The present invention relates to a velocity-changing apparatus for a web, wherein predetermined processing can be added onto the web while the web is being transported.
When a processing such as bonding is added onto the web which is being carried, a certain amount of time for the processing is required. The time for processing can be gained by decreasing the speed of the whole production line, but it might lead to decreased production efficiency. Velocity-changing apparatuses and apparatuses for producing absorbent articles, in which apparatuses the velocity of the web can be slowed down during the processing of the web with the speed of the production line kept constant in order to increase the production efficiency, are heretofore known (for example, the following first and second patent documents).
[First patent document] U.S. Pat. No. 6,596,108 B2 (abstract)
[Second patent document] Japanese Patent No. 3,452,577 (FIG. 5, the nineteenth column) (WO 95/012491)
However, the patent documents fail to disclose the slowdown of the drum itself for processing or cutting the web, and fail to disclose cutting the web on the drum.
Generally, processing of the web by ultrasonic welding requires more time for processing than that by heat sealing. Therefore, introducing the ultrasonic welding in place of the heat sealing into the existing production line might cause slowdown of the production line as a whole, thereby decreasing the production efficiency.
An object of the present invention is to provide a new velocity-changing apparatus for a web that can be incorporated into the production line without decreasing the speed of the production line as a whole.
A velocity-changing apparatus of the present invention for changing a velocity of a continuous web, comprises: a drum for transporting (carrying) the continuous web at a transport velocity (carrying velocity) which is generally equal to a circumferential velocity (peripheral velocity) of the drum while changing the circumferential velocity periodically at least once per one rotation of the drum; a movable member disposed upstream of the drum for feeding the continuous web to the drum; and a cutter for cutting, on the drum, the continuous web being transported at the transport velocity which is generally equal to the circumferential velocity of the drum. The movable member moves according to the change of the circumferential velocity of the drum so that a feed velocity at which the continuous web is fed to the drum is generally equal to the transport velocity of the continuous web being transported by the drum.
In this velocity-changing apparatus, the rotational velocity of the drum is changed periodically while the continuous web is being transported by means of the rotation of the drum. Thus, the transport velocity of the continuous web, which is transported by the drum, is changed periodically. Furthermore, the movable member moves periodically so that the feed velocity of the continuous web decreases when the transport velocity of the continuous web on the drum decreases and that the feed velocity of the continuous web increases when the transport velocity of the continuous web on the drum increases. Thus, the continuous web on the drum or on the upstream side of the drum can be prevented from substantially slacking or shrinking.
In the present invention, the velocity-changing apparatus for the web may include only one drum or may include a plurality of drums. In a case where a plurality of the drums are provided, the processing of the continuous web may be carried out on one of the drums and the cutting of the continuous web may be carried out on another of the drums. In a case where a plurality of the drums are provided, it is preferred that the circumferential velocities of the drums are set substantially the same.
According to a preferred aspect of the present invention, the velocity-changing apparatus further comprises a processing device for processing the continuous web on the drum.
In this aspect, the continuous web on the drum can be processed when the circumferential velocity of the drum slows down, i.e., the transport velocity of the continuous web slows down, which allows for more time for processing. On the other hand, the transport velocity of the continuous web can be accelerated by accelerating the circumferential velocity of the drum when the processing is not performed, which makes the average transport velocity of the continuous web in conformity with the speed of the production line as a whole.
In this view, it is preferred that the processing device processes the continuous web when the transport velocity at which the drum transports the continuous web is lower than an average circumferential velocity of the drum. The processing device may be a welder for welding the continuous web.
According to another preferred aspect of the present invention, the cutter cut the continuous web when the transport velocity at which the drum transports the continuous web is lower than the average circumferential velocity of the drum. In this aspect, the accuracy of cutting can be improved.
According to another preferred aspect of the present invention, the velocity-changing apparatus further comprises a receiving device for receiving a cut-off web cut off by the cutter and then transporting the cut-off web. A velocity at which the received cut-off web is transported by the receiving device when the receiving device receives the cut-off web is set larger than the transport velocity of the continuous web at the time of cutting. Thereby, a tip end of the continuous web and a rear end of the cut-off web are spaced from each other.
In this aspect, after the cutter cuts the continuous web, the cut-off web produced by cutting the continuous web can be transported (moved) at a velocity which is higher than the circumferential velocity of the drum at the time of the cutting. Furthermore, since the receiving device transports (moves) the cut-off web at such a higher velocity, the tip end of the continuous web can get away from the rear end of the cut-off web. Thus, even when the transport velocity of the continuous web is accelerated after this spacing, the front end of the continuous web can be prevented from interfering with the rear end of the cut-off web.
In the present invention, regarding the cycle of the change of the circumferential velocity of the drum, the circumferential velocity may be changed once per one rotation of the drum, or may be changed two or more times per one rotation of the drum. The number of the change of the circumferential velocity per one rotation of the drum may be set according to the position of the web to be processed or according to the type of the article to be produced.
a) is a schematic side view showing a velocity-changing apparatus for web according, to the first embodiment of the present invention and
a), 3(b) are schematic side views each showing a velocity-changing apparatus for web according to the second embodiment of the present invention.
a), 7(b), 7(c) are characteristic curves each showing a change of a circumferential velocity of a drum.
2: Movable roller (movable member)
3, 3A: Work drum
4: Cutter roller
6: Processing device
50: Receiving device
W1: Continuous web
W2: Cut-off web
WS: Velocity-changing apparatus for web
V(θ): Circumferential velocity
Va: Average circumferential velocity
The present invention will be understood more clearly from the following description of preferred embodiments taken in conjunction with the accompanying drawings. However, it will be appreciated that the embodiments and the drawings are given for the purpose of mere illustration and explanation and that the scope of the present invention is to be defined by the appended claims. In the accompanying drawings, the same reference numerals denote the same or corresponding elements throughout several figures.
Embodiments of the present invention will now be described with reference to the drawings.
According to this embodiment, the velocity-changing apparatus WS includes a movable roller 2 (an example of movable member), a work drum 3 and a cutter roller 4. A fixed roller 1 may be located upstream of the movable roller 2. A continuous web W1 is fed successively to the work drum 3 from the movable roller 2, which is located upstream of the work drum 3. On the outer circumferential surface of the cutter roller 4, two blades 41 are provided. One or more blade rests (beds) for receiving the blades 41 may be provided on the work drum 3.
The work drum 3 can rotate while changing periodically its circumferential velocity V(θ) (peripheral velocity). Thus, in a case where a processing device is provided on the work drum 3, the work drum 3 enables the continuous web W1 to move at a velocity which is commensurate with the processing ability of the processing device. The work drum 3 may have a structure wherein the continuous web W1 can be held thereon by suction. If a structure for sucking the continuous web W1 by means of vacuum is employed, a suction hole (not shown) may be provided on the work drum 3.
The work drum 3 is rotatably driven by a motor, for example, a servo motor. By changing the rotational velocity of the motor according to the phase (rotation angle) of the work drum 3, the circumferential velocity of the work drum 3 can be changed according to a position of the processing device.
The change of the circumferential velocity of the work drum 3 may be realized by employing a method wherein the velocity is changed by means of combination of a main motor for rotatably driving the work drum 3 and a servo motor for changing the velocity (for example, Japanese Patent Laid-Open No. 2003-145485).
The cutter roller 4 can cut the continuous web W1 on the work drum 3 after some processing is added onto the continuous web W1. Since the continuous web W1 is cut by the cutter roller 4, a cut-off web W2 located downstream of the cutting position 31 can move at a different velocity from the continuous web W1 located upstream of the cutting position 31.
Now, the transport velocity (circumferential velocity) of the continuous web W1 at the time of cutting the continuous web W1 is indicated by V1, for example. Even when, after cutting, the transport velocity (carrying velocity) of the continuous web W1 located upstream of the cutting position 31 shifts to a velocity V2 which is lower than or higher than V1, the transport velocity (carrying velocity) of the cut-off web W2 located downstream of the cutting position 31 won't be affected by the shifted velocity V2. That is, the transport velocity of the cut-off web W2 is independent from the circumferential velocity of the work drum 3, i.e., the transport velocity of the continuous web W1. In this case, in order to move the downstream cut-off web W2 at a different velocity from the circumferential velocity V1 of the work drum 3, it is preferred that the cut-off web W2 is released from the work drum 3 and is carried by another carrying device or that the cut-off web W2 is subject to some force from another carrying device if not released from the work drum 3.
If the transport velocity of the cut-off web W2 is higher than the transport velocity V1 of the continuous web W1 at the time of cutting, the tip end (front end) of the continuous web W1 and the rear end of the cut-off web W2 get spaced apart from each other. Thus, even when the transport velocity of the continuous web is increased to be higher than the transport velocity of the cut-off web after this spacing, the front end of the continuous web can be prevented from interfering with the rear end of the cut-off web.
A receiving device 50 shown in
If the circumferential velocity V(θ) becomes V4 that is lower than the feed velocity at which the movable roller 2 shown in
The relationship between the move of the movable roller 2 and the change (acceleration) of the circumferential velocity V(θ) of the work drum 3 is as shown by the following expression (1).
2·dx/dt≈dV(θ) (1)
dt: minute period of time
dx: amount of displacement of the movable roller 2 with respect to the work drum 3 per minute period of time
dV(θ): variation (acceleration) of the circumferential velocity of the work drum 3 per minute period of time
That is, a value obtained by dividing the amount of displacement dx of the movable roller 2 with respect to the work drum 3 per minute period of time dt by the minute period of time dt and then doubling the divided amount is generally equal to the acceleration dV(θ) of the work drum 3.
For example, when the movable roller 2 gets near to the work drum 3 (the movable roller 2 moves in the feed direction A1 of the continuous web W1, and therefore dx>0), the feed velocity of the continuous web W1 is increased (accelerated) and it becomes possible to increase (accelerate) the circumferential velocity V(θ) of the work drum 3 according to the increased feed velocity. On the other hand, when the movable roller 2 gets away from the work drum 3 (the movable roller 2 moves in the opposite direction A2 from the feed direction A1 of the continuous web W1, and therefore dx<0), the feed velocity of the continuous web W1 is decreased (slowed down) and it becomes possible to decrease (slow down) the circumferential velocity V(θ) of the work drum 3 according to the decreased feed velocity.
As shown in
The fixed roller 1 and the movable roller 2 may be arranged as shown in
The velocity-changing apparatus of the present invention may include a processing device. The processing device is capable of carrying out steps of cutting, forming holes, sealing, attaching or applying something, or the like. For example, in a case of welding or sealing the continuous web W1, ultrasonic welding means or heat sealing means may be employed thereto. Hereinafter, the second embodiment, in which ultrasonic welding means is used, will be described with reference to
At least one main body of the processing device 6 is located around the work drum 3. As shown in
As shown in
As shown in
Generally, in a case of processing the web by ultrasonic welding, it is necessary to set the line speed (moving velocity of the web) at the processing position lower than in a case of processing the web by heat sealing. Therefore, if the ultrasonic welding device is incorporated into the existing production line in place of the heat sealing device, it is necessary to lower the velocity of the web at the processing position.
Accordingly, in this embodiment, the moving velocity of the continuous web W1 at the time of processing is lowered by the movable roller 2 and the work drum 3, as above mentioned. That is, as shown in
A plurality of the processing devices 6, 6 may be arranged around the work drum 3, which makes it possible to apply efficiently the ultrasonic energy onto portions of the web to be welded, and therefore such configuration can be expected to lead to more speed-up of the production line.
The circumferential velocity V(θ) of the work drum 3 changes periodically according to the phase θ of the work drum 3. The relationship between the circumferential velocity V(θ) and the phase θ may be defined by various functions. For example, the circumferential velocity V(θ) may change according to simple sine curve, as shown in
The processing by the processing device 6 may be carried out while the circumferential velocity V(θ) of the work drum 3 is lower than the average circumferential velocity Va of the work drum 3. This processing may also be carried out while the circumferential velocity V(θ) of the work drum 3 is generally equal to or slightly higher than the average circumferential velocity Va of the work drum 3, in addition to while the circumferential velocity V(θ) of the work drum 3 is lower than the average circumferential velocity Va of the work drum 3.
The cutting of the continuous web W1 by the cutter roller 4 may be carried out when the processing is carried out, as shown in
The rotation angle per cycle (period) of velocity-changing of the work drum 3, i.e., 2π (pi)/N, may be, for example, an angle obtained by dividing 2π by the number m of the anvils provided on the work drum 3. If a plurality of the processing devices 6 are provided, the rotation angle 2π/N may be, for example, an angle obtained by dividing 2π by the product of the number m of the anvils and the number of the processing devices 6. That is, the rotation angle 2π/N may be a value obtained by the following expressions.
2π/N=2π/m (2)
2π/N=2π/(m·n) (3)
The receiving device 50 shown in
In this embodiment, as shown in
In this embodiment, as shown in
The cutting position at which the continuous web is cut is not limited to such position. For example, the continuous web W1, which has been released from the work drum 3, may be cut by the cutter roller 4 at a position between the work drum 3 and the receiving device 50 for receiving the continuous web W1 from the work drum 3.
As shown in
In this embodiment, preferably, the second work drum 3A rotates while changing periodically its circumferential velocity in synchronism with the first work drum 3. That is, it is preferred that the circumferential velocity of the second work drum 3A is controlled to be generally equal to the circumferential velocity of the first work drum 3. In this case, the transport velocity of the continuous web W1 on the first work drum 3 is generally equal to the transport velocity of the continuous web W1 on the second work drum 3A.
The cut-off web W2, which is produced by cutting the continuous web W1 on the second work drum 3A, is handed over to the conveyor (receiving device) 51 and then transported downstream.
While preferred embodiments of the present invention have been described above with reference to the drawings, obvious variations and modifications will readily occur to those skilled in the art upon reading the present specification.
For example, three or more work drum may be used. The movable member is not limited to the roller. A web guider may be provided for carrying the web smoothly.
Thus, such variations and modifications shall fall within the scope of the present invention as defined by the appended claims.
The present invention is preferably applicable to facilities where the web is processed successively, for example, production facilities for producing disposable worn articles, building materials, medical materials or the like.
Number | Date | Country | Kind |
---|---|---|---|
2004-061518 | Mar 2004 | JP | national |
This application is a continuation application of U.S. Non-Provisional application Ser. No. 10/598,265 filed on Aug. 23, 2006 now abandoned which is a 371 of International Application No. PCT/JP2005/003355 filed in Japan on Mar. 1, 2005, the entire contents of which are hereby incorporated by reference.
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Number | Date | Country | |
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20100282812 A1 | Nov 2010 | US |
Number | Date | Country | |
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Parent | 10598265 | US | |
Child | 12791099 | US |