Anti-drift probe implant positioning device

By combining the probe implantation drive component and the positioning component, the problem of probe deviation during high-speed movement in traditional devices is solved, achieving precise fabric implantation position and ensuring the vertical trajectory accuracy of probe implantation.

CN224468086UActive Publication Date: 2026-07-07LIANYUNGANG LIANRUI CARD CLOTHING CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
LIANYUNGANG LIANRUI CARD CLOTHING CO LTD
Filing Date
2025-08-12
Publication Date
2026-07-07

AI Technical Summary

Technical Problem

Traditional probe implantation devices are prone to displacement due to mechanical gaps or inertial impacts during high-speed reciprocating motion, affecting the accuracy of implantation position.

Method used

The design employs a combination of probe implantation drive and positioning components, including a rotating elliptical block drive, a limiting slide bar, and an anti-drop plate, to ensure that the probe moves vertically. Precise implantation is achieved through the coordinated work of the fabric conveying component and the controller.

Benefits of technology

It effectively suppresses horizontal probe deviation, ensures the vertical trajectory accuracy of the implantation site, and improves the accuracy of the implantation site.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses a kind of anti-deviation probe implantation positioning device, including probe implantation mounting frame, probe implantation mounting frame inside is equipped with probe implantation drive assembly, probe implantation drive assembly side is equipped with probe implantation positioning assembly, probe implantation positioning assembly side is equipped with cloth conveying assembly, the utility model makes improvement to prior art, in actual use, by probe implantation drive, it has solved that traditional device is more used cylinder or linear motor directly drive probe movement, although it can realize basic implantation function, but in high-speed reciprocating motion, probe deviation is caused by mechanical clearance or inertial impact easily, affect the problem of implantation position accuracy.
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Description

Technical Field

[0001] This utility model relates to the field of anti-offset probe implantation, specifically, to an anti-offset probe implantation positioning device. Background Technology

[0002] Fabric implantation machines are automated devices specifically designed for the textile industry. Their core function is to implant specific materials (such as metal probes, fiber bundles, functional components, etc.) into the base fabric to give the fabric special properties or structures.

[0003] Traditional devices often use cylinders or linear motors to directly drive the probe movement. Although they can achieve basic implantation functions, the probe is prone to deviation due to mechanical gaps or inertial impacts during high-speed reciprocating motion, affecting the accuracy of the implantation position. Utility Model Content

[0004] In view of the problems in the related technologies, this utility model proposes an anti-deviation probe implantation and positioning device to overcome the above-mentioned technical problems existing in the existing related technologies.

[0005] Therefore, the specific technical solution adopted by this utility model is as follows:

[0006] An anti-offset probe implantation positioning device includes a probe implantation mounting frame, a probe implantation driving component is provided inside the probe implantation mounting frame, a probe implantation positioning component is provided on one side of the probe implantation driving component, and a fabric conveying component is provided on one side of the probe implantation positioning component.

[0007] To achieve the function of driving probe implantation, the probe implantation driving component includes a probe implantation positioning frame, which is connected to the probe implantation mounting frame. The probe implantation positioning frame has a sliding groove inside, and a sliding rod is slidably fitted inside the sliding groove. A reciprocating moving plate is connected above the sliding rod, and an elastic pad is connected between the reciprocating moving plate and the probe implantation positioning frame. A rotating elliptical block is slidably fitted above the reciprocating moving plate, and a rotating rod is connected to the middle of the rotating elliptical block. The rotating rod is movably connected to the probe implantation positioning frame, and a rotating motor is connected to one end of the rotating rod.

[0008] Furthermore, a controller is installed on one side of the probe implantation mounting bracket, and the rotary motor is electrically connected to the controller.

[0009] Furthermore, in order to achieve the function of probe implantation and positioning, the probe implantation and positioning component includes a probe mounting plate, which is connected to a sliding rod. An implantation probe is connected below the probe mounting plate, and a limiting sliding rod is connected above the probe mounting plate. The limiting sliding rod slides in cooperation with the probe implantation and positioning frame through a limiting sliding groove.

[0010] Furthermore, an anti-detachment plate is connected to one end of the limiting slide rod.

[0011] Furthermore, in order to achieve the function of fabric conveying, the fabric conveying assembly includes a winding mounting plate, which is symmetrically installed on one side of the probe implantation mounting frame. A winding roller is movably connected inside the winding mounting plate, and a winding motor is connected to one side of the winding roller.

[0012] Furthermore, the winding motor is electrically connected to the controller.

[0013] Furthermore, a driven mounting bracket is connected to one side of the probe implantation mounting bracket, and a driven roller is movably connected inside the driven mounting bracket.

[0014] The beneficial effects of this utility model are as follows:

[0015] (1) This utility model has made improvements to the existing technology. In actual use, the probe implantation drive solves the problem that traditional devices often use cylinders or linear motors to directly drive the probe movement. Although they can achieve basic implantation functions, the probe is prone to deflection due to mechanical gaps or inertial impacts during high-speed reciprocating motion, which affects the accuracy of the implantation position.

[0016] (2) In actual use, to eliminate the risk of movement deviation, the limiting slide bar above the probe mounting plate is inserted into the limiting slide groove of the probe implantation positioning frame to form a rigid sliding pair. This structure forcibly restricts the probe mounting plate to move only in the vertical direction, and the anti-drop plate at the end of the limiting slide bar can prevent slippage. Attached Figure Description

[0017] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the embodiments 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.

[0018] Figure 1 This is a schematic diagram of the main structure of an anti-offset probe implantation and positioning device according to an embodiment of the present utility model;

[0019] Figure 2 This is a perspective view of an anti-offset probe implantation and positioning device according to an embodiment of the present utility model;

[0020] Figure 3 This is a schematic diagram of the structure of a probe implantation driving component in an anti-offset probe implantation positioning device according to an embodiment of the present utility model;

[0021] Figure 4 This is a schematic diagram of the fabric conveying component in an anti-offset probe implantation and positioning device according to an embodiment of the present utility model.

[0022] In the picture:

[0023] 1. Probe implantation mounting frame; 2. Probe implantation drive assembly; 201. Probe implantation positioning frame; 202. Sliding groove; 203. Sliding rod; 204. Reciprocating moving plate; 205. Elastic pad; 206. Rotating elliptical block; 207. Rotating rod; 208. Rotary motor; 3. Probe implantation positioning assembly; 301. Probe mounting plate; 302. Implanted probe; 303. Limiting slide rod; 304. Limiting slide groove; 4. Fabric conveying assembly; 401. Winding mounting plate; 402. Winding roller; 403. Winding motor; 5. Controller; 6. Anti-drop plate. Detailed Implementation

[0024] 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.

[0025] According to an embodiment of the present invention, an anti-offset probe implantation positioning device is provided, including a probe implantation mounting frame 1, a probe implantation driving component 2 is provided inside the probe implantation mounting frame 1, a probe implantation positioning component 3 is provided on one side of the probe implantation driving component 2, and a fabric conveying component 4 is provided on one side of the probe implantation positioning component 3.

[0026] like Figure 1-4 As shown, according to an embodiment of the present invention, an anti-deviation probe implantation positioning device includes a probe implantation driving component 2 comprising a probe implantation positioning frame 201, which is connected to a probe implantation mounting frame 1. The probe implantation positioning frame 201 has a sliding groove 202 inside, and a sliding rod 203 is slidably fitted inside the sliding groove 202. A reciprocating moving plate 204 is connected above the sliding rod 203. An elastic pad 205 is connected between the reciprocating moving plate 204 and the probe implantation positioning frame 201. A rotating elliptical block 206 is slidably fitted above the reciprocating moving plate 204. A rotating rod 207 is connected to the middle of the rotating elliptical block 206. The rotating rod 207 is movably connected to the probe implantation positioning frame 201. A rotating motor 208 is connected to one end of the rotating rod 207. A controller 5 is installed on one side of the probe implantation mounting frame 1, and the rotating motor 208 is electrically connected to the controller 5.

[0027] Through the above technical solution, the core power transmission process of the probe implantation driving component 2 is as follows: After the rotary motor 208 starts, it drives the rotary rod 207 to drive the rotary elliptical block 206 to rotate at a constant speed around the axis. Since the outer contour of the rotary elliptical block 206 is a non-circular eccentric structure, it will generate periodic pressure on the reciprocating moving plate 204 below it when it rotates. When the long axis end of the rotary elliptical block 206 presses down, it pushes the reciprocating moving plate 204 to move downward in the vertical direction; when the short axis end turns downward, the pressure is released, and at this time the elastic pad 205 releases the stored energy, pushing the reciprocating moving plate 204 to reset and move upward. The up and down movement of the reciprocating moving plate 204 is transmitted through the sliding rod 203 fixed to it. The sliding rod 203 is precisely guided in the sliding groove 202 of the probe implantation positioning frame 201, forming a stable reciprocating linear motion, providing driving force for probe implantation.

[0028] like Figure 1-4 As shown, according to an embodiment of the present invention, an anti-deviation probe implantation positioning device includes a probe implantation positioning component 3 comprising a probe mounting plate 301, which is connected to a sliding rod 203. An implantation probe 302 is connected below the probe mounting plate 301, and a limiting slide rod 303 is connected above the probe mounting plate 301. The limiting slide rod 303 slides with the probe implantation positioning frame 201 through a limiting slide groove 304, and an anti-drop plate 6 is connected to one end of the limiting slide rod 303.

[0029] Through the above technical solution, the lower end of the sliding rod 203 is rigidly connected to the probe mounting plate 301, synchronously transmitting the reciprocating motion of the drive component to the probe mounting plate 301. The implantation probe 302 installed below the probe mounting plate 301 moves synchronously with it, realizing the vertical implantation action. To eliminate the risk of movement deviation, the limiting sliding rod 303 above the probe mounting plate 301 is inserted into the limiting sliding groove 304 of the probe implantation positioning frame 201, forming a rigid sliding pair. This structure forcibly restricts the probe mounting plate 301 to move only in the vertical direction, and the anti-drop plate 6 at the end of the limiting sliding rod 303 can prevent slippage. The dual-track cooperative sliding rod 203 + limiting sliding rod 303 completely suppresses horizontal deviation, ensuring the vertical trajectory accuracy of the implantation probe 302.

[0030] like Figure 1-4 As shown, according to an embodiment of the present invention, an anti-deviation probe implantation positioning device includes a fabric conveying assembly 4 comprising a winding mounting plate 401, which is symmetrically mounted on one side of the probe implantation mounting frame 1. A winding roller 402 is movably connected inside the winding mounting plate 401. A winding motor 403 is connected to one side of the winding roller 402 and is electrically connected to a controller 5. A driven mounting frame 7 is connected to one side of the probe implantation mounting frame 1, and a driven roller 8 is movably connected inside the driven mounting frame 7.

[0031] Through the above technical solution, the winding motor 403, controlled by the controller 5, drives the winding roller 402 to rotate between the symmetrically arranged winding mounting plates 401. The fabric roll is sleeved on the winding roller 402 and is released at a uniform speed as it rotates. After being guided by the driven roller 8 in the driven mounting frame 7, the fabric is precisely conveyed to the positioning area directly below the implantation probe 302. When the implantation probe 302 moves downward, its tip pierces the fabric to complete the implantation; when it moves upward to reset, the fabric is pulled by the winding roller 402 to move step by step, so that the unprocessed area is moved to the next station. The controller 5 synchronously coordinates the start and stop sequence of the rotary motor 208 and the winding motor 403 to ensure that the fabric conveying and probe implantation actions are strictly matched.

[0032] The above are merely preferred embodiments of the present utility model and are 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 shall be included within the protection scope of the present utility model.

Claims

1. A device for implanting and positioning an anti-deviation probe, characterized in that, The device includes a probe implantation mounting frame (1), inside which is a probe implantation driving component (2), on one side of the probe implantation driving component (2) is a probe implantation positioning component (3), and on one side of the probe implantation positioning component (3) is a fabric conveying component (4). The probe implantation drive assembly (2) includes a probe implantation positioning frame (201), which is connected to the probe implantation mounting frame (1). The probe implantation positioning frame (201) has a sliding groove (202) inside, and a sliding rod (203) is slidably fitted inside the sliding groove (202). A reciprocating moving plate (204) is connected above the sliding rod (203). An elastic pad (205) is connected between the reciprocating moving plate (204) and the probe implantation positioning frame (201). A rotating elliptical block (206) is slidably fitted above the reciprocating moving plate (204). A rotating rod (207) is connected to the middle of the rotating elliptical block (206). The rotating rod (207) is movably connected to the probe implantation positioning frame (201), and a rotating motor (208) is connected to one end of the rotating rod (207).

2. The anti-deviation probe implantation positioning device according to claim 1, characterized in that, A controller (5) is installed on one side of the probe implantation mounting bracket (1), and the rotary motor (208) is electrically connected to the controller (5).

3. The anti-deviation probe implantation positioning device according to claim 2, characterized in that, The probe implantation positioning component (3) includes a probe mounting plate (301), which is connected to the sliding rod (203). An implantation probe (302) is connected below the probe mounting plate (301), and a limiting slide rod (303) is connected above the probe mounting plate (301). The limiting slide rod (303) slides with the probe implantation positioning frame (201) through a limiting slide groove (304).

4. The anti-deviation probe implantation positioning device according to claim 3, characterized in that, One end of the limiting slide bar (303) is connected to an anti-fall plate (6).

5. The anti-deviation probe implantation positioning device according to claim 4, characterized in that, The fabric conveying assembly (4) includes a winding mounting plate (401), which is symmetrically mounted on one side of the probe implantation mounting frame (1). A winding roller (402) is movably connected inside the winding mounting plate (401), and a winding motor (403) is connected to one side of the winding roller (402).

6. The anti-deviation probe implantation positioning device according to claim 5, characterized in that, The winding motor (403) is electrically connected to the controller (5).

7. The anti-deviation probe implantation positioning device according to claim 6, characterized in that, The probe implantation mounting frame (1) is connected to a driven mounting frame (7) on one side, and a driven roller (8) is movably connected inside the driven mounting frame (7).