KR800001440B1 - Apparatus for automatically connecting the sheet - Google Patents

Abstract

A connection for wound paper materials has turnable frame with two rollers as a connection station near supply. The non-stop paper web spicer uses a new roll of paper with a trangular-shaped leaded and double sided adhesive tape. The new roll is loaded onto a set of brackets. when the amount of paper on roll(Pa) becomes low the rotatable frame(3)is rotated so that the positions of the rolls are reversed. When the frame is stopped the pivotal frames(5a,b) on a paper web connecting stand(6) are pivoted outwardly to a predetermined position.

Description

Automatic measuring device

1 is a side view showing the configuration of the present invention.

2 is a front view of the ground stand of the present invention.

3 is a perspective view of line III-III of FIG. 2;

4 is an operation explanatory diagram.

The present invention relates to the transfer of sheet material such as paper. Therefore, the present invention can be used for the transfer of paper in a machine for supplying paper with a printed pattern. In these machines, the plate material is released from the rolls while feeding the plate material. If the plate material is almost released from the scroll, it must be connected to the leading edge of the second scroll in order to continue transferring the plate material in this way.

However, the above operation has some problems that have not been satisfactorily solved to date. These problems arise from the fact that sheet materials, such as paper, are not wound to specification. Such plate materials have a front face and a back face, with some manufacturers winding the plate with the front side facing the axis of the roll, and another manufacturer winding the plate with the front side outside the axis of the roll. As a result, when connecting a scroll with another scroll, the fronts of the plate material may be flipped. Thus, the outer surface of the final product has an irregular shape.

It is known to implement the above operation by hand. To manually connect the leading edge of the scroll and the tail end of the loose scroll requires the action of cutting off the loose plate material and connecting it with the leading edge of the new scroll. This manual operation prevents the loss of sheet material and requires highly skilled techniques for efficient connection. In addition, there is a need to temporarily reduce the rate of transfer of the plate material or to stop the transfer so as to enable a change of supply from one roll to another and to detect unnecessary excess plate material in the replaced roll. Reducing or interrupting the transfer rate of sheet material results in quality loss of the final product. Qualitative losses of the product occur especially when the produce is dried. For example, loosening of operation results in excessive drying of the product.

Solving the above problem is particularly important in view of the fact that the production speed of printed materials such as printed paper has increased greatly until recently. In addition, the above problems must be solved in order to produce high-quality uniform standards.

It is a main object of the present invention to provide an apparatus for solving the above problems.

It is an object of the present invention, in particular, to provide a device which allows continuous feeding without slowing down or speeding up the feeding of many rolls.

In particular, the rotation speed of the bird roll is adjusted so that the speed of the plate material released from the bird scroll is almost the same as the speed of the material released from the roll released, and the plate material and the rod of the bird roll are made so that the continuous supply of the plate material is made. It is another object of the present invention to provide a device that allows attachment of the entire roll to a plate material.

It is an object of the present invention to provide an apparatus for minimizing the consumption of plate material in performing the above operation.

It is also an object of the present invention to provide a device that can be operated simply and easily while performing the above operation efficiently.

According to the present invention, at some position, when the supply of the first scroll is nearly finished, the first scroll is moved from its original position and the second scroll is moved to that position. At this time, the feed of the first roll is not stopped. The web of the first roll is then squeezed onto the second scroll, and the second scroll is rotated without slipping with the web of the first roll.

The first roll of web that rotates with the second roll is pressed against the outermost part of the second roll so that the plate material begins to be released from the second roll, and eventually the first roll of web is compressed between the first roll of web and the second roll of web. It is cut at the position between the points, and the speed continues on the second scroll, and the first scroll stops rotating.

The above operation is performed by the frame structure, which supports rotational movement about the axis located between the first and second scroll axes. The first scroll is in the transport position while the plate material is released, and the second scroll is in the position to occupy the transport position. Thus, as the frame structure rotates, the first scroll is released from the transmission position and the second scroll is moved to the transmission position. The combined compression rotating structure compresses the first roll of webs onto the second roll to rotate the second roll without slipping between the first roll of webs and the rotating second roll. The adhesive structure is joined to the compression, rotating structure by bonding the outermost portion of the second roll to the web of the first roll to release the plate material from the second roll. The cleavage relief is connected to the combined compression rotating structure such that the first roll of web is bonded to the outermost portion of the second roll, then the first roll of web is cut and in this way the transmission continues from the second roll and the transfer of the first roll is It is over.

In FIG. 1 the right part of the sheet material supply device 1 is illustrated, which device 1 comprises a rotatable frame device 3 which is illustrated in FIG. The position supports the free-rotating movement of the roll-rolled Pb and the nearly rolled-rolled Pa, where the web is guided, to continue the transfer of plate material without interruption when it is replaced from the scroll Pa to the roll Pb. The frame structure 3 comprises a pair of side plates 2 which support rotational movement in the horizontal shaft 7, and the shaft 7 is supported so that the side plates 2 support the free rotational movement. Include a suitable stand or base (4) to provide. Thus, the plate 2 can rotate around the transverse axis of the shaft 7 and maintain the proper distance by a horizontally extending rob so that the distance between the plate 2 accommodates the plate rolls Pa and Pb. Enough to do it.

A connecting device 6 connecting the rear end of the almost rolled sheet material to the head end of the rolled sheet material is illustrated on the left side of the device 1 in FIG. The device 6 comprises a stationary frame 18 which forms part of the support structure according to the structure of the invention. This frame 18 has a pair of opposing upright beams and horizontal beams extending horizontally, and are connected in horizontal beams between the heads of the upright beams as shown in FIG. As illustrated in FIG. 1, the portion 18 of the support structure comprises a top compression rotating structure, which structure is a pair of rotatable arms or levers 5a and a pair of compression drives. Roll 29a. And part 18 comprises a bottom compression rotating structure, which comprises a pair of arms or levers 5b and a pair of compression drive rolls 29b. The top compression rotating structure moves clockwise from the nearly upright position illustrated in FIG. 1 to the illustrated operating position, so that the roll 29a compresses the web of the almost unrolled scroll Pa to a new feed scroll Pb. In the same way, the lower compression rotating structure moves counterclockwise from the stop position to the illustrated operating position, so that the roll 29b operates with the feed roll Pb.

The side plate 2 of the rotatable support structure 3 has protrusions 8a, 9a, 8b, 9b as illustrated, which has a first roll Pa and a second roll Pb. Located in the space between. A pair of protrusions 8a (only one shown in FIG. 1) has empty rolls 10a at the outer distal end for free-rotating motion, and similarly with other protrusions 9a, 8b, 9b ( 11a), 10b, and 11b. The pair of upright frames 18 of the support structure have a pair of empty rolls 35a and 35b for free-rotating motion as illustrated in FIG. These rolls then form a horizontally extending opening 12 therebetween, through which the sheet-like plate material is transferred. The web emanating from the almost exhausted scroll Pa of FIG. 1 extends through this opening 12 formed between the empty rolls 35a and 35b. Empty rolls 10a and 11b are located above and below the second roll Pb, and the plate material released from Pb is sufficiently through the opening 12 to the roll 10a to form a straight line illustrated in FIG. Stretched There is no straight line connecting the roll 11b from the opening 12 or it is located outside the roll Pb. This relationship is obtained when the rolls 11a and 10b are located closest to the opening 12. As a result of this arrangement, the second scroll Pb is positioned at the transmission position occupied by the first scroll Pa without any aid between the web of the scroll Pa and the second scroll Pb while moving to the transmission position illustrated in FIG. Done.

In the particular example illustrated in FIG. 1 each side plate 2 has projections 13a and 13b fixed for moving the roll of plate material. These protrusions 13a and 13b are symmetrically located opposite to the horizontal shaft 7. A roll of plate material may provide another arrangement that is located at an adjacent distal end of the side plate 2. In this modification, the projections 8a, 9a, 8b, 9b are rearranged to move the new scroll to the transfer position and at the same time to release the almost exhausted scroll from the transfer position (3). The web of nearly exhausted scrolls during the rotation will provide the above relationship without attracting the new scrolls.

The frame structure 3 of the device 1 is in cooperation with the device which senses the position of the frame structure 3 and stops the rotational movement when the second scroll Pb of the plate material reaches the position of the first scroll Pa. . Such an arrangement may be provided for the sensing device to detect when the frame structure 3 has moved a new roll to a transfer position and rotated at an angle sufficient to stop the rotation of the frame structure 3 to provide. Such sensing devices include optical or mechanical elements.

In the particular example in FIG. 7, the shaft 7 is illustrated which is fixed to the shaft plate 2 and connected to the reversible motor 50 by any suitable gear or other transmission means. This reversible motor 50 is illustrated in the electrical circuit 52 to rotate in the selected direction by manually closing the switch 54. It is well known how switch 54 is connected to motor 50 to provide a selected direction of rotation.

The shaft 7 located on the stand 4 has an electrical non-conducting protrusion 56 and a conductive strip 58, as shown in FIG. 7, to open the switch when the solenoid 62 is energized. There is a pair of contact ends 60 such that the circuit is configured through a solenoid 62 connected to a switch 54. The operator keeps the switch 54 closed when he wants to rotate the frame device 54 in any direction. If the switch 54 is closed by hand for a few seconds, the conductive strip 58 leaves the stretched position between the contact ends 60 such that the solenoid 62 is deactivated and the switch 54 remains closed. . When the frame device 3 is driven in either direction, the strip 58 contacts the other pair of contact ends 61 to activate the solenoid 62 to open the switch 54. The rotational movement of the frame structure 3 is then automatically stopped. In the example illustrated in FIG. 7, the frame structure 3 rotates approximately 180 ° in either direction to enable automatic stop of the frame structure 3 when the second scroll reaches the transfer position.

In Figures 2 and 3, the upright supports of the frame 18 are supported by a pair of elongated shafts 14a and 14b for free rotational movement, which extend horizontally between the upright supports and provide suitable bearing rotation. I'm exercising. As described above, the rollers 35a and 35b that determine the opening 12 are tubular. Plate material such as paper is transferred through the opening 12 to achieve a smooth supply of plate material.

The upper shaft 14a serves to support the pair of levers 5a, and the upper end of the lever 5a is engaged with the compression rotating structure. The lower shaft 14b serves to support the lever 5b, and the lower end of the lever 5b is coupled to the compression rotating structure. Thus, the roller 35a is located between the distal ends of the lever 5a, and the lever 5a rotates on the shaft 14a. And the roller 35b is located between the distal end of the lever 5b, 5b rotates on the shaft 14b, and is located on the same plane as 5a.

The fan-shaped gear 17a also rotates on the shaft 14a and is fixed to the lever 5a toward the outside. In this manner, the fan gear 17b also rotates on the shaft 14b and is fixed to the lever 5b toward the outside. The pair of pinions 16a, which are connected by suitable shafts, are engaged with the fan gear 17a to rotate with the aid of the upright support of the frame 18, and are driven by the motor 15a by a suitable transmission device. The pair of pinions 16b are also connected between the upright structures of the frame 18 by a suitable shaft, rotate in engagement with the fan gear 17b, and are driven by the motor 15b. These motors are supported on the upright support of FIG. 2 and are driven from a suitable power source as follows. As illustrated in FIG. 3, the upper lever 5a moves from the stop position clockwise to the operating position, and then back to the stop position illustrated in FIG. Then, the lower lever 5b moves from the illustrated stop position to the operating position counterclockwise to the stop position again.

The upper end of the lever 5a rotates with the help of an elongated shaft extending horizontally, which becomes a tube roller 19a which is a guide guide roller. In this way the lower end of the lever 5b rotates with the help of a horizontal shaft extending between them, which serves as a tubular induction roller. These rollers 19a and 19b are rotatable freely. The elongated cutters 20a adjacent to each other at some distance from the guide roller 19a form a cutting device for the following purposes. The cutter 20a is shaped like a cutting knife that extends horizontally and has a distal end connected to a pair of sleeves or loops, which are fixed to a shaft extending through the guide roller 19a. . Thus, when this shaft is rotated, the cutting device 20a rotates around the axis of the roller 19a. In the same manner, the lower end cutting device 20a has an elongated blade shape, the distal end of which is fixed to a ring or a sleeve, and is fixed to a shaft extending through the lower side guide roller 19b. These cutters 20a and 20b have the same width as the guide rollers 19a and 19b. The levers 5a, 5b carry drive motors 28a and 28b at their outer edges, respectively, which are driven in a suitable manner and connected with shafts extending through rollers 19a and 19b. Then, the cutter is rotated to cut the plate material as follows.

The compression roller 21a, which is located along the central position of the guide roller 19a, forms an adhesive structure that adheres the web of birds to the web of almost exhausted scrolls. This adhesive roller 21a is supported by a shaft extending horizontally and elongately, and the distal end of the shaft is supported by a free end of a pair of levers connected to the shaft extending through the guide roller 19a. Thus, these levers are located outside the ring or sleeve that connects the blade to the shaft extending toward the guide roller 19a. These levers, which bear the shaft with the adhesive roller 21a, are connected with the shaft extending through the roller 19a to rotate with the shaft when the motor 28a is activated. Thus, the adhesive structure 21a and the cutting structure 20a operate when the motor 28a is activated. The lever with the shaft attached with the adhesive structure 21a can be fixed to the shaft with the cutter 20a, which is activated by the motor 28a by the motor 28a together with the shaft. The roller 21a forms a friction clutch that compresses the almost exhausted roll web onto the new roll while the rotating shaft is rotated at an angle sufficient to cut the plate material released from the almost exhausted roll.

In the same way, the compression roller or adhesive structure 21b is arranged along the central portion of the lower guide roller 19b, is carried by the shaft, connected to the shaft extending through the roller 19b, and the lower motor 28b. It is accompanied by the free distal end of the pair of levers driven by.

The pair of lever structures 23a support a horizontally extending shaft, which carries the pair of drive rollers 29a. In this manner, the lower lever structure 23b supports the horizontally extending shaft, which carries a pair of lower driving rollers 29b. The adhesive structures 21a are arranged with a little space between the drive rollers 29a, and in the same manner, the adhesive structures 21b are arranged with a little space between the drive rollers 29b. The distance between the rolls 29a is longer than the length of the adhesive roller 21a, and the distance between the rolls 29b is longer than the length of the adhesive roller 21b.

As illustrated in FIG. 2, the right end of the shaft with the drive roller 29a has a belt or chain 30a on a pulley or sprocket wheel fixed to the shaft 24a which can freely rotate the gear 24a and the lever structure. It is fixed by a pulley or sprocket whoel connected by This pulley or sprocket wheel fixed to the shaft 22a is driven when the shaft 22a is driven. And for this purpose, the shaft 22a carries another pulley or sprocket wheel connected to the belt or chain 31a adjacent the right end, which belt or chain is fixed to the shaft 14a. It is wound around a locale wheel, and this shaft 14a is driven from the motor 33 via a suitable transmission device 32. Through this transmission device 32, the motor 33 serves to drive the shaft 14b carrying a pulley or sprocket wheel driven by the belt or chain 31b, which belt or chain carries the shaft 22b. By driving a pulley or sprocket wheel fixed to it to rotate the shaft with an accessory pulley or sprocket wheel for driving the belt or chain, the belt or chain being the right end of the shaft with the drive roller 29b. Drive the pulley or sprocket wheel fixed to it. The motor 33 is a reversible motor, and the roll 29b is also rotated clockwise when the driving roll 29a is rotated clockwise through the above-described transmission device. Conversely, when the roll 29b rotates counterclockwise, the roll 29a also rotates counterclockwise. The lever structures 23a and 23b are accompanied by a known detection in order to detect the rotational speeds of the driving rolls 29a and 29b. The detector is electrically connected to the motor 33 to control the motor to drive the rolls 29a and 29b at a speed equal to the speed at which these rolls are driven by external forces. In the device according to the invention, the external force will be the rotational speed exerted on the rolls 29a and 20b by the web of plate material released from the almost exhausted scroll Pa.

The lever 5a carries an optical sensor 34a at the outer end, and the lever 5b carries an optical sensor 34b at the outer end. The detector is located outside the levers 5a and 5b and is located outside the sides of all the rollers, cutters and rolls Pb in the transmission position. This sensor senses the outer part of the roll Pb to stop the rotation of the lever by the motor 15a. Thus, the operating position of the upper compression rotating structure is determined. In the same way, the bottom detector 34b determines the operating position of the bottom compression, rotating structure. Thus, the movement of each compression rotating structure to the operating position can proceed without interrupting the continuous transmission of the plate material of almost exhausted scroll Pa. At the same time the operating position is determined according to the specific diameter of the scroll Pb, so that the other diameter scroll Pb is suitably handled according to the manner and the device according to the invention.

The manner in which the inventive structure described above operates in accordance with the manner of the invention is described below.

Figure 4a shows the location of all structures when the scroll is almost exhausted and must be replaced by the second scroll. The scroll Pa is then placed in the transmission position. Thus, in this position the roll Pb is supported by the projection 13a of the frame structure 3, and the sheet material such as paper is released through the opening 12 as described above. The second scroll Pb is supported by the protrusion 13b of the frame structure 3 while the crane Pa is consumed as illustrated in figure 4a. The frame structure 3 rotates clockwise B or counterclockwise C when the diameter of the roll Pa is reduced to at least some extent. In this way the first roll Pa is moved away from the transfer position and the second roll Pb is moved to the transfer position.

The direction of rotation of the frame structure 3 is selected according to the direction in which the paper is released from the first roll Pa and the way in which the second roll Pb is wound.

Assuming that the plate material having different front and back shapes is released from Pa with the front face up, two of FIGS. 5A and 5B are possible. So one manufacturer winds the front inward and the other winds the front out. The front side is marked with F and the rear side is indicated with R. If the roll Pb is rolled up on the front side F and the front face of the sheet of Pa is released upward, the operator holds the roll Pb on the projection 13b so that the roll material Pb is rotated clockwise to release. . In other cases, when the sheet material is released as shown in figure 5b, the scroll Pb is fixed as shown in figure 5b, and the web of plate material is released from the outer portion of the scroll with the scroll rotating counterclockwise. In this way, the plate material released from the roll Pb face up may have the same direction as the plate material released from the scroll Pa. Assuming that the front face of the sheet material faces outward as shown in figure 5b, the frame structure 3 rotates clockwise as shown in figure 4a and arrow B, and the web of scroll Pa is positioned on the scroll Pb. It becomes the position of FIG. 4b. Thus, as transmission continues from the roll, the web is released in the same direction as the web of the scroll Pa. The rollers 11a and 10a prevent the web of the roll Pa from encountering the scroll Pb while the frame structure 3 rotates from the position in FIG. 4a to the position in FIG. Transmission continues without any interruption from the scroll.

In other cases, if the front face of the sheet material is wound inward, as shown in figure 5a, the frame structure 3 is rotated in the direction of arrow C in figure 4a so that the web of Pa is positioned below the web of Pb. At the same time, it is rollers 10b and 11b that prevent the web of Pa from encountering the bird roll Pb during the positional movement.

When the front face of the web of the scroll Pa faces downward as shown in figure 4a, the scroll Pb illustrated in figure 5b is fixed to the frame structure in the position illustrated in figure 5c, and the frame structure 3 is indicated by arrow C. Rotation in the direction of continues transmission from the bottom of the bird roll face down. If the front face of the scroll Pa faces downward, and the scroll Pb is the same as the drawing 5a, the scroll is fixed to the frame structure 3 as shown in the drawing 5d, so that the frame structure 3 rotates clockwise B so that the front face is down. Enables continuous transmission of bird rolls towards.

Rollers 10a, 10b, 11a, and 11b ensure that the plate material of the first roll does not come into contact with the second scroll while the position is moved, so that it is smoothly transmitted without any interference while the position is moved. It is possible to be continuous.

When the second scroll Pb reaches the transmission position shown in Figs. 4B and 4C, the motors 15a and 15b are activated to move the upper and lower compression rotating structures from the stationary state to the operating state. This movement is then terminated by the sensors 34a and 34b described above. In this way, the pair of compression-rotating structures occupy the correct position relative to the bird scroll. In the case of FIG. 4B, it is the upper drive roll 29a that engages the web of the roll Pa, and in the case of FIG. 4C, the lower drive roll 29b. With the levers 5a and 5b in the operating position, the motor 33 is activated to rotate in either direction to drive the drive rolls 29a and 29b.

In the case of FIG. 4B, the rolls 29a and 29b rotate clockwise, and in the case of FIG. 4C, the rolls 29a and 29b are driven counterclockwise. So the rolls 29a and 29b which engage the web of the first roll Pa are driven from the motor 33. Then, the above-described detector senses the speed required to rotate the driving roll 29a or 29b so that the roll is driven without any slippage between the roll 26a or 29b and the web. The motors 27a and 27b are activated to move the lever structures 23a and 23b while rotating the rolls 29a and 29b at the same speed as the web being released from the scroll Pa, and the driving roller ( 29a) and 29b are moved inward to face the lateral direction of the roll Pb.

In the case of FIG. 4B, this action causes the roll 29a to compress the web of Pa to Pb to rotate with the web, while simultaneously rotating the roll Pb counterclockwise as shown in FIG. 4B at the same speed as the web released from the scroll Pa. Drive it. In the case of FIG. 4C, it is the lower drive roll 29b that compresses the almost exhausted roll of web to the roll and rotates the roll with the pressure applied through the web.

As described above, the upper and lower compression rotating structures simultaneously move from the stop position to the movement position. In this way, when the structure is brought to the position of FIG. 4b, the lower roll 29b is directly rotated by acting on the roll Pb, and at the same time the roll 29a acting through the web released through the scroll Pa. Help. In the case of FIG. 4C, the driving rolls 29a and 29b rotate counterclockwise, the roll 29a is directly acted on the new feed scroll Pb, and the driving roll 29b is almost exhausted. It acts on the roll Pb through the web released from it. However, only the upper compression rotating structure as shown in FIG. 4B or the lower compression rotating structure as shown in FIG. 4C moves to their operating position, acting through a web that is released from the scroll where the second scroll Pb is almost exhausted. The arrangement method driven only by the driving roller is equally possible in both cases.

As illustrated in FIG. 6, the producer of the roll Pb usually has a narrow free end portion 72 positioned at the middle of both ends at the outermost portion 70 so as to have a triangular shape as shown in FIG. So, the leading edge of each scroll is pointed in a triangle. In order to secure the outermost portion 70 to the next inner 74, an elongated strip 76 extends over the free end portion 72 to the portion 74 so that the strip 76 extends to the next inner portion. And hold the wound on the plate material. In this way, the roll is prevented from dislodging while transporting. Since both surfaces of the strip 76 are sticky, the exposed surface of the strip 76 shown in FIG. 6 is made of a sticky material that is sensitive to pressure. If the plate material acts on the exposed surface of the sticky strip 76 and breaks away from the portion 74, the portion 70 is separated from the portion 74. The reason is that the sheet applied to the outer surface of the strip 76 is in contact with an area larger than the contact area between the strip 76 and the inner region 74, and generally with the strip 76 and the outer region 70. This is because the contact area is wider than the contact area with the area 74.

The position of the driving roller 29a in the case of FIG. 4B is illustrated in FIG. These drive rolls 29a are thus located outside of the strip 76 in the drawing. As a result, the web of scroll Pa does not adhere to strip 76, but instead the web of Pa continues to be released from Pa while the scroll Pb rotates at a speed corresponding to the web speed of the scroll Pa. Of course, in the case of FIG. 4C, the roll 29b also has the same relationship to the strip 76 as 29a. Thus, the spacing of the rolls 29a or the spacing of 29b is such a spacing that these rolls rotate outside the strip. Thus, while the spent scroll's web is compressed in the bird's roll, the bird's roll rotates without loosening the plate material. When the plate material of the first roll Pa is almost exhausted, in the case of FIG. 4B or in FIG. 4C, the motor 28a moves the compression roller 21a to act on the web of the roll Pa (Fig. 4B). In the case of FIG. 4C, the compression roller 21b is moved to act on the web of almost exhausted scroll. In any case, this tightly compresses the web to the strip 76 to separate the outer area 70 from the inside 74 of the roll, and in this way the webs of the roll and the spent roll are attached to each other and plated from the roll. The material begins to loosen. Thus, the compression rollers 21a and 21b together with the associated structure form an attachment device, which acts to compress the second roll of plate material onto the first roll of plate material, during which the second scroll is compressed. Without the action of a rotating device, this compression rotating device only serves to rotate the second roll before the action of attaching the second roll of plate material to the first roll of plate material. As soon as the plate material starts to be released from the roll, in the case of Fig. 4b, the cutting device 20a or in the case of Fig. 4c, the cutting device 20b is used to cut the plate from the spent roll at the web connection position of the bird and the exhausted scroll. The material is cut to end the feed of the roll Pa and continue feeding from the roll Pb without interruption. The motors 15a and 15b and the motors 27a, 28a, 27b and 28b are all driven in opposite directions so that the devices return to the stop position and the motor 33 is stopped and the roller ( The driving of 29a) and 29b also stops.

In the device described above the cutter is located at the top of the attachment rollers 21a or 21b, but the first time a change in the paper thickness supplied through the opening 12 is detected (this is the moment when the rolls of webs It is possible to provide an apparatus in which the cutter is operated after a predetermined time has elapsed from the time of bonding). A sensing device that detects increased thickness by attaching two webs can be used to operate a cutter located at the bottom of the extrusion roller 21a or 21b at a position suitable for cutting a web of nearly exhausted scroll Pa. In either case, the operating time of each device should be sufficient time for the cutting device not to cut the web until the spent roll web is attached to the web of the bird roll.

It should be noted that with the device according to the present invention no matter what direction the sheet material is wound in, we can perform highly accurate plate material linking in the desired direction. In addition, the method and apparatus of the present invention may also use feed rolls of different radii. Moreover, no need for highly skilled operators, no need to interrupt the supply of plate material, the continuous supply of plate material can be continued and the delivery of feeds from one scroll to another can be done automatically and accurately in a fast way. .

Claims (1)

When the first scroll is exchanged for the second scroll, the supply of the first roll is connected to the second scroll, without the interruption of the supply of the plate, and the second scroll is the first scroll of the second scroll. It should be able to be pressed against the outer attachment and attached to the plate material of the first roll, and the glued portion described above will be axially narrower than the width of the plate on the second roll, and the frame device will feed the first roll while the plate material is released. While retaining its position, it supports the first and second scrolls, the support supports the frame device that moves the plate material to the supply position while the plate material continues to be released, and the compression rotator supports the second scroll. First roll web from above and second roll web Compressing, and at the same time rotating the second scroll, the support supports the compression rotator moving from the stationary position to the operating position, and the gluing device is connected to the compression rotator but is different from the axial direction of the compression circuit arrangement. At a distance from the axis of the second scroll, axially aligned with the adhesive portion of the outermost region of the second scroll, and the first roll of plate material in the outer region of the second scroll after the rotation of the second scroll is initiated by the compression rotary device. Compressing, adhering the second roll of plate material to the first roll of plate material so that the plate material begins to be released from the second roll at the same time as the first roll of plate material is transferred, and the cutting device is connected to the gluing device to connect the web of the first roll. Is connected to the outer part of the second scroll The web of plate material is cut from the first roll to terminate the supply of the first roll and continue the supply of the second roll, and the above-described frame apparatus supports the first and second rolls rotating about parallel horizontal axes, as described above. The holding device supports a frame device that rotates about an intermediate axis located between the first and second roll rotational axes during the rotational movement of the frame device which disengages the first scroll from the supply position and moves the second scroll to the supply position, as described above. The retaining device includes a stand and a pair of hollow rolls, which are provided by the stand at the height of the feed position, which itself constitutes the mechanism through which the web of plate material exits from the scroll in the feed position, Extends below and above the empty roll and rotates from the stop position to the operating position. And a pair of compression rotators to allow the web of rolled plate material at the feed position to be released from the top or bottom of the scroll, each compression rotator having a gluing device and a cutting device connected thereto to operate together. Automatic counting device.

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