The present invention relates to tearing and thus separating a web material, and in particular to a method and a structure for separating the web material in a winding machine
A conventional winding machine comprises an upper winding roller, a guide plate, a lower winding roller, and a rider roller. The guide plate is arranged at a location close to and below a circumferential surface of the upper winding roller and forms a channel with the upper winding roller. The upper winding roller, the lower winding roller, and the rider roller form therebetween a winding nip.
A core around which a web material is wound to form a roll of paper is fed by a conveyor to a location beside the upper winding roller and is then pushed by a core inserter into a passage delimited by the guide plate to reach the winding nip where the web material is wound around the core to form the roll of paper, such as a roll of toilet tissue. After completion of the winding operation of a roll of paper, a rotatable arm is controlled to have a speed that is faster or slower than the rotational speed of the upper winding roller in order to induce a speed difference by which the web material is torn and thus separated.
Another known technique uses a method and a structure that realizes separation of web material with physical engagement. For example, a driving arm is positioned against a surface of an upper winding roller arranged in a winding machine to hold down a web material passing through the surface of the upper winding roller. The web material is then torn and thus separated by a pulling force induced by a roll of paper that is formed in a winding nip by wounding the paper around a core.
However, in the above discussed conventional winding machine, care must be taken for the rotatable arm to rotate at a speed not equal to that of an upper winding roller in order to pull apart the web material through a difference in speed. In case the web material is made of a tough material, the speed difference between the rotatable arm and the upper winding roller must be sufficiently large, otherwise the web material would not be pulled apart by the speed difference.
In the known web material separation technique that employs physical engagement, the driving arm must be positioned to physically contact the surface of the upper winding roller. This causes certain concerns about the durability and operation safety of the components and parts of the machine.
Thus, an objective of the present invention is to provide a winding machine comprising a separation mechanism that tears up and separates a web material with a non-physical-engagement type operation.
Another objective of the present invention is to provide a winding machine that comprises an evacuation device and a separation mechanism comprising a suction channel and a passage.
A further objective of the present invention is to provide a method and a device for separating the web material in a winding machine that employ a vacuum suction force to separate the web material.
The solution adopted in the present invention to overcome the problems of the conventional techniques comprises a winding machine that comprises an upper winding roller and a separation mechanism arranged at a location close to and below a circumferential surface of the upper winding roller. The separation mechanism comprises a pivot shaft having an outer circumferential surface and at least one pinch arm having a connecting end and a web engagement end. The connecting end is coupled to the outer circumferential surface of the pivot shaft. The web engagement end extends outward from the outer circumferential surface of the pivot shaft. When the pinch arm is driven by a driving mechanism to rotate the web engagement end of the pinch arm to an engagement position where the web engagement end opposes the upper winding roller, the web engagement end of the pinch arm sucks and holds or guides a web material passing therethrough, whereby the web material is subjected to a pulling force induced by a roll of paper formed in a winding nip to tear and thus separate.
With the solution provided by the present invention, the pinch arm is allowed to tear a web material fed through a winding machine without physical contact with an upper winding roller of the machine. Thus, smoothness and safety of the operation of the winding machine are enhanced and mechanical durability of the components and parts of the winding machine is improved.
The present invention will be apparent to those skilled in the art by reading the following description of preferred embodiments of the present invention and the best modes for carrying out the present invention, with reference to the attached drawings, in which:
With reference to the drawings and in particular to
The guide plates 13 are located at positions near and below the upper winding roller 12 such that a channel 3 is formed between the guide plates 13 and the upper winding roller 12. A winding nip 19 is formed between the upper winding roller 12, the lower winding roller 15, and the rider roller 16. A long tape of web material 4 that has a predetermined thickness and width is fed along a feeding direction I1 by the feed rollers 21 to pass through the perforation device 22 that forms a line of perforations 41 that extends in a direction substantially normal to the feeding direction I1 at a fixed interval (see
Referring to
A driving mechanism (not shown) drives the pinch arm 142 to rotate about the pivot shaft 141. The pinch arm 142 is rotatable in a rotation direction 13 that is opposite to a rotation direction 12 of the upper winding roller 12 so that the web engagement end 142b of the pinch arm 142 is rotated to be selectively set on an engagement position A or off the engagement position A. The rotation of the pinch arm 142 defines a circular rotation locus 142d.
Also referring to
Referring to
A second core 6 is carried forward by one of a number of carriers 171 of the core conveyor 17 to a loading nip of the channel 3 formed between the guide plates 13 and the upper winding roller 12. Afterwards, a core inserter 172 of the core conveyor 17 is automatically turned to push the second core 6 into the channel 3 (as shown in
In a preferred embodiment of the present invention, to allow the web engagement end 142b of the pinch arm 142 to properly attract and hold the web material 4 passing through the channel 3, the rotational speed of the lower winding roller 15 is controlled by a controller (not shown) to reduce and get slightly slowed down at the time when the web engagement end 142b of the pinch arm 142 reaches the engagement position A, whereby the web material 4 gets partially slackened and hangs down (as shown in
When the web material 4 is sucked and held by the web engagement end 142b of the pinch arm 142, the paper roll 51 that is formed by being rolled up in the winding nip 19 applies a pulling force to a right-hand side portion of the web material 4 so as to tear the web material 4, whereby the web material 4 that is so torn forms, at the location where the tearing occurs, a trailing edge 43 in connection with the first core 5 and a leading edge 44 in connection with the second core 6. The trailing edge 43 of the web material 4 keeps moving to and is then wound around the first core 5 to complete the winding operation of the paper roll 51 (see
When the web material 4 is torn, the web engagement end 142b of the pinch arm 142 sucks and holds the leading edge 44 of the web material 4 and the pinch arm 142 is caused to rotate in an opposite direction to bring the leading edge 44 of the web material 4 to the second core 6 that is just fed into the channel 3, to allow the leading edge 44 of the web material 4 to be primarily wound around an outer circumferential surface of the second core 6.
When the pinch arm 142 is rotated to such an extent to get away from the web material 4 and the channel 3, the second core 6 keeps rolling forward along the channel 3, and the leading edge 44 of the web material 4 is completely wound around the second core 6. Meanwhile, the trailing edge 43 of the web material 4 is attached to the paper roll 51 to complete the winding operation of the roll paper 51 (as shown in
Referring to
When the paper roll 51 is being discharged, the rider roller 16 that is connected to a oscillable gripping arm 161 (see
Referring to
Similar to the previous embodiment, when the pinch arm 142 is driven to rotate in the rotation direction 13 to bring the web engagement end 142b of the pinch arm 142 to periodically reach the engagement position A where the web engagement end 142b opposes the upper winding roller 12, the suction opening 142c of the web engagement end 142b of the pinch arm 142 generates a suction force, which helps the web engagement end 142b of the pinch arm 142 to clamp at least a portion of the slack portion 42 of the web material 4 between the second core 6 and the guide plates 13.
When the web material 4 is torn, the subsequent operations (as shown in
Although the present invention has been described with reference to the preferred embodiments thereof and the best modes for carrying out the present invention, it is apparent to those skilled in the art that a variety of modifications and changes may be made without departing from the scope of the present invention which is intended to be defined by the appended claims.
Number | Date | Country | Kind |
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96127668 A | Jul 2007 | TW | national |
This application is a continuation-in-part of Ser. No. 11/902,812 filed on Sep. 26, 2007, entitled “WEB SEPARATOR WITH REVERSE ROTATION MECHANISM FOR TISSUE PAPER WINDING MACHINE”, currently pending.
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Number | Date | Country | |
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Parent | 11902812 | Sep 2007 | US |
Child | 13222058 | US |