CN215954920U - Coaxial wire harness double-end tin sticky device - Google Patents

Abstract

The utility model belongs to the technical field of wire harness tin pick-up, and particularly discloses a coaxial wire harness double-end tin pick-up device which comprises a case and a bedplate arranged on the case; a wire harness feeding mechanism is arranged on one side of the case; the bedplate is sequentially provided with a fixed-length cutting wire feeding mechanism, a front-end wire harness carrying mechanism, a wire harness switching mechanism, a rear-end wire harness carrying mechanism and a material taking mechanism; the bedplate is also provided with a front-end wire harness processing assembly and a rear-end wire harness processing assembly which have the same structure; the front-end wire harness processing assembly is arranged along the conveying direction of the front-end wire harness conveying mechanism, and the rear-end wire harness processing assembly is arranged along the conveying direction of the rear-end wire harness conveying mechanism. The wire harness conveying device is produced in a mode of conveying the wire harness by the clamp air cylinder, the working time of a single station is independent, the production time is shortened, and the production efficiency is improved.

Description

Coaxial wire harness double-end tin sticky device

Technical Field

The utility model belongs to the technical field of wire harness tin dipping, and particularly relates to a coaxial wire harness double-end tin dipping device.

Background

Coaxial wire harnesses on the market are various in size (such as 0.64mm, 0.81mm, 1.13mm and the like). The method for tin dipping of the coaxial wire harness in the existing factory adopts an artificial tin dipping mode, namely, the cut coaxial wire harness is immersed into a tin furnace manually, although the tin dipping of the coaxial wire harness can be realized by the method, certain defects also exist, such as low efficiency and the like caused by the fact that the coaxial wire harness is dipped manually, and for the coaxial wire harness with shorter length, the problems of difficult manual operation, easy scalding and the like caused by the manual tin dipping are caused; in addition, the toxic gas volatilized from the tin furnace can cause certain damage to human health after long-time manual tin dipping operation.

Therefore, it is a technical problem to be solved by those skilled in the art to provide a new coaxial harness dual-head tin dipping device.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the defect of low efficiency of manual tin dipping in the prior art, and provides a coaxial wire harness double-end tin dipping device.

The utility model provides coaxial wire harness double-end tin-dipping equipment which comprises a case and a bedplate arranged on the case, wherein the bedplate is arranged on the bedplate;

a wire harness feeding mechanism is arranged on one side of the case;

the bedplate is sequentially provided with a fixed-length cutting wire feeding mechanism, a front-end wire harness carrying mechanism, a wire harness switching mechanism, a rear-end wire harness carrying mechanism and a material taking mechanism;

the bedplate is also provided with a front-end wire harness processing assembly and a rear-end wire harness processing assembly which have the same structure;

the front-end wire harness processing assembly is arranged along the transportation direction of the front-end wire harness transporting mechanism, and the rear-end wire harness processing assembly is arranged along the transportation direction of the rear-end wire harness transporting mechanism;

the wire harness feeding mechanism, the fixed-length cutting wire feeding mechanism, the front end wire harness carrying mechanism, the wire harness switching mechanism, the rear end wire harness carrying mechanism and the material taking mechanism sequentially complete transmission of the wire harness in at least one tin dipping stroke.

The front-end wire harness processing assembly and the rear-end wire harness processing assembly comprise a soldering flux mechanism, a baking mechanism and a tin dipping mechanism which are arranged side by side;

and the soldering flux dipping mechanism, the baking mechanism and the tin dipping mechanism are sequentially arranged along the conveying direction of the front-end wire harness conveying mechanism.

The wire harness carrying mechanism comprises a first linear slide rail, a push rod cylinder and a first wire clamping cylinder;

the first linear sliding rail is fixedly arranged on the surface of the bedplate, and the push rod cylinder is fixedly connected with the first linear sliding rail;

the wire harness carrying mechanism further comprises a sliding plate, and the sliding plate is connected with the first linear sliding rail in a sliding manner;

the first wire clamping cylinder is fixedly connected with the sliding plate;

the tail end of the first wire clamping cylinder is provided with a first wire clamping end.

The wire harness switching mechanism comprises a supporting plate, a mounting plate, a wire feeding motor, an upper air cylinder, a lower air cylinder and a second wire clamping air cylinder;

the supporting plate is fixedly arranged on the surface of the bedplate;

the supporting plate is provided with a sliding groove, and the mounting plate is connected with the sliding groove in a sliding manner;

the wire feeding motor and the second wire clamping cylinder are arranged on the mounting plate;

the piston ends of the upper and lower cylinders are fixedly connected with the mounting plate;

and a second wire clamping end is arranged at the tail end of the second wire clamping cylinder.

The further proposal is that the material taking mechanism comprises a base and a left cylinder and a right cylinder;

a second linear slide rail is arranged on the base;

the base is fixedly arranged on the surface of the bedplate;

a sliding block is arranged on the second linear sliding rail and fixedly connected with the left and right cylinders;

and a third wire clamping end is fixedly arranged at the piston end of the left and right cylinders.

The equipment further comprises a finished product box, and the finished product box is fixedly arranged on the surface of the bedplate.

The wire harness feeding mechanism comprises a wire feeding wheel and a motor;

the wire feeding wheel is axially connected with the motor;

the motor is arranged inside the case.

The further proposal is that the equipment also comprises a man-machine operation panel;

the man-machine operation panel is electrically connected with the wire harness feeding mechanism, the front end wire harness carrying mechanism, the wire harness switching structure, the rear end wire harness carrying mechanism and the material taking mechanism.

Compared with the prior art, the utility model has the beneficial effects that:

according to the utility model, the soldering flux dipping mechanism, the baking mechanism and the tin dipping mechanism are integrated on the bedplate, linear transportation of the wiring harness is realized through the wiring harness transporting mechanism, and in the transporting process, the working procedures of automatic soldering flux dipping, baking, tin dipping and the like of the wiring harness are realized, so that one worker can follow up a plurality of devices, and production operators are reduced; the wire harness conveying device is produced in a mode of conveying the wire harness by the clamp air cylinder, the working time of a single station is independent, the production time is shortened, and the production efficiency is improved.

Drawings

The utility model is illustrated and described only by way of example and not by way of limitation in the scope of the utility model as set forth in the following drawings, in which:

FIG. 1: the utility model is a schematic view of a top-down structure;

FIG. 2: the utility model is a schematic structural diagram of the front side;

FIG. 3: a schematic structural diagram of a wire harness handling mechanism;

FIG. 4: a schematic structural diagram of a wiring harness switching mechanism;

FIG. 5: the material taking mechanism is schematically structured;

in the figure: the wire harness cutting machine comprises a wire harness feeding mechanism 1, a fixed-length cutting wire feeding mechanism 2, a front end wire harness carrying mechanism 3, a first linear slide rail 31, a push rod cylinder 32, a first wire clamping cylinder 33, a first wire clamping end 34, a sliding plate 35, a soldering flux mechanism 4, a baking mechanism 5, a tin wetting mechanism 6, a wire harness switching mechanism 7, an upper cylinder 71, a lower cylinder 71, a second wire clamping cylinder 72, a support plate 73, a wire feeding motor 74, a material taking mechanism 8, a second linear slide rail 81, a sliding block 82, a left cylinder 83, a right cylinder 83, a base 84, a rear end wire harness carrying mechanism 9, a bedplate 10, a chassis 11, a man-machine operation panel 12 and a finished product box 13.

Detailed Description

In order to make the objects, technical solutions, design methods, and advantages of the present invention more apparent, the present invention will be further described in detail by specific embodiments with reference to the accompanying drawings. It should be understood that the specific embodiments described herein are merely illustrative of the utility model and are not intended to limit the utility model.

As shown in fig. 1 and 2, the present invention provides a pallet 10 including a cabinet 11 and a deck 10 provided on the cabinet 11;

a wire harness feeding mechanism 1 is arranged on one side of the case 11;

the bedplate 10 is sequentially provided with a fixed-length cutting wire feeding mechanism 2, a front-end wire harness carrying mechanism 3, a wire harness switching mechanism 7, a rear-end wire harness carrying mechanism 9 and a material taking mechanism 8;

the bedplate 10 is also provided with a front-end wire harness processing assembly and a rear-end wire harness processing assembly which have the same structure;

the front-end wire harness processing assembly is arranged along the transportation direction of the front-end wire harness transporting mechanism 3, and the rear-end wire harness processing assembly is arranged along the transportation direction of the rear-end wire harness transporting mechanism 9;

the wire harness feeding mechanism 1, the fixed-length cutting wire feeding mechanism 2, the front end wire harness carrying mechanism 3, the wire harness switching mechanism 7, the rear end wire harness carrying mechanism 9 and the material taking mechanism 8 sequentially complete transmission of wire harnesses in one tin dipping stroke.

The front-end wire harness processing assembly and the rear-end wire harness processing assembly comprise a soldering flux dipping mechanism 4, a baking mechanism 5 and a tin dipping mechanism 6 which are arranged side by side;

and the soldering flux dipping mechanism 4, the baking mechanism 5 and the tin dipping mechanism 6 are sequentially arranged along the conveying direction of the front end wire harness conveying mechanism 3.

As shown in fig. 3, the wire harness carrying mechanism 3 includes a first linear slide rail 31, a push rod cylinder 32, and a first wire clamping cylinder 33;

the first linear slide rail is fixedly arranged on the surface of the bedplate 10, and the push rod cylinder 32 is fixedly connected with the first linear slide rail 31;

the wire harness carrying mechanism 3 further comprises a sliding plate 35, and the sliding plate 35 is slidably connected with the first linear slide rail 31;

the first wire clamping cylinder 33 is fixedly connected with the sliding plate 35;

the first wire clamping cylinder 33 is provided with a first wire clamping end 34 at the end.

As shown in fig. 4, the wire harness switching mechanism 7 includes a support plate 73, a mounting plate, a wire feeding motor 74, an up-down cylinder 71, and a second wire clamping cylinder 72;

the supporting plate 73 is fixedly arranged on the surface of the bedplate 10;

a sliding groove is formed in the supporting plate 73, and the mounting plate is connected with the sliding groove in a sliding manner;

the wire feeding motor 74 and the second wire clamping cylinder 72 are arranged on the mounting plate;

the piston ends of the upper and lower cylinders 71 are fixedly connected with the mounting plate;

the end of the second wire clamping cylinder 72 is provided with a second wire clamping end.

As shown in fig. 5, the material taking mechanism 8 includes a base 84 and left and right air cylinders 83;

the base 84 is provided with a second linear slide rail 81;

the base 84 is fixedly arranged on the surface of the bedplate 10;

a sliding block 82 is arranged on the second linear sliding rail 81, and the sliding block 82 is fixedly connected with the left and right air cylinders 83;

and a third wire clamping end is fixedly arranged at the piston end of the left and right air cylinders 83.

Optionally, the apparatus further comprises a finished box 13, and the finished box 13 is fixedly arranged on the surface of the platen 10.

Optionally, the wire harness feeding mechanism 1 comprises a wire feeding wheel and a motor;

the wire feeding wheel is axially connected with the motor;

the motor is disposed inside the cabinet 11.

In this embodiment, the device further comprises a human machine operation panel 12;

the man-machine operation panel 12 is electrically connected with the wire harness feeding mechanism 1, the front end wire harness carrying mechanism 3, the wire harness switching mechanism 7, the rear end wire harness carrying mechanism 9 and the material taking mechanism 8.

The using process of the utility model is as follows: the platen 10 is fixed to a box making machine 11, which constitutes an equipment table. The wire harness feeding mechanism 1 conveys the uncut wire harness to the wire harness fixed-length cutting wire feeding mechanism 2, the wire harness fixed-length cutting wire feeding mechanism 2 is fixed on the bedplate 10 to cut the wire harness at a fixed length, and the front-end wire harness carrying mechanism 3 carries the wire harness which is cut at a fixed length to a rear-end station. Specifically, the push rod cylinder 32 drives the sliding plate 35 to slide on the first linear sliding rail 31, the first wire clamping cylinder 33 drives the first wire clamping end 35 to clamp the wire harness, the clamped wire harness is conveyed, and the soldering flux dipping mechanism 4, the baking mechanism 5 and the tin dipping mechanism 6 are used for respectively dipping the soldering flux, baking and tin dipping on the wire harness, so that automatic tin dipping of the front end of the wire harness is realized. After a stroke of the front end wire harness carrying mechanism 3 is finished, the wire harness is transported to the wire harness switching mechanism 7, a second wire clamping cylinder 72 of the wire harness switching mechanism 7 controls a second wire clamping end to clamp the wire harness, an upper air cylinder 71 and a lower air cylinder 71 control the height of the mounting plate, adjustment of the height of the wire harness is further achieved, a wire feeding motor 74 enables the mounting plate to slide along a sliding groove of a supporting plate 73, it is guaranteed that one end, which is not stained with tin, of the wire harness is sent to a rear end wire harness carrying mechanism 9, the wire harness is transported after the rear end wire harness carrying mechanism 9 is clamped, the wire harness is stained with a soldering flux, baking and tin staining are respectively carried out on the wire harness by the soldering flux dipping mechanism 4, the baking mechanism 5 and the tin staining mechanism 6, and automatic tin staining of the rear end of the wire harness is achieved (the process is the same as automatic tin staining of the front end wire harness). After the tin dipping is finished at both ends, the material taking mechanism 8 clamps the wire harness and places the wire harness in the finished product box 13, so that the tin dipping work at both ends of the wire harness is finished. The on/off of the motor and the cylinder in the process are controlled by the man-machine operation panel 12.

Having described embodiments of the present invention, the foregoing description is intended to be exemplary, not exhaustive, and not limited to the embodiments disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art without departing from the scope and spirit of the described embodiments. The terminology used herein is chosen in order to best explain the principles of the embodiments, the practical application, or improvements made to the technology in the marketplace, or to enable others of ordinary skill in the art to understand the embodiments disclosed herein.

Claims (8)

1. The coaxial harness double-head tin dipping equipment is characterized by comprising a case (11) and a bedplate (10) arranged on the case (11);

a wire harness feeding mechanism (1) is arranged on one side of the case (11);

the bedplate (10) is sequentially provided with a fixed-length cutting wire feeding mechanism (2), a front-end wire harness conveying mechanism (3), a wire harness switching mechanism (7), a rear-end wire harness conveying mechanism (9) and a material taking mechanism (8);

the bedplate (10) is also provided with a front-end wire harness processing assembly and a rear-end wire harness processing assembly which have the same structure;

the front-end wire harness processing assembly is arranged along the transportation direction of the front-end wire harness carrying mechanism (3), and the rear-end wire harness processing assembly is arranged along the transportation direction of the rear-end wire harness carrying mechanism (9);

the wire harness feeding mechanism (1), the fixed-length cutting wire feeding mechanism (2), the front end wire harness carrying mechanism (3), the wire harness switching mechanism (7), the rear end wire harness carrying mechanism (9) and the material taking mechanism (8) sequentially complete transmission of the wire harness in at least one tin dipping stroke.

2. The coaxial harness double-end tin-dipping device as claimed in claim 1, wherein the front end harness processing assembly and the rear end harness processing assembly comprise a flux-dipping mechanism (4), a baking mechanism (5) and a tin-dipping mechanism (6) which are arranged side by side;

be stained with scaling powder mechanism (4), toast mechanism (5) and be stained with tin mechanism (6) and follow the direction of transportation of front end pencil transport mechanism (3) sets gradually.

3. The coaxial harness double-end tin dipping device as claimed in claim 1, wherein the front end harness carrying mechanism (3) and the rear end harness carrying mechanism (9) are identical in structure and comprise a first linear slide rail (31), a push rod cylinder (32) and a first wire clamping cylinder (33);

the first linear slide rail is fixedly arranged on the surface of the bedplate (10), and the push rod cylinder (32) is fixedly connected with the first linear slide rail (31);

the wire harness carrying mechanism (3) further comprises a sliding plate (35), and the sliding plate (35) is connected with the first linear sliding rail (31) in a sliding mode;

the first wire clamping cylinder (33) is fixedly connected with the sliding plate (35);

the tail end of the first wire clamping cylinder (33) is provided with a first wire clamping end (34).

4. The coaxial harness double-head tin dipping device as claimed in claim 1, wherein the harness switching structure (7) comprises a support plate (73), a mounting plate, a wire feeding motor (74), an upper and lower cylinder (71) and a second wire clamping cylinder (72);

the supporting plate (73) is fixedly arranged on the surface of the bedplate (10);

a sliding groove is formed in the supporting plate (73), and the mounting plate is connected with the sliding groove in a sliding mode;

the wire feeding motor (74) and the second wire clamping cylinder (72) are arranged on the mounting plate;

the piston ends of the upper and lower cylinders (71) are fixedly connected with the mounting plate;

and a second wire clamping end is arranged at the tail end of the second wire clamping cylinder (72).

5. The coaxial harness double-headed tin dipping device as claimed in claim 1, wherein the material taking mechanism (8) comprises a base (84) and left and right air cylinders (83);

a second linear slide rail (81) is arranged on the base (84);

the base (84) is fixedly arranged on the surface of the bedplate (10);

a sliding block (82) is arranged on the second linear sliding rail (81), and the sliding block (82) is fixedly connected with the left and right air cylinders (83);

and a third wire clamping end is fixedly arranged at the piston end of the left and right cylinders (83).

6. The coaxial harness double-ended tinning device according to claim 5, characterized in that the device further comprises a finished box (13), wherein the finished box (13) is fixedly arranged on the surface of the bedplate (10).

7. The coaxial harness double-head tin dipping device as claimed in claim 1, wherein the harness feeding mechanism (1) comprises a wire feeding wheel and a motor;

the wire feeding wheel is axially connected with the motor;

the motor is arranged inside the case (11).

8. The dual-headed coaxial harness tin dipping device according to any one of claims 1 to 7, further comprising a human operator panel (12);

the man-machine operation panel (12) is electrically connected with the wire harness feeding mechanism (1), the front end wire harness carrying mechanism (3), the wire harness switching mechanism (7), the rear end wire harness carrying mechanism (9) and the material taking mechanism (8).

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