KR101506141B1 - Device for regulating a tension and method of continuously processing a web - Google Patents

Abstract

The present invention provides a tension control device and comprises a dancer which applies pressure on a web to adjust tension of the web, including a first ultrasonic wave vibration unit. The first ultrasonic wave vibration unit is vibrated by ultrasonic waves and applies repulsive power due to the ultrasonic vibration to the web while not being in contact with the web. Moreover, the present invention provides a method of continuously processing the web and comprises: a step of controlling the tension of the web by using the tension control device; and a step of processing the web whereof tension is adjusted.

Description

TECHNICAL FIELD [0001] The present invention relates to a tension control apparatus and a web continuous processing method using the tension control apparatus.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a tension control apparatus and a web continuous processing method using the same, and more particularly, to a tension control apparatus for controlling a tension of a web in a noncontact manner by applying a repulsive force generated by ultrasonic vibration to a web, .

The web means a flexible, continuous material in the longitudinal direction, and a continuous processing system for continuously processing the web includes a winder, an unwinder, a plurality of driven rollers, An idle roller, and the like. The continuous treatment process generally proceeds to a roll-to-roll or roll-to-sheet process. One of the methods of controlling the tension in the roll-to-roll or roll-sheet process is to use a dancer mechanism, which applies a certain amount of force in a certain direction by a spring, air pressure, or weight to a pressurizing device, Is applied.

1 is a schematic view of a conventional tension control device.

As shown, the dancer roller 311 mechanically contacts (rubs) with the web W to adjust the tension. The support rollers 312 and 313 support the web W in a fixed position.

The web, particularly the thin plate glass web or sheet glass sheet obtained therefrom, can be used in various fields such as displays, electronic materials (solar cells, touch sensors, wafers, etc.), construction, and home appliances. The laminated glass web is susceptible to damage by mechanical contact before being coated with a protective film. Therefore, uncoated glass web before coating of the protective film should avoid mechanical contact. Further, the thin plate glass web is a glass which is a hard material and damages the roller surface. Conventionally, in the case of the tension adjusting device, expensive chrome coating or the like is used in order to protect the roller from damage, but this has been a factor of increasing the cost of the equipment.

There has been a method of supporting the web by being supported by a conventional contact (friction) dancer roller or by releasing a fluid vent to the outer surface of the arcuate dancer roller by a contactless technique. However, in the former, the surface of the thin glass web tends to be damaged by mechanical contact. In the latter case, it is difficult to adjust the uniform height of the web only by the flow rate of the compressed air, and the repelling force There is a problem that it is easily contacted when a weak state or an unstable state (shaking or the like) of the web occurs. (Non-contact dancer mechanism KR 2011-0095191)

In addition, the thin glass web has brittle material properties, and is fragile in the conventional method of controlling the elongation. In addition, in the conventional web conveying, if a deviation occurs in the lateral direction, the elongation of the web itself is used to drive the dancer roller only up and down to stretch the web to control the tension. However, the thin web of the brittle material, elongation is small, which increases the possibility of mechanical contact or breakage.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the problems of the prior art as described above, and it is an object of the present invention to provide a method and apparatus for maintaining a uniform tension of a web by applying a uniform force It is the purpose of the dancer mechanism to provide.

In order to accomplish the above object, the present invention provides a dancer comprising a dancer which adjusts a tension of the web by applying a force to a web, the dancer including a first ultrasonic vibrator, wherein the first ultrasonic vibrator is ultrasonically vibrated, And applies the force to the web in a non-contact state by applying a repulsive force by the ultrasonic vibration to the web.

In addition, the present invention provides a web continuous processing method, comprising: controlling the tension of the web using the tension adjusting device; and processing the web with the tension adjusted.

The present invention as described above can provide a device having a noncontact dancer mechanism (tension control and mechanical contact elimination occurring during transportation) for stably transporting a web and a method for using the same.

Thus, the present invention avoids damage due to mechanical contact of brittle materials such as thin glass webs, eliminates the need for additional dancer rollers such as mechanical coatings, returns the web to a uniform height, Provide a possible method.

1 is a view showing a conventional tension adjusting device.
Fig. 2 is a schematic view showing the basic principle of tension control according to the present invention.
FIGS. 3 to 13 are views schematically showing a tension adjusting device according to the first to eleventh embodiments of the present invention. FIG.
FIGS. 14 and 15 are views schematically showing a tension adjusting device according to a twelfth embodiment of the present invention.
16 to 18 are views schematically showing a tension adjusting apparatus according to a thirteenth embodiment of the present invention.
19 is a schematic view showing a web continuous processing method according to a fourteenth embodiment of the present invention.

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

In the roll to roll or roll to sheet process for continuous web processing, the tension disturbance that occurs during web conveyance is controlled using a noncontact dancer.

The invention relates more particularly to the treatment of a web of brittle material, such as thin glass webs, and more particularly to a tension control device having a contactless dancer (320) for conveying a web of brittle material, To a continuous processing method of the web (W).

Fig. 2 is a schematic view showing the basic principle of tension control according to the present invention.

The tension regulating device of the present invention includes a dancer (320). 2 includes a first ultrasonic vibration section 321, an ultrasonic wave generation section 322, a vibration absorption section 324, and a fixed frame 325. The first ultrasonic vibration section 321, the ultrasonic wave generation section 322, The dancer 320 adjusts the tension of the web W by applying a force to the web W. The dancer 320 includes a first ultrasonic vibration unit 321. The first ultrasonic vibration section 321 is ultrasonically vibrated. The first ultrasonic vibration unit 321 applies a force to the web W in a non-contact state by applying a repulsive force of a high-pressure air layer generated by ultrasonic vibration to the web W.

In addition, the dancer 320 includes an ultrasonic wave generator 322. The ultrasonic wave generating unit 322 generates ultrasonic waves to vibrate the first ultrasonic vibration unit 321. The dancer 320 may include a vibration absorbing portion 324 for preventing the vibration of the first ultrasonic vibrating portion 321 from being transmitted to other components of the tension generating device.

An ultrasonic wave excitation technique (Patent Publication KR 2010-0057530) is applied so as to be spaced from the outer surface of the dancer 320. A force pushing the web W due to the periodic air compression phenomenon by the ultrasonic wave is generated on the outer surface of the dancer 320 to prevent mechanical contact and damage of the brittle material with the web W.

Unlike the non-contact tension adjusting device using the conventional fluid vent, since the magnitude of the repelling force is automatically adjusted when an unstable state (vibration, shaking, etc.) of the web W is generated, So that the non-contact state with the thin glass web W can be maintained constant.

The constant tension is maintained on the web (W) by constant force externally applied to the web (W) for tension control. For speed control, if one of the winding and unwinding is the master and the other is the slave, the height of the dancer 320 is measured and fed back in real time to increase or decrease the winding speed of the slave, can do.

Here, the web W may typically be a thin plate glass, but the present invention is not limited thereto. The web (W) of the present invention may be made of various other materials.

3 is a schematic view of a tension adjusting apparatus according to a first embodiment of the present invention.

The tensioning device of FIG. 3 includes a link 331 for supporting the dancer 320. One end of the link 331 is hinged to the dancer 320 and the other end is hinged to the anchor point. Accordingly, the dancer 320 can be freely rotated about the fixed point as the center of rotation, and the dancer 320 applies a uniform force corresponding to the weight of the dancer 320 to the web W. Therefore, the tension adjusting device can actively adjust the tension of the web W.

4 to 5 are views schematically showing a tension adjusting device according to a second embodiment of the present invention.

As shown in Fig. 4, the outer surface of the first ultrasonic vibration portion 321 is formed so that a portion facing the web W has an opening curve along the longitudinal direction of the web W, As can be seen in the circle. In the conventional contact dancer 320, the dancer roller must rotate due to the friction with the web W, but the dancer 320 of the present invention does not generate friction due to the non-contact force pushing the compressed air, Need not be rotated together. Therefore, unlike the conventional circular dancer roller, the outer surface of the first ultrasonic vibrator 321 does not always have to be round.

4 and 5 include a support for supporting the web W at a fixed position. The supporting portion includes a second ultrasonic vibration portion (341, 342). The second ultrasonic vibration portion is ultrasonically vibrated. The first ultrasonic vibration section 321 applies a repulsive force to the first surface of the web W while the second ultrasonic vibration sections 341 and 342 apply a repulsive force by the ultrasonic vibration to the second surface And supports the web W in a non-contact state.

As shown in FIGS. 4 and 5, the thin glass web W is gently restrained by using the dancer 320 and the arched support to minimize the stress of the thin glass web W, which is a brittle material, so as not to break.

If necessary, it is also possible to use the dancer 320 instead of the fixed position support.

6 to 9 are views schematically showing a tension adjusting apparatus according to fourth to seventh embodiments of the present invention.

The tension regulating device of Figs. 6 to 9 includes a link 332. One end of the link 332 is coupled to the dancer 320 and the other end is coupled to the piston of the cylinder 333 (e.g., hydraulic cylinder, pneumatic cylinder, etc.). The internal pressure of the cylinder 333 is kept constant and a pressure difference between the internal pressure and the external atmospheric pressure is applied to the dancer 320 via the link 332. [ That is, the dancer 320 is mechanically connected to the cylinder 333 to uniformly apply a constant pressure to the web W.

In addition, various other pressing means can be used. For example, a spring may be provided, one end of the spring may be coupled to the dancer 320, and the other end may be coupled to the fixing point. That is, the dancer 320 is mechanically connected to the spring to uniformly apply a certain elastic force to the web W.

10 and 11 are views schematically showing a tension adjusting device according to eighth and ninth embodiments of the present invention.

This is an embodiment of a contactless vertical dancer 320 mechanism using a cylinder 333 in a down horizontal or horizontal up web process as shown.

12 and 13 are views schematically showing a tension adjusting apparatus according to a tenth embodiment and an eleventh embodiment of the present invention.

As shown in the figure, there is shown a mechanism of the non-contact dancer 320 having the cylinders 333T and 333B arranged vertically. The bending stress of the brittle material is minimized by moderately configuring the web (W), and the upper and lower tension control can be finely adjusted.

12 and 13 additionally include a link (T) 332T and a link (B) 332B which are respectively coupled to the dancer 320 in opposite directions toward both sides of the web W do. The link (T) 332T is coupled at one end to the dancer 320 and at the other end to the piston of the cylinder (T) 333T. The link (B) 332B is coupled at one end to the dancer 320 and at the other end to the piston of the cylinder (B) 333B.

FIGS. 14 and 15 are views schematically showing a tension adjusting device according to a twelfth embodiment of the present invention.

As shown in the figure, when the web W is conveyed, the left and right positions of the noncontact dancer 320 are shifted up and down as the lateral tension deviation occurs. Therefore, it is possible to individually cope with the left and right tension deviation without elongating the thin plate glass.

The tension adjusting apparatuses shown in Figs. 14 and 15 include a link L (not shown) coupled to the dancer 320 on both sides along the width direction of the web W, so that the left and right positions of the dancer 320 can be individually adjusted 332L and a tilt link 334 and a link R 332R coupled to the tilt link 334. [ The link (L) 332L is hinged at one end to the dancer 320 and the other end is coupled to the piston of the cylinder (L) 333L. The tilt link 334 is hinged to the dancer 320 at one end. One end of the link (R) 332R is hinged to the other end of the tilt link 334, and the other end is coupled to the piston of the cylinder (R) 333R.

For example, assume that the cylinder (L) 333L and the cylinder (R) 333R apply a constant downward force 10 to the web W. Corresponding to this, the web W applies the upward force 10 to the cylinders 333L and 333R by the tension thereof to balance the forces. It is assumed that the tension at the left end of the web W does not change but the tension at the right end decreases. In this case, there will be no positional variation of the left end of the dancer 320. However, when the balance of the upward force applied to the dancer 320 by the downward force applied to the right end of the dancer 320 by the cylinder 333R and the tension of the web W is broken, and the new force is balanced The dancer 320 will be moved downward. Thus, the dancer 320 will have the right end lower than the left end.

16 to 18 are views schematically showing a tension adjusting apparatus according to a thirteenth embodiment of the present invention.

The tension can be finer even if the left and right tension deviations of the web W occur by coupling the cylinders 333LT, 333LB, 333RT, and 333RB to the both ends of the dancer 320 left and right and up and down.

The tension regulating apparatus of Figs. 16 to 18 includes a link (LT) 332LT, a link LB 332LB, a tilt link 334, a link (RT) 332RT and a link (RB) 332RB, .

The link LT 332LT and the link LB 332LB are hinged at one end in the width direction of the dancer 320 along the width direction of the web W and are hinged to opposite sides of the web W In the width direction of the dancer 320, respectively. One end of the link (LT) 332LT is hinged at one end in the width direction of the dancer 320, and the other end is coupled to the piston of the cylinder LT (333LT). One end of the link (LB) 332LB is hinged to one end in the width direction of the dancer 320, and the other end is coupled to the piston of the cylinder (LB) 333LB.

The tilt link 334 is hinged to the other end in the width direction of the dancer 320 along the width direction of the web W. One end of the tilt link 334 is hinged to the other end in the width direction of the dancer 320.

The link (RT) 332RT and the link (RB) 332RB are coupled to the tilt link 334, respectively. One end of the link (RT) 332RT is hinged to the other end of the tilt link 334 and the other end is coupled to a piston of the cylinder (RT) 333RT. The link (RB) 332RB is connected to the tilt One end is hinged to the other end of the link 334, and the other end is coupled to the piston of the cylinder (RB) 333RB.

19 is a schematic view showing a web continuous processing method according to a fourteenth embodiment of the present invention.

The present invention provides a web continuous processing method for adjusting and controlling the tension of a web (W) using the tension control device (300) as described above. The web continuous processing method includes the steps of adjusting the tension of the web W by using the tension adjusting device 300 and processing the web W whose tension is adjusted. The processing includes at least one of molding, cutting, polishing, printing, coating, cleaning and inspection of the web W. The web continuous processing method is preferably performed by a roll-to-roll or roll-to-sheet process. Fig. 19 shows a continuous cleaning and inspection method of the web W. Fig. Here, the processing of the web W means cleaning and inspection.

The web W and the protective film are unwound from the unwinding roller 715. The protective film is wound around the protective film take-up roller 716. The tension of the web W is adjusted by the tension adjusting device 300 and is transported by the transporting unit 100. [ The web W is cleaned in the cleaning section 800 and inspected in the inspection section 900. Then, it is wound around a winding roller 717. At this time, the protective film supplied from the protective film pulling-up roller 718 is wound together.

Claims (13)

And a dancer that applies a force to the web to adjust the tension of the web,
Wherein the dancer includes a first ultrasonic vibration part,
Wherein the first ultrasonic vibrator is ultrasonically vibrated and applies the force to the web in a non-contact state by applying a repulsive force by the ultrasonic vibration to the web,
And a support for supporting the web at a fixed position,
The support portion is composed of a pair of second ultrasonic vibration portions formed on both sides of the first ultrasonic vibration portion on the basis of the longitudinal direction of the web, the pair of second ultrasonic vibration portions are formed in an arcuate shape, Lt; / RTI >
The first ultrasonic vibrator applies a repulsive force to the first surface of the web,
Wherein the second ultrasonic vibrator is ultrasonically vibrated and applies a repulsive force by the ultrasonic vibration to a second surface which is a back surface of the first surface to support the web in a noncontact state. The method according to claim 1,
Wherein the web is a thin plate glass. The method according to claim 1,
Wherein the outer surface of the first ultrasonic vibrating part forms a circle or a portion of the first ultrasonic vibrating part facing the web forms an opening curve along the longitudinal direction of the web. delete The method according to claim 1,
Wherein the tension regulating device further comprises a spring,
Wherein the spring is coupled at one end to the dancer and the other end is coupled to a fixation point. The method according to claim 1,
The tensioning device additionally comprises a link,
Wherein the link is hinged at one end to the dancer and the other end is hinged to a fixing point. The method according to claim 1,
The tensioning device additionally comprises a link,
Wherein the link is coupled at one end to the dancer and the other end to a piston of the cylinder. The method according to claim 1,
Wherein the tension regulating device further comprises a link (T) and a link (B) each coupled to the dancer in opposite directions toward opposite sides of the web,
The link T is coupled at one end to the dancer and at the other end to the piston of the cylinder T,
Wherein the link (B) is coupled to the dancer at one end and the other end is coupled to the piston of the cylinder (B). The method according to claim 1,
The tension adjusting device may further include a link L and a tilt link hinged to both ends of the dancer in the width direction along the width direction of the web and a link R hinged to the tilt link,
The link L is hinged at one end to the dancer and the other end is coupled to the piston of the cylinder L,
Wherein the tilt link is hinged at one end to the dancer,
Wherein the link (R) is hinged at one end to the other end of the tilt link and the other end is coupled to the piston of the cylinder (R). The method according to claim 1,
The tension adjusting device includes:
A link LT and a link LB hinged to one end in the width direction of the dancer along the width direction of the web and hinged to one end in the width direction of the dancer in opposite directions toward both sides of the web, and,
And a tilt link hinged to the other end in the width direction of the dancer,
A link (RT) and a link (RB) hinged to the tilt link;
One end of the link LT is hinged at one end in the width direction of the dancer and the other end is coupled to the piston of the cylinder LT,
One end of the link LB is hinged at one end in the width direction of the dancer and the other end is coupled to the piston of the cylinder LB,
Wherein one end of the tilt link is hinged to the other end in the width direction of the dancer,
The link (RT) is hinged at one end to the other end of the tilt link and the other end is coupled to the piston of the cylinder (RT)
Wherein the link (RB) is hinged at one end to the other end of the tilt link and the other end is coupled to the piston of the cylinder (RB). delete delete delete

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