CN114084750A - Double-station wire rewinding machine - Google Patents

Abstract

The invention relates to a double-station wire rewinding machine which comprises two wire rewinding groups of a rotary cylinder, wherein the rotary cylinder is arranged in the direction of the rotary cylinder, the rotary cylinder horizontally penetrates through a connecting axis and is intersected with a vertical axis of the rotary cylinder, the bottom of the rotary cylinder is in transmission connection with a driving group in a connecting transmission mode, and two wire rewinding groups in a steering mode are arranged at two ends of the rotary cylinder respectively. This duplex position admission machine adopts the duplex position, can realize unloading under the state of not shutting down, has practiced thrift the time of unloading, has further improved work efficiency, moreover, forms the tapering through the inner circular plate, can be convenient for the product and unload.

Description

Double-station wire rewinding machine

Technical Field

The invention relates to a double-station wire rewinding machine, and belongs to the field of packaging production lines.

Background

In order to prevent the steel wire rope from collapsing in the transportation process and improve the appearance quality of products, the products need to be subjected to Z2 falling (the Z2 products are steel wire rope discs with regular rectangular sections relative to common steel wire rope discs, and the Z2 products have the advantages of being neat and attractive, not prone to collapsing and the like in appearance and stacking transportation), wherein the take-up machine is one of devices in a Z2 falling production line and is mainly used for winding the products.

The existing double-station wire rewinding machine consumes a large amount of time when frequently discharging in the working process, and reduces the working efficiency, so that the double-station wire rewinding machine needs to be designed in order to reduce the labor intensity of workers and improve the production efficiency.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: in order to overcome the defects of the prior art, the double-station wire rewinding machine is provided.

The technical scheme adopted by the invention for solving the problems is as follows: the utility model provides a duplex position admission machine, includes gyration barrel and two receipts line subassemblies, the vertical setting of gyration barrel, the connecting axle is worn to be equipped with by the level on the gyration barrel, the axis of connecting axle intersects with the vertical axis of gyration barrel, the transmission is connected with drive assembly on the connecting axle, the bottom transmission of gyration barrel is connected with and turns to the motor, and two receipts line subassemblies set up the both ends at the connecting axle respectively.

Preferably, the two wire take-up assemblies are symmetrical about a vertical axis of the rotary cylinder.

As preferred, it includes sleeve pipe, clutch and fixed disk to receive the line subassembly, the coaxial movable sleeve of sleeve pipe is established on the connecting axle, the coaxial fixed cover of fixed disk is established on the sleeve pipe, the clutch includes pressure disk and flywheel, the flywheel is installed on the connecting axle, the flywheel is located sheathed tube one side that is close to the gyration barrel, the pressure disk is located between flywheel and the sleeve pipe, the pressure disk is installed in sheathed tube one end, be equipped with the clearance between pressure disk and the flywheel, the both ends of connecting axle all are provided with the blind hole coaxial with the connecting axle, be provided with spring and receipts line bearing in the blind hole, the one end of spring is through the interior wall connection who receives line bearing and blind hole, the other end and the bushing of spring, one side circumference of keeping away from the gyration barrel of fixed disk evenly is provided with a plurality of interior plectanes.

Preferably, the double-station take-up machine is further provided with an extrusion disc coaxial with the connecting shaft, the extrusion disc is located on one side, away from the rotary cylinder, of the inner circular plate, a first air cylinder coaxial with the connecting shaft is arranged on one side, away from the rotary cylinder, of the extrusion disc, and the extrusion disc is arranged at the telescopic end of the first air cylinder through a rotating bearing.

Preferably, the extrusion disc is provided with anti-skid lines.

Preferably, each connecting shaft is provided with two auxiliary assemblies, the auxiliary assemblies correspond to the fixed disc one to one, the auxiliary assemblies are located on one side, away from the rotary cylinder, of the fixed disc, the inner circular plate is hinged to the fixed disc, and the auxiliary assemblies are connected with the inner circular plate.

As preferred, the auxiliary assembly includes second slider and fourth cylinder, the second slider cover is established on the sleeve pipe, be provided with a plurality of connecting rods on the second slider, a plurality of connecting rods and a plurality of interior crown plate one-to-one, interior crown plate is articulated with the fixed disk, interior crown plate passes through the connecting rod and is articulated with the second slider, the cylinder body and the bushing of fourth cylinder, be provided with the connecting block between the cylinder body of connecting axle and fourth cylinder, be equipped with the clearance between connecting block and the connecting axle, the piston of fourth cylinder, the one end of keeping away from the line receiving bearing of second slider and spring all are connected with the connecting block.

Preferably, the connecting block abuts against a cylinder body of the fourth cylinder.

Preferably, the driving assembly comprises a wire winding driving wheel, a wire winding driven wheel and a wire winding driving belt, the wire winding driven wheel is mounted on the connecting shaft, the wire winding driving wheel is driven by a wire winding motor, and the wire winding driving wheel is connected with the wire winding driven wheel through the wire winding driving belt.

Preferably, the double-station wire rewinding machine comprises the following working steps: the direction close to the vertical axis of the rotary cylinder body is defined as the inner side, otherwise, the direction is defined as the outer side, the first air cylinder pushes the extrusion disc to move inwards, so that the extrusion disc is abutted against and extruded with the inner circular plate, a spool structure is formed, the first air cylinder continuously pushes the extrusion disc to move inwards, the inner circular plate drives the fixed disc to move inwards, the fixed disc drives the sleeve to move synchronously, the sleeve moves to drive the flywheel to move synchronously, when the flywheel is abutted against the pressure plate, the clutch is closed, meanwhile, the sleeve moves to deform the spring, the product is wound on the inner circular plate abutted against the extrusion disc around the axis of the connecting shaft, at the moment, the take-up motor drives the take-up driving wheel to rotate, the take-up driven wheel is driven by the take-up driving belt, and the rotation of the take-up driven wheel can drive the connecting shaft to rotate, the rotation of the connecting shaft drives the flywheel to synchronously rotate through the pressure plate, the rotation of the flywheel drives the sleeve to drive the fixed disc to rotate, the rotation of the fixed disc drives the inner circular plate to rotate and wind the product, the rotation of the connecting shaft cannot drive the fixed disc to rotate because the flywheel and the pressure plate are not closed, and the connecting shaft is prevented from driving the spring to synchronously rotate through the characteristic of the take-up bearing, so that one fixed disc drives the inner circular plate to rotate and wind the product and the inner circular plate on the other fixed disc is in a static state, when the product on the inner circular plate is fully wound, the connecting shaft stops rotating and drives the extrusion disc to move outwards through the first air cylinder, the extrusion disc is separated from the inner circular plate, and the sleeve drives the fixed disc to move outwards through the elastic action of the spring and separates the flywheel from the pressure plate, then, the rotation degree of the rotary cylinder is changed through the rotating assembly, so that the two fixed disks on the same connecting shaft can exchange positions, then, the fixed disks of the products which are not wound can continuously wind the products through the inner circular plate, at the moment, the fixed disks of the wound products in a static state are used for discharging and the products enter the next process, the discharging time is saved, the working efficiency is improved, in addition, when the double-station wire-rewinding machine discharges the materials, the gas is filled into the cylinder body of the fourth cylinder at the product saturation position, the piston of the fourth cylinder can drive the connecting block to move under the action of the gas pressure, the spring is deformed, the second sliding block is driven by the movement of the connecting block to synchronously move, the inner circular plate is driven by the connecting rod to rotate on the fixed disks towards the direction close to the connecting shaft, so that the inner circular plate on the fixed disks forms a taper, and the rolled products can be conveniently discharged, after unloading, the fourth cylinder body exhausts, at the moment, the piston reverse movement of the fourth cylinder is reset under the elastic action of the spring, the second sliding block is driven by the connecting block to move reversely to reset, and the reset of the second sliding block drives the inner circular plate to rotate reversely to reset through the connecting rod.

Compared with the prior art, the invention has the advantages that: the double-station wire-rewinding machine adopts double stations, can realize discharging in a non-stop state, saves discharging time, further improves working efficiency, and can facilitate product discharging by forming a taper through the inner circular plate;

drawings

FIG. 1 is a schematic structural view of a double-station wire rewinding machine according to the present invention;

fig. 2 is a schematic structural view of the wire take-up assembly.

Wherein: the double-station wire rewinding machine comprises a double-station wire rewinding machine 404, a rotary cylinder 404.1, a wire rewinding assembly 404.2, a sleeve 402.21, a clutch 402.22, a pressure plate 402.221, a flywheel 402.222, a fixed disc 402.23, a blind hole 402.24, a spring 402.25, a wire rewinding bearing 402.26, an inner circular plate 402.27, a connecting shaft 404.3, a driving assembly 404.4, a wire rewinding driving wheel 404.41, a wire rewinding driven wheel 404.42, a wire rewinding driving belt 404.43, a wire rewinding motor 404.44, a steering motor 404.5, a pressing disc 404.6, a first air cylinder 404.7, an auxiliary assembly 404.8, a second sliding block 404.81, a fourth air cylinder 404.82, a connecting rod 404.83, a connecting block 404.84, a rotary bearing 404.9 and a product 500.

Detailed Description

As shown in fig. 1-2, the double-station wire rewinding machine in this embodiment includes a rotary cylinder 404.1 and two wire rewinding assemblies 404.2, the rotary cylinder 404.1 is vertically arranged, a connecting shaft 404.3 is horizontally arranged on the rotary cylinder 404.1, an axis of the connecting shaft 404.3 intersects with a vertical axis of the rotary cylinder 404.1, a driving assembly 404.4 is connected to the connecting shaft 404.3 in a transmission manner, a steering motor 404.5 is connected to the bottom of the rotary cylinder 404.1 in a transmission manner, and the two wire rewinding assemblies 404.2 are respectively arranged at two ends of the connecting shaft 404.3.

The direction close to the vertical axis of the rotary cylinder 404.1 is defined as the inner side, otherwise, the direction is defined as the outer side, the first cylinder 404.7 pushes the extrusion disc 404.6 to move inwards, so that the extrusion disc 404.6 is abutted against and extruded by the inner circular plate 402.27, thereby forming a spool structure, as the first cylinder 404.7 continues to push the extrusion disc 404.6 to move inwards, the fixed disc 402.23 is driven to move inwards by the inner circular plate 402.27, the fixed disc 402.23 moves to drive the sleeve 404.21 to move synchronously, the sleeve 404.21 moves to drive the flywheel 402.222 to move synchronously, when the flywheel 402.222 is abutted against the pressure plate 402.221, the clutch 402.22 is closed, meanwhile, the movement of the sleeve 404.21 deforms the spring 402.25, and the product 500 is wound on the inner circular plate 402.27 abutted against the extrusion disc 404.6 around the axis of the connecting shaft 404.3, at this time, the take-up driving wheel 404.41 is driven to rotate by the take-up motor 404.44, and the take-up driving wheel 404.42 is driven by the take-up driving belt 404.43, the rotation of the wire-rewinding driven wheel 404.42 can drive the connecting shaft 404.3 to rotate, the rotation of the connecting shaft 404.3 drives the flywheel 402.222 to rotate synchronously through the pressure plate 402.221, the rotation of the flywheel 402.222 drives the sleeve 404.21 to drive the fixed disk 402.23 to rotate, the rotation of the fixed disk 402.23 drives the inner circular plate 402.27 to rotate and wind the product 500, the other fixed disk 402.23 on the connecting shaft 404.3 cannot drive the fixed disk 402.23 to rotate because the flywheel 402.222 and the pressure plate 402.221 are not closed, and the connecting shaft 404.3 is prevented from driving the spring 402.25 to rotate synchronously through the characteristics of the wire-rewinding bearing 402.26, so that in the two fixed disks 402.23 on the same connecting shaft 404.3, one fixed disk 402.23 drives the inner circular plate 402.27 to rotate and wind the product 500, the other fixed disk 402.27 on the fixed disk 402.23 is in a stationary state, when the product 500 on the inner circular plate 402.27 winds to be saturated, the connecting shaft 404.3 stops rotating, and drives the extruding disk 404.6 to move outwards through the first air cylinder 404.7, the extrusion disc 404.6 is separated from the inner circular plate 402.27, the sleeve tube 404.21 drives the fixed disc 402.23 to move outwards under the elastic action of the spring 402.25, the flywheel 402.222 is separated from the pressure plate 402.221, then the rotary cylinder 404.1 is rotated 180 degrees through the rotating assembly 404.5, so that the two fixed discs 402.23 on the same connecting shaft 404.3 can exchange positions, then the fixed disc 402.23 which does not wind the product 500 is enabled to continue to wind the product 500 through the inner circular plate 402.27, the fixed disc 402.23 which is in a static state and is in a saturated state and winds the product 500 is unloaded and enters the next procedure, the unloading time is saved, the working efficiency is improved, and when the double-station wire-rewinding machine 404 unloads, air is filled into the cylinder body of the fourth air cylinder 404.82 in the saturated position of the product 500, so that the piston of the fourth air cylinder 404.82 can drive the connecting block 404.84 to move under the action of air pressure and deform the spring 402.25, the removal of connecting block 404.84 drives second slider 404.81 synchronous motion, the removal of second slider 404.81 then drives interior crown plate 402.27 and rotates towards being close to connecting axle 404.3 direction on fixed disk 402.23 through connecting rod 404.83, thereby make interior crown plate 402.27 on the fixed disk 402.23 form the tapering, so that the product 500 that the rolling was accomplished unloads, the back of unloading is accomplished, fourth cylinder 404.82 cylinder body is carminative, this moment, make the piston reverse movement realization of fourth cylinder 404.82 reset through the elastic action of spring 402.25, and drive second slider 404.81 reverse movement realization through connecting block 404.84 and reset, the reset of second slider 404.81 drives interior crown plate 402.27 reverse rotation realization through connecting rod 404.83 and resets.

Preferably, the two wire takeup assemblies 404.2 are symmetrical about the vertical axis of the rotary cylinder 404.1.

Preferably, the wire rewinding assembly 404.2 includes a sleeve 404.21, a clutch 402.22 and a fixed disk 402.23, the sleeve 404.21 is coaxially and movably sleeved on the connecting shaft 404.3, the fixed disk 402.23 is coaxially and fixedly sleeved on the sleeve 404.21, the clutch 402.22 includes a pressure plate 402.221 and a flywheel 402.222, the flywheel 402.222 is installed on the connecting shaft 404.3, the flywheel 402.222 is located at one side of the sleeve 404.21 close to the rotary cylinder 404.1, the pressure plate 402.221 is located between the flywheel 402.222 and the sleeve 404.21, the pressure plate 402.221 is installed at one end of the sleeve 404.21, a gap is provided between the pressure plate 402.221 and the flywheel 402.222, blind holes 402.24 coaxial with the connecting shaft 404.3 are respectively arranged at two ends of the connecting shaft 404.3, springs 402.25 and wire rewinding bearings 402.26 are arranged in the blind holes 402.24, one end of the springs 402.25 is connected with the inner walls of the blind holes 402.24 through the wire rewinding bearings 402.26, the other end of the springs 402.25 is connected with the sleeve 404.21, one side of the fixed disc 402.23, which is far away from the rotary cylinder 404.1, is circumferentially and uniformly provided with a plurality of inner circular plates 402.27.

Preferably, the double-station wire rewinding machine 404 is further provided with a squeezing disc 404.6 coaxial with the connecting shaft 404.3, the squeezing disc 404.6 is located on one side, away from the rotary cylinder 404.1, of the inner circular plate 402.27, a first cylinder 404.7 coaxial with the connecting shaft 404.3 is arranged on one side, away from the rotary cylinder 404.1, of the squeezing disc 404.6, and the squeezing disc 404.6 is arranged at the telescopic end of the first cylinder 404.7 through a rotating bearing 404.9.

Preferably, the pressing plate 404.6 is provided with anti-slip threads.

Preferably, each connecting shaft 404.3 is provided with two auxiliary assemblies 404.8, each auxiliary assembly 404.8 corresponds to a fixed disk 402.23 one by one, each auxiliary assembly 404.8 is located on one side of the fixed disk 402.23 far away from the rotary cylinder 404.1, the inner circular plate 402.27 is hinged to the fixed disk 402.23, and each auxiliary assembly 404.8 is connected with the inner circular plate 402.27.

Preferably, the auxiliary assembly 404.8 includes a second slider 404.81 and a fourth cylinder 404.82, the second slider 404.81 is sleeved on the sleeve 404.21, the second slider 404.81 is provided with a plurality of connecting rods 404.83, the plurality of connecting rods 404.83 correspond to the plurality of inner circular plates 402.27 one to one, the inner circular plate 402.27 is hinged to the fixed plate 402.23, the inner circular plate 402.27 is hinged to the second slider 404.81 through the connecting rod 404.83, a cylinder body of the fourth cylinder 404.82 is connected to the sleeve 404.21, a connecting block 404.84 is provided between the connecting shaft 404.3 and a cylinder body of the fourth cylinder 404.82, a gap is provided between the connecting block 404.84 and the connecting shaft 404.3, and one ends of the piston of the fourth cylinder 404.82, the second slider 404.81 and the spring 402.25, which are far away from the wire-rewinding bearing 402.26, are all connected to the connecting block 404.84.

Preferably, the connecting block 404.84 abuts against the cylinder body of the fourth cylinder 404.82.

Preferably, the driving assembly 404.4 includes a take-up driving wheel 404.41, a take-up driven wheel 404.42 and a take-up transmission belt 404.43, the take-up driven wheel 404.42 is mounted on the connecting shaft 404.3, the take-up driving wheel 404.41 is driven by a take-up motor 404.44, and the take-up driving wheel 404.41 is connected with the take-up driven wheel 404.42 through a take-up transmission belt 404.43.

Preferably, the double-station wire rewinding machine comprises the following working steps: the direction close to the vertical axis of the rotary cylinder 404.1 is defined as the inner side, otherwise, the direction is defined as the outer side, the first air cylinder 404.7 pushes the extrusion disc 404.6 to move inwards, so that the extrusion disc 404.6 is abutted against and extruded by the inner circular plate 402.27, thereby forming a spool structure, as the first air cylinder 404.7 continues to push the extrusion disc 404.6 to move inwards, the fixed disc 402.23 is driven to move inwards by the inner circular plate 402.27, the sleeve 404.21 is driven to move synchronously by the movement of the fixed disc 402.23, the flywheel 402.222 is driven to move synchronously by the movement of the sleeve 404.21, when the flywheel 402.222 is abutted against the pressure plate 402.221, the clutch 402.22 is closed, meanwhile, the spring 402.25 is deformed by the movement of the sleeve 404.21, the product 500 is wound around the inner circular plate 402.27 abutted against the extrusion disc 404.6 around the axis of the connecting shaft 404.3, at this time, the wire-winding motor 404.44 drives the wire-winding 404.41 to rotate, and the driven wheel 404.42 is driven by the wire-winding belt 404.43, the rotation of the take-up driven wheel 404.42 can drive the connecting shaft 404.3 to rotate, the rotation of the connecting shaft 404.3 drives the flywheel 402.222 to rotate synchronously through the pressure plate 402.221, the rotation of the flywheel 402.222 drives the sleeve 404.21 to drive the fixed disk 402.23 to rotate, the rotation of the fixed disk 402.23 drives the inner circular plate 402.27 to rotate and wind the product 500, the other fixed disk 402.23 on the connecting shaft 404.3 cannot drive the fixed disk 402.23 to rotate because the flywheel 402.222 and the pressure plate 402.221 are not closed, and the connecting shaft 404.3 is prevented from driving the spring 402.25 to rotate synchronously through the characteristics of the take-up bearing 402.26, so that in the two fixed disks 402.23 on the same connecting shaft 404.3, one fixed disk 402.23 drives the inner circular plate 402.27 to rotate and wind the product 500, the inner circular plate 402.27 on the other fixed disk 402.23 is in a static stop state, when the product 500 on the inner circular plate 402.27 is wound in a saturated state, the connecting shaft 404.3 stops rotating, and drives the extrusion disk 404.6 to move outwards through the first air cylinder 404.7, the extrusion disc 404.6 is separated from the inner circular plate 402.27, the sleeve tube 404.21 drives the fixed disc 402.23 to move outwards under the elastic action of the spring 402.25, the flywheel 402.222 is separated from the pressure disc 402.221, then the rotary cylinder 404.1 is rotated 180 degrees through the rotating assembly 404.5, so that the positions of the two fixed discs 402.23 on the same connecting shaft 404.3 can be exchanged, then the fixed disc 402.23 which does not wind the product 500 is continuously wound on the product 500 through the inner circular plate 402.27, the fixed disc 402.23 which is in a static state and is saturated with the wound product 500 realizes unloading and enables the product 500 to enter the next process, the unloading time is saved, the working efficiency is improved, and when the double-station wire-rewinding machine 404 unloads, the piston of the fourth cylinder 404.82 at the saturation position of the product 500 is inflated, the piston of the fourth cylinder 404.82 can drive the connecting block 404.84 to move under the action of air pressure, and the spring 402.25 is deformed, the removal of connecting block 404.84 drives second slider 404.81 synchronous motion, the removal of second slider 404.81 then drives interior plectane 402.27 through connecting rod 404.83 and rotates towards being close to connecting axle 404.3 direction on fixed disk 402.23, thereby make interior plectane 402.27 on the fixed disk 402.23 form the tapering, so that the product 500 that the rolling was accomplished unloads, the back of unloading is accomplished, fourth cylinder 404.82 cylinder body exhaust, at this moment, make the piston reverse movement of fourth cylinder 404.82 realize reseing through the spring action of spring 402.25, and drive second slider 404.81 reverse movement through connecting block 404.84 and realize reseing, the reseing of second slider 404.81 drives interior plectane 402.27 reverse rotation through connecting rod 404.83 and realizes reseing.

In addition to the above embodiments, the present invention also includes other embodiments, and any technical solutions formed by equivalent transformation or equivalent replacement modes should fall within the protection scope of the claims of the present invention.

Claims (10)

1. The utility model provides a duplex position admission machine which characterized in that: including gyration barrel (404.1) and two receipts line subassemblies (404.2), the vertical setting of gyration barrel (404.1), connecting axle (404.3) are worn to be equipped with by the level in gyration barrel (404.1), the axis of connecting axle (404.3) intersects with the vertical axis of gyration barrel (404.1), the transmission is connected with drive assembly (404.4) on connecting axle (404.3), the bottom transmission of gyration barrel (404.1) is connected with steering motor (404.5), and two receipts line subassemblies (404.2) set up the both ends at connecting axle (404.3) respectively.

2. The double-station wire rewinding machine according to claim 1, characterized in that: the two wire take-up assemblies (404.2) are symmetrical about a vertical axis of the rotary cylinder (404.1).

3. The double-station wire rewinding machine according to claim 1, characterized in that: the wire take-up component (404.2) comprises a sleeve (404.21), a clutch (402.22) and a fixed disc (402.23), the sleeve (404.21) is coaxially sleeved on the connecting shaft (404.3) in a movable manner, the fixed disc (402.23) is coaxially sleeved on the sleeve (404.21) in a fixed manner, the clutch (402.22) comprises a pressure plate (402.221) and a flywheel (402.222), the flywheel (402.222) is installed on the connecting shaft (404.3), the flywheel (402.222) is located on one side, close to the rotary cylinder (404.1), of the sleeve (404.21), the pressure plate (402.221) is located between the flywheel (402.222) and the sleeve (404.21), the pressure plate (402.221) is installed at one end of the sleeve (404.21), a gap is arranged between the pressure plate (402.221) and the flywheel (402.222), blind holes (402.24) coaxial with the connecting shaft (404.3) are formed at two ends of the connecting shaft (404.3), and a spring (402.25) and a wire take-up bearing (402.26) are arranged in the blind holes (402.24), one end of the spring (402.25) is connected with the inner wall of the blind hole (402.24) through a take-up bearing (402.26), the other end of the spring (402.25) is connected with the sleeve (404.21), and a plurality of inner circular plates (402.27) are uniformly arranged on one side of the fixed disc (402.23) which is far away from the rotary cylinder (404.1) in the circumferential direction.

4. The double-station wire rewinding machine according to claim 3, characterized in that: the double-station wire rewinding machine (404) is further provided with an extrusion disc (404.6) coaxial with the connecting shaft (404.3), the extrusion disc (404.6) is located on one side, away from the rotary cylinder (404.1), of the inner circular plate (402.27), a first air cylinder (404.7) coaxial with the connecting shaft (404.3) is arranged on one side, away from the rotary cylinder (404.1), of the extrusion disc (404.6), and the extrusion disc (404.6) is arranged at the telescopic end of the first air cylinder (404.7) through a rotating bearing (404.9).

5. The double-station wire rewinding machine according to claim 4, characterized in that: the extrusion disc (404.6) is provided with anti-skid lines.

6. The double-station wire rewinding machine according to claim 3, characterized in that: all be provided with two auxiliary assembly (404.8) on each connecting axle (404.3), auxiliary assembly (404.8) and fixed disk (402.23) one-to-one, auxiliary assembly (404.8) are located the one side of keeping away from gyration barrel (404.1) of fixed disk (402.23), interior plectane (402.27) is articulated with fixed disk (402.23), auxiliary assembly (404.8) are connected with interior plectane (402.27).

7. The double-station wire rewinding machine according to claim 6, characterized in that: the auxiliary assembly (404.8) includes a second slider (404.81) and a fourth cylinder (404.82), the second sliding block (404.81) is sleeved on the sleeve (404.21), the second sliding block (404.81) is provided with a plurality of connecting rods (404.83), the plurality of connecting rods (404.83) correspond to the plurality of inner circular plates (402.27) one by one, the inner circular plate (402.27) is hinged with the fixed disc (402.23), the inner circular plate (402.27) is hinged with the second sliding block (404.81) through a connecting rod (404.83), the cylinder body of the fourth cylinder (404.82) is connected with a sleeve (404.21), a connecting block (404.84) is arranged between the connecting shaft (404.3) and the cylinder body of the fourth cylinder (404.82), a gap is formed between the connecting block (404.84) and the connecting shaft (404.3), and one ends, far away from the wire collecting bearing (402.26), of the piston of the fourth cylinder (404.82), the second sliding block (404.81) and the spring (402.25) are connected with the connecting block (404.84).

8. The double-station wire rewinding machine according to claim 1, characterized in that: the connecting block (404.84) abuts against the cylinder body of the fourth cylinder (404.82).

9. The double-station wire rewinding machine according to claim 1, characterized in that: drive assembly (404.4) are including receiving line drive wheel (404.41), receiving line from driving wheel (404.42) and receiving line drive belt (404.43), receive line from driving wheel (404.42) and install on connecting axle (404.3), receive line drive wheel (404.41) through receiving line motor (404.44) drive, receive line drive wheel (404.41) through receiving line drive belt (404.43) with receive line from driving wheel (404.42) and be connected.

10. The double-station take-up machine according to any one of claims 1 to 9, wherein: the double-station wire rewinding machine comprises the following working steps: defining the direction close to the vertical axis of the rotary cylinder body (404.1) as the inner side, otherwise, defining the direction close to the vertical axis as the outer side, pushing the extrusion disc (404.6) to move inwards through the first air cylinder (404.7), so that the extrusion disc (404.6) is abutted against and extruded by the inner circular plate (402.27), thereby forming an I-shaped wheel structure, driving the extrusion disc (404.6) to move inwards through the inner circular plate (402.27) as the first air cylinder (404.7) continues to push the extrusion disc (404.6), driving the fixed disc (402.23) to move inwards through the inner circular plate (402.27), driving the sleeve (404.21) to move synchronously through the movement of the fixed disc (402.23), driving the flywheel (402.222) to move synchronously through the movement of the sleeve (404.21), realizing the closing of the clutch (402.22) when the flywheel (402.222) is abutted against the pressure plate (402.221), simultaneously, enabling the spring (402.25) to deform through the movement of the sleeve (404.21), and winding the product (500) on the inner circular plate (402.27) abutted against the extrusion disc (402.27) around the axis of the connecting shaft (404.3), at the moment, a wire take-up driving wheel (404.41) is driven to rotate by a wire take-up motor (404.44), a wire take-up driven wheel (404.42) is driven by a wire take-up transmission belt (404.43), the rotation of the wire take-up driven wheel (404.42) can drive a connecting shaft (404.3) to rotate, the rotation of the connecting shaft (404.3) drives a flywheel (402.222) to synchronously rotate through a pressure plate (402.221), the rotation of the flywheel (402.222) enables a sleeve (404.21) to drive a fixing disc (402.23) to rotate, the rotation of the fixing disc (402.23) drives an inner circular plate (402.27) to rotate and wind a product (500), the fixing disc (402.23) on the other connecting shaft (404.3) cannot drive the fixing disc (402.23) to rotate because the flywheel (402.222) and the pressure plate (402.221) are not closed, and the connecting shaft (404.3) is prevented from driving a spring (402.25) to synchronously rotate through the characteristics of a wire take-up bearing (402.26), so that two fixing discs (402.23) on the same connecting shaft (404.3) are realized, one fixed disk (402.23) drives an inner circular plate (402.27) to rotate and wind a product (500), the inner circular plate (402.27) on the other fixed disk (402.23) is in a static state, when the product (500) on the inner circular plate (402.27) is wound to saturation, a connecting shaft (404.3) stops rotating, a squeezing disk (404.6) is driven by a first air cylinder (404.7) to move outwards, the squeezing disk (404.6) is separated from the inner circular plate (402.27), a sleeve (404.21) drives a fixed disk (402.23) to move outwards through the elastic action of a spring (402.25), a flywheel (402.222) is separated from a pressure plate (402.221), then a rotary cylinder (404.1) is rotated (180 degrees) through a rotating assembly (404.5), so that two fixed disks (402.23) on the same fixed disk (404.3) can exchange positions, and then the fixed disk (402.23) on which the product (500) is not wound continues to wind the product (500) through the inner circular plate (402.27), and the fixed disk (402.23) which is in a static state and is saturated with the wound product (500) realizes unloading and enables the product (500) to enter the next process, thereby saving the unloading time and improving the working efficiency, moreover, when the double-station wire-rewinding machine (404) unloads, the cylinder body of the fourth cylinder (404.82) at the saturation position of the product (500) is inflated, the piston of the fourth cylinder (404.82) can drive the connecting block (404.84) to move under the action of air pressure, and the spring (402.25) is deformed, the movement of the connecting block (404.84) drives the second slider (404.81) to move synchronously, the movement of the second slider (404.81) drives the inner circular plate (402.27) to rotate on the fixed disk (402.23) towards the direction close to the connecting shaft (404.3) through the connecting rod (404.83), so that the inner circular plate (402.27) on the fixed disk (402.23) forms a taper, thereby facilitating the unloading of the product (500) which is completely coiled, after the unloading is completed, the cylinder body of the fourth cylinder (404.82) exhausts, at the moment, the piston of the fourth cylinder (404.82) moves reversely to realize resetting under the elastic action of the spring (402.25), the connecting block (404.84) drives the second sliding block (404.81) to move reversely to realize resetting, and the resetting of the second sliding block (404.81) drives the inner circular plate (402.27) to rotate reversely to realize resetting through the connecting rod (404.83).

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