CN218298743U

CN218298743U - CCD detection mechanism for tin immersion end of coaxial line

Info

Publication number: CN218298743U
Application number: CN202222827812.6U
Authority: CN
Inventors: 余涵
Original assignee: Dongguan Daumak Machinery Co ltd
Current assignee: Dongguan Daumak Machinery Co ltd
Priority date: 2022-10-26
Filing date: 2022-10-26
Publication date: 2023-01-13
Anticipated expiration: 2032-10-26

Abstract

The utility model belongs to the technical field of signal communication, especially, a coaxial line wicking end CCD detection mechanism, including install the clamp line subassembly, camera subassembly one, camera subassembly two, camera subassembly three on the end wicking machine bottom plate of the wire stripping that carries on, be provided with annular light source between camera subassembly one, camera subassembly two, the camera subassembly three, camera subassembly one, camera subassembly two, the symmetrical 120 mode installation of three parallel cloth of camera subassembly three; the wire clamping assembly comprises: the device comprises an installation vertical plate, a finger cylinder and bilateral symmetry clips, wherein the finger cylinder is installed on the installation vertical plate, and the bilateral symmetry clips are respectively installed on the output ends of the finger cylinder. The utility model discloses a 3 camera evenly distributed symmetry 120 mode installation, 360 the scope does not have the dead angle detection mechanism that shoots, has alleviateed workman's operation intensity, has avoided the defective products to flow out the risk, has saved the manual work, has improved efficiency.

Description

CCD detection mechanism for tin immersion end of coaxial line

Technical Field

The utility model relates to a signal communication technical field especially relates to a coaxial line wicking holds CCD detection mechanism.

Background

The tin immersion end of the coaxial line end-punching tin immersion automaton in the current market is manually placed under a magnifier for visual detection, tin immersion big heads, tin bead residue, core line jag, tin immersion plumpness, and easy fatigue and misjudgment caused by long-time line-looking detection of workers, and the defective products flow into the good products to cause customer complaints after delivery.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the defects existing in the prior art and providing a coaxial line wicking end CCD detection mechanism.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a CCD detection mechanism for a tin immersion end of a coaxial line comprises a wire clamping component, a first camera component, a second camera component and a third camera component which are arranged on a bottom plate of a loaded wire stripping and beating end tin immersion machine, wherein an annular light source is arranged among the first camera component, the second camera component and the third camera component, and the first camera component, the second camera component and the third camera component are symmetrically arranged in a 120-degree mode in a three-dimensional equal distribution mode;

the wire clamping assembly comprises: the device comprises a mounting vertical plate, a finger cylinder and bilateral symmetrical clamps, wherein the finger cylinder is mounted on the mounting vertical plate, and the bilateral symmetrical clamps are respectively mounted at the output ends of the finger cylinder;

the first camera assembly comprises a support, an upright post, a square support, a first camera mounting seat, a first industrial camera and a first telecentric lens, wherein the upright post is mounted on the support;

the second camera component and the third camera component comprise a vertical base, a second camera mounting base, a second industrial camera and a second telecentric lens, the second camera mounting base is mounted on the vertical base, the second industrial camera is mounted on the second camera mounting base, and the second telecentric lens is mounted on the second industrial camera.

Preferably, the bilateral symmetry clip is located between the first camera assembly, the second camera assembly and the third camera assembly, and the bilateral symmetry clip is located on one side of the annular light source.

Preferably, the annular light source comprises a vertical plate and a light source, and the light source is installed on the vertical plate.

Preferably, the second camera assembly and the third camera assembly are symmetrically arranged based on the mounting vertical plate.

Preferably, the vertical base is of an L-shaped structure, and the second camera mounting base is obliquely mounted on the vertical base.

The utility model discloses in, a coaxial line wicking end CCD detection mechanism has designed 3 camera average distribution symmetry 120 mode installations, and 360 the scope does not have the dead angle detection mechanism of shooing, has alleviateed workman's operation intensity, has avoided the defective products to flow the risk, has saved the manual work, has improved efficiency.

Drawings

Fig. 1 is a schematic structural view of a CCD detection mechanism for a tin-dipped end of a coaxial line provided by the present invention;

fig. 2 is a schematic structural view of a wire clamping assembly of the CCD detection mechanism for the tin-dipped coaxial wire end of the present invention;

fig. 3 is a schematic structural view of a camera assembly of a CCD detection mechanism for a solder dip end of a coaxial line according to the present invention;

fig. 4 is a schematic structural diagram of a camera assembly two and a camera assembly three of the CCD detection mechanism for the tin-dipped coaxial end of the present invention;

fig. 5 is the utility model provides a coaxial line wicking holds CCD detection mechanism's annular light source structure sketch map.

In the figure: the camera comprises a 1 wire clamping component, a 2 camera component I, a 3 camera component II, a 4 camera component III, a 5 annular light source, a 1A mounting vertical plate, a 2A finger cylinder, a 3A bilateral symmetry clamp, a 1B support, a 2B upright post, a 3B square support, a 4B camera mounting seat I, a 5B industrial camera I, a 6B telecentric lens I, a 1C vertical seat, a 2C camera mounting seat II, a 3C industrial camera II, a 4C telecentric lens II, a 1D vertical plate and a 2D light source.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

Referring to fig. 1-5, a CCD detection mechanism for a tin immersion end of a coaxial line comprises a wire clamping assembly 1, a camera assembly one 2, a camera assembly two 3 and a camera assembly three 4 which are mounted on a bottom plate of a mounted wire stripping and beating end tin immersion machine, wherein an annular light source 5 is arranged among the camera assembly one 2, the camera assembly two 3 and the camera assembly three 4, and the camera assembly one 2, the camera assembly two 3 and the camera assembly three 4 are mounted in a symmetrical 120-degree manner in an average distribution manner;

the wire clamping assembly 1 comprises: the device comprises an installation vertical plate 1A, a finger cylinder 2A and a bilateral symmetry clamp 3A, wherein the finger cylinder 2A is installed on the installation vertical plate 1A, and the bilateral symmetry clamp 3A is respectively installed on the output end of the finger cylinder 2A to clamp and position the coaxial line tin-dipped end;

the camera assembly I2 comprises a support 1B, an upright post 2B, a square support 3B, a camera mounting seat I4B, an industrial camera I5B and a telecentric lens I6B, wherein the upright post 2B is mounted on the support 1B, the square support 3B is mounted on the top of the upright post 2B, the camera mounting seat I4B is mounted on the square support 3B, the industrial camera I5B is mounted on the camera mounting seat I4B, and the telecentric lens I6B is mounted on the industrial camera I5B;

the second 3 and the third 4 camera components comprise a vertical base 1C, a second 2C camera mounting base, a second 3C industrial camera and a second 4C telecentric lens, the second 2C camera mounting base is mounted on the vertical base 1C, the second 3C industrial camera is mounted on the second 2C camera mounting base, and the second 4C telecentric lens is mounted on the second 3C industrial camera.

The utility model discloses in, bilateral symmetry clip 3A is located between camera subassembly one 2, camera subassembly two 3, the camera subassembly three 4, and bilateral symmetry clip 3A is located one side of annular light source 5.

The utility model discloses in, annular light source 5 includes riser 1D, light source 2D, and light source 2D installs on riser 1D, carries out the light filling when the camera shoots.

The utility model discloses in, two 3 and three 4 settings of camera subassembly are based on installation riser 1A symmetry of camera subassembly.

The utility model discloses in, found seat 1C and be L type structure, and two 2C slopes of camera mount pad are installed on founding seat 1C.

In the utility model, the camera component I2, the camera component II 3 and the camera component III 4 are symmetrically arranged in a 120-degree mode, the tin immersion end of the wiring harness is photographed and detected, each angle of the wiring harness is detected at 360 degrees, the wire clamping component 1 clamps and positions the wire of the tin immersion end of the coaxial wire, the camera component I2 is used for carrying out visual detection on the upper part of the tin immersion end of the coaxial wire within 120-degree range, and the camera component II 3 and the camera component III 4 are symmetrically arranged for carrying out visual detection on the left part and the right part of the tin immersion end of the coaxial wire within 120-degree range; adopt 3 camera evenly distributed symmetry 120 modes installation, 360 no dead angles of scope detection mechanism of shooing has alleviateed workman's operation intensity, has avoided the defective products to flow out the risk, has saved the manual work, has improved efficiency.

The above, only be the embodiment of the preferred of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, which are designed to be replaced or changed equally, all should be covered within the protection scope of the present invention.

Claims

1. A CCD detection mechanism for a tin immersion end of a coaxial line is characterized by comprising a wire clamping component (1), a camera component I (2), a camera component II (3) and a camera component III (4) which are arranged on a bottom plate of a carried wire stripping and beating end tin immersion machine, wherein an annular light source (5) is arranged among the camera component I (2), the camera component II (3) and the camera component III (4), and the camera component I (2), the camera component II (3) and the camera component III (4) are arranged in a mode of even distribution and symmetry at 120 degrees;

the wire clamping assembly (1) comprises: the device comprises an installation vertical plate (1A), finger cylinders (2A) and bilateral symmetrical clamps (3A), wherein the finger cylinders (2A) are installed on the installation vertical plate (1A), and the bilateral symmetrical clamps (3A) are respectively installed at the output ends of the finger cylinders (2A);

the camera assembly I (2) comprises a support (1B), an upright post (2B), a square support (3B), a camera mounting seat I (4B), an industrial camera I (5B) and a telecentric lens I (6B), wherein the upright post (2B) is installed on the support (1B), the square support (3B) is installed on the top of the upright post (2B), the camera mounting seat I (4B) is installed on the square support (3B), the industrial camera I (5B) is installed on the camera mounting seat I (4B), and the telecentric lens I (6B) is installed on the industrial camera I (5B);

camera subassembly two (3) and camera subassembly three (4) are including founding seat (1C), two (2C) of camera mount pad, two (3C) of industrial camera, telecentric lens two (4C), install on founding seat (1C) two (2C) of camera mount pad, install on two (2C) of camera mount pad industrial camera two (3C), telecentric lens two (4C) are installed on two (3C) of industrial camera.

2. The CCD detection mechanism for the tin-dipped end of the coaxial line as claimed in claim 1, wherein the bilateral symmetry clamp (3A) is positioned among the first camera component (2), the second camera component (3) and the third camera component (4), and the bilateral symmetry clamp (3A) is positioned at one side of the annular light source (5).

3. The CCD detection mechanism for the tin-dipped end of the coaxial line according to claim 1 is characterized in that the annular light source (5) comprises a vertical plate (1D) and a light source (2D), and the light source (2D) is installed on the vertical plate (1D).

4. The CCD detection mechanism for the tin-dipped end of the coaxial line as recited in claim 1, wherein the second camera component (3) and the third camera component (4) are symmetrically arranged based on the mounting vertical plate (1A).

5. The CCD detection mechanism for the tin-dipped end of the coaxial line as recited in claim 1, wherein the vertical base (1C) is of an L-shaped structure, and the second camera mounting base (2C) is obliquely mounted on the vertical base (1C).