CN211283083U - Surface tension winding station - Google Patents

Abstract

The utility model provides a surface tension rolling station, which comprises a rolling frame, a rolling roller driven by a first driving mechanism is rotatably arranged on the rolling frame, a pressurizing shaft and a blanking shaft parallel to the rolling roller are rotatably arranged in the rolling frame, the blanking shaft is driven by a second driving mechanism to rotate, a blanking arm is respectively arranged at two ends of the blanking shaft, a blanking part is arranged on each blanking arm, a pressurizing arm driven by a pressurizing cylinder to rotate is respectively arranged at two ends of the pressurizing shaft, a bearing part used for bearing the air expansion shaft and pushing the air expansion shaft into the blanking part is arranged on each pressurizing arm, a guide roller group used for guiding printing paper to advance is also arranged in the rolling frame, the utility model discloses an automatic rolling and automatic blanking of a printing machine, greatly improving the simplicity of rolling operation of the rolling station, improving the working efficiency of the printing machine and saving labor force, the rolling stability of the printing paper is improved.

Description

Surface tension winding station

Technical Field

The utility model belongs to the technical field of the printing machine technique and specifically relates to a surface tension rolling station is related to.

Background

The printing machine mainly comprises an uncoiling feeding part, a printing part, a drying part and a rewinding receiving part, wherein the coiling station is positioned in the rewinding receiving part of the printing machine and winds the printing paper into a coil material in a mechanical mode. The winding station is an indispensable part of a unit type printing machine and is widely applied to processing production lines of paper rolls, cloth, plastic rolls and the like.

The existing winding station mainly has the following problems: after the rolling was accomplished to physiosis axle in the rolling station, the staff needed the manual work to dismantle the physiosis axle that the rolling is good, changed new physiosis axle again, unusual trouble, need shut down at the in-process printing machine of changing the physiosis axle moreover, had seriously influenced the work efficiency of whole printing machine.

Therefore, a surface tension take-up station is needed that can solve the above problems.

SUMMERY OF THE UTILITY MODEL

The utility model provides a surface tension rolling station has realized the automatic rolling and the automatic unloading of printing machine, has greatly improved the simplicity and convenience of rolling station rolling operation, has improved the work efficiency of printing machine, has saved the labour, has improved the stationarity of printing paper rolling.

The technical scheme of the utility model is realized like this:

surface tension rolling station, including the rolling frame, the rolling frame is gone up to rotate and is installed by first actuating mechanism driven wind-up roll, rolling frame internal rotation install be on a parallel with the pressurization axle and the unloading axle of wind-up roll, the unloading axle is rotated by the drive of second actuating mechanism, a unloading arm is installed respectively at the both ends of unloading axle, each all be equipped with unloading portion on the unloading arm, a pressurization arm by pressurization cylinder drive pivoted, each is installed respectively at the both ends of pressurization axle all be equipped with on the pressurization arm and be used for bearing physiosis axle and push it into bearing portion in the unloading portion, still be provided with a guide roller set that is used for guiding printing paper to advance in the rolling frame.

As a preferred technical scheme, the pressure shaft and the blanking shaft are both arranged below the winding roller, and the distance between the pressure shaft and the winding roller is smaller than the distance between the blanking shaft and the winding roller.

As a preferable technical scheme, one end of each pressurizing arm is fixedly mounted on the pressurizing shaft, the other end of each pressurizing arm is provided with one supporting part, each supporting part comprises a pressing block used for pressing the air expanding shaft and the winding roller together, each supporting part further comprises a pushing block used for pushing the air expanding shaft into the blanking part, a supporting groove is formed between each pressing block and the corresponding pushing block, and the length of each pressing block is greater than that of the pushing block.

As a preferred technical scheme, each blanking arm is arranged at the outer side corresponding to the pressure arm, one end of each blanking arm is fixedly arranged on the blanking shaft, the other end of each blanking arm is provided with one blanking part, each blanking part is provided with a stop block, and the end part of the other end of each blanking arm is provided with an inclined surface inclined towards the stop block.

As a preferable technical solution, the guide roller group includes a first guide roller, a second guide roller and a third guide roller which are sequentially arranged along an advancing direction of the printing paper, the first guide roller, the second guide roller and the third guide roller are all rotatably mounted in the winding frame, and the first guide roller, the second guide roller and the third guide roller are all parallel to the winding roller.

As a preferred technical scheme, a floating mechanism is further arranged on the winding rack.

As an optimal technical scheme, the relocation mechanism including rotate install in just be on a parallel with in the rolling frame the swing arm axle of wind-up roll, the both ends of swing arm axle fixed mounting respectively has a pendulum rod, two the pendulum rod is kept away from the one end of swing arm axle is rotated jointly and is installed a straining roller, each the lower extreme of pendulum rod all with a tensioning cylinder's piston rod articulated together, each tensioning cylinder's cylinder body all rotate install in the rolling frame, the encoder gear that detects printing paper power size is still installed to the one end of swing arm axle.

As a preferred technical scheme, first actuating mechanism is including being fixed in the inverter motor on the motor cabinet, the motor cabinet is fixed in one side of rolling frame, be fixed with a mount pad on the lateral wall of rolling frame, rotate on the mount pad install by inverter motor drive pivoted transmission shaft, install the driving synchronization pulley through first tight cover that expands on the transmission shaft, the one end of wind-up roll be equipped with the installation axle of the coaxial setting of wind-up roll, install epaxial through high accuracy bearing rotation install in on the rolling frame, the installation axle stretches out the outside of rolling frame, the installation axle stretches out the one end of rolling frame is installed from the synchronous pulley through the tight cover that expands of second, from the synchronous pulley with it is equipped with a synchronous belt to wind jointly on the driving synchronization pulley.

As a preferred technical scheme, the second driving mechanism comprises two connecting rods which are respectively arranged on two sides of the winding frame, one end of each connecting rod is fixedly arranged on the discharging shaft, the other end of each connecting rod is hinged to a piston rod of a discharging oil cylinder, and a cylinder body of each discharging oil cylinder is rotatably arranged on the outer side wall of the winding frame.

As a preferred technical scheme, the top of two side walls of the winding rack is respectively provided with a sliding rail, and two ends of the inflatable shaft are respectively and slidably mounted on the corresponding sliding rails.

By adopting the technical scheme, the beneficial effects of the utility model are that:

because the surface tension rolling station comprises a rolling frame and a rolling roller, in the utility model, the whole frame of the rolling station adopts a frame structure, the rolling roller is independently driven by a first driving mechanism, the rolling action of the printing paper in the whole rolling station is completed through the rotation of the rolling roller, and the first step of rolling the printing paper is realized; meanwhile, the winding roller is rotatably arranged on the winding rack by adopting a high-precision bearing, so that the winding roller can bear high-speed rotation, the rotating stability of the winding roller in the winding process is improved, and the winding stability of the printing paper is improved.

Because the wind-up roll is rotated by a actuating mechanism drive, using the utility model discloses the time, inverter motor starts, and the motor shaft rotates and drives transmission shaft and the epaxial initiative synchronous pulley of transmission and rotate, and initiative synchronous pulley drives hold-in range and driven synchronous pulley and rotates, makes inverter motor's power transmission drive the wind-up roll and rotate on the wind-up roll, and inverter motor can control the slew velocity of wind-up roll through the converter simultaneously, realizes the rolling to the different speed of printing paper.

Because the pressurizing shaft and the blanking shaft are rotatably arranged in the rolling frame, two ends of the pressurizing shaft are respectively and fixedly provided with the pressurizing arm, two ends of the blanking shaft are respectively and fixedly provided with the blanking arm, when the utility model is used, a piston rod of the pressurizing cylinder is recycled to drive the pressurizing arm to rotate by taking the pressurizing shaft as a fulcrum, a pressing block in a bearing part of the pressurizing arm presses the air expanding shaft onto the rolling roller, the rolling roller rotates to drive the air expanding shaft to rotate, so that the rolling action of printing paper is realized, the diameter of a paper roll is continuously increased in the rolling process, a piston rod of the pressurizing cylinder pops out at a uniform speed to drive the pressurizing arm to rotate towards the direction of the blanking arm by taking the pressurizing shaft as the fulcrum, the pressurizing arm drives the air expanding shaft and the paper roll to move towards the direction of the blanking arm, when the air expanding shaft moves to the limit position of the blanking arm, the height position of the pressing block is lower than the blanking part on the blanking arm, the pressurizing arm continuously rotates to enable a pushing, and a piston rod of the blanking oil cylinder extends out to drive the blanking arm to rotate by taking the blanking shaft as a fulcrum, so as to drive the paper roll to fall down and finish the blanking action.

In-process at whole rolling and unloading, the staff only need with the physiosis axle place in the rolling frame can, the rolling station can accomplish the rolling of printing paper and the unloading action of scroll automatically, can accomplish the change of physiosis axle and the unloading of scroll under the circumstances of not shutting down, the simplicity of rolling station rolling operation and the work efficiency of printing machine have greatly been improved, need not many staff simultaneously and go to remove heavy scroll from the rolling frame, just can accomplish the operation at rolling station alone, the labour has been saved, staff's intensity of labour has also been reduced.

Because still be provided with the relocation mechanism in the rolling frame, when using the utility model discloses the time, the tensioning roller setting of relocation mechanism is between first guide roller and second guide roller, the printing paper that the printing was accomplished is walked around first guide roller in proper order, the tensioning roller, the guide of second guide roller and third guide roller, rotation through the wind-up roll is epaxial with its rolling physiosis, the swing of tensioning cylinder among the relocation mechanism drives the encoder gear and rotates the tensile size of detection printing paper, realize the tensile accurate control of printing paper, the stationarity of printing paper rolling has been improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without inventive exercise.

Fig. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of the installation of the pressurizing arm and the discharging arm of the present invention;

fig. 3 is a schematic structural view of the floating mechanism of the present invention;

FIG. 4 is a cross-sectional view taken along line A-A of FIG. 3;

fig. 5 is a schematic structural diagram of the first driving mechanism of the present invention.

Wherein: 1. a rolling frame; 2. a wind-up roll; 3. a pressurizing shaft; 4. a blanking shaft; 5. a blanking arm; 6. a blanking part; 7. a pressurizing cylinder; 8. a pressurizing arm; 9. an inflatable shaft; 10. a bearing part; 11. printing paper; 12. briquetting; 13. a push block; 14. a bearing groove; 15. a stopper; 16. an inclined surface; 17. a first guide roller; 18. a second guide roller; 19. a third guide roller; 20. a swing arm shaft; 21. a swing rod; 22. a tension roller; 23. a tensioning cylinder; 24. an encoder gear; 25. a motor base; 26. a variable frequency motor; 27. a mounting seat; 28. a drive shaft; 29. a first expansion sleeve; 30. a driving synchronous pulley; 31. installing a shaft; 32. a high-precision bearing; 33. a second expansion sleeve; 34. a driven synchronous pulley; 35. a synchronous belt; 36. a connecting rod; 37. a blanking oil cylinder; 38. a sliding rail.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

As shown in fig. 1 and fig. 2, the surface tension winding station includes a winding frame 1, a winding roller 2 driven by a first driving mechanism is rotatably mounted on the winding frame 1, a pressure shaft 3 and a blanking shaft 4 parallel to the winding roller 2 are rotatably mounted in the winding frame 1, the blanking shaft 4 is driven by a second driving mechanism to rotate, a blanking arm 5 is respectively mounted at two ends of the blanking shaft 4, a blanking portion 6 is disposed on each blanking arm 5, a pressure arm 8 driven to rotate by a pressure cylinder 7 is respectively mounted at two ends of the pressure shaft 3, a support portion 10 for supporting an air expansion shaft 9 and pushing the air expansion shaft into the blanking portion 6 is disposed on each pressure arm 8, and a guide roller set for guiding a printing paper 11 to advance is further disposed in the winding frame 1.

The pressurizing shaft 3 and the discharging shaft 4 are both arranged below the winding roller 2, and the distance between the pressurizing shaft 3 and the winding roller 2 is smaller than the distance between the discharging shaft 4 and the winding roller 2.

Wherein, the equal fixed mounting of one end of each loading arm 8 is on the pressure shaft 3, the other end of each loading arm 8 all is provided with a supporting portion 10, each supporting portion 10 all includes a briquetting 12 that is used for pressing physiosis axle 9 and wind-up roll 2 together, each supporting portion 10 still includes a ejector pad 13 that is used for pushing physiosis axle 9 into unloading portion 6, all form a supporting groove 14 between each briquetting 12 and the corresponding ejector pad 13, the length of each briquetting 12 all is greater than the length of ejector pad 13.

Every unloading arm 5 all sets up in the outside that corresponds the loading arm 8, and the equal fixed mounting in unloading epaxial 4 of one end of every unloading arm 5, the other end of every unloading arm 5 all is equipped with a unloading portion 6, and every unloading portion 6 all is equipped with a dog 15, and the tip of the other end of every unloading arm 5 all is equipped with an inclined plane 16 towards dog 15 slope.

Use the utility model discloses when rolling printing paper 11, the loading arm 8 rotates the in-process, briquetting 12 and ejector pad 13 on the bearing portion 10 can be spacing with physiosis axle 9 in bearing groove 14 of bearing portion 10, guarantee that physiosis axle 9 can be along with loading arm 8 at the uniform velocity outside removal always, ejector pad 13 of bearing portion 10 can push into unloading portion 6 at physiosis axle 9 when the unloading in, and be equipped with an inclined plane 16 in the unloading portion 6, physiosis axle 9 can roll the bottommost of unloading portion 6 along the inclination of inclined plane 16, dog 15 on unloading in-process unloading portion 6 rolls from unloading arm 5 to blockking physiosis axle 9 and falls.

Moreover, the guide roller group comprises a first guide roller 17, a second guide roller 18 and a third guide roller 19 which are arranged in sequence along the advancing direction of the printing paper 11, the first guide roller 17, the second guide roller 18 and the third guide roller 19 are all rotatably installed in the winding frame 1, and the first guide roller 17, the second guide roller 18 and the third guide roller 19 are all parallel to the winding roller 2.

As shown in fig. 3 and 4, the winding frame 1 is further provided with a floating mechanism.

The floating mechanism comprises a swing arm shaft 20 which is rotatably installed in the winding rack 1 and is parallel to the winding roller 2, two ends of the swing arm shaft 20 are respectively and fixedly provided with a swing rod 21, one ends of the two swing rods 21, which are far away from the swing arm shaft 20, are jointly rotatably installed with a tensioning roller 22, the lower end of each swing rod 21 is hinged with a piston rod of a tensioning cylinder 23, the cylinder body of each tensioning cylinder 23 is rotatably installed on the winding rack 1, one end of the swing arm shaft 20 is also provided with an encoder gear 24 for detecting the tension of the printing paper 11, in the embodiment, the tensioning cylinders 23 are low-friction cylinders, the starting pressure of the low-friction cylinders is very small, and the low-friction cylinders can sensitively respond under the condition of slight pressure change.

Therefore, in the winding process, when the rotating speed of the winding roller 2 is greater than the unwinding speed of the printing paper 11 in the last process of the winding station, the tension on the printing paper 11 can be increased, the piston rod of the tensioning cylinder 23 is recovered to drive the swing rod 21 to rotate by taking the swing arm shaft 20 as a fulcrum, the tensioning roller 22 is driven to be close to the first guide roller 17 and the second guide roller 18 to reduce the tension on the printing paper 11, similarly, when the rotating speed of the winding roller 2 is less than the unwinding speed of the printing paper 11 in the last process of the winding station, the tension on the printing paper 11 can be reduced, the piston rod of the tensioning cylinder 23 is popped out to drive the tensioning roller 22 to be far away from the first guide roller 17 and the second guide roller 18 to increase the tension on the printing paper 11, so as to ensure that the printing paper 11 is kept tensioned constantly; meanwhile, the encoder gear 24 rotates along with the rotation of the swing rod 21 and the swing arm shaft 20 to detect the tension of the printing paper 11, so that the tension of the printing paper 11 is accurately controlled, and the rolling stability of the printing paper 11 in the rolling station is improved.

As shown in fig. 5, the first driving mechanism includes a variable frequency motor 26 fixed on a motor base 25, the motor base 25 is fixed on one side of the winding frame 1, a mounting base 27 is fixed on the outer side wall of the winding frame 1, a transmission shaft 28 driven by the variable frequency motor 26 to rotate is rotatably mounted on the mounting base 27, a driving synchronous pulley 30 is mounted on the transmission shaft 28 through a first expansion sleeve 29, a mounting shaft 31 coaxial with the winding roller 2 is arranged at one end of the winding roller 2, the mounting shaft 31 is rotatably mounted on the winding frame 1 through a high-precision bearing 32, the mounting shaft 31 extends out of the outer side of the winding frame 1, a driven synchronous pulley 34 is mounted at one end of the mounting shaft 31 extending out of the winding frame 1 through a second expansion sleeve 33, and a synchronous belt 35 is wound on the driven synchronous pulley 34 and the driving synchronous pulley 30 together.

The second driving mechanism comprises two connecting rods 36 respectively arranged on two sides of the rolling rack 1, one end of each connecting rod 36 is fixedly arranged on the discharging shaft 4, the other end of each connecting rod 36 is hinged to a piston rod of a discharging oil cylinder 37, and a cylinder body of each discharging oil cylinder 37 is rotatably arranged on the outer side wall of the rolling rack 1.

In addition, the top of the two side walls of the rolling frame 1 is respectively provided with a sliding rail 38, and the two ends of the air inflation shaft 9 are respectively and slidably mounted on the corresponding sliding rails 38.

Use the utility model discloses carry out the process of rolling to printing paper 11 as follows:

firstly, the staff places physiosis axle 9 on the slide rail 38 at rolling frame 1 top, one side of rolling frame 1 still is provided with the operation panel, staff's accessible operation panel control two pressurized cylinder 7's piston rod is retrieved simultaneously, drive forcing arm 8 and use forcing shaft 3 as the fulcrum and rotate, briquetting 12 of bearing portion 10 on two forcing arm 8 is pressed simultaneously at the both ends of physiosis axle 9, press physiosis axle 9 to the wind-up roll 2 on, then start inverter motor 26 among the first actuating mechanism, inverter motor 26 drives transmission shaft 28 in proper order, initiative synchronous pulley 30, hold-in range 35, driven synchronous pulley 34 and wind-up roll 2 rotate, the rotation of wind-up roll 2 can drive physiosis axle 9 and rotate, and realize the rolling action of printing paper 11 in the rotation process.

Secondly, in the process of rolling the printing paper 11, the diameter of the paper roll is continuously increased, the air inflation shaft 9 is pushed to continuously move outwards, meanwhile, the piston rod of the pressurizing air cylinder 7 is ejected outwards at a uniform speed, the air inflation shaft 9 enters the bearing groove 14 in the bearing part 10 on the pressurizing arm 8, the pressurizing arm 8 rotates to drive the air inflation shaft 9 and the paper roll to rotate towards the blanking arm 5, when the air inflation shaft 9 moves to the limit position of the blanking arm 5, the position of the pressing block 12 in the bearing part 10 on the pressurizing arm 8 is lower than that of the blanking part 6 on the blanking arm 5, the pushing block 13 on the bearing part 10 can push the air inflation shaft 9 into the blanking part 6 in the process of continuously rotating the pressurizing arm 8, a worker cuts the printing paper 11 and places the new air inflation shaft 9 on the machine frame 1, then the piston rod of the pressurizing air cylinder 7 is controlled by the operation platform to be rapidly recovered, the pressing block 12 on the pressurizing arm 8 presses the new air inflation shaft 9 on the rolling roller 2, the new air shaft 9 starts to wind up the printing paper 11.

And thirdly, the worker controls a piston rod of the discharging oil cylinder 37 to extend out through the operating platform, the discharging arm 5 is driven to drive the wound paper roll to rotate towards the direction far away from the winding roller 2 by taking the discharging shaft 4 as a fulcrum, and the paper roll is driven to fall down to complete the discharging action of the paper roll.

To sum up, the utility model provides a surface tension rolling station has realized the automatic rolling and the automatic unloading of printing machine, has greatly improved the simplicity and convenience of rolling station rolling operation, has improved the work efficiency of printing machine, has saved the labour, has improved the stationarity of 11 rolling of printing paper.

The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. Surface tension rolling station, its characterized in that, including the rolling frame, the rolling roller by first actuating mechanism driven is installed in the last rotation of rolling frame, rolling frame internal rotation install be on a parallel with the pressurization axle and the unloading axle of rolling roller, the unloading axle is rotated by the drive of second actuating mechanism, there is a unloading arm at the both ends of unloading axle fixed mounting respectively, each all be equipped with a unloading portion on the unloading arm, install one respectively by pressurized cylinder drive pivoted forcing arm, each at the both ends of pressurization axle all be equipped with on the forcing arm and be used for bearing physiosis axle and push it bearing portion in the unloading portion, still be provided with a guide roller group that is used for guiding printing paper to go forward in the rolling frame.

2. The surface tension winding station of claim 1, wherein the pressure shaft and the discharge shaft are both disposed below the winding roller, and a distance between the pressure shaft and the winding roller is smaller than a distance between the discharge shaft and the winding roller.

3. The surface tension winding station as claimed in claim 1, wherein one end of each of the pressure arms is fixedly mounted on the pressure shaft, the other end of each of the pressure arms is provided with a support portion, each of the support portions comprises a pressing block for pressing the air expanding shaft and the winding roller together, each of the support portions further comprises a pushing block for pushing the air expanding shaft into the blanking portion, a support slot is formed between each of the pressing blocks and the corresponding pushing block, and the length of each of the pressing blocks is greater than that of the pushing block.

4. The surface tension winding station as claimed in claim 3, wherein each of the discharging arms is disposed outside the corresponding pressure arm, one end of each of the discharging arms is fixedly mounted on the discharging shaft, the other end of each of the discharging arms is provided with a discharging portion, each of the discharging portions is provided with a stopper, and the end of the other end of each of the discharging arms is provided with an inclined surface inclined toward the stopper.

5. The surface tension wind-up station of claim 1, wherein the set of guide rollers includes a first guide roller, a second guide roller, and a third guide roller arranged in sequence along a print paper advance direction, the first guide roller, the second guide roller, and the third guide roller are all rotatably mounted within the wind-up frame, and the first guide roller, the second guide roller, and the third guide roller are all parallel to the wind-up roller.

6. The surface tension wind-up station of claim 5, wherein the wind-up frame is further provided with a floating mechanism.

7. The surface tension winding station according to claim 6, wherein the floating mechanism comprises a swing arm shaft which is rotatably installed in the winding frame and is parallel to the winding roller, two ends of the swing arm shaft are respectively and fixedly provided with a swing rod, one end of each swing rod, which is far away from the swing arm shaft, is jointly rotatably installed with a tensioning roller, the lower end of each swing rod is hinged to a piston rod of a tensioning cylinder, the cylinder body of each tensioning cylinder is rotatably installed on the winding frame, and one end of the swing arm shaft is further provided with an encoder gear for detecting the force of printing paper.

8. The surface tension take-up station of claim 1, wherein the first drive mechanism includes a variable frequency motor secured to a motor mount, the motor seat is fixed on one side of the rolling frame, a mounting seat is fixed on the outer side wall of the rolling frame, a transmission shaft driven by the variable frequency motor to rotate is rotatably arranged on the mounting seat, a driving synchronous belt wheel is arranged on the transmission shaft through a first expansion sleeve, one end of the wind-up roll is provided with a mounting shaft which is coaxial with the wind-up roll, the mounting shaft is rotatably mounted on the wind-up rack through a high-precision bearing, the installation axle stretches out the outside of rolling frame, the installation axle stretches out the one end of rolling frame is installed driven synchronous pulley through the tight cover of second inflation, driven synchronous pulley with it is equipped with a synchronous belt to wind jointly on the initiative synchronous pulley.

9. The surface tension winding station according to claim 1, wherein the second driving mechanism comprises two connecting rods respectively arranged at two sides of the winding frame, one end of each connecting rod is fixedly arranged on the feeding shaft, the other end of each connecting rod is hinged to a piston rod of a feeding oil cylinder, and a cylinder body of each feeding oil cylinder is rotatably arranged on the outer side wall of the winding frame.

10. The surface tension winding station of claim 1, wherein the top of each of the two side walls of the winding frame is provided with a sliding rail, and the two ends of the air inflation shaft are slidably mounted on the corresponding sliding rails.

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