CN211812746U - Horn tube wire bonder's case parallel slide mechanism that traverses - Google Patents

Abstract

The utility model discloses a traverse box parallel sliding mechanism of a horn tube wire bonder, which comprises a frame and an active winding mechanism on the frame, wherein the active winding mechanism comprises a swingable active motor, a main scroll on the active motor, a control box, a touch wheel rotatably arranged on the control box, and a yarn guide head which can be arranged on the control box in a sliding way and is used for guiding yarns, and the main scroll presses the touch wheel to clamp the yarns and is matched with the rotation; the control box can be arranged on the rack in a sliding manner relative to the axial direction of the main scroll in parallel, and is linked with the driving motor through a connecting rod mechanism. In the process that the yarn is wound on the flared tube on the main winding shaft, the main winding shaft on the driving motor is unfolded along with the increase of the yarn, the driving motor synchronously drives the control box to move by means of the connecting rod mechanism, so that the yarn guide head on the driving motor moves backwards, the wound axial position gradually moves towards the rear part of the flared tube, and the yarn can be stably wound in a shape matched with the flared tube.

Description

Horn tube wire bonder's case parallel slide mechanism that traverses

Technical Field

The utility model belongs to the technical field of spinning machine and specifically relates to a horn tube wire bonder's case parallel slide mechanism that traverses.

Background

The trumpet tube wire bonder is a machine for winding yarns into a tube on a trumpet tube, and the trumpet tube is provided with a trumpet-shaped rear seat with inclination, so that if the yarns are required to be wound more and more, the winding axial position can be moved to the rear part of the trumpet tube, the yarns can be stably supported on the trumpet tube rear seat, the cross section of the yarns can be parallelogram after winding, namely, the front end of the trumpet tube is an inclined plane with inclination, and the trumpet tube wire bonder is more attractive and stable. The utility model discloses be promptly to design the case parallel slide mechanism that traverses of a horn tube routing machine, can structurally realize along with the coiling of yarn, the position of whole coiling can remove gradually to make the shape of yarn adaptation horn tube carry out good coiling routing.

SUMMERY OF THE UTILITY MODEL

The utility model aims at overcoming prior art's not enough, providing a horn tube routing machine's the parallel slide mechanism of case that traverses, structurally realize along with the coiling of yarn, the position of whole coiling can remove gradually to the shape that makes yarn adaptation horn tube carries out good coiling routing.

The utility model adopts the following technical scheme: a traverse box parallel sliding mechanism of a horn tube wire bonder comprises a rack and an active winding mechanism arranged on the rack; the driving winding mechanism comprises a driving motor which can be arranged on the rack in a swinging mode, a main scroll which can be rotatably arranged on the shaft of the driving motor, a control box which is arranged on the rack, a touch wheel which can be rotatably arranged on the control box, and a yarn guide head which can be arranged on the control box in a sliding mode, wherein the main scroll presses the touch wheel to clamp yarns and rotates in a matching mode, and the yarn guide head is positioned below the position between the main scroll and the touch wheel to guide the yarns and slides along the axial direction of the main scroll and the touch wheel; the method is characterized in that: the control box can be arranged on the rack in a manner of sliding in parallel relative to the axial direction of the main reel, the control box is connected and linked with the driving motor through a connecting rod mechanism, and when the driving motor drives the main reel to rotate in the direction of being far away from the touch wheel in the axial direction, the driving motor drives the control box to translate in the direction close to the driving motor through the connecting rod mechanism, so that the stroke position of the yarn guide head on the control box translates.

As an improvement, the connecting rod mechanism comprises a crank, a first connecting rod and a second connecting rod, wherein the first connecting rod and the second connecting rod are respectively arranged on two sides of the crank; the crank enables the first connecting rod and the second connecting rod to form an included angle structure.

As an improvement, the second connecting rod comprises a rod body and a sliding block arranged at one end of the rod body, the rod body is connected with a crank, the sliding block can be arranged on the rack in a sliding mode through a sliding rail mechanism, and the sliding block is connected with a control box.

As an improvement, the driving motor is connected with the first connecting rod, the first connecting rod and the crank, the crank is connected with the rod body, and the rod body and the sliding block are connected through the joint bearing.

As an improvement, a waist-shaped hole is formed in the crank, and the second connecting rod is arranged at the waist-shaped hole through a fastener in an adjustable position.

As an improvement, the first connecting rod or/and the second connecting rod are/is of a multi-section structure, and the multiple sections are connected through a thread structure and used for adjusting the overall length.

As an improvement, the first connecting rod or the second connecting rod comprises an outer rod and an inner rod which are sleeved with each other, the inner side wall of a sleeve hole for the inner rod to be sleeved on the outer rod penetrates outwards to form a mounting hole, the outer side wall of the inner rod is provided with an annular groove, a ball is arranged at the mounting hole, and the ball is abutted to the inner rod through an elastic abutting part; when the ball is clamped into the annular groove, the inner rod is axially locked, and when the axial external force applied to the outer rod and the inner rod is greater than the contact force of the elastic contact piece, the ball is separated from the annular groove to unlock.

As an improvement, the elastic abutting piece comprises a spring for abutting against the ball and a bolt spirally arranged at the mounting hole and used for abutting against the spring, and the abutting degree of the bolt against the spring corresponds to the abutting force of the spring against the ball.

As an improvement, an adjusting frame is arranged at the position of the driving motor, a plurality of adjusting holes which are radially arranged along the rotating shaft of the driving motor are arranged on the adjusting frame, and when the first connecting rod is arranged at different adjusting holes, the distance for driving the control box to move by the driving motor is correspondingly adjusted.

The utility model has the advantages that: in the process of winding the yarn on the flared tube on the main winding shaft, the main winding shaft on the driving motor is unfolded along with the increase of the yarn, the driving motor synchronously drives the connecting rod mechanism, the connecting rod mechanism synchronously drives the control box to move, so that the yarn guide head on the connecting rod mechanism moves backwards, the axial position of the winding gradually moves towards the rear part of the flared tube, the yarn can be stably supported on the rear seat of the flared tube, the cross section of the yarn after being wound and formed is parallelogram, namely the front end of the yarn is an inclined plane with inclination, and the yarn winding is attractive and stable.

Drawings

Fig. 1 is a schematic front perspective view of the present invention.

Fig. 2 is a schematic perspective view of the back of the present invention.

Fig. 3 is a schematic perspective view of the link mechanism of the present invention.

Fig. 4 is a longitudinal sectional view of the first link or the second link of the link mechanism of the present invention.

Detailed Description

The following detailed description of the embodiments of the present invention will be made with reference to the accompanying drawings.

As shown in fig. 1, 2, 3 and 4, the present invention is a specific embodiment of the traverse box parallel sliding mechanism of the horn wire bonder. The embodiment comprises a frame 0 and an active winding mechanism 1 arranged on the frame 0; the driving winding mechanism 1 comprises a driving motor 11 which can be arranged on the rack 0 in a swinging mode, a main winding shaft 12 which can be arranged on the shaft of the driving motor 11 in a rotating mode, a control box 10 which is arranged on the rack 0, a touch wheel 13 which can be arranged on the control box 10 in a rotating mode, and a yarn guide head 14 which can be arranged on the control box 10 in a sliding mode, wherein the main winding shaft 12 presses the touch wheel 13 to clamp yarns and rotates in a matched mode, and the yarn guide head 14 is located below the position between the main winding shaft 12 and the touch wheel 13 to guide the yarns and slides along the axial direction of the main winding shaft 12 and the touch; the control box 10 can be arranged on the frame 0 in a sliding manner in parallel relative to the axial direction of the main reel 12, the control box 10 is connected and linked with the driving motor 11 through a link mechanism 4, when the driving motor 11 drives the main reel 12 to rotate in the direction away from the touch wheel 13, the driving motor 11 drives the control box 10 to translate in the direction close to the driving motor 11 through the link mechanism 4, and therefore the stroke position of the thread guide head 14 on the control box 10 is translated.

The utility model discloses when using, its horn tube routing machine of using, it has unwinding mechanism, adjusting part and initiative winding mechanism 1, it sets up to side by side multiunit and lies in the upper and lower the place ahead of frame 0 respectively, initiative winding mechanism 1 and the adjusting part between the unwinding mechanism, set up electronic tension sensor as required, visit yarn sensor, tension (holding) chuck isotructure and combination use, electronic tension sensor detects yarn tension, the tension (holding) chuck is relaxed or is pressed from both sides tight yarn, it has yarn to visit yarn sensor detection, the realization is controlled the elasticity of yarn, the coiling that keeps the yarn can not be too loose or tension, the sensor can feedback signal give initiative motor 11, keep suitable rotational speed, the elasticity of control yarn that can be good, can coil out the suitable and neat and orderly yarn of elasticity on the horn tube. The unwinding mechanism can adopt a vertically placed cylinder or a horizontally placed cylinder to directly arrange the cylindrical yarn, or adopt a motor with an active unwinding function and the cylinder to actively unwind, and the unwinding mechanism can be selectively arranged according to different processed yarns.

As shown in fig. 1 and 2, for the active winding mechanism 1, the active motor 11 is swingably disposed on the frame 0 through a shaft structure, a main winding shaft 12 is sleeved on a motor shaft of the active motor 11, the main winding shaft 12 presses against a contact wheel 13 on the control box 10 by means of the gravity of the active motor 11 or by means of an elastic structure, a flared tube is sleeved on the main winding shaft 12 and is fixed, a yarn passing through the lower portion of the main winding shaft to the rear of the yarn guide head 14 is further clamped between the flared tube and the contact wheel 13, the flared tube is driven to actively rotate through the main winding shaft 12, the contact wheel 13 follows and passively rotates, and the yarn is wound on the flared tube. During the winding process, the yarn is guided by the yarn guide 14 which can move back and forth along the axial direction of the abutting wheel 13, and is uniformly wound on the flared tube back and forth, and the movement of the yarn guide 14 can be realized by the prior art such as an air cylinder or a motor arranged in the control box 10, which is not described in more detail herein. In the process of winding the yarn on the flared tube on the main winding shaft 12, the main winding shaft 12 on the active motor 11 and the flared tube are opened along with the increase of the yarn, the active motor 11 synchronously drives the connecting rod mechanism 4, the connecting rod mechanism 4 synchronously drives the control box 10 to move, the control box 10 can be arranged by adopting a structure of a transverse shaft and a sliding block and horizontally moves, a blocking piece with an adjusting function can be arranged in the front and the back for front and back limiting, or the structure of the machine frame 0 is used for limiting; the control box 10 moves to move the wire guide head 14 backwards, and the winding axial position gradually moves towards the rear part of the trumpet tube, so that the yarn can be stably supported on the rear seat of the trumpet tube, the cross section of the yarn after being wound is parallelogram, namely the front end of the yarn is an inclined plane with inclination, and the yarn winding is beautiful and stable. After the wire bonding process of a trumpet tube is completed, the trumpet tube on the main winding shaft 12 is detached by a worker and the next trumpet tube is replaced, the driving motor 11 and the main winding shaft 12 return to the initial positions and abut against the contact wheel 13, and meanwhile, the control box 10 is driven to reset.

As a modified specific embodiment, the link mechanism 4 includes a crank 41 and a first link 42 and a second link 43 respectively disposed at two sides of the crank 41, the crank 41 is rotatably disposed on the frame 0, the first link 42 is connected to the driving motor 11, and the second link 43 is connected to the control box 10; the crank 41 forms an angle structure between the first link 42 and the second link 43.

As shown in fig. 2 and 3, the crank 41 is rotatably disposed on the frame 0 through a middle shaft structure, and with reference to the drawing, the left end is connected to the first connecting rod 42, the first connecting rod 42 is connected to the driving motor 11, the right end is connected to the second connecting rod 43, and the second connecting rod 43 is connected to the control box 10; the first connecting rod 42 and the second connecting rod 43 form an included angle structure by means of the structure of the crank 41; when the driving motor 11 swings outwards, the driving motor 11 drives the first link 42 to pull to the left, and the crank 41 rotates to drive the second link 43 to pull to the rear, so that the control box 10 moves backwards. In the reverse direction, the driving motor 11 swings back inward, and the control box 10 moves forward. The specific link mechanism 4 well realizes the transmission effect when the action directions of the driving motor 11 and the control box 10 are different.

As a modified embodiment, the second link 43 includes a rod 431 and a slider 432 disposed at one end of the rod 431, the rod 431 is connected to the crank 41, the slider 432 is slidably disposed on the frame 0 through a slide rail mechanism 01, and the slider 432 is connected to the control box 10.

As shown in fig. 2, in this embodiment, by means of the structures of the sliding block 432 and the sliding rail mechanism 01, one end of the rod body 431 and the sliding block 432 perform a translational motion on the rack 0, and then the sliding block 432 is connected to the control box 10 downward, so that the overall motion structure is more stable, and the structural arrangement is more reasonable. The rod body 431 and the sliding block 432 are provided with a joint bearing, so that the angle position change between structures is adapted, and the transmission is better performed.

As a modified embodiment, the active motor 11 and the first link 42, the first link 42 and the crank 41, the crank 41 and the rod 431, and the rod 431 and the slider 432 are coupled by a knuckle bearing.

The arrangement mode enables the link mechanism 4 to adapt to the position change of the angle between the structures, and can better adapt to the motion tracks of the driving motor l1 and the control box 10.

As a modified embodiment, a kidney-shaped hole 44 is formed on the crank 41, and the second link 43 is arranged at the kidney-shaped hole 44 in an adjustable position through a fastener.

As shown in fig. 2 and 3, the connection position of the end of the second connecting rod 43 connected to the crank 41 can be changed by adjusting the waist-shaped hole 44, and the distance between the end of the second connecting rod 43 and the rotation axis of the crank 41, which is changed in position, can be changed, so that the distance that the second connecting rod 43 can be driven to move when the crank 41 rotates can be changed, the movement distance of the control box 10 can be adjusted, and the swing of the driving motor 11 can be adapted to different movement distances and speeds of the control box 10 under different specification of the bell pipes.

As a modified embodiment, the first link 42 or/and the second link 43 are in a multi-segment structure, and the multiple segments are connected by a thread structure for adjusting the overall length.

As shown in fig. 2, 3 and 4, the overall length of the connecting rod can be changed by a spiral through a multi-section structure, so that the initial positions or the moving relations of the driving motor 11 and the control box 10 under different horn tube specifications can be adjusted when the driving motor and the control box are driven by the connecting rod mechanism 4. The different specifications of the trumpet tube are mainly embodied in that different trumpet tubes may have trumpet shapes with different slopes, so that different traveling distances and different speeds of the control box 10 need to be corresponding to the swing of the driving motor 11, and the debugging work during routing of the trumpet tubes with different specifications can be better completed by means of the adjustable overall length of the first connecting rod 42 or/and the second connecting rod 43.

As an improved specific embodiment, the first link 42 or the second link 43 includes an outer rod 421 and an inner rod 422, which are sleeved with each other, an installation hole 424 is formed by the inner side wall of a sleeve hole 423 on the outer rod 421, in which the inner rod 422 is sleeved, penetrating outwards, an annular groove 425 is formed on the outer side wall of the inner rod 422, a ball 426 is arranged at the installation hole 424, and the ball 426 is abutted to the inner rod 422 through an elastic abutting part 427; when the balls 426 are engaged in the annular groove 425, the inner rod 422 is axially locked, and when the external axial force applied to the outer rod 421 and the inner rod 422 is larger than the abutting force of the elastic abutting member 427, the balls 426 are disengaged from the annular groove 425 to unlock.

As shown in fig. 4, in actual operation, after the yarn winding is completed, a worker needs to pull the handles at the driving motor 11 and the main winding shaft 12 to unlock the flare tube on the main winding shaft 12, and a force is continuously applied to the driving motor 11, which will connect with the link mechanism 4 to drive the control box 10, and after the control box 10 is in place, the control box 10 is in a limit position or a stable position. The outer rod 421 and the inner rod 422 which are further arranged are of a structure capable of sliding relatively, and in an initial state, the balls 426 are clamped into the annular groove 425 to axially lock the outer rod 421 and the inner rod 422; when the driving motor 11 runs routing, along with the gradual increase of yarns on the flared tube, the driving motor 11 and the main reel 12 are slowly unfolded and swung, and at the moment, the first connecting rod 42 or the second connecting rod 43 which is synchronously driven bears smaller driving force, so that the ball 426 which is propped against the annular groove 425 by the elastic propping component 427 cannot be pulled, and the locking state of the outer rod 421 and the inner rod 422 is kept; when a subsequent worker pulls the handle, a large force can be used, the force can overcome the resisting force of the elastic resisting part 427, the ball 426 can move to be separated from the annular groove 425, the inner rod 422 can be pulled to move relative to the outer rod 421, the force generated when the worker pulls the handle is an instantaneous force, the outer rod 421 cannot be driven to move by the force, or only has small movement displacement, and under the obstruction of the crank 41, another connecting rod and the control box 10 structure, the force cannot drive the control box 10 to generate displacement, so that the operation when the horn tube is detached cannot damage the structure at the control box 10 or pull yarns, the service life of the mechanism is prolonged, and the routing quality is ensured. When the active motor 11 swings back and resets, the outer rod 421 and the inner rod 422 can also complete the reset to make the ball 426 snap back to the annular groove 425 again for limiting. In the design process, the force of the elastic contact element 427 against the ball 426 can be set to be the driving pull-off when the driving motor 11 runs and wires are wound, and the instantaneous pulling force when the driving motor is operated by a worker can be used for pulling off.

As a modified embodiment, the elastic contact member 427 includes a spring 428 for abutting against the ball 426 and a bolt 429 screw-installed at the installation hole 424 for abutting against the spring 428, and the interference of the bolt 429 against the spring 428 corresponds to the interference of the spring 428 against the ball 426.

As shown in fig. 4, the elastic contact element 427 is specifically provided as a spring 428 and a bolt 429, and a worker can adjust the compression degree of the spring 428 by adjusting the pressing force of the bolt 429 on the spring 428, so that the contact force can be changed to adapt to workers with different strength degrees.

As an improved specific embodiment, an adjusting frame 111 is disposed at the position of the driving motor 11, a plurality of adjusting holes 112 radially arranged along the rotating shaft of the driving motor 11 are disposed on the adjusting frame 111, and when the first connecting rod 42 is installed at different adjusting holes 112, the distance that the driving motor 11 drives the control box 10 to move is correspondingly adjusted.

As shown in fig. 2, in order to adapt to the wire bonding process of the trumpet tubes with different specifications, a plurality of adjusting holes 112 are further provided, the connecting position between the first connecting rod 42 and the adjusting frame 111 can be adjusted and changed by the arrangement of the plurality of adjusting holes 112, the distance between the end of the first connecting rod 42 with the changed position and the rotating shaft of the driving motor 11 is changed, so that the distance that the first connecting rod 42 can be driven to move when the driving motor 11 rotates can be changed, the movement distance of the control box 10 can be adjusted, and the swinging of the driving motor 11 corresponds to different movement distances and speeds of the control box 10 under different trumpet tube specifications.

Above only the utility model discloses an it is preferred embodiment, the utility model discloses a scope of protection not only limits in above-mentioned embodiment, and the all belongs to the utility model discloses a technical scheme under the thinking all belongs to the utility model discloses a scope of protection. It should be noted that, for those skilled in the art, various modifications and decorations can be made without departing from the principle of the present invention, and these modifications and decorations should also be regarded as the protection scope of the present invention.

Claims (9)

1. A traverse box parallel sliding mechanism of a horn tube wire bonder comprises a rack (0) and an active winding mechanism (1) arranged on the rack (0); the driving winding mechanism (1) comprises a driving motor (11) which can be arranged on the rack (0) in a swinging mode, a main reel (12) which can be arranged on the shaft of the driving motor (11) in a rotating mode, a control box (10) which is arranged on the rack (0), a touch wheel (13) which can be arranged on the control box (10) in a rotating mode, and a yarn guide head (14) which can be arranged on the control box (10) in a sliding mode, wherein the main reel (12) presses the touch wheel (13) to clamp yarns and rotates in a matched mode, and the yarn guide head (14) is located below the position between the main reel (12) and the touch wheel (13) to guide the yarns and slides along the axial direction of the main reel (12) and the touch wheel (13); the method is characterized in that: the control box (10) can be arranged on the rack (0) in a manner of sliding in parallel relative to the axial direction of the main reel (12), the control box (10) is connected and linked with the driving motor (11) through a connecting rod mechanism (4), when the driving motor (11) drives the main reel (12) to rotate in the direction away from the contact wheel (13), the driving motor (11) drives the control box (10) to translate in the direction close to the driving motor (11) through the connecting rod mechanism (4), and therefore the stroke position of the yarn guide head (14) on the control box (10) is made to translate.

2. The traverse box parallel sliding mechanism of the horn wire bonder of claim 1, wherein: the connecting rod mechanism (4) comprises a crank (41), a first connecting rod (42) and a second connecting rod (43) which are respectively arranged on two sides of the crank (41), the crank (41) is rotatably arranged on the rack (0), the first connecting rod (42) is connected with the driving motor (11), and the second connecting rod (43) is connected with the control box (10); the crank (41) forms an included angle structure between the first connecting rod (42) and the second connecting rod (43).

3. The traverse box parallel sliding mechanism of the horn wire bonder as claimed in claim 2, wherein: the second connecting rod (43) comprises a rod body (431) and a sliding block (432) arranged at one end of the rod body (431), the rod body (431) is connected with the crank (41), the sliding block (432) is arranged on the rack (0) in a sliding mode through a sliding rail mechanism (01), and the sliding block (432) is connected with the control box (10).

4. The traverse box parallel sliding mechanism of the horn wire bonder of claim 3, wherein: the driving motor (11) is connected with the first connecting rod (42), the first connecting rod (42) is connected with the crank (41), the crank (41) is connected with the rod body (431), and the rod body (431) is connected with the sliding block (432) in four pairs through joint bearings.

5. The traverse box parallel sliding mechanism of the horn wire bonder as claimed in claim 2, wherein: the crank (41) is provided with a waist-shaped hole (44), and the second connecting rod (43) is arranged at the waist-shaped hole (44) through a fastener in an adjustable position.

6. The traverse box parallel sliding mechanism of the horn wire bonder as claimed in claim 2, wherein: the first connecting rod (42) or/and the second connecting rod (43) are/is of a multi-section structure, and the multiple sections are connected through a thread structure and used for adjusting the whole length.

7. The traverse box parallel sliding mechanism of the trumpet tube wire bonder according to any one of claims 2 to 6, wherein: the first connecting rod (42) or the second connecting rod (43) comprises an outer rod (421) and an inner rod (422) which are sleeved with each other, the inner side wall of a sleeve hole (423) for the inner rod (422) to be sleeved with penetrates outwards to form a mounting hole (424), the outer side wall of the inner rod (422) is provided with an annular groove (425), a ball (426) is arranged at the mounting hole (424), and the ball (426) is abutted to the inner rod (422) through an elastic abutting part (427); when the balls (426) are clamped into the annular groove (425), the inner rod (422) is axially locked, and when the axial external force applied to the outer rod (421) and the inner rod (422) is greater than the contact force of the elastic contact piece (427), the balls (426) are separated from the annular groove (425) to release the locking.

8. The traverse box parallel sliding mechanism of the horn wire bonder of claim 7, wherein: the elastic abutting piece (427) comprises a spring (428) for abutting against the ball (426) and a bolt (429) which is spirally arranged at the mounting hole (424) for abutting against the spring (428), wherein the abutting degree of the bolt (429) against the spring (428) corresponds to the abutting force of the spring (428) against the ball (426).

9. The traverse box parallel sliding mechanism of the trumpet tube wire bonder according to any one of claims 2 to 6, wherein: the driving motor (11) is provided with an adjusting frame (111), the adjusting frame (111) is provided with a plurality of adjusting holes (112) which are radially arranged along the rotating shaft of the driving motor (11), and when the first connecting rod (42) is arranged at different adjusting holes (112), the distance for driving the control box (10) to move by the driving motor (11) is correspondingly adjusted.

Images