Automatic cutting and winding apparatus for a web-like material such as a film

In the known turret type automatic cutting and winding apparatus for automatically cutting a web-like material such as a film or the like, in order to eliminate scratches and/or uneven deformation which can be generated at a cut end portion of a web-like material during tapeless winding also to obviate creases which might occur in a mill roll, an electrostatic charging means is mounted on a swingable arm for giving electrostatic charge to a cut end portion of the web-like material and/or to a surface of a core, a cutter and a pair of press members are swingably mounted and oppose each other across the web-like material, and the arrangement is such that the press members may be positioned with the cutter when at a cutting position therebetween.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The present invention relates to an automatic cutting and winding apparatus 
for a web-like material such as a film, which automatically cuts a 
web-like material such as a film and continuously performs rewinding. The 
present invention can also be used for winding a web of paper, cloth or 
the like, and is applicable to a biaxial oriented film manufacturing 
system, an unoriented film manufacturing system or the like. 
2. Description of the Prior Art 
A winding system for a web-like material such as a film (hereinafter called 
simply "film") in which a medium such as an adhesive tape is not used on a 
core but a film is wrapped directly around a core (hereinafter called 
"tapeless winding system") has been being given attention in various 
fields because damage of films in inner layers of a mill roll caused by 
unevenness of a core surface due to an adhesive tape or the like are not 
present and also the work of removing remaining adhesive materials upon 
reuse of the core is unnecessary. However, there still remain problems 
resulting in scratches being generated at a cut end of a film and winding 
creases being generated in a mill roll formed by winding the film on a 
core, and therefore, development of a more complete system has been 
strongly desired. 
SUMMARY OF THE INVENTION 
It is therefore one object of the present invention to provide an improved 
automatic cutting and winding apparatus for a web-like material such as a 
film in which scratches are not generated at a cut end portion of a 
web-like material, uneven deformation does not occur at a cut portion of a 
web-like material, and creases are not generated during winding in a mill 
roll. 
According to one feature of the present invention, there is provided a 
turret type automatic cutting and winding apparatus for automatically 
cutting and winding a web-like material such as a film by means of a press 
roll, press members and a cutter, in which electrostatic charging means 
mounted on a swingable arm for giving an electrostatic charge to a cut end 
portion of the web-like material and/or onto a surface of a core is 
provided, a cutter and a pair of press members are swingable relative to 
and oppose each other across the web-like material, and the arrangement is 
such that at a cutting position the press members may be positioned with 
the cutter placed therebetween. 
According to another feature of the present invention, there is provided a 
turret type automatic cutting and winding apparatus for automatically 
cutting and winding a web-like material such as a film by means of a press 
roll, press members and a cutter, in which electrostatic charging means 
mounted on a swingable arm for giving an electrostatic charge to a cut end 
portion of the web-like material and/or onto a surface of a core is 
provided, a cutter and a pair of press means are swingably mounted so as 
to swing relative to and oppose each other across the web-like material, 
and the arrangement is such that at a cutting position the press members 
may be respectively disposed to the front of and the rear of the cutter 
which is preliminarily standing by. 
According to still another feature of the present invention, there is 
provided the above-featured automatic cutting and winding apparatus for 
winding a web-like material such as a film, in which swing acceleration 
means is associated with the press members. 
According to yet another feature of the present invention, there is 
provided the above-featured automatic cutting and winding apparatus for a 
web-like material such as a film, in which the cutter is provided with a 
heater and has a plurality of semi-circular edges that are contiguous. 
According to a further feature of the present invention, there is provided 
a turret type automatic cutting and winding apparatus for automatically 
cutting and winding a web-like material such as a film by means of a press 
roll, support members and a cutter, in which electrostatic charging means 
for giving an electrostatic charge to a cut end portion of the web-like 
material and/or to a surface of a core is provided, a cutter and a pair of 
support members are swingably mounted so as to swing relative to and 
oppose each other across the web-like material, and the arrangement is 
such that at a cutting position the cutter may come in between the pair of 
support members which are preliminarily standing by. 
According to a yet further feature of the present invention, there is 
provided the above-featured automatic cutting and winding apparatus for a 
web-like material such as a film, in which a locus of movement of the 
cutter during cutting extends along a surface of a core. 
According to a still further feature of the present invention, there is 
provided the above-featured automatic cutting and winding apparatus for a 
web-like material such as a film, in which an expander roll, positioned 
close to a mill roll which is formed of the web-like material wound around 
a core with a small interval held therebetween so that the expander roll 
does not contact the mill roll, is provided. 
According to the present invention, upon winding a film on a new core, a 
swingable arm swings, an electrostatic charge is given to a cut end 
portion of a film and/or onto a surface of a core by electrostatic 
charging means mounted on the swingable arm to make the cut end portion of 
the same film adhere to the surface of the core, and at the same time 
winding is commenced. Subsequently, upon cutting the film, a pair of press 
members which are opposed to a cutter with the film extending 
therebetween, depress the film towards the cutter while both of the press 
members are pressing the film, or the cutter is moved between the pair of 
press members, and thereby cut the film while tension in the film is 
increased. 
In addition to the above-described operation, according to one aspect of 
the present invention, upon cutting a film, a pair of press members which 
are opposed to a cutter with the film extending therebetween are depressed 
at a high speed towards the cutter by swing acceleration means while both 
of the press members are pressing the film, thereby cutting the film while 
tension in the film is increased. 
According to another aspect of the present invention, upon cutting a film, 
a cutter which is opposed to a pair of support members with the film 
extending therebetween comes in between the pair of support members, 
thereby cutting the film while tension in the film is increased. 
Furthermore, according to still another aspect of the present invention, a 
film is cut by a cutter moving along that intercepts a surface of a core. 
Also, according to yet another aspect of the present invention, an 
expanding capability of an expander roll positioned close to a mill roll, 
which is formed of a film wound around a core, with a small interval being 
maintained therebetween so that the expander roll does not contact the 
mill roll, is employed to remove creases from the film just prior to 
winding. 
Due to the above-described constructions and operations of the automatic 
cutting and winding apparatus for a web-like material such as a film 
according to the present invention, the problems in the automatic cutting 
and winding apparatuses of the prior art such as the generation of 
scratches at a cut end portion of a web-like material, the occurrence of 
uneven deformation at a cut portion of a web-like material, and the 
generation of creases in a mill roll formed by winding a web-like material 
around a core, can be eliminated entirely. 
The above-mentioned and other objects, features and advantages of the 
present invention will become more apparent by reference to the following 
description of preferred embodiments of the invention taken in conjunction 
with the accompanying drawings.

DETAILED DESCRIPTION OF THE PRIOR ART 
Before entering the description of the preferred embodiments of the present 
invention, a construction and an operation of one example of a turret type 
automatic cutting and winding apparatus for a film heretofore used will be 
described in greater detail with reference to FIGS. 29 to 34. In these 
figures, reference numeral 1 designates a film, reference numeral 2 
designates a new core around which a cut film is to be rewound, and the 
core 2 is mounted on one arm of a turret 4 so as to be rotationally driven 
in the direction of arrow A by means of a driving device not shown. 
Reference numeral 3 designates a guide roll that is pivotably supported at 
an end of another arm 4a of the turret 4 that is disposed 90.degree. from 
the arm on which the core 2 is mounted. Reference numeral 5 also 
designates a guide roll, and this guide roll 5 is pivotably supported at a 
film feed end of a frame 10. Additionally, there is provided a wrapping 
roll 6 which can be pivoted in the direction of arrow B so as to traverse 
a middle portion disposed between the guide roll 5 and the above-described 
core 2. The wrapping roll 6 is pivotably supported at a tip end of a 
swingable arm 7, and the other end of the same swingable arm 7 is 
pivotably supported at one end of the above-mentioned frame 10 on the side 
for winding a tape. The above-mentioned wrapping roll 6 is adapted to 
pivot so as to traverse the middle portion disposed between the guide roll 
5 and the core 2 as described above and to reach the rear side of the core 
2. 
Reference numeral 8 designates a cutter which is mounted at a tip end of an 
arm 9, the other end of which is likewise pivotably mounted at an 
appropriate position located on the frame 10. This arm 9 is swung by a 
driving device not shown in synchronism with the pivoting of the 
above-mentioned wrapping roll 6, and the cutter 8 at the tip end of the 
arm 9 is adapted to cut the film 1. 
Describing now the operation of the above-described apparatus, in FIG. 29 
the film 1 is being wound around a core (not shown) mounted at a remote 
end of the turret 4, and if a mill roll being wound around that core 
reaches its full volume, then the wrapping roll 6 is pivoted in the 
direction of arrow B so as to urge the film 1 against the core, and the 
state shown in FIG. 30 is attained. 
Subsequently, the cutter 8 descends to cut the film 1 as shown in FIG. 31, 
then a film end a is forced to enter a gap b between the core 2 and the 
wrapping roll 6, and thus, wrapping is finished. 
However, in the case of the prior art apparatus as described above, in 
order to wrap in the cut end a of the film 1 upon winding a cut film 
around a new core in the above-described manner, it was necessary to 
embrace the core 2 with the film 1 prior to cutting as shown in FIG. 30. 
The film 1 is held under a predetermined tension generated between the 
wrapping roll 6 and the guide roll 3 in FIG. 29 for the purpose of 
winding, and so, in upon transferring from the state shown in FIG. 29 to 
the state shown in FIG. 30, it was necessary to gradually move the roll 6 
over a large period of time for the purpose of preventing breaking, 
zig-zag traveling, the generation of creases and the like due to unnatural 
forces applied to the film 1. 
But since the surface of the core 2 is not smooth as is the case with a 
smoothening roll, and since the circumferential speed of the core 2 is 
preset somewhat faster than the traveling speed of the film 1 in order to 
prevent slackening of the film immediately after the wrapping, slip would 
occur between the film 1 and the core 2, and hence there was a possibility 
that scratches could be generated on the film. Accordingly, the portion of 
the film scratched by the core 2 was unacceptable as a product, and 
moreover, there was a shortcoming in that the amount of such a loss would 
become larger as the film traveling speed became higher. 
Referring now to FIG. 31, the film 1 is supported by the core 2 and the 
guide roll 3, and is cut when the arm 9 descends and the cutter is brought 
to the film 1 as described above. It is to be noted that normally the 
cutter 8 employs a saw-tooth shaped blade as shown in FIGS. 32 and 33. 
In the above-described automatic cutting and winding apparatus for a film 
in the prior art, in order to realize a good cutting face of a film 
material, counter-measures were necessary including providing an excellent 
cutting capability of a cutter providing, an operation speed of a cutter 8 
that became faster as a traveling speed of a film became faster, 
increasing tension in a film or providing means for supporting a film in 
order that upon cutting the film can hardly escape when pressed by the 
cutter. In the event that these counter-measures were not provided, 
band-shaped cutting residuals would be produced at a cut portion 9 as 
shown in FIG. 34. Hence, when the cut portion is wrapped around a new 
core, the respective band-shaped pieces in the cut portion 9 would be 
folded or overlapped, resulting in unevenness. This unevenness would cause 
uneven deformation of a film 1 as a result of winding of the film 1 over 
the unevenness. Hence, flatness of a rewound film 1 would be deteriorated 
and many unacceptable portions would be produced. The length l of this 
unacceptable cut portion becomes longer as the traveling speed of the film 
1 is faster, as the operating speed of the cutter is slower, and as the 
tension in the film is smaller, and therefore there was a shortcoming in 
that an unacceptable film subjected to uneven deformation could be long. 
DESCRIPTION OF THE PREFERRED EMBODIMENTS 
Now the present invention will be described in more detail in connection 
with the preferred embodiments of the invention with reference to FIGS. 1 
to 28. 
A first preferred embodiment of the present invention is illustrated in 
FIGS. 1 to 4, in which reference numeral 11 designates a film, numerals 12 
and 13 designate cores, and these cores 12 and 13 are pivotably supported 
at opposite end portions of a turret 16 so as to be rotatable in the 
direction of arrows A when driven by a driving device not shown, the 
turret 16 being mounted on a frame 19 so as to be rotatable about its 
center in the direction of arrow C. In addition, arms 18 are provided on 
opposite sides of the central portion of the turret 16 and project 
therefrom, and at the respective tip end portions of the arms 18 are 
pivotably supported guide rolls 17, respectively. Reference numeral 14 
designates a mill roll formed by winding the film 11 around the core 12. 
On the film feed side of the above-described frame 19 is disposed another 
frame 28, on which a guide roll 27 is pivotably mounted along a film feed 
passageway. Also on the frame 28 adjacent to the guide roll 27, are 
pivotably mounted swingable arms 26 and 23 which can swing about an 
identical axis D. At the tip end of the swingable arm 23 is mounted a 
cutter 22. Also, on the swingable arm 26 are mounted a press roll 25 and 
electrostatic charging means 20. Furthermore, at the tip end of the 
swingable arm 26 is pivotably mounted an arm 29 which can likewise swing 
about a center point E, and at the tip end of the arm 29 are mounted a 
pair of press members 30 consisting of a press bar 30a and a press rod 
30b. In addition, an air blow nozzle 30c could be formed in the press 
member 30 so that a film end a may be pressed against the core 13 by air 
as shown in FIG. 4. The above-referred electrostatic charging means 20 is 
a well-known corona discharge charging type, and an electrode section of 
an electrostatic charging device is employed therefor. It is to be noted 
that a power supply section and wirings of the electrostatic charging 
device are omitted from the illustrations. 
Now description will be made as to the operation wherein tapeless winding 
of a film is carried out by making use of the apparatus according to the 
above-described embodiment of the present invention. FIG. 1 shows the 
state of the apparatus when the mill roll 14 on the right side core 12 as 
viewed in the figure has reached a full amount. The wound length of the 
film 11 is measured by a wound length counter not shown, and when it has 
reached the full amount, the arm 23 is actuated and is made to stand by at 
the position shown in FIG. 2. Subsequently the swingable arm 26 is 
actuated to press the film 11 against the new core 13 with the press roll 
25. At the same time, the swingable arm 29 descends so that the pair of 
press members 30 depress the film 11 towards the cutter 22, and thus, the 
tension in the film 11 is increased to cut the film 11 momentarily. 
Simultaneously with the cutting, an electric charge is given by the 
electrostatic charging means 20 to a cut end portion a of the film 11 to 
make it adhere to the core 13 for carrying out wrapping, and thus 
automatic cutting and winding are effected in a tapeless manner. It is to 
be noted that blowing of air from the air blow nozzle 30c in FIG. 4 is 
carried out simultaneously with charging by the electrostatic charging 
means 20. 
By employing the above-described construction, in order to minimize the 
film cut end a, the stop position of the cutter 22 can be made as close as 
possible to the core 13 as shown in FIG. 2. In addition, by pivotably 
mounting the arm 29, which is short and light, at the tip end portion of 
the arm 26, high-speed cutting becomes possible with a small swinging 
operation. Subsequently, when the winding has been finished, the arms 23 
and 26 are actuated to return them to the state shown in FIG. 3, and 
winding of the film 11 for producing a mill roll 15 is carried out on the 
new core 13. 
In the above-described embodiment, the press roll 25 can be used as a 
lay-on roll for controlling a winding tightness of a mill roll. 
Furthermore, as the electrostatic charging means, air blow type 
electrostatic charging means could be employed. The interval between the 
press bar 30a and the press rod 30b could be made variable so that the 
apparatus can be adjusted to accomodate for a change in the type and 
thickness of the film, and the air blow nozzle can be provided separately 
from the press members 30. 
Now a second preferred embodiment of the present invention will be 
described with reference to FIGS. 5 to 7. 
This preferred embodiment is similar to the embodiment shown in FIGS. 1 to 
4 except for the following points. That is, on the swingable arm 26 are 
mounted press cylinders 32 consisting of two sets of air cylinders 32a and 
32b and electrostatic charging means 20. In addition, the arm 29 is 
coupled to the arm 26 via a spring 33. On the same arm 26 are provided 
anti-impact support members (not shown) for supporting the arm 29 in the 
state shown in FIG. 5 or 6, and the press cylinders 32 and the spring 33 
jointly form swing acceleration means. A heater 31 is mounted on the lower 
surface of the cutter 22 to heat the cutter up to a temperature higher 
than a melting point of the film. Furthermore, on the swingable arm 23 is 
mounted electrostatic charging means 20 for giving an electric charge to 
the surface of the core 13. 
Description will be made as to the operation of the illustrated apparatus 
when carrying out tapeless winding of the film 11. FIG. 5 shows the state 
of the apparatus at the time when the mill roll 14 on the right side core 
12 as viewed in the figure has reached a full amount. The wound length of 
the film 11 is measured by a wound length counter not shown, and when it 
has reached the full amount, the arm 23 is actuated to make the cutter 22 
stand by at the position shown in FIG. 6, subsequently the swingable arm 
26 is actuated to press the film 11 against the new core 13 by means of 
the press roll 25. At the same time, in response to a signal issued from a 
control device not shown the air cylinder 32a is actuated to project a rod 
that pushes up the arm 239 to cause the arm 29 to rotate in the clockwise 
direction about a center point E, and so, the arm 29 rotates while 
increasing a deformation of the spring 33 until a dead point of the spring 
33 is passed. Once the arm 29 has passed the dead point of the spring 33, 
a restoring force of the spring 33 will accelerate the projecting motion 
imparted by the air cylinder 32a to the arm 29, and hence the arm 29 will 
accelerate rapidly to the cutting position shown in FIG. 6. That is, the 
pair of press members 30 mounted at the tip end of the arm 29 depress the 
film 11 at a high speed towards the cutter 22, and the film 11 is cut 
while the tension in the film is increased. 
Simultaneously with this cutting, an electric charge is given by the 
electrostatic charging means 20 to a cut end portion a of the film and/or 
to a surface of the core 13, to make the cut end portion a adhere to the 
core 13 for wrapping, and thus, automatic cutting and rewinding are 
carried out in a tapeless manner. 
By employing the above-described construction, as shown in FIG. 6, the stop 
position of the cutter 22 can be brought as close as possible to the core 
13 for the purpose of minimizing the cut end portion a of the film 11. In 
addition, due to the fact that the arm 29 having a short arm length and a 
light weight is pivotably mounted at the tip end portion of the arm 26 and 
also the cylinders 32 and the spring 33 are used in combination in the 
above-described manner, high-speed cutting becomes possible with a small 
swinging operation. Subsequently, when the wrapping has been finished, the 
arm 23 is actuated to be restored to the state shown in FIG. 7, the air 
cylinder 32b is actuated to rotate the arm 29 in the anti-clockwise 
direction until it is restored to the state shown in FIG. 7, and winding 
of the film 11 for producing the mill roll 15 is carried out on the new 
core 13. 
In the above-described embodiment, the press roll 25 can be used as a 
lay-on roll for controlling a winding tightness of a mill roll. 
Furthermore, as the electrostatic charging means, an air blow type 
electrostatic charging means could be employed. The interval between the 
press bar 30a and the press rod 30b could be made variable so that the 
apparatus can be adjusted to accomodate for a change in the type and 
thickness of the film, and the air blow nozzle can be provided separately 
from the press members 30. 
In the following, a third preferred embodiment of the present invention 
will be described with reference to FIGS. 8 to 12. 
This preferred embodiment is similar to the embodiment shown in FIGS. 1 to 
4 except for a cutter 122 and a heater 131 as will be described hereunder 
and shown in FIGS. 8 and 9. 
More particularly, a cutter 122 having a plurality of semi-circular edges 
as shown in FIGS. 10 and 11 and a heater 131 are mounted at the tip end of 
the arm 23. In this preferred embodiment, upon cutting a film, as shown in 
FIG. 9, the swingable arm 26 is actuated to press the film 11 against the 
new core 13 by means of the press roll 25. At the same time, the swingable 
arm 29 descends so that the pair of press members 30 depress the film 11 
towards the cutter 122 which has been heated by the heater 131, and the 
film 11 is cut while a tension in the film 11 is increased. In this 
instance, since the cutter 122 has been heated to a temperature higher 
than a melting point of the film, the film is momentarily cut by melting, 
and also since the edges of the cutter 122 is have a semi-circular shape, 
the cut end portion of the film has the configuration shown in FIG. 12. 
Hence, a cut length l.sub.1 is negligibly short, and can be formed into a 
stable favorable shape. 
Next, a fourth preferred embodiment of the present invention will be 
described with reference to FIGS. 13 to 16. 
In these figures, reference numeral 11 designates a film, numerals 12 and 
13 designate cores, and these cores 12 and 13 are pivotably supported from 
the opposite end portions of a turret 16 so as to be rotatable in the 
direction of arrow A when driven by a driving device not shown. The turret 
16 is mounted on a frame 19 so as to be rotatable about its center in the 
direction of arrow C. In addition, arms 18 are provided on opposite sides 
of the central portion of the turret 16 and project therefrom, and at the 
tip end portions of the arms 18 are pivotably supported guide rolls 17, 
respectively. Reference numeral 14 designates a mill roll formed by 
winding the film 11 around the core 12. 
On the film feed side of the above-described frame 19 is disposed another 
frame 28, on which a guide roll 27 is pivotably mounted along a film feed 
passageway. Also on the frame 28, adjacent to the guide roll 27 are 
pivotably mounted swingable arms 26 and 23 which can swing about a same 
axis D. At the tip end of the swingable arm 23 are mounted a pair of 
support members 230 consisting of a support bar 230a and a support rod 
230b. Also, on the swingable arm 26 are mounted a press roll 25 and 
electrostatic charging means 20. This electrostatic charging means 20 
could be mounted on the swingable arm 23. Furthermore, at the tip end of 
the swingable arm 26 is pivotably mounted an arm 29 which can likewise 
swing about a center point E, and at the tip end of the arm 29 is mounted 
a cutter 222. In addition, an air blow nozzle 231 could be mounted at the 
tip end of the swingable arm 29 so that a film end a may be pressed 
against the core 13 by air as shown in FIG. 16. 
Now description will be made as to the operation in which tapeless winding 
of a film is carried out by making use of the apparatus according to the 
embodiment of the present invention described above. FIG. 13 shows the 
state of the apparatus at the time when the mill roll 14 on the right side 
core 12 as viewed in the figure has reached a full amount. The wound 
length of the film 11 is measured by a wound length counter not shown, and 
when it has reached the full amount, the arm 23 is actuated to make the 
support members 230 stand by at the position shown in FIG. 14. 
Subsequently, the swingable arm 26 is actuated to press the film 11 
against the new core 13 with the press roll 25, and at the same time the 
swingable arm 29 descends so that the cutter 222 presses the film 11 
against the pair of support members 230a and 230b to cut the film 11 while 
tension in the film is increased. 
Simultaneously with the cutting, an electric charge is given by the 
electrostatic charging means 20 to a cut end portion a of the film and/or 
to a surface of the core to make the film cut end a adhere to the core 13 
for carrying out wrapping, and thus automatic cutting and winding are 
effected in a tapeless manner. It is to be noted that blowing of air from 
the air blow nozzle 231 in FIG. 16 is carried out simultaneously with the 
charging by the electrostatic charging means. 
By employing the above-described construction, in order to minimize the cut 
end portion a of the film, the pair of support members 230 can be brought 
as close as possible to the core 13 as shown in FIG. 14. In addition, by 
pivotably mounting the arm 29, which is short in arm length and light in 
weight, at the tip end portion of the arm 26, high-speed cutting becomes 
possible with a small swinging operation. 
Subsequently, when the wrapping has been finished, the arms 23 and 26 are 
actuated to return to the state shown in FIG. 15, and winding of the film 
11 for producing a mill roll 15 is carried out on the new core 13. 
In the above-described embodiment, the press roll 25 can be used as a 
lay-on roll for controlling a winding tightness of a mill roll. 
Furthermore, as the electrostatic charging means, an air blow type 
electrostatic charging means could be employed. 
Now, a fifth preferred embodiment of the present invention will be 
described with reference to FIGS. 17 to 22. 
This preferred embodiment is a modification of the fourth preferred 
embodiment shown in FIGS. 13 to 16 in which a locus of movement of the 
cutter extends along the surface of the core, and the respective members 
as explained hereunder are added to the fourth preferred embodiment. 
More particularly, as shown in FIGS. 17 to 20, a support member 324 is 
mounted at the tip end of the swingable arm 23. 
On the swingable arm 26, in addition to the press roll 25 and the 
electrostatic charging means 20, an air cylinder 331, a sector gear 333 
adapted to swing about a center point E, and a pinion 329 pivotably 
supported at the tip end F, are provided. An arm 330 is fixedly secured to 
the pinion 329, and at the tip end of the arm 330 is mounted a cutter 322. 
It is to be noted that electrostatic charging means 20 could be mounted to 
the swingable arm 23. The air cylinder 331, sector gear 333, pinion 329, 
arm 330 and cutter 322 can be provided independently of the pivot axis D. 
Next, description will be made as to the operation in which tapeless 
winding of the film 11 is carried out by the apparatus according to the 
described above embodiment of the present invention. FIG. 17 shows the 
state of the apparatus at the time when the mill roll 14 on the right side 
core 12 as viewed in the figure has reached a full amount. The wound 
length of the film 11 is measured by a wound length counter not shown, and 
when it has reached the full amount, the arm 23 is actuated to make the 
support member 324 stand by at the position shown in FIG. 19. 
Subsequently, the swingable arm 26 is actuated to press the film 11 
against the new core 13 with the press roll 25, and at the same time the 
air cylinder 331 is actuated. Then, the arm 330 is accelerated via the 
sector gear 333 and the pinion 329. Hence, the cutter 322 moves at a high 
speed along the locus shown in FIG. 21, and it cuts the film 11 while 
tension in the film is increased. Accordingly, the cut edge of the film 11 
is improved as shown in FIG. 22, and an unacceptable portion of the film 
can be extremely reduced. 
In addition, if the support member 324 is brought as close as possible to 
the core 13 and the distance between the press roll 25 and the support 
point for the film is made short when the film is to be cut, then the 
tension of the film at cutting is higher, and the film can be cut easily 
and finely. It is to be noted that in order to enhance the cutting speed, 
the movements of the support member 324 and the cutter 322 could be 
synchronized. Also, for the purpose of improving the cutting efficiency, a 
heater (heating device) 332 could be associated with the cutter 322 as 
shown in FIG. 20. 
Simultaneously with the cutting, an electric charge is given by the 
electrostatic charging means 20 to a cut end portion a of the film and/or 
to a surface of the core to make the film cut end a adhere to the core 13 
for carrying out wrapping, and thus automatic cutting and winding are 
effected in a tapeless manner. Due to the employment of the structure in 
which rotation is given to only the cutter portion, the cutter portion can 
be made light in weight. More particularly, since the only parts that are 
required to be moved for cutting are the cutter 322, the air cylinder 331, 
the sector gear 333 and the small arm 330, by appropriately selecting a 
lever ratio with respect to the air cylinder, the cutting speed and the 
cutting capability can be easily enhanced. 
Subsequently, when the wrapping has been finished, the arm 23 and the 
cutter 322 are restored to the state shown in FIG. 20, and winding of the 
film 11 for producing a mill roll 15 is carried out on the new core 13. 
Next, a sixth preferred embodiment of the present invention will be 
described with reference to FIGS. 23 to 28. 
Except for an expander roll and a control mechanism therefor, this 
preferred embodiment is similar to the first preferred embodiment 
illustrated in FIGS. 1 to 4. More particularly, on the frame 28 is 
pivotably mounted a swingable arm 432 which can swing about a center point 
F, and at the tip end of the swingable arm 432 is pivotably supported an 
expander roll 431. A detailed structure of the expander roll 431 is shown 
in FIGS. 27 and 28. Tip ends of an appropriate number of adjusting bolts 
432b threadedly penetrating left and right brackets 432a which are fixed 
to the swingable arm 432, are held in contact with inclined cams 432c, and 
these cams 432c can be adjusted to various inclination angles one of which 
is indicated by .theta. shown in FIG. 27 by manipulating the adjusting 
bolts 432b. A shaft 431c of left and right ribs 431b each having a 
plurality of radial parts, extends externally through center holes in the 
cams 432c and is pivotably supported by the brackets 432a. The ribs 431b 
are accommodated in annular grooves of the cams 432c so as to be slidable 
along the grooves. The ribs 431b and the shaft 431c are so connected with 
each other that the ribs 431b can rotate in the inclined annular grooves 
of the cams 432b when ribs 431b rotate with the shaft 431c. Opposite ends 
of a plurality of rubber bands 431a having the cross-sections shown in 
FIG. 28 are mounted to the radial parts of the left and right ribs 431b, 
respectively, at equal angular intervals. 
A control mechanism for the position of the above-described expander roll 
will be explained with reference to FIG. 26. 
A core 12 is adapted to be rotated by a variable speed motor 433, and a 
rotational speed detector 434 coupled to the variable speed motor 433 for 
detecting the rotational speed of the motor 433 is provided. Reference 
numeral 435 designates a speed detector for detecting a winding speed, 
i.e., a traveling speed of a film, numeral 431 designates an expander roll 
that is rotatably supported by an arm 432, and this arm 432 is formed 
integrally with a shaft 436. Reference numeral 437 designates an angle 
detector for detecting an angular position of the shaft 436, and numeral 
438 designates a motor which rotates the above-mentioned shaft 436 via a 
reduction gear 439 and thus the arm 432 is swung about an axis of the 
shaft 436. It is to be noted that the above-described shaft 436, angle 
detector 437, motor 438 and reduction gear 439 are supported by means not 
shown. 
In addition, reference numeral 440 designates a wound film diameter 
detector, numeral 441 designates a gap setter for setting the distance of 
a gap extending between the surfaces of the expander roll 431 and the mill 
roll 15, numeral 442 designates an adder, numeral 443 designates a 
comparator and numeral 444 designates a controller coupled to the motor 
433. 
The operations of rewinding and cutting a film are shown in FIGS. 23 and 
24, but since the operations are similar to those in the first preferred 
embodiment described above, further explanation thereof will be omitted. 
Once the cutting and rewinding of the film has been finished, the film 11 
would be wound around a new core 13 after it passes over a guide roll 27 
and comes into contact with the expander roll 431. 
In this instance, in the expander roll 431, since the inclined cams 432c 
are inclined at an appropriate angle by manipulating the adjusting bolts 
432b, the ribs 431b slide along the annular grooves in the cams 432c and 
the rubber bands 431a of the expander roll 431 stretch and contract as the 
expander roll 431 rotates. As shown in FIG. 27, by fastening the adjusting 
bolts 432b on the inlet side for the film 11 and by loosening the bolts 
432b on the outlet side, the rubber bands contract on the inlet side for 
the film and stretch on the outlet side. Hence, the film 11 coming into 
contact with these rubber bands 431a is stretched uniformly by the 
stretching and contracting of the rubber bands 431a, and thus, 
longitudinal creases generated on the film 11 can be removed. 
Moreover, as will be explained in the following, the expander roll 431 is 
positioned so as not to come into contact with the mill roll, and also 
upon winding of the film, so as to come close to the mill roll with a 
fixed minute interval always maintained between it and the mill roll. 
Therefore, a film path through the interval can always be maintained from 
the beginning of winding up to the end of winding. Accordingly, 
longitudinal creases generated would be removed just prior to the winding 
of the film, and the generation of winding creases in a mill roll can be 
prevented in general. As a result, an excellent mill roll that is free 
from winding creases, can be formed. 
The position control for the expander roll 431 will be described with 
reference to FIG. 26. A film 11 is wound around the core 13 that is driven 
by the high-speed motor 433, via the speed detector 435 and the expander 
roll 431. When the film 11 begins to be wound around the core 13, the 
expander roll 431 placed at the position indicated by double-dot chain 
lines in FIG. 26 is advanced to the position indicated by solid lines, and 
expander roll 431 stops so as to establish a gap width (a dimension l in 
FIG. 26) that is preset by the gap setter 441. 
A film winding speed is detected by the speed detector 435, a rotational 
speed of the mill roll is detected by the rotational speed detector 434, 
the respective speeds are input to the wound film diameter detector 440, 
in which the wound film diameter of the mill roll 15 is calculated through 
an electrical process, and the calculated value is input to the adder 442 
as a reference position instruction adapted for the expander roll 431. It 
is to be noted that the calculation of the wound film diameter of the mill 
roll 15 is conducted according to the following formula: 
EQU D=1/.pi..multidot.(V/N)(m) 
that is, 
EQU D.varies.V/N 
where 
V: film speed (m/min.) 
N: rotational speed of a mill roll (r.p.m.) 
.pi.: the circular constant (dimensionless) 
D: wound film diameter of a mill roll (m) 
In the adder 442, the reference position instruction value sent from the 
wound film diameter detector 440 and the preset gap value sent from the 
gap setter 441 are added together, and the sum is input to the comparator 
443 as a control position instruction for the expander roll 431. On the 
other hand, the angle detector 437 detects the position of the expander 
roll 431 via the arm 432 and the shaft 436, and the position information 
is fed back to the comparator 443. In the comparator 443, the control 
position instruction sent from the adder 442 is compared with the position 
information sent from the angle detector 437. 
Furthermore, the electrical signal generated as a result of comparative 
operations in the comparator 443 is input to the controller 444, in which 
it is determined whether or not the expander roll 431 is placed at a 
predetermined position. If the expander roll 431 has been advanced too 
much, a retract signal is applied to the motor 438, while if it has 
advanced insufficiently, an advance signal is applied to the motor 438, 
and in this way automatic control for the position of the expander roll 
431 is effected. Thus, the diameter of the mill roll, which increases as 
time elapses, is detected and the film 11 is wound around the core 13 
while controlling the position of the backwardly moving expander roll 431 
so that the preset gap width l is always maintained constant. Once a 
predetermined amount of film 11 has been wound around the core 13, the 
expander roll 431 is retracted to the position (the position shown by 
double-dot chain lines in FIG. 26) where the expander roll 431 does not 
hinder the rotation of the turret 16. It is to be noted that the 
above-described position control is effected by a closed-loop control 
system consisting of the rotational speed detector 434, speed detector 
435, wound film diameter detector 440, gap setter 441, adder 442, angle 
detector 437, comparator 443, controller 444, motor 438, reduction gear 
439 and shaft 436. The control system should not be limited to that 
illustrated in FIG. 26, but can be made modified to include one in which, 
for example, the mechanical rotary structure coupling the motor 438, 
reduction gear 439, shaft 436 and arm 432 is replaced by a hydraulic or 
pneumatic rotary structure or reciprocating structure. 
As described above, in the last-mentioned preferred embodiment, since the 
expander roll 431 is spaced from the mill roll by a fixed small interval 
from the beginning of winding of the film up to the end of winding and 
just before the film is wound around the core 13, longitudinal creases 
produced so far in the film can be removed, generation of winding creases 
in the mill roll 15 can be prevented, and consequently, excellent mill 
rolls which are free from winding creases can be formed. 
As described in detail above, according to the present invention, since 
winding of a film can be carried out with a cut end of the film adhering 
to a core by giving an electric charge to the film simultaneously with the 
cutting of the film, there is no need to embrace a core with the film 
before cutting. Hence, the film portion at the end of winding of a mill 
roll which comes into contact with a core and which is subjected to 
scratches and is wasted, is eliminated, and therefore, a yield of the film 
can be greatly improved. 
In addition, since a pair of press members for pressing a film against a 
cutter and a cutter coming into press contact with a film for cutting the 
film oppose each other with the film extending therebetween, tension in 
the film upon cutting is increased by the pair of press members. Moreover, 
since the pair of press members press the film so as not to move away from 
the cutter, a cut end of the film can have a good cutting configuration. 
Therefore, there is an advantage in that an unacceptable portion of a film 
wound in a mill roll can be remarkably reduced. The above-mentioned 
advantage becomes more remarkable as the cutting and winding speed becomes 
higher. 
Also, according to the present invention, since a pair of press members for 
pressing a film against a cutter and a cutter coming into press contact 
with a film for cutting the film oppose each other with the film extending 
therebetween and also a device for increasing a swinging speed of the 
press members is provided, tension in the film upon cutting is increased 
by the pair of press members. Moreover, since the pair of press members 
press the film so as not to move away from the cutter, high speed cutting 
becomes possible, and a cut end of the film can have a good cutting 
configuration. Furthermore, by heating a cutter up to a temperature higher 
than a melting point of a film by means of a heater mounted to the cutter, 
the cutting can be made reliable. 
Furthermore, according to the present invention, by employing a cutter 
having a plurality of contiguous semi-circular edges as a heatable cutter, 
cutting of a film can be achieved reliably and with a reduced cut end 
length. 
Moreover, according to the present invention, since a pair of support 
members and a cutter coming into press contact with a film for cutting the 
film oppose each other with the film extending therebetween and the cutter 
moves in between the pair of support members to cut the film, a tension in 
the film upon cutting is increased. Furthermore, since the pair of support 
members press the film so as not to move away from the cutter, a cut end 
of the film can have a good cutting configuration. 
Also, according to the present invention, since a cutter rotary shaft is 
provided for a cutter adapted to come between the pair of support members 
so that the cutter can move at a high speed along a surface of a core, 
upon the cutting of a film, a cut end of the film is guided so as to 
extend along the core and floating of the film from the core is reduced. 
Therefore, simultaneously with the cutting, the film is adhered smoothly 
onto the surface of the core, and separation or floating of the film cut 
end from the core surface does not occur. This perfectly eliminates a 
fold-back phenomena of the cut end of the film, creases caused by folding 
back can be preliminarily prevented, and therefore, the present invention 
can provide great advantages in that a yield of a mill roll is improved. 
In addition, since support members and a cutter are disposed in the 
proximity of a cutting position of a film and each other with a film 
extending therebetween and a cutting speed is raised, the film can be cut 
by the cutter without being broken and the cut end portion of the film can 
have an improved configuration shown in FIG. 22. Consequently, there is an 
advantage in that an unacceptable portion of a film can be remarkably 
reduced. The above-mentioned advantage becomes more remarkable as the 
cutting and winding speeds become higher. 
Furthermore, according to the present invention, since winding is effected 
while removing longitudinal creases generated by means of an expander roll 
just before the film is wound around a core, excellent mill rolls which 
are free from creases can be obtained. Consequently, there is an advantage 
in that an unacceptable portion of a film can be remarkably reduced. The 
above-mentioned advantage becomes more remarkable as the cutting and 
winding speeds become higher and as the width of the film becomes broader. 
Since many changes and modifications in design can be made to the 
above-described construction without departing from the spirit of the 
present invention, it is intended that all matter contained in the above 
description and illustrated in the accompanying drawings shall be 
interpreted to be illustrative and not in a limiting sense.