The present invention relates to a web conveyor for conveying a web having a top surface on which workpieces are disposed at predetermined intervals in a machine direction along a flow direction of manufacturing steps for an absorbent article.
In the current field of manufacturing absorbent articles such as sanitary napkins and disposable diapers, techniques are desired for efficiently conveying soft absorbent articles without damage thereto. An apparatus for manufacturing absorbent articles desirably has a manufacturing line that is as linear as possible. In actuality however, an apparatus for manufacturing absorbent articles is constructed in a limited space, and so the conveying direction of the articles being conveyed (referred to hereinafter as “workpieces”) is frequently changed. A web conveyor has been disclosed that conveys workpieces pressed against a pair of endless belts (see Patent Document 1).
However, the conventional web conveyor described above has the following problems. A belt that presses the workpieces from two surfaces has a non-continuous region. In this region, the workpieces cannot be sufficiently pressed, and so the workpieces cannot be reliably conveyed.
For example, in a region where one of two belts pressing the surfaces of the workpieces is separated from a workpiece, this workpiece can stick to this separated belt and become wrapped around the belt. Furthermore, as the conveying speed is increased, the wind speed is also increased, so that there is a worry that the workpiece will rise up. These problems that can occur in the workpieces during the conveying lead to manufacturing defects and a drop in the manufacturing efficiency.
Patent Document 1: Patent No. 003647301
A web conveyor of first aspect conveys a web in a machine direction along a flow direction of steps for manufacturing absorbent articles, the web having a top surface on which workpieces are arranged at predetermined intervals. The web conveyor includes: a belt conveyor that includes a region for adsorbing a bottom surface of the web, and conveys the web in the machine direction; and a holding conveyor that holds at least top surfaces of the workpieces. The belt conveyor has a length in the machine direction greater than a length of the holding conveyor in the machine direction, and extends downstream from an end portion of the holding conveyor at least at a downstream side. The holding conveyor has a width arranged at least within a width of the workpieces. A boundary at which conveying conditions of the belt conveyor change exists between an upstream end portion and a downstream end portion of the holding conveyor.
An embodiment of a web conveyer according to the present invention will be described with reference to the drawings. Note that, in the following description of the drawings, the same or similar numerals denote the same or similar portions. In addition, it should be noted that the drawings are schematic and ratios of dimensions and the like are different from actual ones. Therefore, specific dimensions and the like should be determined in consideration of the following description. Moreover, as a matter of course, the drawings also include portions having different dimensional relationships and ratios from each other.
The web 200 is a product such as an absorbent article that is in the process of being manufactures, and is conveyed in a machine direction MD as it progresses through the manufacturing steps. Workpieces 210 are arranged on the top surface of the web 200 at predetermined intervals. Region 210A represents the portion of a workpiece 210 that leads in the machine direction MD. The length in the width direction of the region 210A is represented as La. In a case where the product is a diaper, for example, the web 200 is a top sheet arranged on the skin contact surface side or a back sheet arranged on the clothing contact surface side, and the workpieces are absorbers. The web 200 is conveyed as it progresses through the manufacturing steps in the machine direction MD by a web conveyor 100 described below.
The web conveyor 100 includes belt conveyors 110A and 110B that convey the web 200 in the machine direction MD, and a holding conveyor 120 that holds the top surface of the web 200. The holding conveyor 120 presses the top surface of the web 200 against the conveyor belts 110A and 110B.
The length L1 of the belt conveyors 110A, 110B, in the machine direction MD is greater than the length L2 of the holding conveyor 120 in the machine direction MD. The length L2 of the holding conveyor 120 is greater than the interval between workpieces 210, i.e. the work pitch. The belt conveyor 110B includes a roller 111 disposed upstream in the machine direction MD, a roller 112 disposed downstream, and an endless belt that is wrapped around the rollers 111 and 112. The endless belt 113 has a plurality of through-holes 113a formed therein.
An imaginary line 11 that is orthogonal to the machine direction MD and parallel to the conveying surface in the belt conveyor 110A is parallel to an imaginary line 12 of the belt conveyor 110B that is oriented in the same manner. In other words, the conveying surfaces of the belt conveyors 110A, 110B, adjacently disposed are flat, without bending in the machine direction MD.
The belt conveyor 110B includes a plurality of suction boxes 114a, 114b, that suck external air through the through-holes 113a. As a result, the belt conveyors 110A, 110B, can convey the web 200 while adsorbing the bottom surface thereof. The belt conveyor 110A has the same configuration as the belt conveyor 110B.
The holding conveyor 120 includes an end portion 121u that is upstream in the machine direction MD and an end portion 121d that is downstream. The width w of the holding conveyor 120 is less than at least the width La (see
As shown in
By providing the holding conveyor 120 at the boundary between the belt conveyor 110A and the belt conveyor 110B in the web conveyor 100, the top surfaces of the web 200 and the workpieces 210 are pressed, and so the workpieces 210 being conveyed are prevented from rising up from the web 200.
With this web conveyor 100, the leading end of the web 200 is prevented from sticking and wrapping around the belt conveyor 110A at the boundary between the belt conveyor 110A and the belt conveyor 110B, which are the two belts pressing the top surfaces of the workpieces 210. Thus, the web 200 and the workpieces 210 can be reliably passed between the conveyors.
Furthermore, with the web conveyor 100, even when the wind pressure on a workpiece 210 increases due to an increase in the conveying speed, rising of the workpiece 210 from the web 200 or floating of the web 200 from the conveying surface can be prevented at locations where the web 200 and the workpieces 210 cannot be adsorbed to the conveying surface, such as the boundary between the belt conveyor 110A and the belt conveyor 110B. Furthermore, the web conveyor 100 can prevent problems with the workpieces during the conveying to enable reliable conveying, thereby preventing manufacturing defects and a drop in manufacturing efficiency.
In
The following describes a web conveyor 101 according to the second embodiment of the present invention.
The web conveyor 101 has boundaries between suction boxes 114a, 114b, 114c, 114d between the upstream end portion 121u and the downstream end portion 121d of the holding conveyor 120. Specifically, the holding conveyor 120 is arranged to press on the top surface of the web 200 at a boundary between the suction boxes 114b, 114c, of the belt conveyor 110.
Since a common suction box has a suitable size for achieving suction to reliably suck the web 200, a plurality of suction boxes are required to exert suction over the entire region of the belt conveyor 110. Therefore, there is a case where the conveying surface of the belt conveyor 110 includes locations which cannot adsorb the web 200 and the workpieces 210.
With the web conveyor 101 shown in
The following describes a web conveyor 102 according to a modification of the second embodiment.
At locations where the conveying surface is curved to cause the top surface of the web 200 to protrude, such as corner portions of the conveying path where suction boxes cannot be disposed, particularly at locations where there is a change between an ascending surface and a descending surface, the workpieces 210 are more easily affected by wind resistance, causing the leading ends of the workpieces 210 to float up.
To prevent this floating, in the web conveyor 102 shown in
The following describes a web conveyor 103 according to the third embodiment of the present invention.
The apparatus (equipment) for manufacturing absorbent articles is divided into units that represent a portion of a manufacturing step or a plurality of steps. The web is conveyed between units where predetermined manufacturing steps are performed, in order to produce a final product.
The absorber forming unit 300 includes a discharger 310 that discharges a ground pulp 400 and a drum 320 that has a suction mechanism for sucking up the discharged pulp 400. A mold 321 is formed in the drum 320, and mesh or the like is provided on a bottom 322 of the mold 321 in order to adsorb the pulp 400. The absorbers that are layered within the mold 321 by the drum 320 are arranged on the web 200 at predetermined intervals.
In the Uf unit (absorber forming unit 300) shown in
Since the unit Uf is provided with the drum 320 having the suction mechanism, the internal pressure of the unit Uf is lower than that of the unit Ur. Therefore, airflow AR occurs through the opening 330 from the unit Ur toward the unit Uf. Accordingly, the wind pressure on the web 200 and the workpieces 210, which are being conveyed from the unit Uf to the unit Ur, is greater than in a normal conveying path. Thus, it is assumed that the web 200 and the workpieces 210 are more likely to rise up.
On the other hand, in the present embodiment, as shown in
As shown in
As described above, the details of the embodiment of the present invention has been exemplarily disclosed. However, it should not be understood that the description and drawings which constitute part of this disclose limit the present invention. Based on this disclosure, various alternative embodiments, examples, and operation techniques are apparent to those skilled in the art.
In the above embodiments, the holding conveyor 120 presses the top surfaces of the web 200 and the workpieces 210 toward the belt conveyors 110A, 110B. However, the holding conveyor 120 may have any configuration that enables reliable conveying of the web 200 and the workpieces 210. For example, the belt conveyor can have a suction mechanism that can convey the web 200 and the workpieces 210 while adsorbing them.
In the above embodiments, the suction boxes were used as an example of a mechanism for sucking the bottom surface of the web 200. However, such a mechanism is not limited to the suction boxes and any mechanism capable of adsorbing the web 200 can be used.
As described above, the present invention naturally includes various embodiments which are not described herein. Accordingly, the technical scope of the present invention should be only determined according to the subject matters recited in the scope of claims which is appropriate based on the foregoing description.
The entire content of Japanese Patent Application No. 2009-229147 (filed on Sep. 30, 2009) is incorporated herein by reference.
According to the present invention, provided is a web conveyor that can prevent ripping of workpieces and skew of workpieces relative to the web while conveying the workpieces in a machine direction along a flow direction of manufacturing steps for an absorbent article, and can thereby reliably convey the workpieces.
Number | Date | Country | Kind |
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2009-229147 | Sep 2009 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2010/066576 | 9/24/2010 | WO | 00 | 5/4/2012 |