CN221070495U - Disc unloading device of automatic wire winding machine - Google Patents

Abstract

The utility model discloses a disc unloading device of an automatic wire winding machine, which comprises a base and a driving assembly, wherein a first guide plate and a second guide plate are arranged on the base, the first guide plate is provided with a first guide surface, the second guide plate is provided with a second guide surface, the first guide plate can rotate close to or far away from the first guide plate, and a positioning space for preventing a wire winding disc from rolling is formed by the first guide surface and the second guide surface in a first state; the first guide surface is used for being mutually engaged with the second guide surface in the second state and jointly forming a rolling surface for guiding the winding drum to roll; the driving assembly is arranged on the base and used for driving the first guide plate to rotate. According to the disc unloading device of the automatic wire winding machine, the first guide plate is driven to rotate through the driving assembly, so that the first guide surface of the first guide plate and the second guide surface of the second guide plate are matched to form a rolling surface, and the wire winding disc is guided to automatically roll.

Description

Disc unloading device of automatic wire winding machine

Technical Field

The utility model relates to the field of disc type automatic wire winding machines in the wire and cable equipment industry, in particular to a disc unloading device of an automatic wire winding machine.

Background

In the current domestic wire and cable industry, the traditional disc type wire winding machine is adopted to manually perform the disc unloading operation, so that the defects of high labor intensity, low production efficiency, low automation level and high production and manufacturing cost are overcome, the application and popularization of the automatic wire winding machine improves the labor environment of first-line workers in the wire and cable production industry, improves the automation level of the whole industry, and promotes the development of the wire and cable equipment industry to an intelligent and digital direction.

The wire and cable is wound on the take-up reel, the wire and cable is wound in the rotation process of the take-up reel, and after the wire and cable on the take-up reel is wound to reach the preset capacity, the take-up reel needs to be detached, but on the existing automatic take-up machine, a take-up reel unloading structure for the take-up reel generally needs to continuously push the take-up reel to roll to a conveying structure to unload the reel by means of external force, and in order to prevent the take-up reel from rolling during winding, a positioning structure of the take-up reel needs to be additionally arranged, so that the whole take-up reel unloading structure is complex.

Disclosure of utility model

In order to overcome at least one of the above-mentioned drawbacks of the prior art, the present utility model provides a disc unloading device of an automatic wire rewinding machine, which drives a first guiding plate to rotate through a driving assembly, so that a first guiding surface of the first guiding plate and a second guiding surface of the second guiding plate cooperate to form a rolling surface, and a wire rewinding disc is guided to automatically roll.

The utility model adopts the technical proposal for solving the problems that:

a disc unloading device of an automatic wire winding machine, which comprises,

The base is provided with a first guide plate and a second guide plate, the first guide plate is provided with a first guide surface, the second guide plate is provided with a second guide surface, the first guide plate can be close to or far away from the first guide plate to rotate, the first guide plate is in a first state after moving close to the second guide plate, and a positioning space for preventing a take-up reel from rolling is formed by the first guide surface and the second guide surface in the first state; the first guide plate is in a second state after moving away from the second guide plate, and the first guide surface is used for being mutually engaged with the second guide surface in the second state and jointly forming a rolling surface for guiding the take-up reel to roll;

the driving assembly is arranged on the base and used for driving the first guide plate to rotate.

Further, a first inclined surface is arranged on the first guide plate and used for gradually inclining downwards from one end close to the second guide plate to one end far away from the second guide plate in the second state; the first inclined surface is formed into the first guide surface; the second guide plate is provided with a second inclined surface, the second inclined surface gradually inclines downwards from one end far away from the first guide plate to one end close to the first guide plate, and the second inclined surface is formed on the second guide surface.

Further, a guide sliding rail is further arranged on the base, and the guide sliding rail is arranged at the end part of the first guide plate far away from the second guide plate; the guide sliding rail is used for being connected with one end, away from the second guide surface, of the first guide surface in the second state so as to receive the winding disc rolling on the rolling surface and guide the winding disc to continue rolling.

Further, the guide sliding rail gradually inclines downwards from one end close to the first guide plate to one end far away from the first guide plate.

Further, two sides of the guide sliding rail are respectively provided with a positioning baffle plate.

Further, a buffer backing plate is arranged at the end part of the guide sliding rail, which is close to the first guide plate.

Further, the second guide plates are provided with two, and two side parts of one end of the first guide plate are respectively rotatably connected with the two second guide plates.

Further, the drive assembly includes driving piece, connecting rod and connecting axle, first guide board with the second guide board passes through the connecting axle rotatable coupling, the one end of connecting rod with first guide board is connected, the other end of connecting rod with the drive end of driving piece is connected, the drive end of driving piece is used for driving the connecting rod motion in order to order about first guide board rotates.

Further, the driving piece is a driving air cylinder, and a piston rod of the driving air cylinder is hinged with the connecting rod; the cylinder body of the driving cylinder is hinged on the base.

Further, be equipped with the detector on the base, the detector is used for detecting first guide board with take-up reel on the second guide board, and send the detection signal for drive assembly.

In summary, the utility model has the following technical effects:

When the disc is unloaded, the driving assembly can drive the first guide plate to rotate away from the second guide plate, the first guide surface of the first guide plate can rotate to a state of being mutually engaged with the second guide surface of the second guide plate, the first guide surface and the second guide surface are formed into a rolling surface together, the take-up disc is not blocked by the first guide plate, and the first guide plate can roll to the conveying mechanism along the rolling surface formed by the second guide surface and the first guide surface, so that automatic disc unloading is realized, and manual disc unloading is not needed. In addition, this embodiment only needs to drive first guide board through the driving force that provides and rotates for first guide board and second guide board can form the rolling surface that drives about take-up reel automatic roll, and it is assisted its to unload the dish, need not to provide great driving force, practices thrift power resource, and the energy consumption is littleer.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic diagram of an assembly structure of a disc unloading device and a take-up reel according to the present utility model;

FIG. 3 is a schematic view of a first state of the disc unloading device of the present utility model;

Fig. 4 is a schematic structural view of a second state of the disc unloading device of the present utility model.

Wherein the reference numerals have the following meanings: 10. a base; 11. a cushion pad; 20. a first guide plate; 30. a second guide plate; 41. a driving cylinder; 42. a connecting rod; 43. a connecting shaft; 50. guiding the sliding rail; 51. and positioning a baffle.

Detailed Description

For a better understanding and implementation, the technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the drawings in the embodiments of the present utility model.

In the description of the present utility model, it should be noted that the terms "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, only for convenience in describing the present utility model and simplifying the description, and do not indicate or imply that the apparatus or elements to be referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this utility model belongs. The terminology used herein in the description of the utility model is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model.

Referring to fig. 1-4, the utility model discloses a disc unloading device of an automatic wire rewinding machine, comprising a base 10 and a driving assembly, wherein a first guide plate 20 and a second guide plate 30 are arranged on the base 10, the first guide plate 20 and the second guide plate 30 are oppositely arranged in the embodiment, the first guide plate 20 has a first guide surface, the second guide plate 30 has a second guide surface, the first guide plate 20 can rotate close to or far from the first guide plate 20, the first guide plate 20 is in a first state after rotating close to the second guide plate 30, and the first guide plate 20 is in a second use state after rotating far from the second guide plate 30.

In the first state, the first guide surface of the first guide plate 20 and the second guide surface of the second guide plate 30 may enclose a positioning space, and the winding reel may be prevented from rolling after being placed in the positioning space. In the second state, the first guide surface and the second guide surface are mutually engaged and jointly form a rolling surface for guiding the winding drum to roll. In addition, the driving assembly is mounted on the base 10 and drives the first guide plate 20 to rotate.

On the basis of the structure, when the disc unloading device of the automatic wire rewinding machine is used, the driving component can drive the first guide plate 20 to rotate towards the direction close to the second guide plate 30 during wire rewinding, so that the first guide surface of the first guide plate 20 and the second guide surface of the second guide plate 30 can enclose a positioning space, the wire rewinding disc is placed in the positioning space between the first guide plate 20 and the second guide plate 30 and can be abutted against the first guide surface and the second guide surface respectively, the first guide plate 20 is positioned on the rolling path of the wire rewinding disc, the wire rewinding disc is prevented from rolling, and the wire rewinding operation can be performed at the moment.

And after the take-up reel is completed, the take-up reel needs to be replaced, at the moment, the driving assembly can drive the first guide plate 20 to be far away from the second guide plate 30 and rotate, the first guide surface of the first guide plate 20 can rotate to be mutually engaged with the second guide surface of the second guide plate 30, the first guide surface and the second guide surface are formed into a rolling surface together, the take-up reel does not have the blocking of the first guide plate 20, and the take-up reel can roll to a conveying mechanism along the rolling surface formed by the second guide surface and the first guide surface, so that automatic disc unloading is realized, and manual disc unloading actions are not needed. In addition, because the take-up reel is heavy after the line is received, if directly apply the driving force to the take-up reel and drive it to roll, then required power consumption's power is big, and this embodiment only need can drive first guide board 20 rotation through the driving force that provides for first guide board 20 and second guide board 30 can form the rolling surface that drives take-up reel automatic roll, assist its to unload the dish, need not to provide great motive force, practice thrift power resource, the energy consumption is littleer.

Further, in the present embodiment, the first inclined surface may be provided on the first guide plate 20, and in the second state, the first inclined surface is gradually inclined downward from the end close to the second guide plate 30 to the end far from the second guide plate 30. Correspondingly, a second inclined surface is provided on the second guide plate 30, the second inclined surface gradually inclined downward from one end far from the first guide plate 20 to one end close to the first guide plate 20, on the basis of this structure, the first inclined surface is formed into a first guide surface; the second inclined surface is formed into a second guide surface.

So, when carrying out the admission action, drive assembly orders about first guide board 20 and is close to the rotation of second guide board 30, and first inclined plane and second inclined plane can form "V" type groove, can prevent effectively that the take-up reel from rolling after the take-up reel is put into. And when carrying out the action of unloading the dish, drive assembly drives first guide board 20 to keep away from second guide board 30 and rotates, first inclined plane alright link up in the second inclined plane, the two can form the guide rolling surface of downward sloping jointly, the take-up reel alright roll to first inclined plane along the second inclined plane, form a continuous inclined plane by second inclined plane, first guide board 20 loses the blocking effect to the take-up reel, the take-up reel rolls down under the action of the gravity component that the inclined plane produced, the take-up reel rolls to predetermined take-up reel conveying mechanism directly, need not in this way other thrust.

Of course, the first guide surface and the second guide surface may be continuous arc surfaces, in the first state, after the first guide plate 20 approaches to the second guide plate 30 and rotates, the arc surfaces of the first guide surface and the second guide plate 30 may also enclose a positioning space, and in the second state, the arc surfaces of the first guide surface and the second guide surface may be mutually engaged so that the continuous arc surfaces face downward, and may also form a rolling surface for guiding the winding disc to roll. Of course, compared with the cambered surface, the inclined surface adopted by the application is continuously guided downwards on the same plane, the guiding process is more stable, and the cambered surface is unstable because continuous points are connected on different surfaces.

Further, a guide rail 50 may be further disposed on the base 10, where the guide rail 50 is disposed at an end of the first guide plate 20 away from the second guide plate 30, and when the first guide plate 20 rotates to the second state, the guide rail 50 may be engaged with an end of the first guide surface away from the second guide surface, and if the rolling path from the base 10 to the conveying mechanism is large, if the first guide plate 20 is directly engaged to the edge of the base 10 for guiding, the volume of the first guide plate 20 is too large, the guide rail 50 is disposed and engaged at an end of the first guide plate 20 away from the second guide plate 30 to receive the winding disc rolling on the rolling surface and guide the winding disc to continue rolling to the conveying structure, so that the winding disc is continuously guided by a section of fixed guide rail 50.

Similarly, in the present embodiment, the guide rail 50 gradually slopes downward from the end near the first guide plate 20 to the end far from the first guide plate 20, that is, the guide rail 50 guides the take-up reel with an inclined surface. When the disc unloading operation is performed, the second inclined plane, the first inclined plane and the inclined plane of the guide sliding rail 50 form a continuous inclined plane, the first guide plate 20 loses the blocking effect on the take-up disc, and the take-up disc rolls onto the preset take-up disc conveying mechanism under the action of gravity component force generated by the inclined plane.

Further, the two sides of the guiding slide rail 50 are respectively provided with a positioning baffle plate 51, and because the second inclined plane, the first inclined plane and the inclined plane of the guiding slide rail 50 form a continuous inclined plane together to roll on the take-up reel, the deviation is easy to occur, the two sides of the guiding slide rail 50 are provided with the positioning baffle plates 51, which can be blocked at the two axial sides of the take-up reel, and when the take-up reel rolls to the position of the guiding slide rail 50, the positioning baffle plates 51 at the two sides perform positioning deviation correction, so that the rolling path of the take-up reel is aligned and rolls to a preset take-up reel conveying mechanism.

Further, the end portion of the guide rail 50, which is close to the first guide plate 20, may be provided with the cushion plate 11, and since the first guide plate 20 rotates away from the second guide plate 30, the first guide plate may rotate towards the guide rail 50, in order to prevent the first guide plate 20 from striking the guide rail 50 or the base 10 when rotating downward, the guide rail 50 is provided with the cushion plate 11, and the cushion plate 11 may be made of flexible materials such as rubber, silica gel, or sponge, so as to effectively prevent striking.

Further, in this embodiment, the two second guiding plates 30 are provided, and two side portions of one end of the first guiding plate 20 can be respectively connected to the two second guiding plates 30 in a rotating manner, and the middle portion of the specific first guiding plate 20 can be protruded to form a swivel seat, that is, the swivel seat in the middle of the first guiding plate 20 extends between the two second guiding plates 30, and two sides of the first guiding plate 20 can be connected to the second guiding plates 30 in a shaft rotatable manner, so that the rotating connection structure is more stable.

More specifically, the driving assembly includes a driving member, a connecting rod 42 and a connecting shaft 43, the first guide plate 20 and the second guide plate 30 are rotatably connected through the connecting shaft 43, one end of the connecting rod 42 is connected with the first guide plate 20, the other end of the connecting rod 42 is connected with the driving end of the driving member, and the driving end of the driving member is used for driving the connecting rod 42 to move so as to drive the first guide plate 20 to rotate. Thus, the driving piece can pull the connecting rod 42 upwards to guide the first guide plate 20 to rotate upwards towards the second guide plate 30, and the driving piece pushes the connecting rod 42 downwards to guide the first guide plate 20 to rotate downwards away from the second guide plate 30, so that the connecting rod 42 is linked, and the driving is more labor-saving.

Further, the driving member is a driving cylinder 41, and a piston rod of the driving cylinder 41 is hinged with a connecting rod 42; the cylinder body of the driving cylinder 41 is hinged on the base 10, so that the connecting rod 42 can be pushed forward by extending the piston rod of the driving cylinder 41, so that the connecting rod 42 pushes the first guide plate 20 connected with the connecting rod to rotate downwards far away from the second guide plate 30, and the piston rod of the driving cylinder 41 is retracted, so that the connecting rod 42 can be pulled to drive the connecting rod 42 to pull the first guide plate 20 connected with the connecting rod to rotate upwards towards the second guide plate 30.

In addition, since the first guide plate 20 pulls the link 42 when rotating downward toward away from the second guide plate 30, and the length of the link 42 is limited, in order to prevent the driving cylinder 41 from being blocked during this process, the cylinder body of the driving cylinder 41 is hinged to the base 10, so that the cylinder body of the driving cylinder 41 has a certain swing space with respect to the base 10.

Of course, the driving member can be an oil cylinder, and in other cases, the driving assembly can also directly select a motor structure to directly rotate.

Further, a detector is provided on the base 10, and the detector can detect whether there is a take-up reel on the first guide plate 20 and the second guide plate 30, and send a detection signal to the driving component. After the detector detects that the take-up reel takes up action is completed, the driving assembly drives the first guide plate 20 to rotate away from the second guide plate 30 according to the detection signal, and the unloading action is completed.

The technical means disclosed by the scheme of the utility model is not limited to the technical means disclosed by the embodiment, and also comprises the technical scheme formed by any combination of the technical features. It should be noted that modifications and adaptations to the utility model may occur to one skilled in the art without departing from the principles of the present utility model and are intended to be within the scope of the present utility model.

Claims (10)

1. The disc unloading device of the automatic wire winding machine is characterized by comprising,

The base is provided with a first guide plate and a second guide plate, the first guide plate is provided with a first guide surface, the second guide plate is provided with a second guide surface, the first guide plate can be close to or far away from the first guide plate to rotate, the first guide plate is in a first state after moving close to the second guide plate, and a positioning space for preventing a take-up reel from rolling is formed by the first guide surface and the second guide surface in the first state; the first guide plate is in a second state after moving away from the second guide plate, and the first guide surface is used for being mutually engaged with the second guide surface in the second state and jointly forming a rolling surface for guiding the take-up reel to roll;

the driving assembly is arranged on the base and used for driving the first guide plate to rotate.

2. The wire-rewinding machine as claimed in claim 1, wherein a first inclined surface is provided on the first guide plate, the first inclined surface being configured to gradually incline downward from one end close to the second guide plate to one end far from the second guide plate in the second state; the first inclined surface is formed into the first guide surface; the second guide plate is provided with a second inclined surface, the second inclined surface gradually inclines downwards from one end far away from the first guide plate to one end close to the first guide plate, and the second inclined surface is formed on the second guide surface.

3. The disc unloading device of the automatic wire rewinding machine according to claim 1, wherein the base is further provided with a guide sliding rail, and the guide sliding rail is arranged at the end part of the first guide plate far away from the second guide plate; the guide sliding rail is used for being connected with one end, away from the second guide surface, of the first guide surface in the second state so as to receive the winding disc rolling on the rolling surface and guide the winding disc to continue rolling.

4. A wire-rewinding machine as claimed in claim 3, characterized in that the guide rail is inclined gradually downwards from the end close to the first guide plate to the end remote from the first guide plate.

5. A disc unloading device of an automatic wire rewinding machine according to claim 3, characterized in that the two sides of the guiding slide rail are respectively provided with a positioning baffle.

6. A wire-rewinding machine as claimed in claim 3, characterized in that the end of the guide rail close to the first guide plate is provided with a buffer pad.

7. The wire-rewinding machine as claimed in any one of claims 1 to 6, wherein said second guide plates are provided with two, and both side portions of one end of said first guide plate are rotatably connected to said two second guide plates, respectively.

8. The wire-rewinding machine as claimed in any one of claims 1 to 6, wherein the driving assembly comprises a driving member, a connecting rod and a connecting shaft, the first guide plate and the second guide plate are rotatably connected through the connecting shaft, one end of the connecting rod is connected with the first guide plate, the other end of the connecting rod is connected with the driving end of the driving member, and the driving end of the driving member is used for driving the connecting rod to move so as to drive the first guide plate to rotate.

9. The wire-rewinding machine as claimed in claim 8, wherein said driving member is a driving cylinder, a piston rod of which is hinged to said link; the cylinder body of the driving cylinder is hinged on the base.

10. The wire-rewinding machine as claimed in any one of claims 1 to 6, wherein a detector is provided on the base, and the detector is configured to detect the wire-rewinding disc state on the first guide plate and the second guide plate, and send a detection signal to the driving member.