adjustment component includes two sets of first adjustment frames symmetrically disposed on the upper end of the workbench. A first motor is disposed on the outer wall of one set of first adjustment frames. A first bidirectional lead screw is disposed at the output end of the first motor. Two sets of first ball screw sleeves are symmetrically disposed on the outer wall of the first bidirectional lead screw. A second adjustment frame is disposed on the upper end of the first ball screw sleeve. A second motor is disposed on the outer wall of the second adjustment frame. A second bidirectional lead screw is disposed at the output end of the second motor. Two sets of second ball screw sleeves are symmetrically disposed on the outer wall of the second bidirectional lead screw. A fixing plate is disposed on the upper end of the second ball screw sleeve. An identification component is disposed at one end of the outer wall of the workbench.
[0006] In a preferred embodiment of the visualization device based on line identification described in this utility model, the first ball screw sleeve is movably inserted into the inner wall of the first adjustment frame.
[0007] As a preferred embodiment of the visualization device based on line identification described in this utility model, a slide rod is fixedly provided in a set of first adjustment frames symmetrical to the first bidirectional lead screw, and two sets of mutually symmetrical slide sleeves are movably sleeved on the outer wall of the slide rod, and the upper end of the slide sleeve is fixedly connected to the second adjustment frame.
[0008] As a preferred embodiment of the visualization device based on line identification described in this utility model, the second ball screw sleeve is movably inserted into the inner wall of the second adjusting frame, and a U-shaped groove is provided at the upper end of the fixing plate.
[0009] As a preferred embodiment of the visualization device based on line identification according to this utility model, the identification component includes a third motor disposed on the upper end of the workbench, the output end of the third motor is provided with a first gear, a second gear is provided on one side of the first gear, the second gear and the first gear mesh with each other, and the upper end shaft of the second gear passes through the workbench and is connected to a connecting frame.
[0010] As a preferred embodiment of the visualization device based on line identification described in this utility model, a sensor is hinged to the front side of the upper end of the connecting frame, an electric telescopic rod is provided on one side of the sensor, the extension end of the electric telescopic rod is hinged to the sensor, and the upper end of the electric telescopic rod is hinged to the connecting frame.
[0011] Compared with the prior art, the present invention has at least the following beneficial effects:
[0012] 1. In this utility model, the circuit board to be identified is placed between four sets of fixing plates. According to the width of the circuit board, the first motor is started to drive the first bidirectional lead screw to rotate. The two sets of first ball screw sleeves slide along the inner wall of the first adjusting frame and move closer to each other until the circuit board can be inserted into the U-shaped groove opened in the fixing plate. Then, according to the width of the circuit board, the second motor is started to drive the second bidirectional lead screw to rotate. The second ball screw sleeve slides along the inner wall of the second adjusting frame and moves closer to each other. The two sets of fixing plates move closer to each other to clamp the circuit board, thereby fixing circuit boards of different sizes and avoiding scanning errors caused by circuit board movement when inspecting the circuit board circuit.
[0013] 2. In this utility model, starting the third motor can drive the first gear to rotate, the first gear drives the second gear to rotate, the second gear drives the connecting frame to rotate, and the sensor at the upper end of the connecting frame rotates accordingly, thereby enabling scanning and detection of lines in different parts of the circuit board. Furthermore, the scanning angle of the sensor can be adjusted by using an electric telescopic rod. Circuit boards often have multi-layer stacked structures or three-dimensional layouts. By adjusting the detection angle of the sensor, tilt scanning can capture the underlying lines or connection points that are difficult to observe from a vertical perspective. Attached Figure Description
[0014] Figure 1 This is a schematic diagram of the overall three-dimensional structure of the visualization device based on line identification according to this utility model;
[0015] Figure 2 This is a three-dimensional cross-sectional structural diagram of the adjustment component of the visualization device based on line identification according to this utility model;
[0016] Figure 3 This is a three-dimensional structural diagram of the identification component of the visualization device based on line identification according to this utility model.
[0017] Explanation of reference numerals in the attached figures:
[0018] 1. Workbench; 2. Base; 3. Adjustment assembly; 301. First adjustment frame; 302. First motor; 303. First bidirectional lead screw; 304. First ball screw sleeve; 305. Second adjustment frame; 306. Second motor; 307. Second bidirectional lead screw; 308. Second ball screw sleeve; 309. Fixing plate; 310. Slide rod; 311. Slide sleeve; 4. Identification assembly; 41. Third motor; 42. First gear; 43. Second gear; 44. Connecting frame; 45. Sensor; 46. Electric telescopic rod. Detailed Implementation
[0019] To make the above-mentioned objectives, features and advantages of this utility model more apparent and understandable, the specific embodiments of this utility model will be described in detail below with reference to the accompanying drawings.
[0020] Example 1
[0021] Reference Figures 1-2 This is the first embodiment of the present invention, providing a visualization device based on line identification, including a workbench 1 and a base 2 disposed at the lower end of the workbench 1. An adjustment component 3 is provided at the upper end of the workbench 1. The adjustment component 3 includes two sets of first adjustment frames 301 symmetrically disposed at the upper end of the workbench 1. A first motor 302 is provided on the outer wall of one set of first adjustment frames 301. A first bidirectional lead screw 303 is provided at the output end of the first motor 302. Two sets of first ball screw sleeves 304 symmetrically disposed on the outer wall of the first bidirectional lead screw 303. A second adjustment frame 305 is provided at the upper end of the first ball screw sleeve 304. A second motor 306 is provided on the outer wall of the second adjustment frame 305. A second bidirectional lead screw 307 is provided at the output end of the second motor 306. Two sets of second ball screw sleeves 308 symmetrically disposed on the outer wall of the second bidirectional lead screw 307. A fixing plate 309 is provided at the upper end of the second ball screw sleeve 308.
[0022] The first ball screw sleeve 304 is movably inserted into the inner wall of the first adjusting frame 301.
[0023] A slide rod 310 is fixedly provided in a set of first adjustment frames 301 symmetrical to the first bidirectional lead screw 303. Two sets of symmetrical slide sleeves 311 are movably sleeved on the outer wall of the slide rod 310. The upper end of the slide sleeve 311 is fixedly connected to the second adjustment frame 305.
[0024] The second ball screw sleeve 308 is movably inserted into the inner wall of the second adjusting frame 305, and the upper end of the fixing plate 309 is provided with a U-shaped groove.
[0025] The circuit board to be identified is placed between four sets of fixing plates 309. Based on the width of the circuit board, the first motor 302 is started to drive the first bidirectional lead screw 303 to rotate. The two sets of first ball screw sleeves 304 slide along the inner wall of the first adjusting frame 301 and move closer to each other until the circuit board can be inserted into the U-shaped groove opened in the fixing plate 309. Then, based on the width of the circuit board, the second motor 306 is started to drive the second bidirectional lead screw 307 to rotate. The second ball screw sleeve 308 slides along the inner wall of the second adjusting frame 305 and moves closer to each other. The two sets of fixing plates 309 move closer to each other to clamp the circuit board, thereby fixing circuit boards of different sizes and avoiding scanning errors caused by circuit board movement when checking the circuit board circuit.
[0026] Example 2
[0027] Reference Figure 1 and Figure 3 This is the second embodiment of the present utility model. The difference between this embodiment and the first embodiment is that an identification component 4 is provided at one end of the outer wall of the workbench 1.
[0028] The identification component 4 includes a third motor 41 located on the upper end of the workbench 1. The output end of the third motor 41 is provided with a first gear 42. A second gear 43 is provided on one side of the first gear 42. The second gear 43 and the first gear 42 mesh with each other. The upper end of the second gear 43 has a rotating shaft that passes through the workbench 1 and is connected to a connecting frame 44.
[0029] A sensor 45 is hinged to the front of the upper end of the connecting frame 44. An electric telescopic rod 46 is provided on one side of the sensor 45. The extended end of the electric telescopic rod 46 is hinged to the sensor 45, and the upper end of the electric telescopic rod 46 is hinged to the connecting frame 44.
[0030] Starting the third motor 41 can drive the first gear 42 to rotate, the first gear 42 drives the second gear 43 to rotate, the second gear 43 drives the connecting frame 44 to rotate, and the sensor 45 on the upper end of the connecting frame 44 rotates accordingly, thereby scanning and detecting the lines in different parts of the circuit board. Furthermore, the scanning angle of the sensor 45 can be adjusted by the electric telescopic rod 46. Circuit boards often have multi-layer stacked structures or three-dimensional layouts. By adjusting the detection angle of the sensor 45, tilt scanning can capture the underlying lines or connection points that are difficult to observe from a vertical perspective.
[0031] The remaining structure is the same as that in Example 1.
[0032] It should be noted that the above embodiments are only used to illustrate the technical solution of this utility model and are not intended to limit it. Although this utility model has been described in detail with reference to preferred embodiments, those skilled in the art should understand that modifications or equivalent substitutions can be made to the technical solution of this utility model without departing from the spirit and scope of the technical solution of this utility model, and all such modifications or substitutions should be covered within the scope of the claims of this utility model.
Claims
1. A visualization device based on line identification, comprising a workbench (1) and a base (2) disposed at the lower end of the workbench (1), characterized in that: The upper end of the workbench (1) is provided with an adjustment component (3). The adjustment component (3) includes two sets of first adjustment frames (301) symmetrically arranged on the upper end of the workbench (1). One set of first adjustment frames (301) is provided with a first motor (302) on its outer wall. The output end of the first motor (302) is provided with a first bidirectional lead screw (303). The outer wall of the first bidirectional lead screw (303) is fitted with two sets of first ball screw sleeves (304) symmetrically arranged. The upper end of the first ball screw sleeve (304) is provided with a second adjustment frame (305). The outer wall of the second adjustment frame (305) is provided with a second motor (306). The output end of the second motor (306) is provided with a second bidirectional lead screw (307). The outer wall of the second bidirectional lead screw (307) is fitted with two sets of second ball screw sleeves (308) symmetrically arranged. The upper end of the second ball screw sleeve (308) is provided with a fixing plate (309). One end of the outer wall of the workbench (1) is provided with an identification component (4).
2. The visualization device based on line identification according to claim 1, characterized in that: The first ball screw sleeve (304) is movably inserted into the inner wall of the first adjusting frame (301).
3. The visualization device based on line identification according to claim 1, characterized in that: A slide rod (310) is fixedly provided in a set of first adjustment frames (301) symmetrical to the first bidirectional lead screw (303). Two sets of sliding sleeves (311) are movably sleeved on the outer wall of the slide rod (310). The upper end of the sliding sleeve (311) is fixedly connected to the second adjustment frame (305).
4. The visualization device based on line identification according to claim 1, characterized in that: The second ball thread sleeve (308) is movably inserted into the inner wall of the second adjusting frame (305), and a U-shaped groove is provided at the upper end of the fixing plate (309).
5. The visualization device based on line identification according to claim 1, characterized in that: The identification component (4) includes a third motor (41) located on the upper end of the workbench (1). The output end of the third motor (41) is provided with a first gear (42). A second gear (43) is provided on one side of the first gear (42). The second gear (43) and the first gear (42) mesh with each other. The upper shaft of the second gear (43) passes through the workbench (1) and is connected to a connecting frame (44).
6. The visualization device based on line identification according to claim 5, characterized in that: A sensor (45) is hinged to the front of the upper end of the connecting frame (44). An electric telescopic rod (46) is provided on one side of the sensor (45). The extension end of the electric telescopic rod (46) is hinged to the sensor (45), and the upper end of the electric telescopic rod (46) is hinged to the connecting frame (44).