KR101951440B1 - Pulling roll, apparatus and method for drawing glass ribbon - Google Patents

Abstract

A pulling roll is provided for drawing the glass ribbon. A pulling roll having a roll body including a central passage extending therethrough in a longitudinal direction, a shaft extending through the central passage and spaced apart from the roll body, and a shaft disposed on the shaft so as to be movable in the longitudinal direction of the shaft A first flange supporting the roll body, and a spring pressing the first flange in the longitudinal direction of the shaft.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a pulling roll, an apparatus and a method for drawing a glass ribbon,

Embodiments of the present disclosure relate to pulling rolls, glass ribbon drawing devices, and glass ribbon drawing methods for drawing glass ribbon.

A pulling roll is used to thinly draw a glass ribbon to a desired final thickness in a sheet glass manufacturing process. For example, a pulling roll is positioned below the tip or root of the melt pipe to adjust the rate at which the glass ribbon leaves the melt pipe by drawing the glass ribbon to determine the final thickness of the glass ribbon.

A conventional pulling roll includes a plurality of compressed disks stacked in the axial direction of the shaft. The disks are held stationary on the shaft in a compressed state by color. The plurality of discs are made of a ceramic composite material (usually made of ceramic fiber, mica, clay) which is in contact with a glass ribbon and draws a glass ribbon.

However, since these ceramic discs are vulnerable to thermal shock, they are liable to release an excessive number of particles in contact with the hot glass ribbon. These particles can adhere to the surface of the glass ribbon and cause surface defects, known as onclusion. In particular, when the sheet glass is made of a substrate for a flat panel display, the sheet glass must have a very low level of onclusion, since each onclusion is a defective area of the final product (e.g. a display panel) One or more defective pixels). Thus, there is a need in the art for a pulling roll that minimizes or prevents multiple onclination generations.

According to the present disclosure, a pulling roll, a glass ribbon drawing device, and a glass ribbon drawing method for drawing a glass ribbon capable of minimizing or preventing the generation of an onclusion are provided. For example, a pulling roll can be made of a heat resistant material to prevent the generation of onclination

In one embodiment, a pulling roll for drawing a glass ribbon includes a roll body including a central passage extending therethrough in a longitudinal direction, a shaft extending through the central passage and spaced apart from the roll body, And a spring for pressing the first flange in the longitudinal direction of the shaft. The spring is a coil spring disposed inside or outside the shaft, and the coil spring disposed at the outside surrounds at least a part of the shaft and is extendable. The roll body is single side and comprises a fused silica material. The pulling roll may be a full length pulling roll or a stub pulling roll.

According to embodiments described below, the first flange may further include a sleeve slidably coupled with the shaft, and a cap extending outwardly from the sleeve. The cap contacts the roll body so that the first flange supports the roll body. The roll body and the cap may include a convex portion and a concave portion that receives the convex portion, and the convex portion and the concave portion may include complementary inclined surfaces contacting each other.

In some embodiments, the pulling roll further comprises a rod disposed within the shaft and coupled with the spring, and a pin coupling the first flange to the rod, wherein the shaft extends in the longitudinal direction of the shaft And at least one slot extending therefrom. The pin is movable in the longitudinal direction of the shaft in the slot. The pulling roll further includes a second flange fixed on the shaft, and the roll body is disposed between the second flange and the first flange.

In yet another embodiment, an apparatus for drawing a glass ribbon comprises at least a pair of first pulling rolls and at least a pair of second pulling rolls disposed downstream from the first pair of pulling rolls along a pulling path Wherein the first pulling roll is a full length pulling roll and the second pulling roll is a stub pulling roll.

In yet another embodiment, a method of drawing a glass ribbon includes drawing a glass ribbon by at least a pair of pulling rolls. The pulling roll includes a shaft, a roll body rotatable with the shaft, a moving flange disposed on the shaft and supporting the roll body, and a moving flange provided on the shaft and exerting a force on the moving flange in the longitudinal direction of the shaft Wherein the roll body comprises a fused silica material and is disposed spaced apart from the shaft. The drawing step includes moving the moving flange in the longitudinal direction of the shaft by the spring such that the moving flange maintains support of the roll body while drawing the glass ribbon.

In a pulling roll according to one embodiment of the present disclosure, the generation of onclination is minimized or prevented.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 schematically shows a glass manufacturing apparatus according to an embodiment for forming glass ribbon from molten glass.
Figure 2 schematically illustrates a glass ribbon drawing apparatus according to one embodiment.
3 is a sectional view showing an example in which a glass ribbon is drawn by a pulling roll in the glass ribbon drawing apparatus shown in Fig.
4 is a plan view showing a pulling roll according to the first embodiment.
5 is a cross-sectional view taken along the line VI-VI in Fig.
6 is an enlarged view of a portion A in Fig.
7 is a plan view showing a pulling roll according to the second embodiment.
8 is a cross-sectional view taken along the line VII-VII in FIG.
9 is an enlarged view of a portion B in Fig.
Fig. 10 is a plan view showing a pulling roll according to the third embodiment, in which the coil spring is installed inside the shaft. Fig.
11 is a plan view showing a pulling roll according to the fourth embodiment.
12 is a plan view showing a pulling roll according to the fifth embodiment.
13 is a cross-sectional view taken along the line XII-XII in Fig.
14A schematically shows a part of a pulling roll according to the sixth embodiment which is not thermally expanded at normal temperature.
14B schematically shows a part of the pulling roll according to the sixth embodiment which thermally expanded at a high temperature.

In the following, embodiments of the present disclosure will be described with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 schematically shows a glass manufacturing apparatus according to an embodiment for forming glass ribbon from molten glass. 1, a glass manufacturing apparatus 100 includes a melting vessel 101, a refining vessel 103, a mixing vessel 104, a transfer vessel 108, and a Fusion Drawing Machine 120 do. A glass batch material is injected into the dissolution vessel 101 as indicated by arrow 102. The glass batch material is dissolved in the melting vessel 101 to form the molten glass 106. The tablet vessel 103 has a high temperature processing area for receiving the molten glass 106 from the dissolution vessel 101 and air bubbles are removed from the molten glass 106 in the tablet vessel 103. The tablet vessel (103) is fluidly connected to the mixing vessel (104) by a connecting tube (105). That is, the molten glass 106 flows from the tablet vessel 103 to the mixing vessel 104 through the connecting tube 105. The mixing vessel 104 stirs the molten glass 106 and is in turn fluidly connected to the transfer vessel 108 by a connecting tube 107 and the molten glass 106 is mixed through the connecting tube 107 And flows from the container 104 to the transfer container 108.

The transfer vessel 108 supplies the molten glass 106 to the FDM 120 through a downcomer 109. The FDM 120 has an enclosure 122 in which an inlet 110, a molding vessel 111 and a glass ribbon drawing apparatus 150 according to an embodiment are disposed within the envelope 122 . As shown in Fig. 1, the molten glass 106 from the downcomer 109 flows into the inlet 110 and reaches the molding vessel 111. The molding vessel 111 includes an opening 112 for receiving a molten glass 106 flowing into a trough 113. The molten glass 106 overflows from the troughs 113 and flows down along the two converging surfaces 114a and 114b as different streams of molten glass. The different flows are merged along the bottom edge, i.e., the root 116, where the two converging surfaces 114a, 114b meet. The combined molten glass 106 is then drawn by the glass ribbon drawing device 150 in the drawing direction 151 to form a continuous glass ribbon 148. The glass ribbon drawing apparatus 150 includes at least a pair of pulling rolls and an actuator for rotating and driving the same.

Fig. 2 schematically illustrates an exemplary glass ribbon drawing apparatus 150, and Fig. 3 illustrates a glass ribbon drawn in a glass ribbon drawing apparatus 150. Fig. Referring to Figures 2 and 3, the glass ribbon drawing apparatus 150 has a plurality of pulling roll pairs for drawing glass ribbon, and the plurality of pulling roll pairs are arranged along a pulling path (that is, (Along the drawing direction 151). Each pair of pulling rolls has two pulling rolls, through which the glass ribbon 148 is drawn. Each pulling roll of each pulling roll pair is in contact with a first major surface of the glass ribbon 148 and a second major surface opposite the first major surface in the thickness direction of the glass ribbon 148, The glass ribbon 148 is drawn by rotation. In some embodiments, the glass ribbon drawing apparatus 150 includes a pair of pulling rolls 161 having two full length pulling rolls 200 and two opposing cantilevered stub pulling rolls < RTI ID = 0.0 > 163, 164, 165, 166, 167 having a cantilevered stub pulling roll (600). The full length pulling roll 200 extends over the entire width of the glass ribbon 148 and the stub pulling roll 600 extends over only a portion of the entire width of the glass ribbon 148.

As shown in Figures 2 and 3, the full length pulling roll 200 is positioned upstream relative to the stub pulling roll 600, and the glass ribbon 148 is temporarily placed over most of the entire width of the glass ribbon The glass ribbon 148 is formed in the initial stage of the drawing process by drawing the glass ribbon 148 in contact. The stub pulling roll 600 is disposed downstream of the full length pulling roll 200 in the drawing direction 151 and contacts the edge portion of the glass ribbon 148 to cause the glass ribbon 148 to be drawn in the drawing direction 151 do. By adjusting the rotational angular velocity of each stub pulling roll 600, the rate at which the glass ribbon 148 is drawn can be adjusted to achieve the final thickness of the glass ribbon 148.

Figs. 4-9 illustrate embodiments of the full length pulling roll 200 described above, and Figs. 10-13 illustrate embodiments of the stub pulling roll 600 described above. The configuration of the pulling roll disclosed herein can be applied to both the full length pulling roll and the stub pulling roll.

Figures 4-6 illustrate an exemplary pulling roll 200 according to the first embodiment. FIG. 4 is a plan view of the pulling roll, FIG. 5 is a sectional view taken along a line VI-VI in FIG. 4, and FIG. 6 is an enlarged view of a portion A shown in FIG. 4 and 5, the pulling roll 200 of the first embodiment includes a shaft 210, a roll body 220, a fixing flange 230, a moving flange 240, and a coil spring 250 .

The shaft 210 has a substantially cylindrical shape and extends in the longitudinal direction of the shaft 210 (i.e., the axial direction of the shaft 210). The roll body 220 is part of a pulling roll that contacts the glass ribbon 148. The roll body 220 has a substantially cylindrical shape and forms a central passage 222 extending between the first end of the roll body and the second end opposite thereto and extending therethrough in the longitudinal direction of the roll body. The diameter D1 of the central passage 222 is larger than the outer diameter D2 of the shaft 210. [ That is, a predetermined gap G1 exists between the roll body 220 and the shaft 210.

  The shaft 210 is inserted into the center passage 222 of the roll body 220 so that the roll body 220 is mounted on the shaft 210 by the fixing flange 230 and the moving flange 240 which will be described later.

The roll body 220 of the pulling roll 200 according to the first embodiment may be made of fused silica, which is an amorphous form of silicon dioxide. Fused silica is resistant to thermal shock because it has a coefficient of thermal expansion (CTE) close to zero (e.g., 5.5 x 10 ^-6 m / C at room temperature). In addition, fused silica has high heat resistance. Thus, as the roll body 220 is made of fused silica, the pulling roll 200 can significantly reduce particle generation and release due to thermal shock.

The pulling roll structure of the prior art is not suitable for materials with low coefficient of thermal expansion such as fused silica. For example, in a conventional pulling roll, a plurality of ceramic disks are fixed on a shaft by a collar in a compressed state. The color is fixed to the shaft so that when the shaft is thermally expanded, the color moves with the shaft. Therefore, when the shaft is thermally expanded at a high temperature such as the temperature exposed during the operation of the pulling roll, not only the ceramic disk is thermally expanded, but also the compressive force against the ceramic disk (the color shifts as the shaft expands) And the ceramic disk is further expanded. Thus, the fixed color is moved by the thermal expansion of the shaft, but the ceramic disk is not separated from the shaft. However, when the thermal expansion coefficient of the roll body 220 is very low as in the embodiment disclosed herein, if the roll body 220 is fixed to the shaft 210 by the conventional fixing method, And the thermal expansion coefficient of the shaft is much larger than the thermal expansion coefficient of the roll body, so that the compressive force applied to the roll body is greatly affected.

In accordance with one embodiment of the present invention, the roll body 220 is spaced from the shaft 210 as a single piece, and only the moving flange 240, which will be described below, moves relative to the shaft 210 While pressing the roll body 220 to fix the roll body 220 in the correct position. It is therefore possible to fix the roll body 220 in place even if the roll body 220 is made of a material having a coefficient of thermal expansion such as fused silica that is considerably smaller than the thermal expansion coefficient of the shaft 210. This will be described in more detail below.

4 and 5, the roll body 220 of the pulling roll 200 according to the first embodiment includes a fixed flange 230 disposed on the shaft 210 and a fixed flange 230 disposed between the movable flange 240 And is fixed. 6 shows that the step S is formed in the roll body 220, steps may not be formed in order to prevent cracks from being concentrated due to thermal stress at the bent portions See the second embodiment of Fig. 9).

6, the moving flange 240 includes a sleeve 242 extending along the length of the shaft 210 and a cap 244 extending radially outwardly from the sleeve 242. As shown in FIG. The sleeve 242 has an opening 246 through which the shaft 210 extends and is movable on the shaft 210.

The sleeve 242 extends in the longitudinal direction of the shaft 210 to allow the moving flange 240 to move smoothly in the longitudinal direction of the shaft 210 on the shaft 210. There must be some clearance between the moving flange 240 and the shaft 210 to movably engage the moving flange 240 with the shaft 210. [ Because of this clearance, the moving flange 240 can be inclined relative to the shaft 210 during movement on the shaft 210. The larger the inclination angle is, the greater the possibility that the movement flange 240 is caught by the surface of the shaft 210 while the movement flange 240 is moving on the shaft 210 and the movement of the movement flange 240 is disturbed. It should be understood, however, that the moving flange 240 of the present disclosure has a sleeve 242 extending in the longitudinal direction of the shaft 210, so that the moving flange 240 (as compared to when the sleeve 242 is free) 240 is reduced with respect to the shaft 210. Thus, the moving flange 240 is more smoothly movable on the shaft 210. [ In addition, the end of the sleeve 242 may be chamfered or rounded so that the moving flange 240 is more smoothly movable on the shaft 210.

A space 214 extending in the longitudinal direction of the shaft 210 is formed in the shaft 210 at least at the end of the shaft 210. [ A coil spring 250 and a rod 260 are provided in the space 214. One end of the coil spring 250 contacts the inner wall of the shaft 210 in the space 214 and the other end is connected to the rod 260 Contact. A through hole 264 is formed in the end portion 262 of the rod 260 and a slot 216 is formed in the shaft 210. A through hole 246 is formed in the moving flange 240. A pin 270 is coupled through the slot 216 of the shaft 210 to the through hole 264 of the rod 260 and the through hole 246 of the moving flange 240. Because the slot 216 extends in the longitudinal direction of the shaft 210, the pin 270 is movable in the longitudinal direction of the shaft 210 within the slot 216.

The coil spring 250 is compressed while the roll body 220 is fixed between the fixed flange 230 and the moving flange 240 so that the coil spring 250 moves the rod 260 in the longitudinal direction of the shaft 210 In a direction away from the end portion 212 of the shaft 210. As shown in Fig.

The movable flange 240 can move relative to the shaft 210 in the longitudinal direction of the shaft 210 by the structure of the shaft 210 described above, And presses the roll body 220 in the direction away from the end portion 212 of the shaft 210 in the longitudinal direction of the shaft 210 by the elastic restoring force. Accordingly, at the normal temperature, the moving flange 240 contacts not only the roll body 220 but also the moving flange 240 moves relative to the shaft 210 even if the shaft 210 thermally expands in the longitudinal direction at a high temperature Thereby maintaining the contact state of the roll body 220.

The roll body 220 is spaced from the shaft 210 and is only fixed by the moving flange 240 so that the roll body 220 rotates with the shaft 210 in place. A convex portion may be formed at an end of the roll body 220 and a concave portion may be formed in the cap 244 to receive the convex portion of the roll body 220. [ The roll body 220 is not easily released from the moving flange 240 even if the roll body 220 is subjected to a radial force as the roll body 220 contacts the glass ribbon 148 during the operation of the pulling roll 200. [

When the central axis of the roll body 220 and the central axis of the shaft 210 do not coincide with each other, the roll body 220 to be rotated as the shaft 210 rotates is rocked, The drawing force is not transmitted. To prevent this, the recess of the cap 244 includes a radially inwardly inclined slope 248 and the convex portion of the roll body may include a complementary slope 224 in contact with the slope 248 . The convex portion and the concave portion are designed so that the center axis of the roll body 220 and the central axis of the shaft 210 coincide when the inclined faces 224 and 248 contact each other. Therefore, even if the slopes 224 and 248 are temporarily not brought into contact with each other during the pulling roll operation (due to a reaction force from the glass ribbon 148 or the like), since the slopes 248 press the slopes 224, The inclined planes 224 and 248 are restored to the contact state and the central axis of the roll body 220 and the central axis of the shaft 210 coincide with each other. As a result, the cap 244 centers the roll body 220 relative to the shaft 210 and the outer surface of the roll body 220 is concentric with the axis of rotation of the shaft 210.

The roll body 220 can be rotated together with the shaft 210 when the roll body 220 is in contact with the glass ribbon 148 to tension the glass ribbon 148 The coil spring 250 must apply sufficient force to the moving flange 240 to prevent slippage between the moving flanges 240). The force may be calculated based on the torque applied to the roll body 220 from the glass ribbon during operation of the pulling roll 200 and the coefficient of friction between the moving flange 240 and the roll body 220. Also, the coil spring 250 must maintain an elastic force even at a high temperature, and may be made of NIMONIC 90 material as an example.

 Additional complementary grooves 226 and protrusions 249 can also be formed on the slopes 224 and 248 to more reliably prevent slippage between the roll body 220 and the moving flange 240. In order to prevent slippage between the roll body 220 and the moving flange 240, the end of the roll body 220 is non-circular when viewed in the direction of the center axis of the roll body 220, It may be elliptical.

The fixing flange 230 is designed to be the same as the moving flange in the shape surface except that it is fixed on the shaft 210. The fixing flange 230 may be integrally formed with the shaft 210. [ Alternatively, the fixing flange 230 may be fixed on the shaft 210 as a separate component, and the fixing method in this example may include various known fixing methods such as a screw coupling and a pin coupling. The end of the roll body 220 coupled with the fixing flange 230 is also designed to be the same as the end of the roll body 220 coupled with the movement flange 240. That is, a roll body 220 having ends of a shape complementary to the flanges is fitted between two flanges of the same shape (i.e., a fixed flange and a moving flange), so that the roll body 220 is centered, 220 are prevented from separating from both flanges or slipping on both flanges.

The roll body 220 has an inner diameter D1 that is larger than the outer diameter D2 of the shaft 210 and the outer diameter D3 of the sleeve 242. [ That is, a predetermined gap G1 exists between the roll body 220 and the shaft 210, and a predetermined gap G2 exists between the roll body 220 and the sleeve 242. [ The predetermined intervals G1 and G2 are determined so as not to touch the roll body 220 even if the shaft 210 or the sleeve 242 thermally expands to the maximum radially outward direction.

7 to 9 show a pulling roll 300 according to the second embodiment. FIG. 7 is a plan view of the pulling roll 300 according to the second embodiment, FIG. 8 is a sectional view taken along line VII-VII in FIG. 7, and FIG. 9 is an enlarged view of a portion B in FIG.

7 to 9, in the pulling roll 300 according to the second embodiment, the roll body 320 includes a fixing flange 330 disposed on the shaft 310, And a coil spring 350 is mounted on the outside of the shaft 310.

The moving flange 340 of the second embodiment has a similar shape and function to the moving flange 240 of the first embodiment. That is, the moving flange 340 includes a sleeve 342 and a cap 344 (similar to the moving flange 240 of the first embodiment) to move on the shaft 310 to support the roll body 310.

The shaft 310 is provided with a first spring seat 360 and a second spring seat 370 for seating the coil spring 350. The first spring seat 360 is located at the end 312 of the shaft 310 and the second spring seat 370 is spaced from the first spring seat 360 in the longitudinal direction of the shaft 310. The first spring seat 360 may be integrally formed with the shaft 310. Alternatively, the first spring seat 360, which is a separate part, may be fixed to the shaft 310 by a known fixing method such as screwing, pinning, welding, or the like. The second spring seat 370 has an opening 372 and the second spring seat 370 is movably mounted relative to the shaft 310 in such a manner that the shaft 310 passes through the opening 372. [

The coil spring 350 is disposed between the first spring seat 360 and the second spring seat 370. Since the coil spring 350 is in a compressed state when the roll main body 320 is fixed between the fixed flange 330 and the moving flange 340, the coil spring 350 rotates the second spring seat 370 In the direction away from the end portion 312 of the shaft 310 in the longitudinal direction of the shaft 310. [ The moving flange 340 in contact with the second spring seat 370 is also pressed in the direction away from the end portion 312 of the shaft 310. [ The second spring seat 370 is selectively provided for a more stable seating of the coil spring 350. The pulling rolls of other embodiments may not include the second spring seat 370, in which case the coil spring 350 may contact the moving flange 340 directly.

The roll body 320 is moved in the longitudinal direction of the shaft 310 by the elastic restoring force of the coil spring 350 in a state in which the movable flange 340 is movable relative to the shaft 310 in the longitudinal direction of the shaft 310 In the direction away from the end 312 of the shaft 310. Accordingly, at the normal temperature, the moving flange 340 contacts not only the roll body 320 but also the moving flange 340 relatively moves with respect to the shaft 310 even when the shaft 310 thermally expands in the longitudinal direction at a high temperature Thereby maintaining the contact state of the roll body 320.

The roll body 320 has an inner diameter D5 that is larger than the outer diameter D4 of the shaft 310. [ That is, a predetermined gap G3 exists between the roll body 320 and the shaft 310. [ The predetermined gap G3 is determined not to contact the roll body 320 even if the shaft 310 is thermally expanded to the maximum radially outward direction.

Figures 10 and 11 illustrate pulling rolls 400 and 500 according to the third and fourth embodiments, respectively. The pulling rolls 400 and 500 according to the third and fourth embodiments are cantilevered stub pulling rolls extending over a part of the width of the glass ribbon 148. In the first embodiment And the pulling rolls 200 and 300 according to the second embodiment. Specifically, the pulling roll 400 of the third embodiment shown in Fig. 10 includes a shaft 410, a roll body 420, a fixing flange 430, a moving flange 440 and a coil spring 450 The coil spring 450 is disposed inside the shaft 410. As shown in Fig. The pulling roll 500 of the fourth embodiment shown in Fig. 11 includes a shaft 510, a roll body 520, a fixing flange 530, a moving flange 540 and a coil spring 550, 550 are disposed on the outside of the shaft 510. The coil spring 550 is disposed between the first spring seat 560 and the second spring seat 570.

A portion of the shaft 210, 310, 410, 510 including the coil springs 250, 350, 450, 550 is configured such that the coil springs 250, 350, 450, Only the remaining portion of the pulling rolls 200, 300, 400, and 500 except the externally located portion of the FDM 120 is disposed inside or outside the FDM 120, Lt; / RTI > That is, the above-described portions of the shafts 210, 310, 410 and 510 are not exposed to high temperatures. Thus, the performance of the coil springs 250, 350, 450, 550 is less affected by temperature.

In the pulling rolls 200 and 400 of the first and third embodiments in which the coil springs 250 and 450 are installed inside the shafts 210 and 410, the coil springs 250 and 450 are not exposed to the outside There is no risk that the operator's hand gets caught in the coil springs 250 and 450, so that it is possible to provide the operator with further improved safety. On the other hand, since the pulling rolls 300 and 500 of the second and fourth embodiments have the coil springs 350 and 550 installed outside the shafts 310 and 510, Lt; / RTI >

The pulling rolls 200 and 300 according to the first and second embodiments described above are full-length pulling rolls disposed on the upstream side relative to the stub pulling rolls 400 and 500. The full length pulling rolls 200 and 300 disposed upstream of the stub pulling rolls are exposed to considerably higher temperatures while the glass ribbon 148 is lowered in temperature as it is drawn in the downstream direction 151, 500 are exposed to relatively low temperatures compared to full length pulling rolls 200, Therefore, if the coil spring installed outside the shaft of the stub pulling roll is disposed inside the FDM 120 (as compared with the entire longitudinal pulling roll on the upstream side), the performance of the coil spring does not significantly affect the temperature The coil spring is not exposed to the operator. Figures 12 and 13 illustrate examples of such stub pulling rolls.

12 is a plan view showing a pulling roll according to the fifth embodiment. 13 is a cross-sectional view taken along the line XII-XII in Fig.

The stub pulling roll 600 of the fifth embodiment shown in Fig. 12 includes a shaft 610, a roll body 620, a fixing flange 630, a moving flange 640 and a coil spring 650, (650) is disposed outside the shaft (610). A coil spring 650 is disposed between the spring seat 660 and the moving flange 640. The spring sheet 660 of the fifth embodiment is disposed on a portion of the shaft 610 that is disposed inside the FDM 120. Thus, since the coil spring 650 is disposed between the spring seat 660 and the moving flange 640, the coil spring 650 is disposed inside the FDM 120. Since the coil spring 650 is in a compressed state when the roll body 620 is fixed between the fixed flange 630 and the movable flange 640, the coil spring 650 moves the movable flange 640 to the shaft 610 in the direction away from the end portion 612 of the shaft 610 in the longitudinal direction.

Since the spring sheet 660 of the fifth embodiment is disposed closer to the roll body 620 than the first spring seat 410 of the fourth embodiment, Although the sheet is omitted, the technical idea of the present disclosure is not limited to these embodiments. For example, it is also possible to arrange the spring seat between the coil spring 650 and the moving flange 640 by adjusting the length of the coil spring 650 within a range that sufficiently pressurizes the roll body 620.

In the glass ribbon drawing apparatus 150 according to the embodiment shown in FIG. 2, since the pulling roll 200 according to the first embodiment and the pulling roll 600 according to the fifth embodiment are advantageous in terms of stability, Can be employed as full length pulling rolls and stub pulling rolls, respectively. However, the glass ribbon drawing apparatus of another embodiment may employ the pulling roll 300 according to the second embodiment as the full length pulling roll, and the pulling rolls 400, 400 according to the third or fourth embodiment as the stub pulling roll, 500) may be employed.

The moving flange 240 moves relative to the shaft 210 on the shaft 210 in the pulling roll 200 according to the first embodiment. Unnecessary stress may be applied to the roll body 220 when the glass condensate falls and accumulates in the region of the shaft 210 on which the moving flange 240 moves. That is, in a state where the shaft 210 is thermally expanded at a high temperature, the glass condensate falls on the portion of the shaft 210 that has moved relative to the moving flange 240, and can be accumulated in the portion. Thereafter, when the pulling roll 200 is returned to the normal temperature state and the shaft 210 is contracted to its original length, the accumulated glass condensate on the shaft 210 moves toward the moving flange 240, And is caught by the flange 240. The shrinking force of the shaft 210 is transmitted to the roll body 220 through the moving flange 240 so that the roll body 220 may be damaged or broken.

14A to 14B show a part of the pulling roll according to the sixth embodiment. 14A shows a part of a pulling roll which has not thermally expanded at normal temperature. 14A, the sleeve 242 of the moving flange 240 extends to at least a portion of the region C where the glass condensate of the shaft 210 may fall. The sleeve 242 of the moving flange 240 has an inner surface 252 facing the outer circumferential surface of the shaft 210 and has an end 256 of the inner surface 252, A recess 258 is formed.

14B shows a part of a pulling roll thermally expanded at a high temperature. Referring to FIG. 14B, as the shaft 210 thermally expands in the longitudinal direction of the shaft 210, the shaft 210 moves in a direction indicated by an arrow T relative to the moving flange 240. However, since the sleeve 242 of the moving flange 240 extends to the region C where the glass condensate of the shaft 210 is likely to fall, the glass condensate falls on the sleeve 242 and the accumulated glass G Is formed on the sleeve 242 and the accumulated glass is prevented from being formed on the shaft 210. [ In addition, even if the housed glass condensate falls and accumulates on the shaft 210 (out of the region C), the accumulated glass upon shrinking of the shaft 210 will only enter the recess 258, 240, the moving flange 240 and the roll body 220 are not subjected to stress.

The technical idea of the present disclosure is not limited by the example shown in the above-described embodiment and the accompanying drawings. It will be apparent to those skilled in the art that various substitutions, alterations, and changes can be made without departing from the spirit of the present disclosure.

148: Glass ribbon
150: Glass ribbon drawing device
210: shaft
220: roll body
230: Fixed flange
240: moving flange
250: coil spring

Claims (20)

A pulling roll for drawing glass ribbon,
A roll body including a central passage extending through in the longitudinal direction,
A shaft extending through the central passage and spaced from the roll body to define a gap between the shaft and the roll body;
A first flange disposed on the shaft so as to be movable in the longitudinal direction of the shaft,
And a spring for pressing the first flange in the longitudinal direction of the shaft,
The first flange includes a sleeve slidably engaged with the shaft and a cap extending outwardly from the sleeve,
The cap is in contact with the roll body so that the first flange supports the roll body,
The sleeve including an inner surface facing the shaft and a recess disposed at an end of the inner surface furthest from the roll body. The pulling roll of claim 1, wherein the pulling roll is a full length pulling roll. delete 3. The method according to claim 1 or 2,
Wherein the roll body comprises a fused silica material,
Pooling roll. delete The method according to claim 1,
Wherein the roll body and the cap include a convex portion and a concave portion that receives the convex portion. 7. The pulling roll of claim 6, wherein the convex portion and the concave portion comprise complementary beveled surfaces that contact each other. 8. The pulling roll of claim 7, wherein the inclined surfaces comprise grooves and protrusions that are complementary to each other. The pulling roll of claim 1, wherein the cap is configured to center the roll body with respect to the shaft. delete The method according to claim 1,
Wherein the spring is a coil spring installed inside the shaft. delete 12. The method of claim 11,
A rod installed in the shaft and coupled with the spring,
Further comprising a pin coupling said first flange to said rod,
Wherein the shaft includes at least one slot extending in the longitudinal direction of the shaft such that the pin is movable in the longitudinal direction of the shaft within the slot,
Pooling roll. 3. The method according to claim 1 or 2,
Further comprising a second flange fixed on said shaft,
Wherein the roll body is disposed between the second flange and the first flange,
Pooling roll. delete An apparatus for drawing a glass ribbon,
At least a pair of first pulling rolls including the pulling roll of claim 1,
At least a pair of second pulling rolls disposed downstream from the first pulling roll pair along a pulling path,
Wherein the first pulling roll is a full length pulling roll,
Wherein the second pulling roll is a stub pulling roll,
Apparatus for drawing glass ribbon. CLAIMS 1. A method for glass ribbon drawing,
Drawing the glass ribbon into at least a pair of pulling rolls,
Wherein the pulling roll comprises a shaft, a roll body rotatable with the shaft and spaced from the shaft, a moving flange disposed on the shaft to support the roll body, And a spring for applying a force in the longitudinal direction of the shaft, wherein the roll body includes a fused silica material and is disposed apart from the shaft,
Wherein the drawing step includes moving the moving flange in the longitudinal direction of the shaft by the spring such that the moving flange maintains support of the roll body while drawing the glass ribbon,
The moving flange including a sleeve slidably engaged with the shaft and a cap extending outwardly from the sleeve,
The cap being in contact with the roll body so that the moving flange supports the roll body,
The sleeve including an inner surface facing the shaft and a recess disposed at an end of the inner surface furthest from the roll body,
How to draw glass ribbon. delete 18. The method of claim 17,
Wherein the roll body and the cap comprise a convex portion and a concave portion that receives the convex portion.
delete

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