KR20120038182A - High precision tension load control system for wire winding - Google Patents

Abstract

PURPOSE: A super fine tension load control system for winding a wire is provided to finely control load applied to a wire according to types or properties of the wire. CONSTITUTION: A super fine tension load control system for winding a wire(1) comprises a roller dancer(11), a lever(12), a rotary shaft(13), and a power generator(10). The roller dancer guides a wire to a winding device in order to wind the wire to the winding device. The roller dancer is rotatably installed in one edge of the lever. The rotary shaft is connected to the other edge of the lever to rotate the lever. The power generator rotates the rotary shaft to press the wire with preset load.

Description

High precision tension load control system for wire winding

The present invention relates to an ultra-precision tension load control system for wire winding, and more particularly, by using a roller dancer when winding the wire to the winding machine, an initial load is constantly added according to the type of wire dismantled in the ship wire, It also relates to an ultra-precise tension load control system for wire windings that adjusts the tension acting on the wires so that the wires are wound at a constant speed and pitch in the winding machine.

When winding wires, they are usually wound at a constant speed. However, the outer diameter of the spool on which the wire is wound is increased by the amount of winding of the wire to be wound. That is, the length of the wire per one revolution of the spool is gradually increased so that the linear speed of the wire to be wound changes. Therefore, even if the rotational speed of the winding spool is constant and the wire speed of the wire changes, it is necessary to control the wire breaking speed of the wire so that the winding can be performed with a constant tension. This is because if the tension of the wire is not kept constant, curl or breakage occurs in the wire during the winding of the wire.

In addition, conventionally, since the breaking speed of the breaker and the magnitude of the tension acting on the wire are independently adjusted, it is difficult to control the load applied to the wire according to the breaker speed of the breaker and it is inconvenient to use.

Attached in the 'relative motion control system and method thereof' of the prior patent No. 10-0491679 is a view showing a wire tension control device for controlling the tension on the wire during the wire winding, the first motor connected to the first motor The shaft 400b winds the wire 100 according to the control signal of the wire tension control device, and the second shaft 400a connected to the second motor serves to release the wire 100. The first fixing roller 300a and the second fixing roller 300b rotate only the first fixing roller 300a and the second fixing roller 300b described above at the fixing position, and the roller dancer 200 moves up and down. . Here, the roller dancer 200 is adjusted so that the load acts downward in response to the tension on the wire 100, and the load is applied to the wire 100 by using weights, springs, and the like to the roller dancer 200 described above. . In addition, the position measuring device 900 is a device for measuring the position of the roller dancer 200.

2 is a view showing a wire tension control device for applying a load to the roller dancer 200a using a conventional spring. Referring to FIG. 2, the spring 700 is connected to the lever 500 on which the roller dancer 200a is mounted. And a load is applied to the roller dancer 200a based on the rotation shaft 600 by using the elastic force of the spring 700.

In addition, Figure 3 is a view showing a wire tension control device for applying a load to the roller dancer (200b) using a conventional weight 800, Figure 3 is loaded with a weight on the lever equipped with the roller dancer (200b) It shows a structure that acts to apply a load to the roller dancer 200b based on the rotation axis 600 by adjusting the weight of the.

However, in the case of the method of applying the load to the wire 100 mechanically using the weight of the weight 800 or the elastic force of the spring 700 as described above, the weight of the weight 800 as the load strength of the wire 100 is changed The problem is that the load must be mechanically adjusted, such as changing the spring 700 or changing the spring 700 according to the elastic modulus of the spring 700, and also loads the wire 100 using the weight 800 or the spring 700. In applying the problem, it is difficult to finely adjust the load applied according to the diameter, material, etc. of the wire 100.

Accordingly, the present invention is proposed to solve the above problems of the prior art, by using a tension load control system that applies the torque of the motor or solenoid to maintain a constant tension of the wire, and also using a weight or It is an object of the present invention to provide a high-precision tension load control system for wire windings in which fine adjustment of the initial load applied to the wire through the roller dancer is possible without mechanical change or weight of the weight depending on the type or characteristics of the wire.

The object of the present invention is a roller dancer for guiding the wire to the winding machine so that the wire wired from the ship wire is wound to the winding machine, and a lever in which the roller dancer is rotatably mounted on one side edge area and the other edge of the lever. It is achieved by a high precision tension load control system for a wire winding comprising a rotating shaft connected to an area to rotate the lever and a power generating portion rotating the rotating shaft to press the wire to a predetermined load.

Here, the power generator may include a DC motor or a rotary solenoid. The power generating unit may include a driving unit generating a rotational force, a first pulley coupled to the rotational shaft to rotate in synchronization with the rotational shaft, and a second pulley larger than a diameter of the first pulley and rotating according to the rotational force from the driving unit. It may include a belt for transmitting the rotational force of the first pulley to the second disadvantage, the drive unit may be composed of a DC motor and a rotary solenoid.

The apparatus may further include a tension load control unit controlling the driving unit to adjust the size of the load acting on the wire from the roller dancer.

In addition, it may further include a weight installed on the lever so that the initial load acting on the roller dancer.

The apparatus may further include a rotation position sensor for detecting a rotation position of the lever, wherein the tension load controller is configured to maintain the rotation position of the lever in a preset position range based on a detection result of the rotation position sensor. It is possible to control the dismantling speed of the dismantling machine.

The tension load controller may control the winding speed of the winding machine so that the rotational position of the lever is maintained within a preset position range based on the sensing result of the rotational position sensor. The rotational speed of the spool installed in the winding machine can also be controlled by the controller to be wound at the set winding speed.

According to the configuration as described above, the ultra-precision tension load control system for wire winding according to the present invention is a load acting on the roller dancer using a power generating unit to enable fine adjustment of the load applied to the wire according to the type or characteristics of the wire Can be adjusted precisely. Here, the power generation unit may use a DC motor or a rotary solenoid, which is easy to control the speed and the rotation direction.

In particular, the load generated by the DC motor can be precisely controlled by voltage or current, so that the roller dancer is controlled by controlling the torque formed by the DC motor according to the diameter and material of the wire without adding or changing mechanical weight or weight. Accurately adjust the load applied to the

In addition, the diameter of the second pulley coupled to the shaft of the DC motor is increased, and the diameter of the first pulley coupled to the rotating shaft is configured to be small, so that the positional change of the rotation shaft can be increased by only a small rotational movement of the DC motor. In other words, the DC motor includes a magnet inside, and the diameter of the second pulley is reduced because the rotor inside the DC motor affects the torque of the DC motor as it passes through the disconnected portion located between the magnet and the magnet during rotation. By making it large compared with the diameter of 1 pulley, the influence of this torque can be made small. Therefore, the position change of the position rotation sensor shaft can be enlarged only by small rotational movement of a DC motor.

The apparatus may further include a rotation position sensor that detects a rotation position of the lever, and the tension load controller may remove the ship of the ship to maintain the rotation position of the lever in a preset position range based on the detection result of the rotation position sensor. By controlling the speed or winding speed of the winding machine, the tension of the wire can be controlled.

As described above, productivity and quality can be improved by using an ultra-precision tension load control system for wire winding according to the present invention, for example, a high-speed precision winding machine that needs to wind fine gold wire precisely.

1 is a view showing a wire tension control device for controlling the tension in the wire winding the wire,
2 is a view showing a wire tension control device for applying a load to the roller dancer using a conventional spring,
3 is a view showing a wire tension control device for applying a load to the roller dancer using a conventional weight,
4 is a perspective view showing a winding machine equipped with a high precision tension load control system for wire winding according to the present invention;
5 is a plan view showing a high precision tension load control system for a wire winding according to the present invention,
Figure 6 is a front view showing a high precision tension load control system for wire winding according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

4 is a perspective view showing a winding machine equipped with a high precision tension load control system 1 for winding a wire according to the present invention. In FIG. 4, the ultra-precise tension load control system 1 for winding the wire is guided to the wire 100 so that the wire 100 wired from the wirebreaker 3 is wound on the winding machine 2. Referring to FIG. 4, the ultra-precision tension load control system 1 for wire winding includes a roller dancer 11, a lever 12, a rotation shaft 13, and a power generator 10.

The ultra-precision tension load control system 1 for wire winding according to the present invention maintains a constant tension of the wire 100 wound on the winding machine 2, and also loads acting on the roller dancer 11 Keep it constant.

The roller dancer 11 guides the wire 100 to the winding machine 2 so that the wire 100 removed from the wire drawing machine 3 is wound on the winding machine 2, while pressing the wire 100 to a predetermined load. In order to prevent disconnection from occurring due to the frictional force with the roller dancer 11, 100 is rotatably installed at one side edge area of the lever 12. Here, the wire 100 to be removed from the ship dispensing machine 3 is supported as if wound on the outer circumferential surface of the roller dancer 11 that is rotatably installed.

In addition, it is possible to install a weight 19 to the lever 12 to adjust the initial load acting on the roller dancer 11, the lever 12 is the rotational movement of the lever 12 is the vertical movement of the roller dancer 11 Coupling with the rotary shaft 13 so that it can be converted into. Therefore, as the lever 12 rotates, the rotating shaft 13 also rotates together.

In addition, the torque applied to the rotating shaft 13 is adjusted by the power generating unit 10. Here, the power generating unit 10 may be coupled to the rotating shaft 13 to transmit torque to press the rotating shaft 13 to a predetermined load, and to rotate the rotating shaft 13 to press the wire 100 to the predetermined load. do. The power generator 10 may include a DC motor (not shown) or a rotary solenoid (not shown), and the power generator 10 may depend on the force (torque) of the power generator 10. ), The load acting on the roller dancer 11 can be adjusted.

FIG. 5 is a plan view showing a super precision tension load control system 1 for a wire winding according to the present invention, and FIG. 6 is a front view showing a super precision tension load control system 1 for a wire winding according to the present invention. As shown in FIGS. 5 and 6, the power generator 10 may be configured using the driving unit 17, the belt 18, the first pulley 14, and the second pulley 15. Here, the first pulley 14 is coupled to the rotating shaft 13 to adjust the force to transmit the rotating shaft 13 to rotate, as a result of which to change the rotation position of the rotating shaft (13). In addition, the rotational force is axially coupled to the belt 18 that transmits power so that the first pulley 14 rotates, the second pulley 15 that transmits power to the belt 18, and the second pulley 15. Power is transmitted to the first pulley 14 by using the driving unit 17 to transmit. The above-described belt 18 is an example, and in addition to the belt 18, it is possible to transfer motion using a chain or a gear device, and the driving unit 17 includes a rotary solenoid (not shown) and a DC motor (drawings). Not shown) is also available.

In addition, when the diameter of the second pulley 15 coupled with the driving unit 17 is increased and the diameter of the first pulley 14 coupled with the rotating shaft 13 is configured to be small, the speed of the driving unit 17 may be operated at a low speed. When the position change of the rotary shaft 13 can be increased. Therefore, the rotational position change of the rotating shaft 13 can be enlarged only by the small torque applied to the 2nd pulley 15 by the drive part 17. FIG. In particular, when using a DC motor (not shown) in the drive unit 17, when the speed of the DC motor has a very low rotational movement at a very low speed, the torque generated from the DC motor is dependent on the magnitude of the input voltage or current. Will be proportional. Therefore, the magnet is contained in the DC motor, and the second pulley 15 because the rotor inside the driving unit 17 affects the torque of the driving unit 17 as it passes through the disconnected portion located between the magnet and the magnet when rotating. The diameter of is made larger than the diameter of the first pulley 14 to minimize the influence of this torque.

In addition, the torque acting on the rotary shaft 13 by the driving unit 17 is the sum of the torque generated by the driving unit 17 and the load caused by the load acting on the first pulley 14 and the second pulley 15. When the torque acting on the rotating shaft 13 is zero, that is, the balance of the force is achieved, the lever 12 is synchronized with the rotating shaft 13 so that the roller dancer 11 is maintained as a fixed state. Therefore, in order to maintain the roller dancer 11 at a predetermined position while winding the wire 100, the torque is controlled to the driving unit 17 which rotates the rotary shaft 13 to press the wire 100 to a predetermined load. By sending a signal, the load acting on the roller dancer 11 can be precisely adjusted. In addition, even when the torque acting on the rotary shaft 13 becomes zero, the driving unit 17 may adjust the load by rotating the rotary shaft 13 to press the wire 100 to a predetermined load. . Hereinafter, the driving unit 17 rotates the rotary shaft 13 to examine how a load acts on the wire 100.

Here, the load generated in the lever 12 in accordance with the direction of the torque transmitted to the rotary shaft 13 by the drive unit 17 can be applied in the opposite direction of the downward direction generated by the weight 19 and the lever 12. have. 5 and 6, the load generated by the weight 19 and the lever 12 is applied in the downward direction, and the driving unit (1) is configured to press the wire 100 to a predetermined load. 17 transmits torque to the rotating shaft 13. Then, the driving unit when the predetermined load applied to the wire 100 according to the type of the wire 100 requires less load than the load generated by the weight 19 and the lever 12 to the wire 100 The load generated by 17 is controlled so that the load is applied in a direction opposite to the direction of the load generated by the weight 19 and the lever 12. In addition, when the wire 100 requires more load than the load generated by the weight 19 and the lever 12, the load generated by the driving unit 17 is driven by the weight 19 and the lever 12. The load is controlled to be applied in the same direction as that of the generated load.

In addition, the load generated by the driving unit 17 can be precisely controlled by the voltage or current, so that the driving unit 17 according to the diameter, material, etc. of the wire 100 without mechanical change or weight of the weight 19 is added or reduced. It is possible to precisely adjust the load applied to the roller dancer 11 by controlling the torque formed by the.

In addition, the ultra-precision tension load control system 1 for the wire winding according to the present invention may further include a main body 50 having an accommodating space therein, wherein the accommodating space includes a first pulley 14 and a belt 18. , The second pulley 15 and the like can be accommodated. The lever 12, the roller dancer 11, the weight 19, and the like may be disposed outside the main body 50.

In addition, the ultra-precision tension load control system 1 for the wire winding according to the present invention may further comprise a rotation position sensor 16. Here, the rotation position sensor 16 may detect the rotation position of the rotation shaft 13 coupled with the lever 12. In addition, when the roller dancer 11 moves upward or downward through the tension change of the wire 100, the lever 12 rotates around the rotating shaft 13, and as the lever 12 rotates, Since the rotary shaft 13 also rotates together, the rotational position of the lever 12 is sensed when the lever 12 rotates. For example, the rotational position sensor 16 may use an optical potentio meter, and by using the potentiometer, it is possible to minimize the influence of friction and to increase the precision of the position change of the rotation shaft 13.

The tension load control unit 30 controls the dismantling speed of the dismantling device 3 so that the rotational position of the lever 12 is maintained within a preset position range based on the detection result of the rotational position sensor 16, and the rotational position sensor The rotation position signal is received from (16). Here, the tension load control unit 30 speeds up the desciter motor 4 of the dissociator 3, which automatically disassembles the wire 100 according to the winding speed of the wire 100 wound on the winding machine 2. Outputs the signal command to adjust. Therefore, when the roller dancer 11 is positioned below the reference position when the roller dancer 11 is not moved by pressing the preset load on the wire 100 as described above, the shipboard motor ( 4) outputs a signal to reduce the speed, and if the roller dancer 11 is located above the reference position, the output of the signal to increase the speed of the wire cutter motor 4 is output to make the position of the roller dancer 11 constant. Keep it.

In addition, the tension load control unit 30 may output a signal command for adjusting the winding speed of the wire 100 wound on the winding machine (2). Therefore, when the above-mentioned torque is 0, when the roller dancer 11 is located below the reference position with respect to the reference position, a signal for increasing the speed of the winding machine motor (not shown) of the winding machine 2 is obtained. When the roller dancer 11 is positioned upward from the reference position, the roller dancer 11 outputs a signal to reduce the speed of the winding machine motor, thereby keeping the position of the roller dancer 11 constant. Accordingly, the tension acting on the wire 100 is kept constant to prevent curl or the like from occurring in the wire 100.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments. Those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope of the appended claims, The genius will be so self-evident. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

1: High precision tension load control system for wire winding
2: winding machine 3: wirebreaker
4: wire breaker motor 10: power generating unit
11: roller dancer 12: lever
13: rotating shaft 14: first pulley
15: second pulley 16: rotation position sensor
17 drive unit 18 belt
19: weight 30: tension load control unit
50: 100 body: wire

Claims (7)

A roller dancer for guiding the wires to the winding machine such that the wires wired from the wire drawing machine are wound on the winding machine;
A lever rotatably mounted to one side of the roller dancer;
A rotation shaft connected to the other edge region of the lever to rotate the lever;
And a power generator for rotating the rotating shaft to press the wire to a predetermined load. The method of claim 1,
The power generation unit,
A driving unit generating a rotational force;
A first pulley coupled to the rotation shaft to rotate in synchronization with the rotation shaft;
A second pulley which rotates according to the rotational force from the driving unit and is larger than a diameter of the first pulley;
And a belt that transmits the rotational force of the first pulley to the second disadvantage. The method of claim 2,
The drive unit is a high precision tension load control system for the wire winding, characterized in that any one of a DC motor and a rotary solenoid. The method of claim 1,
And a weight installed on the lever so that the initial load acting on the roller dancer is adjusted. The method according to any one of claims 1 to 4,
And a tension load control unit for controlling the power generating unit to adjust the size of the load acting on the wire from the roller dancer. The method according to claim 5,
A rotation position sensor for sensing a rotation position of the lever;
The tension load control unit controls ultra-precision tension loads for the wire winding, based on a detection result of the rotational position sensor, so that the rotational position of the lever is maintained within a preset position range. system. The method of claim 5,
A rotation position sensor for sensing a rotation position of the lever;
The tension load control unit may control the winding speed of the winding machine so that the rotational position of the lever is maintained within a preset position range based on a sensing result of the rotational position sensor. .

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