CN222507342U - Winding mechanism - Google Patents

Abstract

The utility model provides a winding mechanism which comprises a mounting seat, an outer tube, a first driving piece, a clamp seat and a rotating arm. The mounting seat is provided with a mounting hole which penetrates through the front and rear parts, and the periphery of the front end of the mounting hole is provided with a first gear ring. The outer tube is rotatably mounted through the mounting hole. The chuck seat is rotatably arranged at the front end of the outer tube, and a second gear ring is arranged on the periphery of the chuck seat. The rotating arm is L-shaped, one end of the rotating arm extends towards the front end of the winding mechanism and is provided with a wire outlet hole, and the other end of the rotating arm is relatively and fixedly arranged at the front end of the outer tube. The rotating arm is provided with a rotating shaft parallel to the outer tube, gears are arranged at two ends of the rotating shaft, the gears are respectively meshed with the first gear ring and the second gear ring, and the rotating shaft enables the second gear ring to be relatively static with the mounting seat through rotation and revolution around the outer tube, so that the chuck, the mounting seat and the rotating arm form a compact mounting structure.

Description

Winding mechanism

Technical Field

The utility model relates to a winding mechanism.

Background

The winding equipment comprises a winding mechanism, the coil can be wound rapidly, the winding mechanism is not only provided with a winding rotating arm for improving winding stability and tidily arranging wires, but also is often provided with a main chuck and an auxiliary chuck, wherein the main chuck is arranged between the tail end of the rotating arm and the coil, so that copper wires can slide into a coil framework along the outer side surface of the main chuck, the auxiliary chuck is used for butting or supporting the coil, the distance between the main chuck and the coil can be controlled, and the coil is orderly overlapped layer by layer. At present, the winding mechanism on the market has the problems of dispersed distribution and incompact structure of the rotating arm, the main clamping head and the auxiliary clamping head, and the main reason is that the rotating arm has rotation and winding actions, a relatively isolated space is formed at the front end of the rotating arm, when other parts are arranged in the range of the rotating arm, interference with the rotating arm or copper wires can be generated, or the rotating arm is influenced by the rotation action of the rotating arm, the problems cause the separate arrangement of the parts of the winding mechanism, are relatively independent, and cause the problems of large overall size and large occupied space.

Disclosure of utility model

The utility model provides a winding structure with a compact structure for solving the technical problems.

A winding mechanism comprises a mounting seat, an outer tube, a first driving piece, a clamp seat and a rotating arm, wherein,

The mounting seat is provided with a mounting hole penetrating through the front and rear parts, and the front end periphery of the mounting hole is provided with a first gear ring.

The outer tube passes through the mounting hole and is rotatably mounted, and a bearing can be arranged for improving the rotation smoothness.

The first driving piece is arranged on the back of the mounting seat and connected with the outer tube to drive the outer tube to rotate.

The chuck seat is rotatably arranged at the front end of the outer tube, a second gear ring is arranged on the periphery of the chuck seat, and the second gear ring and the first gear ring are identical in structure and are spaced in parallel.

The rotating arm is L-shaped, one end of the rotating arm extends towards the front end of the winding mechanism and is provided with a wire outlet hole, and copper wires extend out of the rotating arm and are wound through rotation of the rotating arm. The other end of the rotating arm is relatively and fixedly arranged at the front end of the outer tube, is positioned between the second gear ring and the first gear ring, and is driven to rotate by the outer tube. The rotating arm is provided with a rotating shaft parallel to the outer tube, gears are arranged at two ends of the rotating shaft, the gears are respectively meshed with the first gear ring and the second gear ring, and the rotating arm is driven to rotate through rotation of the outer tube so as to perform winding action. When the rotating arm rotates, the gear and the rotating shaft form rotation under the action of the first gear ring, and at the moment, the rotating shaft forms a relatively static state with the first gear ring and the mounting seat through rotation and revolution around the outer tube.

According to the utility model, through the cooperation between the first gear ring, the second gear ring and the gears, the clamp seat rotatably mounted at the end part of the outer tube can be free from the influence of the rotation action of the outer tube, and can be in a relatively static state with the mounting seat, so that the clamp seat can form a compact mounting structure with the mounting seat and the rotating arm, and can also have relatively independent actions with the rotating arm, is free from the influence of the rotation action of the rotating arm, and can not interfere with the rotating arm or a copper wire.

Preferably, the rotating arm comprises two L-shaped plates, the two L-shaped plates are arranged in parallel at intervals and clamp the outer tube, so that the forming difficulty can be reduced, and the rotating arm is convenient to be additionally provided with a plurality of rollers for copper wires to pass through.

Preferably, the gear and the wire outlet hole are respectively positioned at two sides of the outer tube, so that the shaking condition during rotation caused by the deviation of the center of the rotating arm is avoided.

Preferably, the first driving piece drives the outer tube to rotate through connection of the motor, the belt and the belt pulley, and the driving structure is a flexible driving structure, so that vibration is reduced.

Preferably, the winding mechanism further comprises a secondary chuck, the secondary chuck is telescopically arranged at the front end of the chuck seat along the direction of the outer tube, the coil framework which is being wound can be propped against, the winding stability is improved, meanwhile, the uniformity of the winding can be improved through telescopic action, and the stacking condition is avoided during winding.

Preferably, the winding mechanism further comprises an inner tube and a second driving member. One end of the inner tube passes through the outer tube and is abutted against the auxiliary chuck. The second driving piece is arranged at the back of the mounting seat and connected with the outer tube to drive the inner tube to stretch and reciprocate in the outer tube.

Preferably, the front end of the inner tube is provided with a translation seat, and the sub-chuck comprises a bottom plate and a replacement seat. Guide rods penetrating through the clamp seat are arranged on two sides of the back of the bottom plate, the tail ends of the guide rods are arranged at the front end of the translation seat, the replacement seat is arranged at the front end of the bottom plate, and a limiting groove in the vertical direction is formed in the front end of the replacement seat. The replacement seat is provided with a plurality of blocks, and the size or shape of the limit groove of each replacement seat is different, so that the replacement seat can be replaced to wire the skeletons of various different sizes or specifications, and the application range of the equipment is improved.

Preferably, the winding mechanism further comprises two main chucks, the two main chucks are respectively arranged at the front end of the chuck seat in a relatively openable and closable manner through rail sliding, and copper wires can be smoothly transited to the winding layers of each layer through the openable and closable action.

Preferably, the winding mechanism further comprises a telescopic pipe and a third driving piece, the front end of the telescopic pipe penetrates through the inner pipe and is provided with a conical pushing block facing to the space between the two main chucks, the chuck base is provided with a yielding port for the conical pushing block to pass through, the back parts of the two main chucks are respectively provided with an inclined plane facing to the conical pushing block in a rotating mode, and a pulling spring is arranged between the two main chucks. The third driving piece is arranged at the back of the mounting seat and connected with the mounting seat to drive the telescopic rod to stretch out and draw back in the inner tube, and the telescopic rod pushes the inclined plane through the conical pushing block to drive the two main chucks to open against the elasticity.

Preferably, the second driving piece and the third driving piece comprise a connecting seat and a driving motor, the connecting seat is arranged on the back of the mounting seat through a guide rod, and the inner tube and the telescopic tube are respectively and rotatably arranged on the corresponding connecting seats through bearings. The driving motor is arranged on the connecting seat and is in butt joint with the back of the mounting seat through the screw nut, the distance between the connecting seat and the back of the mounting seat is adjusted through the screw nut by the driving motor, and then the inner pipe or the telescopic pipe is driven to move in a telescopic way through the connecting seat, so that the telescopic size precision is higher.

From the above description of the utility model, the utility model has the following advantages:

1. according to the utility model, through the cooperation among the first gear ring, the second gear ring and the gears, the clamp seat rotatably mounted at the end part of the outer tube can be free from the influence of the rotation action of the outer tube, and can be in a relatively static state with the mounting seat, so that the clamp seat can form a compact mounting structure with the mounting seat and the rotating arm, and can also have relatively independent actions with the rotating arm, so that the clamp seat is free from the influence of the rotation action of the rotating arm and can not interfere with the rotating arm or a copper wire;

2. The rotating arm comprises two L-shaped plates, so that the forming difficulty can be reduced, and the rotating arm is convenient to be additionally provided with a plurality of structures such as rollers for copper wires to pass through;

3. The winding mechanism further comprises an inner pipe and a second driving piece, wherein the inner pipe penetrates through the outer pipe and is in butt joint with the auxiliary chuck, and the winding mechanism is ingenious and compact in structure;

4. The winding mechanism further comprises a telescopic pipe and a third driving piece, wherein the telescopic rod penetrates through the inner pipe and is in butt joint with the main chuck, and the structure is ingenious and compact.

Drawings

The accompanying drawings, which are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate embodiments of the utility model and together with the description serve to explain the utility model and do not constitute a limitation on the utility model.

Wherein:

FIG. 1 is an isometric view of a winding mechanism;

FIG. 2 is a second isometric view of a winding mechanism;

FIG. 3 is an isometric view of a winding mechanism;

FIG. 4 is an isometric view of a winding mechanism;

FIG. 5 is an isometric view of a winding mechanism;

FIG. 6 is a top view of a winding mechanism;

FIG. 7 is a cross-sectional view of a winding mechanism (see FIG. 6 at A-A)

The marks in fig. 1 to 7 are respectively a mounting seat 1, a mounting hole 11, a first gear ring 12, an outer tube 2, a first driving member 3, a chuck seat 4, a second gear ring 41, a rotating arm 5, a gear 51, a sub chuck 6, a replacement seat 61, an inner tube 7, a translation seat 71, a second driving member 8, a main chuck 9, a telescopic tube 10, a tapered pushing block 101, and a third driving member 13.

Detailed Description

In order to make the technical problems, technical schemes and beneficial effects to be solved more clear and obvious, the utility model is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

Referring to fig. 1 to 7, a winding mechanism includes a mounting base 1, an outer tube 2, a first driving member 3, a chuck base 4, and a rotating arm 5, wherein,

The mount 1 is provided with a mounting hole 11 penetrating front and rear, and a first ring gear 12 is provided on a front end peripheral portion of the mounting hole 11.

The outer tube 2 passes through the mounting hole 11 and is rotatably mounted, and bearings can be arranged to improve the smoothness of rotation.

The first driving piece 3 is arranged on the back of the installation seat 1 and connected with the outer tube 2 to drive the outer tube to rotate. Preferably, the first driving member 3 drives the outer tube 2 to rotate through connection of a motor, a belt and a belt pulley, and the driving structure is a flexible driving structure, so that vibration is reduced.

The chuck base 4 is rotatably mounted at the front end of the outer tube 2, a second gear ring 41 is arranged on the periphery of the chuck base, and the second gear ring 41 and the first gear ring 12 are identical in structure and are spaced in parallel.

The rotating arm 5 is L-shaped, one end of the rotating arm extends towards the front end of the winding mechanism, and a wire outlet hole is formed in the rotating arm for the copper wire to extend out of the rotating arm 5 and perform winding action through rotation of the rotating arm 5. The other end of the rotating arm 5 is relatively and fixedly arranged at the front end of the outer tube 2, and is positioned between the second gear ring 41 and the first gear ring 12, and is driven to rotate by the outer tube 2. The rotating arm 5 is provided with a rotating shaft parallel to the outer tube 2, two ends of the rotating shaft are respectively provided with a gear 51, the two gears 51 are respectively meshed with the first gear ring 12 and the second gear ring 41, and the rotating arm 5 is driven to rotate by the rotation of the outer tube 2 so as to perform winding action. When the rotating arm 5 rotates, the gear 51 and the rotating shaft rotate under the action of the first gear ring 12, and at this time, the rotating shaft forms a relatively stationary state with the first gear ring 12 and the mount 1 by rotating and transferring the second gear ring 41 around the outer tube 2.

In an embodiment, the rotating arm 5 includes two L-shaped plates, the two L-shaped plates are arranged in parallel at intervals, and clamp the outer tube 2, so that the molding difficulty can be reduced, and some rollers or the like for copper wires to pass through are conveniently added in the rotating arm 5, in addition, the gears 51 and the wire outlet holes are respectively positioned at two sides of the outer tube 2, so that the shaking condition caused by the deviation of the center of the rotating arm 5 during rotation is avoided.

In another embodiment, the winding mechanism further comprises a secondary chuck 6, the secondary chuck 6 is telescopically mounted at the front end of the chuck base 4 along the direction of the outer tube 2, and can prop against a coil skeleton being wound, so that the winding stability is improved, and meanwhile, the uniformity of a winding can be improved through telescopic action, and the stacking condition during winding is avoided.

On the basis of the above embodiment, the winding mechanism further comprises an inner tube 7 and a second driving member 8. One end of the inner tube 7 passes through the outer tube 2 and abuts the sub-chuck 6. The second driving part 8 is arranged at the back of the mounting seat 1 and connected with the inner pipe 7 to drive the inner pipe 2 to stretch and reciprocate in the outer pipe 2.

Specifically, the front end of the inner tube 7 is provided with a translation seat 71, and the sub-chuck 6 includes a bottom plate and a replacement seat 61. Guide rods penetrating through the clamp seat 4 are arranged on two sides of the back of the bottom plate, the tail ends of the guide rods are arranged at the front end of the translation seat 71, the replacement seat 61 is arranged at the front end of the bottom plate, and a limiting groove in the vertical direction is formed in the front end of the replacement seat 61. The replacing seats 61 are provided with a plurality of blocks, and the size or shape of the limiting groove of each replacing seat 61 is different, so that the replacing seats 61 can be replaced to wire the skeletons with different sizes or specifications, and the application range of the equipment is improved.

On the basis of the above embodiment, in one embodiment, the winding mechanism further includes two main chucks 9, where two main chucks 9 are respectively slidably and relatively mounted on the front end of the chuck base 4 through rails, and the copper wire can be smoothly transited to the winding layer of each layer through the opening and closing action.

The winding mechanism further comprises a telescopic pipe 10 and a third driving piece 13, the front end of the telescopic pipe 10 penetrates through the inner pipe 7 and is provided with a conical pushing block 101 facing to the space between the two main chucks 9, the chuck base 4 is provided with a yielding port for the conical pushing block 101 to pass through, the back parts of the two main chucks 9 are respectively provided with an inclined plane facing to the conical pushing block 101 in a rotating mode, and a pulling spring is arranged between the two main chucks 9. The third driving piece 13 is installed at the back of the installation seat 1 and connected with and drives the telescopic rod to stretch and reciprocate in the inner pipe 7, and the telescopic rod pushes the inclined plane through the conical pushing block 101 to drive the two main chucks 9 to open against the elasticity.

In order to improve the control precision, in an embodiment, the second driving piece 8 and the third driving piece 13 each comprise an engagement seat and a driving motor, the engagement seat is mounted on the back of the mounting seat 1 through a guide rod, and the inner tube 7 and the telescopic tube 10 are rotatably mounted on the respective corresponding engagement seats through bearings. The driving motor is arranged on the connecting seat and is in butt joint with the back of the mounting seat 1 through a screw nut, the driving motor adjusts the distance between the connecting seat and the back of the mounting seat 1 through the screw nut, and then the inner pipe 7 or the telescopic pipe 10 is driven to move in a telescopic way through the connecting seat, so that the telescopic size precision is higher.

According to the utility model, through the cooperation between the first gear ring 12, the second gear ring 41 and the gear 51, the chuck seat 4 rotatably mounted at the end part of the outer tube 2 can be free from the influence of the rotation action of the outer tube 2 and can be in a relatively static state with the mounting seat 1, so that the chuck not only can form a compact mounting structure with the mounting seat 1 and the rotating arm 5, but also can have relatively independent actions between the chuck seat 4 and the rotating arm 5, is free from the influence of the rotation action of the rotating arm 5 and is free from interference with the rotating arm 5 or copper wires.

While the utility model has been described above with reference to the accompanying drawings, it will be apparent that the utility model is not limited to the above embodiments, but is capable of being modified or applied directly to other applications without modification, as long as various insubstantial modifications of the method concept and technical solution of the utility model are adopted, all within the scope of the utility model.

Claims (10)

1. The winding mechanism is characterized by comprising a mounting seat, an outer tube, a first driving piece, a clamp seat and a rotating arm;

the mounting seat is provided with a mounting hole which penetrates through the front and rear parts, and the periphery of the front end of the mounting hole is provided with a first gear ring;

The outer tube passes through the mounting hole and is rotatably mounted;

the first driving piece is arranged at the back of the mounting seat and connected with the outer tube to drive the outer tube to rotate;

The chuck seat is rotatably arranged at the front end of the outer tube, a second gear ring is arranged on the periphery of the chuck seat, and the second gear ring and the first gear ring are identical in structure and are spaced in parallel;

The rotating arm is L-shaped, one end extends towards the front end of the winding mechanism and is provided with a wire outlet hole, the other end is relatively and fixedly installed at the front end of the outer tube and is positioned between the second gear ring and the first gear ring, a rotating shaft parallel to the outer tube is arranged, gears are arranged at two ends of the rotating shaft and are meshed with the first gear ring and the second gear ring respectively, the rotating arm drives rotation through rotation of the outer tube so as to perform winding action, and the second gear ring forms a relatively static state with the first gear ring and the mounting seat through rotation of the gears and revolution around the outer tube.

2. A winding mechanism according to claim 1, wherein the rotating arm comprises two L-shaped plates, the two L-shaped plates being arranged in parallel and spaced apart and clamping the outer tube.

3. A wire winding mechanism according to claim 1, wherein the gear and the wire outlet are located on both sides of the outer tube.

4. A winding mechanism according to claim 1, wherein the first driving member is connected to the outer tube via a motor, a belt and a pulley.

5. The winding mechanism of claim 1, further comprising a secondary clip telescopically mounted to the front end of the clip seat in the direction of the outer tube.

6. The winding mechanism according to claim 5, further comprising an inner tube and a second driving member, wherein one end of the inner tube passes through the outer tube and is abutted against the sub-chuck, and the second driving member is mounted on the back of the mounting seat and is connected to drive the inner tube to reciprocate telescopically in the outer tube.

7. The winding mechanism according to claim 6, wherein the front end of the inner tube is provided with a translation seat, the sub-chuck comprises a bottom plate and a replacement seat, guide rods penetrating through the chuck seat are arranged on two sides of the back of the bottom plate, the tail ends of the guide rods are arranged at the front end of the translation seat, the replacement seat is arranged at the front end of the bottom plate, the front end of the replacement seat is provided with a limiting groove in the vertical direction, the replacement seat is provided with a plurality of blocks, and the limiting grooves of the replacement seats are different in size or shape.

8. The winding mechanism according to claim 6, further comprising two main chucks which are slidably and relatively openably mounted on the front ends of the chucks by rails, respectively.

9. The winding mechanism according to claim 8, further comprising a telescopic tube and a third driving member, wherein the front end of the telescopic tube passes through the inner tube and is provided with a conical pushing block facing between the two main chucks, the chuck base is provided with a yielding port for the conical pushing block to pass through, the backs of the two main chucks are rotatably provided with inclined planes facing the conical pushing block, a pulling spring is arranged between the two main chucks, and the third driving member is arranged on the back of the mounting seat and is connected to drive the telescopic tube to stretch and reciprocate in the inner tube, and the telescopic tube pushes the inclined planes through the conical pushing block to drive the two main chucks to open against the elastic force.

10. The winding mechanism according to claim 9, wherein the second driving member and the third driving member each comprise an engagement seat and a driving motor, the engagement seats are movably mounted on the backs of the mounting seats through guide rods, the inner tubes and the telescopic tubes are rotatably mounted on the respective corresponding engagement seats through bearings, the driving motor is mounted on the engagement seats and is abutted to the mounting seat backs through screw nuts, and the driving motor adjusts the distances between the engagement seats and the mounting seat backs through the screw nuts, so that the inner tubes or the telescopic tubes are driven to move in a telescopic manner through the engagement seats.