JP7253522B2 - Elastic sheet manufacturing method and sheet splicing device - Google Patents

Description

TECHNICAL FIELD The present invention relates to a method for producing a stretchable sheet that can be used as a constituent member of various articles that require stretchability, and more particularly, to a stretchable sheet having a sheet splicing step of overlapping and joining a succeeding sheet to a preceding sheet. related to the manufacturing method of The present invention also relates to a sheet splicing device that can be used in such a sheet splicing process.

Using a processing means having a pair of tooth groove rolls provided on the peripheral surface so that the tooth grooves that mesh with each other are along the rotation axis direction, and rotating the rolls to supply a sheet such as a nonwoven fabric to the meshing portion. Therefore, a technique for stretching the sheet has been proposed. For example, in Patent Document 1, a non-woven fabric in which a plurality of elastic filaments are arranged so as to extend in one direction without intersecting each other is applied to the mesh of the pair of tooth groove rolls with the extending direction of the elastic filaments as the flow direction. It is described that the nonwoven fabric is stretched by supplying it to a part. As a result of such stretching, high basis weight portions having a relatively high basis weight and low basis weight portions having a relatively low basis weight are alternately formed in the machine direction in the non-woven fabric to be processed. , the nonwoven becomes stretchable in the machine direction.

By the way, in the conventional technique described above, the sheet to be stretched is generally fed out from a wound body in a roll-like state to a processing line and continuously stretched. Therefore, in order not to stop the processing line, another sheet (following sheet) fed from another roll must It is necessary to perform a so-called sheet splicing operation. In the sheet splicing operation, as means for splicing the preceding sheet and the succeeding sheet, adhesives, adhesive tapes, fusion bonding such as heat sealing, and the like are used.
Patent Document 2 discloses a sheet splicing device for splicing thermoplastic resin sheets together, which includes means for forming an overlapping portion between a portion of a preceding sheet and a portion of a succeeding sheet, and heating the overlapping portion. and a means (heat sealer) for fusing the two sheets by pressing and a means for cooling the heated overlapping portion.
Further, Patent Document 3 describes a heat sealer that heats and melts an object using a thermoplastic resin while sandwiching and pressurizing the object in a press mechanism, and solidifies the object by turning off the power or cooling it with air. The heat sealer described in Patent Document 4 includes a heater wire that generates heat when energized as a heating means for heating an object. It has a wide zigzag shape.

When a sheet to be subjected to stretching processing as described in Patent Document 1 has a sheet spliced portion, the sheet spliced portion and a portion adjacent to the sheet spliced portion in the conveying direction of the sheet have different rigidity. As a result, there is a problem that the sheet breaks at the boundary between the two. In order to solve such a problem, in Patent Document 4, a sheet splicing portion formed on two sheets to be spliced is intermittently provided in a cross direction perpendicular to the conveying direction of the sheets, and It is described that it is not provided over the entire area in

Japanese Patent Application Laid-Open No. 2008-179128 Japanese Patent Publication No. 9-503471 JP 2015-120334 A JP 2012-207336 A

The technique described in Patent Document 4 is intended to solve the problem of sheet breakage that tends to occur when a sheet subjected to stretching has a seamed portion. Sheet breakage cannot be effectively prevented, and there is room for improvement.

SUMMARY OF THE INVENTION An object of the present invention is to provide a technique capable of effectively preventing troubles such as sheet breakage, which is a concern when stretching a sheet having a sheet joint portion.

In the present invention, a high basis weight portion having a relatively high basis weight and a low basis weight portion having a relatively low basis weight are provided in a state of being stretchable in one direction and stretched in at least the one direction. This is a method for manufacturing a stretchable sheet that is alternately arranged in one direction.
In one embodiment of the method for producing a stretchable sheet of the present invention, a base sheet continuous in one direction is conveyed so as to pass through the meshing portions of a pair of tooth groove rolls that mesh with each other, with the one direction being the transport direction. Thus, it has a stretching step of stretching the base sheet in the conveying direction to form the stretchable sheet.
In one embodiment of the method for producing a stretchable sheet of the present invention, the base sheet to be conveyed to the stretching step is a preceding sheet, and the preceding sheet is followed by another base sheet to be conveyed to the stretching step. a sheet splicing step in which a part of the succeeding sheet is overlapped with a part of the preceding sheet as the succeeding sheet and joined, and the joined succeeding sheet is supplied to the stretching process continuously with the preceding sheet; have.
In one embodiment of the stretchable sheet manufacturing method of the present invention, in the sheet joining step, the overlapping portion of the preceding sheet and the succeeding sheet is sandwiched between a pair of pressing members arranged to face each other. While applying pressure in the thickness direction of the overlapped portion, the sheets are fused and joined together in the overlapped portion by heating in the conveying cross direction that intersects the conveying direction using the heating means provided in the pressure member. are doing.
In one embodiment of the stretchable sheet manufacturing method of the present invention, the heating means includes first heat generating portions intermittently arranged in the conveying cross direction, and generating heat at a temperature lower than that of the first heat generating portions. and a second heat-generating portion located between the first heat-generating portions adjacent to each other in the direction.
In one embodiment of the stretchable sheet manufacturing method of the present invention, the length of the first heat generating portion in the conveying direction is the length of the repeating unit of the high basis weight portion and the low basis weight portion in the conveying direction. long compared to

Further, according to the present invention, a portion of a succeeding sheet is superimposed and joined to a portion of a preceding sheet conveyed along a conveying path toward a predetermined conveying destination, and the joined succeeding sheet is continued to the preceding sheet. It is a sheet splicing device that feeds out to the conveying path.
In one embodiment of the sheet splicing device of the present invention, the overlapping portion of the preceding sheet and the succeeding sheet is heated while being pressurized in the thickness direction, thereby fusing and joining the two sheets in the overlapping portion. It has a sheet joint that
In one embodiment of the sheet splicing device of the present invention, the sheet joining section includes a pair of pressing members arranged to face each other, and the overlapping section is sandwiched between the pair of pressing members so as to be pressurized. ing.
In one embodiment of the sheet splicing device of the present invention, at least one of the pair of pressure members is provided with heating means, and the overlapping portion sandwiched between the pair of pressure members is heated by heat generated by the heating means. made possible.
In one embodiment of the sheet splicing device of the present invention, the heating means includes first heat generating portions intermittently arranged in a conveying cross direction crossing the conveying direction of the preceding sheet, and heat is generated at a temperature lower than that of the first heat generating portions. and a second heat-generating portion located between the first heat-generating portions adjacent to each other in the conveying cross direction.
Other features, advantages and embodiments of the invention are described below.

ADVANTAGE OF THE INVENTION According to this invention, the technique which can prevent troubles, such as a sheet breakage|rupture, which is a concern when stretching the sheet|seat which has a sheet|seat joint part is provided effectively.

FIG. 1 is a perspective view schematically showing one embodiment of an elastic sheet manufactured according to the present invention, with a part broken away. 2A and 2B are cross-sectional views schematically showing cross sections along both the thickness direction and the extending direction of the elastic filaments of the elastic sheet shown in FIG. b) shows the stretched state. FIG. 3 is a perspective view schematically showing an example of the stretching step in the method for producing a stretchable sheet of the present invention. 4 is a cross-sectional view schematically showing a cross-section along the flow direction of the meshing portion of the pair of tooth groove rolls in the stretching step shown in FIG. 3. FIG. FIG. 5 is a perspective view schematically showing an example of the manufacturing process of the base sheet to be subjected to the stretching process in the stretchable sheet manufacturing method of the present invention. FIG. 6 is a diagram showing a schematic configuration of an embodiment of a sheet splicing device that can be used in the stretchable sheet manufacturing method of the present invention. 7 is a plan view schematically showing an example of a sheet splicing portion between a preceding sheet and a succeeding sheet formed by the sheet splicing device shown in FIG. 6. FIG. 8 is a schematic perspective view of a pair of pressure members in the sheet piecing device shown in FIG. 6. FIG. 9 is a plan view schematically showing an enlarged part of the heating means shown in FIG. 8. FIG. FIG. 10 is a plan view schematically showing an example of a state in the manufacturing process of the elastic sheet after stretching of the sheet joint portion shown in FIG. 7 . 11(a) and 11(b) are plan views (equivalent to FIG. 7) schematically showing another example of the sheet joining portion between the preceding sheet and the succeeding sheet that can be employed in the present invention. be. Fig. 12(a) is a plan view schematically showing an example of a non-stretched state of the elastic sheet after stretching the sheet spliced portion shown in Fig. 7, and Fig. 12(b) is shown in Fig. 11(a). FIG. 4 is a plan view schematically showing an example of a non-stretched state of the stretchable sheet after stretching of the sheet spliced portion. FIG. 13(a) is a schematic plan view of another embodiment of the heating means according to the present invention, and FIG. 13(b) is a sheet spliced portion formed using the heating means shown in FIG. 13(a). is a plan view (equivalent to FIG. 7) schematically showing the . FIG. 14(a) is a schematic plan view of still another embodiment of the heating means according to the present invention, and FIG. 14(b) is a sheet joint formed using the heating means shown in FIG. 14(a). FIG. 7 is a plan view (equivalent to FIG. 7) schematically showing a part;

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, the present invention will be described based on its preferred embodiments with reference to the drawings. In addition, in the following description of the drawings, the same or similar reference numerals are given to the same or similar parts. The drawings are basically schematic, and the ratio of each dimension may differ from the actual one.

FIGS. 1 and 2 show a stretchable sheet 10, which is one embodiment of the stretchable sheet manufactured by the present invention. The stretchable sheet 10 has stretchability in one direction X, and as shown in FIG. Low basis weight portions 15 having a relatively low basis weight are alternately arranged in one direction X. As shown in FIG. The direction X matches the transport direction (machine direction) MD of the stretchable sheet 10 when it is manufactured, and the direction Y, which will be described later, matches the orthogonal transport direction CD orthogonal to the transport direction MD.

In this embodiment, the stretchable sheet 10 comprises two layers of fiber sheets 11 and 12 facing each other, and a plurality of stretchable sheets 10 extending in one direction X without intersecting each other and arranged between the two layers of fiber sheets 11 and 12. of elastic filaments 13. A plurality of elastic filaments 13 are joined to the extensible fibrous sheets 11, 12 over their entire lengths in a substantially unstretched state.

The fiber sheets 11 and 12 may be of the same type or of different types. The term "of the same type" as used herein means that the fiber sheets to be compared have the same manufacturing process, type of constituent fibers, fiber diameter and length of the constituent fibers, thickness and basis weight of the fiber sheets. means. If any one of these is different, the contrasting fibrous sheets are "dissimilar" to each other.

Both of the fiber sheets 11 and 12 are stretchable. The fiber sheets 11 and 12 are stretchable in the direction in which the elastic filaments 13 extend (direction X). The term "stretchable" as used herein includes (1) the case where the constituent fibers themselves of the fiber sheets 11 and 12 are elongated, and (2) the case where the constituent fibers themselves are not elongated but the fibers bonded at the intersections are It includes cases where the fiber sheets 11 and 12 as a whole elongate due to separation, a structural change in the three-dimensional structure formed by a plurality of fibers due to bonding between fibers, etc., or breakage of the constituent fibers. .

The elastic filament 13 is formed by stretching a melted or softened elastic resin. The plurality of elastic filaments 13 are arranged continuously along the entire length of the elastic sheet 10 in the X direction. The plurality of elastic filaments 13 are arranged so as to extend in one direction (direction X) without intersecting each other. The elastic filaments 13 are joined between the fiber sheets 11, 12 in a substantially non-stretched state. The elastic filaments 13 and the fiber sheets 11 and 12 are joined together by fusing the constituent fibers (non-elastic fibers) of both the fiber sheets 11 and 12 to the elastic filaments 13 while they are buried in the elastic filaments 13. It is not made using an adhesive such as a hot-melt adhesive. Therefore, there is no adhesive between the fiber sheets 11, 12 (stretchable fiber sheets mainly composed of inelastic fibers) and the elastic filaments 13 joined thereto.

The stretchable sheet 10 is stretchable in the direction in which the elastic filaments 13 extend (direction X). The stretchability of the stretchable sheet 10 is developed due to the elasticity of the elastic filaments 13 . When the elastic sheet 10 is stretched in the direction in which the elastic filaments 13 extend, the elastic filaments 13 and the fiber sheets 11 and 12 are elongated. When the stretching of the stretchable sheet 10 is released, the elastic filaments 13 contract, and the fiber sheets 11 and 12 return to the state before stretching along with the contraction. Further, in the stretchable sheet 10, there are no other elastic filaments that are connected perpendicularly to the elastic filaments 13. As shown in FIG. Therefore, when the stretchable sheet 10 is stretched in the same direction as the direction in which the elastic filaments 13 extend, the stretchable sheet 10 can be stretched with almost no width shrinkage.

The fiber sheets 11 and 12 constituting the stretchable sheet 10 may each be a nonwoven fabric of staple fibers. Nonwoven fabrics include air through nonwoven fabrics, heat roll nonwoven fabrics, spunlace nonwoven fabrics, spunbond nonwoven fabrics, meltblown nonwoven fabrics, and the like.
The elastic filaments 13 forming the stretchable sheet 10 are made of thermoplastic elastomer, rubber, or the like, for example. In particular, when a thermoplastic elastomer is used as a raw material, it can be melt-spun using an extruder like a normal thermoplastic resin, and the elastic filaments thus obtained are easy to heat-seal. Suitable for sheet 10 . Examples of thermoplastic elastomers include styrenes such as SBS (styrene-butadiene-styrene), SIS (styrene-isoprene-styrene), SEBS (styrene-ethylene-butadiene-styrene), and SEPS (styrene-ethylene-propylene-styrene). elastomer, olefin elastomer (ethylene-based α-olefin elastomer, propylene-based elastomer obtained by copolymerizing ethylene/butene/octene, etc.), polyester-based elastomer, polyurethane-based elastomer, etc., and one of these may be used alone or Two or more kinds can be used in combination. Moreover, core-sheath type or side-by-side type composite fibers made of these resins can also be used.

As shown in FIG. 2(a), the elastic sheet 10 has a wavy shape in which crests 14a and troughs 14b are alternately arranged in a natural state. The top portion 14a and the valley portion 14b are connected via the ridgeline portion 15a. The ridgeline portion 15a has a slightly smaller thickness than the top portion 14a and the valley portion 14b, and therefore has a higher light transmittance than the top portion 14a and the valley portion 14b. In addition, the top portion 14a, the ridge portion 15a, and the valley portion 14b each extend in a direction (direction Y) perpendicular to the stretching direction (direction X) of the stretchable sheet 10 . Therefore, when the elastic sheet 10 in the natural state is viewed from above, the ridges 15a having relatively high light transmittance and the tops 14a and valleys 14b having relatively low light transmittance correspond to each other. A striped pattern in which a plurality of linear or band-shaped regions with different hues extending in the direction Y are arranged side by side in the direction X can be visually recognized.

In the stretchable sheet 10, when stretched in the stretching direction (direction X) of the elastic filaments 13, as shown in FIG. alternately arranged. More specifically, in the elastic sheet 10 in the stretched state, a plurality of repeating units of the high basis weight portion 14 and the low basis weight portion 15 are continuous in the direction X, and the high basis weight portion 14 and the low basis weight portion are formed in the direction X. 15 are alternately repeated at a constant cycle. The high basis weight portion 14 and the low basis weight portion 15 each extend in a direction (direction Y) orthogonal to the direction in which the elastic filaments 13 extend.
The high basis weight portion 14 is derived from the top portion 14a or the valley portion 14b of the elastic sheet 10 in the natural state shown in FIG. It originates from the ridgeline portion 15a of the adhesive sheet 10. FIG.
The high basis weight portion 14 is derived from the top portion 14a in the elastic sheet 10 in the natural state and protrudes on the same side as the top portion 14a, and the valley portion 14b in the elastic sheet 10 in the natural state is derived from the valley portion. 14b may protrude on the same side, and both may be alternately arranged in the X direction.
Since there is a difference in light transmittance between the high basis weight portion 14 and the low basis weight portion 15 due to the difference in basis weight, the elastic sheet 10 in the stretched state has a relatively high light transmittance. Stripes in which a plurality of linear or band-like regions extending in the direction Y and having different hues are arranged side by side in the direction X corresponding to the basis weight portion 15 and the high basis weight portion 14 having relatively low light transmittance. present a pattern.

The stretchable sheet produced by the present invention is suitable as constituent members such as topsheets, backsheets, three-dimensional gathers and exterior materials of absorbent articles typified by, for example, disposable diapers, sanitary napkins and bodily fluid absorbent pads. can be used. In addition to this, it is suitably used as a constituent member of various articles that require stretchability.

Next, the method for manufacturing the elastic sheet of the present invention will be described by taking the method for manufacturing the elastic sheet 10 described above as an example. FIG. 3 shows a portion (stretching device) for performing the stretching step in the manufacturing device 1 suitable for implementing the method for manufacturing the stretchable sheet 10 .
The manufacturing method of the stretchable sheet 10 includes the base sheet 9 continuous in one direction, the one direction being the conveying direction (machine direction) MD, and the meshing portions of the pair of tooth groove rolls 2 and 3 meshing with each other. It has a stretching step of stretching the base sheet 9 in the transport direction MD by transporting it so as to pass through. The base sheet 9 does not substantially have stretchability, and is stretched in the transport direction MD by being subjected to a stretching step and subjected to stretching processing, so that it becomes stretchable in the same direction MD. .

In the present embodiment, as shown in FIG. 3, the manufacturing apparatus 1 is arranged on the upstream side in the conveying direction MD of the tooth groove rolls 2 and 3, and the original fabric 91 of the base sheet 9 wound in a roll shape is provided. is attached, a pair of infeed rolls 4 and 4 arranged between the roll support shaft 41 and the tooth groove rolls 2 and 3, and downstream in the conveying direction MD from the tooth groove rolls 2 and 3 and a pair of outfeed rolls 5, 5 arranged side by side. By rotationally driving the roll support shaft 41, the base sheet 9 is fed out from the raw roll 91, and the fed base sheet 9 is supplied between the tooth groove rolls 2 and 3 by the pair of infeed rolls 4 and 4. be done. A pair of outfeed rolls 5, 5 pulls out the base sheet 9a stretched between the tooth gap rolls 2, 3 from the tooth gap rolls 2, 3 and conveys it to the next process. The manufacturing apparatus 1 includes a drive section (not shown) for rotating at least one of the pair of infeed rolls 4 and 4 and the pair of outfeed rolls 5 and 5 .

Therefore, in the method for manufacturing the elastic sheet 10 using the manufacturing apparatus 1, the base sheet 9 is supplied from the pair of infeed rolls 4, 4 to the meshing portions of the tooth groove rolls 2, 3 that mesh with each other, and A stretching step of stretching the base sheet 9 in the conveying direction MD between 2 and 3, and supplying the base sheet 9a stretched by the tooth groove rolls 2 and 3 to a pair of outfeed rolls 5 and 5. , pulling out the substrate sheet 9a from the tooth groove rolls 2 and 3 while applying tension to the substrate sheet 9a in the conveying direction MD by both rolls 5 and 5, and the substrate stretched by the tooth groove rolls 2 and 3. The material sheet 9a becomes the elastic sheet 10 by being given a desired tension in the drawing process.

In the method for manufacturing the elastic sheet 10 using the manufacturing apparatus 1, the peripheral speed of the infeed roll 4 is set to a predetermined speed with respect to the peripheral speed of the tooth groove rolls 2 and 3 in the state of meshing with each other. A desired tension is applied to the base sheet 9, or the peripheral speed of the in-feed roll 4 is set to a predetermined speed with respect to the delivery speed of the base sheet 9 delivered from the raw roll 91 attached to the roll support shaft 41. , the desired tension is applied to the base sheet 9 .

One of the pair of tooth groove rolls 2 and 3 is a driving roll and the other tooth groove roll is a co-rotating roll. In the manufacturing apparatus 1, the tooth space roll 2 positioned below the base sheet 9 which is the workpiece is a drive roll, and the tooth space roll 3 positioned above the base sheet 9 is a co-rotating roll. Of course, both the tooth groove rolls 2 and 3 may be drive rolls. The tooth groove rolls 2 and 3 are arranged such that their axial directions are parallel to each other and tooth grooves provided on the peripheral surfaces of the rolls are engaged with each other. The tooth space rolls 2, 3 are adapted to rotate in opposite directions to each other about their axes.

The tooth groove rolls 2 and 3 are composed of rolls of the same form, and as shown in FIG. ing. More specifically, the tooth groove roll 2 has axially extending teeth (ridges) 20 and axially extending grooves 21 alternately along the circumferential direction of the roll. ing. Similarly, the tooth groove roll 3 has axially extending teeth (ridges) 30 and axially extending grooves 31 alternately along the circumferential direction of the roll. The height of the teeth 20 on the tooth gap roll 2 is the same as that of the teeth 30 on the tooth gap roll 3 . Also, the pitch between adjacent teeth 20 in the tooth gap roll 2 is the same as that of the teeth 30 in the tooth gap roll 3 . Here, the tooth height of the tooth groove roll means the length from the root to the tip of the tooth. Also, the pitch between adjacent teeth in the tooth groove roll means the distance between the center line of one tooth and the center line of the adjacent tooth. The width of the teeth 20 and 30 may be uniform over the entire height direction, or they may be trapezoidal teeth that taper from the root of the tooth to the tip of the tooth. Moreover, it is preferable to chamfer the corners of the tips of the teeth 20 and 30 .

In the manufacturing apparatus 1, while the tooth groove rolls 2 and 3 are rotating, the base sheet 9 supplied to the meshing portion thereof is stretched in the conveying direction MD, and stretched along the conveying direction MD. Gives extensibility. 4, the teeth 20 of the tooth space roll 2 are meshed with the grooves 31 of the tooth space roll 3, and the teeth 30 of the tooth space roll 3 are engaged with the tooth space roll 2. Engaged in the grooves 21, the base sheet 9 is stretched or stretched between the teeth 20 of the toothed roll 2 and the adjacent teeth 30 of the toothed roll 3.

More specifically, the base sheet 9 is hardly stretched in the regions (between P3-P2 and between P1-P4) contacting the teeth 20, 30 of the tooth gap rolls 2, 3, but it is a driving roll. In the region (between P2 and P1) pressed by the tooth surfaces of the teeth 20 of the tooth groove roll 2 toward the tooth surfaces of the teeth 30 of the tooth groove roll 3, which is the driven roll, the teeth 20 and 30 are greatly stretched. be done. In addition, the base sheet 9 is separated from the teeth 30 of the tooth gap roll 3 by the tips of the teeth 20 of the tooth gap roll 2 (between P4 and P3), which is not as large as the area (between P2 and P1). is greatly stretched. Further, the base sheet 9 is hardly stretched in the regions (between P3-P2 and between P1-P4) contacting the tips of the teeth 20, 30 of the tooth groove rolls 2, 3, but the teeth 20, 30 Since the front end portion of the base sheet 9 is biased in its radial direction, that is, in the thickness direction of the base sheet 9, the base sheet 9 is thinned in the thickness direction.
By such a drawing process, it is possible to efficiently draw both the fiber sheets 11 and 12 in the base sheet 9 while preventing the separation of the elastic filaments 13 and the two fiber sheets 11 and 12. The base sheet 9a stretched by the rolls 2 and 3 has stretchability in the transport direction MD. Then, in the base sheet 9a, and further in the elastic sheet 10 obtained by applying a desired tension to the base sheet 9a, the greatly stretched regions (between P2-P1 and between P4-P3) have a low basis. The high grammage portion 14 is the high grammage portion 15, and the region that is hardly stretched (between P3 and P2 and between P1 and P4).

5 shows an example of the manufacturing process of the base sheet 9. As shown in FIG. In the manufacturing process of the base sheet 9 shown in FIG. 5, the base sheet 9 is formed by bonding a plurality of elastic filaments 13 to the fiber sheets 11 and 12 so as to extend in one direction and in a substantially unstretched state. to manufacture. The elastic filaments 13 are spun from a plurality of spinning nozzles 16 provided at the lower end of the spinning head 17 . The spinning head 17 is connected to an extruder (not shown), and the elastic resin, which is the raw material of the elastic filaments 13, is supplied to the spinning head 17 by the extruder in a melt-kneaded state, and spun from the spinning nozzle 16. be The spinning nozzles 16 are intermittently arranged along the orthogonal transport direction CD orthogonal to the transport direction MD of the fiber sheets 11 and 12 .

In the manufacturing process of the base sheet 9 shown in FIG. 5, a plurality of molten elastic filaments 13 spun out from the spinning nozzle 16 are drawn at a predetermined speed and stretched, and before the elastic filaments 13 are solidified, the elastic filaments 13 are drawn. The elastic filaments 13 are welded to the two fiber sheets 11 and 12 so that the filaments 13 are arranged in one direction without intersecting each other. The melted elastic filaments 13 spun out from the spinning nozzle 16 join the two fiber sheets 11 and 12 respectively fed out from the raw fabric at the same speed, and are sandwiched between the fiber sheets 11 and 12. Both fiber sheets 11 and 12 are pinched by a pair of nip rolls 18 and 18 in this state. Thus, the base sheet 9 is manufactured.

The base sheet used in the present invention is the base sheet 9 described above, that is, "a base sheet in which a plurality of elastic filaments 13 are joined to fiber sheets 11 and 12 over their entire lengths in a substantially unstretched state." In short, although it does not inherently have stretchability, the above-mentioned stretching step (a pair of tooth groove rolls that mesh with each other with the base sheet continuous in one direction as the conveying direction By conveying so as to pass through the meshing portion of the base sheet, the base sheet is subjected to the step of stretching in the conveying direction), whereby the high basis weight portion with a relatively high basis weight and the relatively basis weight and low basis weight portions are alternately formed in the conveying direction MD of the base sheet so that the base sheet has stretchability in the conveying direction MD.

As the base sheet used in the present invention, in addition to the base sheet 9 described above, for example, paper, a single-layer nonwoven fabric, a resin film, a laminate of two or more types of nonwoven fabrics, a laminate of a resin film and a nonwoven fabric, and the like. mentioned. Specifically, the base sheet may be a thermoplastic polymer nonwoven fabric of polyolefin fibers selected from polypropylene fibers, fibers composed of a composition of polypropylene and polyethylene, and bicomponent fibers of polypropylene and polyethylene.
The base sheet is preferably a nonwoven fabric containing elastic fibers from the viewpoint of imparting extensibility and softness to the base sheet by the stretching process described above. The aforementioned base sheet 9 is a type of nonwoven fabric containing elastic fibers.
As another specific example of the nonwoven fabric containing elastic fibers, a non-elastic fiber layer composed of substantially non-elastic fibers is disposed on at least one side of the elastic fiber layer containing elastic fibers, and both fiber layers are composed of the elastic fibers. A stretchable nonwoven fabric in which the constituent fibers of the fiber layer are joined by heat fusion while maintaining the fiber form can be mentioned. When the base sheet has elasticity, the base sheet after stretching can exhibit stretchability along the stretching direction. Examples of the elastic fibers include fibers made from thermoplastic elastomers such as styrene-based elastomers, polyolefin-based elastomers, polyester-based elastomers or polyurethane-based elastomers, and elastic resins such as rubber. Examples of the inelastic fibers include fibers made of polyethylene (PE), polypropylene (PP), polyester (PET or PBT), polyamide, and the like.

In the above steps, since the stretchable sheet 10 is continuously manufactured, in order not to stop the production line, the base sheet 9 unwound from the original fabric 91 attached to the roll support shaft 41 is joined to the base sheet 9 fed out from a different raw roll than the raw roll 91, that is, a sheet splicing operation is required before the feeding is completed. The sheet splicing operation is performed prior to the stretching step described above. In this embodiment, a sheet splicing operation is performed between the roll support shaft 41 and the infeed roll 4 .

FIG. 6 shows a sheet splicing device 40 that is suitably used for sheet splicing operations. The manufacturing apparatus 1 includes a sheet piecing device 40 . The sheet splicing device 40 overlaps and joins a part of the succeeding sheet to a part of the preceding sheet conveyed along the conveying path toward a predetermined conveying destination (for example, a pair of tooth groove rolls 2 and 3). In addition, the following sheet is fed to the conveying path continuously with the preceding sheet.

In this embodiment, the sheet splicing device 40 is provided with a further roll support shaft 42 in addition to the roll support shaft 41 described in the stretching step, and the sheet splicing device 40 is provided with a roll support shaft 42 which is fed out from the raw fabric 91 attached to the roll support shaft 41 . The first sheet 9A and the second sheet 9B fed out from the original fabric 92 attached to the roll support shaft 42 are joined together, and one of the two sheets 9A and 9B is alternately conveyed. Therefore, in this embodiment, 1) the first sheet 9A is the leading sheet and the second sheet 9B is the trailing sheet, and 2) the second sheet 9B is the leading sheet and the first sheet 9A is the trailing sheet. There is. FIG. 6 shows the case of 1) above.
The raw fabric 92 (second sheet 9B) is the base sheet 9 and is the same as the raw fabric 91 (first sheet 9A). The roll support shaft 42 is configured similarly to the roll support shaft 41 .

In the present embodiment, the sheet splicing device 40 serves as a sheet supply device, and includes a roll support shaft 41 to which the original fabric 91 is attached, a roll support shaft 42 to which the original fabric 92 is attached, and a roll support shaft 41 (original fabric 91). A first drive unit (not shown) that rotates and stops, a second drive unit (not shown) that rotates and stops the roll support shaft 42 (raw material 92), A guide roll 43 that guides the first sheet 9A and a guide roll 44 that guides the second sheet 9B fed out from the raw fabric 92 are provided.

The sheet splicing device 40 includes a sheet splicing unit 50 that fuses and joins the overlapping portions of the preceding sheet and the trailing sheet by heating the overlapping portions while applying pressure in the thickness direction of the sheets. there is

FIG. 7 shows an overlapping portion 90 between the trailing end portion 9AR of the first sheet 9A, which is the preceding sheet, in the conveying direction MD and the leading end portion 9BF of the second sheet 9B, which is the succeeding sheet, in the conveying direction MD. . In this embodiment, the sheet joining portion 50 heats the overlapping portion 90 while pressing it in the thickness direction. The overlapping portion 90 shown in FIG. 7 is after the pressurization and heat treatment by the sheet joining portion 50, and the fused portions 93 formed by such pressurization and heat treatment are intermittently arranged in the conveyance orthogonal direction CD. . The details of the fused portion 93 will be described later.

As shown in FIGS. 6 and 8, the sheet joining section 50 includes a pair of pressure members 51 and 52 arranged opposite to each other. made possible. At least one of the pair of pressurizing members 51 and 52 is provided with heating means 56 so that the overlapping portion 90 sandwiched between the pair of pressurizing members 51 and 52 can be heated by heat generated by the heating means 56. .

In this embodiment, as shown in FIG. 8, the pair of pressure members 51 and 52 each have a long shape in the direction perpendicular to the transport direction CD, and the sheets 9A and 9B to be processed are stretched over the entire length of the direction perpendicular to the transport direction CD. can be pressurized over
In this embodiment, only the pressure member 51 of the pair of pressure members 51 and 52 has the heating means 56 . Therefore, the overlapping portion 90 sandwiched between the pair of pressure members 51 and 52 is heated by the heating means 56 at the surface facing the pressure member 51 . In addition, in the present invention, both the pair of pressure members 51 and 52 may be provided with the heating means 56 .
Further, in the present embodiment, of the pair of pressure members 51 and 52, the pressure member 51 provided with the heating means 56 is fixed, whereas the pressure member 52 not provided with the heating means 56 is fixed. It is connected to a driving portion 59 such as an air cylinder, and arranged to be movable forward and backward with respect to the pressure member 51 . In the present invention, both of the pair of pressure members 51 and 52 may be movable forward and backward relative to the other.

In this embodiment, the sheet splicing device 40 includes cooling means for cooling the overlapping portion 90 heated by the heating means 56 . Specifically, as shown in FIG. 6, from the pressurizing surface of the pressurizing member 52 (the surface facing the pressurizing member 51) in contact with the overlapping portion 90, which is the object to be cooled, from the outside through the coolant supply pipe 53. A gas such as air is injected as a supplied coolant, and the overlapping portion 90 in contact with the pressurized surface is cooled by this injected gas. In this embodiment, the cooling means for the overlapping portion 90 is thus an air cooling means using gas as a coolant, but the type of such cooling means is not particularly limited in the present invention. Cold means may be used.

In this embodiment, the sheet splicing device 40 includes cutting means 54 and 55 arranged upstream in the conveying direction MD from the sheet joining portion 50 (the pair of pressing members 51 and 52) and cutting the preceding sheet. there is The cutting means 54 is for cutting the first sheet 9A, and the cutting means 55 is for cutting the second sheet 9B. is used to cut the preceding sheet after it has been spliced by the sheet splicer 50 . The cutting means 54, 55 may be any means capable of cutting the sheets 9A, 9B (base material sheet 9), for example, cutting means may be one in which a blade is brought into contact with the object to be cut. It is also possible to fuse the object to be cut by laser irradiation. Also, the cutting means 54 and 55 may be movable along the conveying path of the sheets 9A and 9B.

In this embodiment, the sheet splicing device 40 is arranged between the sheet joining section 50 and the conveying destination (the pair of tooth groove rolls 2 and 3), and stores the preceding sheet (the first sheet 9A in FIG. 6). A device 60 is provided so that the preceding sheet stored in the storage device 60 can be delivered to the destination while the transportation of the preceding sheet is stopped.

The storage device 60 is a known device that is also called an accumulator. In this embodiment, as shown in FIG. 6, the storage device 60 includes a pair of roll units 61 and 62 that are arranged facing each other with a predetermined interval in the horizontal direction. 63 are intermittently arranged in the vertical direction. While the fixed roll unit 61 is fixed, the movable roll unit 62 is arranged so as to move forward and backward relative to the fixed roll unit 61 . The preceding sheet (the first sheet 9A in FIG. 6) is alternately stretched over the rolls 63 in the order of the fixed roll unit 61 and the movable roll unit 62 in a bellows shape. , a predetermined tension is applied to the preceding sheet. For example, if the supply amount of the preceding sheet is larger than the discharge amount, the movable roll unit 62 moves away from the fixed roll unit 61 , thereby increasing the amount of the preceding sheet stored in the storage device 60 . Further, when the supply amount of the preceding sheet is smaller than the discharge amount, the movable roll unit 62 moves toward the fixed roll unit 61, thereby reducing the amount of the preceding sheet stored in the storage device 60. FIG. In other words, the storage device 60 is capable of storing a predetermined length of the preceding sheet such that even if the transport speed of the preceding sheet as it enters the storage device 60 is zero, the preceding sheets stored in the storage device 60 The sheet can be fed downstream in the transport direction MD, thereby maintaining the tension of the preceding sheet at a predetermined value.

In this embodiment, the sheet splicing device 40 includes the first driving section and the second driving section, the sheet joining section 50 (the pair of pressing members 51 and 52 and the heating means 56), the cooling means, the cutting means 54, 55, a control section (not shown) for controlling the operation of each section including the storage device 60, etc., and each section of the sheet splicing device 40 operates under the control of the control section. The control section includes, for example, a CPU, a ROM, a RAM, and the like.

As shown in FIG. 6, when the first sheet 9A is continuously conveyed as the preceding sheet to the pair of tooth groove rolls 2 and 3 as the conveying destination, the second sheet 9B as the succeeding sheet is conveyed as follows. It is in a standby state in preparation for the sheet splicing process. It stands still while being positioned between 51 and 52 . Such a waiting state of the trailing sheet 9B may be performed manually. Also, a suction means such as a vacuum roller may be arranged in the vicinity of the sheet joining portion 50 to suck and hold the portion of the second sheet 9B in the standby state, which is fed out from the original sheet 92 .

On the other hand, in the storage device 60, the movable roll unit 62 is at the standby position indicated by reference numeral P1 in FIG. When the amount decreases (the diameter of the original sheet 91 of the first sheet 9</b>A decreases), it starts to move away from the fixed roll unit 61 . As a result, the storage amount of the first sheet 9A in the storage device 60 is increased. When the movable roll unit 62 is at the paper splicing start position P2, the sheet splicing operation is started, and the first sheet 9A stored in the storage device 60 is delivered to the transport destination (the pair of tooth groove rolls 2 and 3). Furthermore, by completing the sheet splicing operation, the first sheet 9A (preceding sheet) can be switched to the second sheet 9B (following sheet) without stopping the production line.

The sheet splicing operation is typically performed after stopping the rotation of the roll support shaft 41 to stop feeding the first sheet 9A from the original fabric 91 and joining the first sheet 9A and the second sheet 9B. , cutting the first sheet 9A at a position on the upstream side in the transport direction MD from the joining position (overlapping portion 90). Cutting of the first sheet 9</b>A is performed by the cutting means 54 .

The joining of the first sheet 9A and the second sheet 9B is specifically performed by the following procedure. That is, the pressure member 52 moves toward the pressure member 51, and overlaps the leading edge portions 9BF of the first sheet 9A and the second sheet 9B positioned between the pair of pressure members 51 and 52 to form an overlapping portion. 90 (see FIG. 7) is formed, and while the overlapping portion 90 is sandwiched between the pair of pressure members 51 and 52 and pressed in the thickness direction, the heating means 56 provided in the pressure member 51 is used to convey. By heating in the cross direction, both sheets 9A and 9B in the overlapped portion 90 are fused and joined. As shown in FIG. 7, the heating means 56 extends in the direction perpendicular to the transport direction CD, so that the heating means 56 generates heat in the vicinity of the overlapped portion 90, thereby moving the overlapped portion 90 in the cross-transportation direction. In practice, it can be heated in the direction perpendicular to the conveying direction CD.

In this specification, the term "intersecting direction of transport" refers to a direction in which the acute side of the angle formed with the transport direction MD is 45 degrees or more. The orthogonal transport direction CD is one of the cross transport directions.

After the leading end portion 9BF of the second sheet 9B (following sheet) is spliced to the trailing end portion 9AR of the first sheet 9A (preceding sheet) in this manner, the second sheet 9B is then subjected to the next stretching step. The second sheet 9B is conveyed and becomes the preceding sheet. While the second sheet 9B is being continuously conveyed to the stretching step, a new original sheet 91 is attached to the roll support shaft 41, and a new first sheet 9A (following sheet) fed out from the original sheet 91 ) is in the above-described standby state in preparation for the next sheet splicing process. Then, when the remaining amount of the second sheet 9B (preceding sheet) becomes small, a new first sheet is placed on a part (end portion) of the second sheet 9B (preceding sheet) in the same procedure as described above. A part (starting end) of the sheet 9A (following sheet) can be overlapped and joined. In this manner, the sheet splicing device 40 alternately splices the first sheet 9A and the second sheet 9B.

The sheet splicing process described above is basically the same as the conventional sheet splicing process. In the stretching process by the grooved rolls 2 and 3, the sheet is more difficult to be stretched than the other parts, and if the strength of the sheet is low, the sheet may be broken, resulting in problems such as a decrease in productivity and damage to the toothed rolls. The present invention is characterized by devising the heating means 56 used for heating the overlapping portion of the preceding sheet and the succeeding sheet in the sheet splicing step in order to prevent the spliced portion from breaking during the stretching step. be done. As one of the characteristic configurations of the heating means 56, as shown in FIGS. It has a second heat generating portion 58 which generates heat at a lower temperature than the portion 57 and is positioned between the first heat generating portions 57 adjacent to each other in the cross-transport direction.

In this embodiment, as shown in FIG. 8, the heating means 56 is provided on the surface layer portion of the pressure member 51 on the side of the pressure surface (the surface facing the pressure member 52) 51a. It extends continuously over the entire length in the direction CD, and has a zigzag shape that oscillates in a direction parallel to the transport direction MD in plan view. In such a zigzag-shaped heating means 56 in a plan view, a convex portion protruding in the same direction as the transport direction MD and a convex portion protruding in a direction opposite to the transport direction MD are arranged in the cross-transport direction (perpendicular to the transport direction CD). are arranged alternately. The former projection and the latter projection have the same length L1 in the direction of projection (see FIG. 9). constant. The first heat generating portions 57 extend parallel to the transport direction MD and are intermittently arranged in the transport orthogonal direction CD.

In this embodiment, the first heat-generating portion 57 and the second heat-generating portion 58 are part of one conductive member that is continuous in the cross-transportation direction (perpendicular to the transport direction CD). Both of the heat generating portions 57 and 58 generate heat when energized. More specifically, in the present embodiment, the heating means 56 is composed of one sheet of conductive member, and the heating means 56 as a whole generates heat by energizing the one sheet of conductive member. The conductive member constituting the heating means 56 may be any conductive member, and typically a metal member is used. A specific example of the heating means 56 is a nichrome plate member.

In the present embodiment, as shown in FIG. 9, the length of the direction perpendicular to the direction in which the current flows when the first heating portion 57 and the second heating portion 58 are energized (hereinafter also referred to as the "perpendicular current direction"). different. Specifically, the first heat generating portion 57, which generates heat at a relatively high temperature and generates a large amount of heat, is longer than the second heat generating portion 58, which generates heat at a relatively low temperature and generates a small amount of heat. short.
The amount of heat generated by the heat generating portions 57 and 58 is proportional to the resistance value of the heat generating portions 57 and 58, and the resistance value is inversely proportional to the cross-sectional area of the heat generating portions 57 and 58 along the direction perpendicular to the current. Here, the area of the cross section is the product of the thickness of the heat generating portions 57 and 58 and the length in the direction orthogonal to the current. The area of is proportional to the length in the direction perpendicular to the current. Therefore, the shorter the length in the direction orthogonal to the current, the greater the amount of heat generated by the heat generating portions 57 and 58, so that the object to be heated (overlapping portion 90) can be heated at a high temperature.
Further, in the present embodiment, since the planar shape of the first heat generating portion 57 is elongated in the transport direction MD (rectangular shape), the direction in which the current flows in the first heat generating portion 57 is the transport direction MD. The length of the first heat generating portion 57 in the current orthogonal direction is equal to the length (width) W2 of the first heat generating portion 57 in the transport orthogonal direction CD. On the other hand, since the shape of the second heat generating portion 58 in plan view is elongated (rectangular shape) in the direction orthogonal to the transport direction CD, the direction in which the current flows in the second heat generating portion 58 is the direction orthogonal to the transport direction CD. The length of the portion 58 in the current orthogonal direction is equal to the length (width) W3 of the second heat generating portion 58 in the transport direction MD.
As described above, in the present embodiment, the magnitude relationship of “width of the first heat generating portion 57 (length in the direction perpendicular to the current) W2<width of the second heat generating portion 58 (length in the direction perpendicular to the current) W3” is established. there is

Assuming that the width W2 of the first heat generating portion 57 is shorter than the width W3 of the second heat generating portion 58, it is preferably 0.5 mm or more, more preferably 1 mm or more, and preferably 10 mm or less, more preferably 5 mm or less.
Assuming that the width W3 of the second heat generating portion 58 is longer than the width W2 of the first heat generating portion 57, it is preferably 1 mm or more, more preferably 2 mm or more, and preferably 20 mm or less, more preferably 10 mm or less. is.

In this embodiment, the pressure member 51 is provided with the heating means 56, and both are integrated. A heating means 56 consisting of a single conductive member (for example, a plate-like member made of nichrome) is arranged on the surface (the surface corresponding to the pressure surface 51a), and the entire surface is covered with an insulating adhesive tape such as a glass tape. can be exemplified. The role of the insulating adhesive tape is not only insulation but also fixing of the heating means 56 and prevention of adhesion of the forming material (resin, etc.) to the pressurized object (base material sheet). Examples of the insulating main body include wood and plastic.
The material of the pressure member 51 that does not have the heating means 56 is not particularly limited, and metal, plastic, wood, or the like can be used, for example.

If such a heating means 56 having a partially different heating temperature is used as the heating means for heating and fusing the overlapping portion of the preceding sheet and the succeeding sheet in the sheet splicing process, the overlapping portion will be: A high-temperature heated portion is formed by the first heat-generating portion 57 that generates heat at a relatively high temperature, and a low-temperature heated portion is formed by the second heat-generating portion 58 that generates heat at a relatively low temperature. Depending on the heating temperature and the type of the base sheet, the high-temperature heated portion typically loses the shape of the constituent fibers of the base sheet and forms a film.

The overlapping portion 90 shown in FIG. 7 is heated by the heating means 56 while being pressed between the pair of pressure members 51 and 52, and the fused portions 93 are intermittently arranged in the direction perpendicular to the transport direction CD. . The fusion-bonded portion 93 is a high-temperature heated portion heated by the first heat-generating portion 57. At the fusion-bonded portion 93, the preceding sheet (first sheet 9A) and the succeeding sheet (second sheet 9B) are fused. are doing. On the other hand, the sheets 9A and 9B are not fused in the portion heated by the second heat generating portion 58 (low-temperature heated portion) in the overlapping portion 90 shown in FIG.

FIG. 10 shows the state of the production line after the overlapping portion 90 shown in FIG. is being conveyed while being elongated in the conveying direction MD. As a result of this stretching step, the base sheet 9 is largely stretched between P2-P1 and between P4-P3 in the fused portion 93 (low basis weight portion 15) as shown in FIG. 4 as described above. It breaks during the process or during subsequent transportation, and an opening 94 is formed in that portion. On the other hand, the regions (high basis weight portions 14) that are hardly stretched between P3-P2 and P1-P4 in the fused portion 93 are usually not broken, and the opening portion 94 is not formed. Since the plurality of fused portions 93 shown in FIG. 10 extend in the conveying direction MD so as to overlap with the plurality of low basis weight portions 15, each of the base sheet 9a stretched after the stretching process has The length L4a of the fused portion 93 in the conveying direction MD is longer than the length L4 before stretching (see FIG. basis weight portions 14) are arranged alternately in the transport direction MD. This opening 94 serves as a margin for elongation of the fused portion 93, and the amount of stretching of the peripheral portion of the fused portion 93 is reduced. is prevented.

From the viewpoint of achieving the above-described effects more reliably, the length L2 (see FIG. 9) of the first heat generating portion 57 in the conveying direction MD is set to the distance between the high basis weight portion 14 and the low basis weight portion 15. It is preferably longer than the length L3 (see FIG. 2B) of the repeating unit in the transport direction MD. Since the fused portion 93 is a portion heated by the first heat generating portion 57 in the sheet splicing process at the overlapped portion 90, the overlapped portion 90 (base sheet 9) of the fused portion 93 before stretching is sheet spliced. The length L4 in the transport direction MD (see FIG. 7) in the state of being stretched in the same manner as in the process (the state during transport in the manufacturing process) is substantially the same as the length L2 of the first heat generating portion 57 in the transport direction MD. be equal. That is, since the size relationship of length L2>length L3 is established, the fused portion 93 is reliably overlapped with the high basis weight portion 14, so that the sheets 9A and 9B are fused together in the high basis weight portion 14. The adhesion is promoted, and the breakage of the sheet at the overlapping portion 90 is more reliably prevented.

As described above, the length L3 is the length in the conveying direction MD of the repeating unit of the high basis weight portion 14 and the low basis weight portion 15 in the elongated state of the base sheet 9a or elastic sheet 10 after stretching. However, such a "stretched state" refers to a state in which the sheets 9a and 10 are stretched during transportation after stretching.
The ratio of length L2 to length L3 is preferably 1.1 or more, more preferably 2 or more, and preferably 20 as length L2/length L3 on the premise that length L2>length L3. Below, more preferably 10 or less.

In the sheet splicing process, it is preferable that the first heat generating portion 57 generate heat at a temperature higher than the melting point of the base sheet 9 and the second heat generating portion 58 generate heat at a temperature lower than the melting point of the base sheet 9 . As a result, the portion of the overlapping portion 90 that is heated by the first heat generating portion 57 (the portion that overlaps with the first heat generating portion 57 when the overlapping portion 90 is sandwiched between the pair of pressure members 51 and 52) is more reliable. As a result, as shown in FIG. 7, the sheets 9A and 9B in the overlapping portion 90 are fused together by the fused portions 93 intermittently arranged in the conveying orthogonal direction CD. is more reliably prevented.
The "melting point of the base sheet" as used herein refers to the melting point of the resin that is the material for forming the base sheet. It refers to the lowest melting point among resin melting points.

7, a gap G1 (see FIG. 7) between fused portions 93 adjacent to each other in the cross-transportation direction (perpendicular to the transport direction CD) is the length of the fused portions 93 in the cross-transportation direction (perpendicular to the transport direction CD). It is preferably longer than the width (width) W1 (see FIG. 7). Since the relationship of the distance G1 between the fused portions 93>the width W1 of the fused portions 93 is established, during the transportation of the base sheet 9a or the stretchable sheet 10 after stretching in the production line, It is possible to prevent the sheet from being broken due to the openings 94 adjacent to each other being connected to each other.

In addition, from the viewpoint of establishing the above-described size relationship “gap G1 between fused portions 93>width W1 of fused portions 93”, in the heating means 56, the first heat generation adjacent to each other in the cross-transport direction (perpendicular to transport direction CD) The interval G2 (see FIG. 9) between the portions 57 is preferably longer than the length (width) W2 (see FIG. 9) of the first heat generating portions 57 in the cross-transport direction (transport orthogonal direction CD).
The ratio of the gap G2 to the width W2 is preferably 1.1 or more, more preferably 2.5 or more, and more preferably 20 or less, assuming that the gap G2>width W2, as the gap G2/width W2. is 10 or less.
The interval G2 between the first heat generating portions 57 adjacent to each other in the cross-transport direction is preferably 1 mm or more, more preferably 2 mm or more, and preferably 50 mm or less, more preferably 20 mm or less.

In the above-described embodiment, the overlapping portion 90 is formed by overlapping and joining the leading edge portion 9BF of the second sheet 9B (following sheet) to the trailing edge portion 9AR of the first sheet 9A (preceding sheet) in the sheet splicing step. 7, the leading end 9BF1 of the second sheet 9B (the front end of the second sheet 9B in the conveying direction MD) extends parallel to the conveying orthogonal direction CD, and the fused portion 93 extends in the conveying orthogonal direction. Although the rows of the fused portions 93 are intermittently arranged in the CD and extend in the same direction CD, in the present invention, the extending directions of the starting ends 9BF1 and the rows of the fused portions 93 are not particularly limited. As indicated by 11, the leading edge 9BF1 may extend in a direction that intersects the orthogonal direction CD instead of intersecting it orthogonally.
In the form shown in FIG. 11A, the leading end 9BF1 of the second sheet 9B extends in a direction that intersects the orthogonal conveying direction CD rather than orthogonally, and the row of fused portions 93 also extends in the same direction. Further, the terminal end 9AR1 of the first sheet 9A (the rear end of the first sheet 9A in the conveying direction MD) also extends in the same direction.
In the form shown in FIG. 11(b), the leading edge 9BF1 of the second sheet 9B extends in a direction that intersects the orthogonal conveying direction CD rather than orthogonally, and the row of the fused portions 93 is parallel to the orthogonal conveying direction CD. extends to Further, the terminal end 9AR1 of the first sheet 9A extends parallel to the conveyance orthogonal direction CD.

The axial direction of the tooth groove rolls 2 and 3 used in the stretching process after the sheet splicing process is typically parallel to the orthogonal transport direction CD. The leading end 9BF1 of the second sheet 9B (the row of fused portions 93, the trailing end 9AR1 of the first sheet 9A) is parallel to the axial direction of the tooth groove rolls 2 and 3, and is perpendicular to the conveying direction as shown in FIG. The starting edge 9BF1 of the second sheet 9B (the row of fused portions 93, the terminal end 9AR1 of the first sheet 9A) that intersects the direction CD also intersects the axial direction of the tooth gap rolls 2,3.

In the stretching process by the tooth groove rolls 2 and 3, the portion other than the overlapping portion 90 in the first sheet 9A (the non-overlapping portion of the first sheet 9A), the starting end 9BF1 side of the overlapping portion 90 (forward in the conveying direction MD of the overlapping portion 90 side), the end 9AR1 side of the overlapping portion 90 (the rear side of the overlapping portion 90 in the conveying direction MD), and the portion of the second sheet 9B other than the overlapping portion 90 (the non-overlapping portion of the second sheet 9B) in this order. 2 and 3 and subjected to stretching processing, the overlapping portion 90 has higher rigidity than the non-overlapping portions of the sheets 9A and 9B. The non-overlapping portion of the first sheet 9A, which is more likely to be stretched, is stretched excessively, and as a result, as shown in FIG. can be formed. At this time, as shown in FIG. 7, if the start edge 9BF1 of the second sheet 9B extends parallel to the conveyance orthogonal direction CD (the axial direction of the tooth groove rolls 2 and 3), as shown in FIG. , the plurality of openings 94 are arranged in the direction perpendicular to the transport direction CD. 9A may break. On the other hand, as shown in FIG. 11, if the start edge 9BF1 of the second sheet 9B extends in a direction that intersects the conveyance orthogonal direction CD (the axial direction of the tooth groove rolls 2 and 3) without being orthogonal, As shown in FIG. 12(b), a plurality of openings 94 formed along the starting edge 9BF1 in the non-overlapping portion of the first sheet 9A are also aligned in the same direction. Compared to the state in which the holes 94 are arranged in the direction perpendicular to the conveyance direction CD, the adjacent openings 94 are less likely to be connected to each other, so breakage of the first sheet 9A can be suppressed. In addition, although only the form of FIG.11(a) is described in FIG.12(b), the same may be said of the form of FIG.11(b).

From the viewpoint of achieving the above-described effects more reliably, the leading edge 9BF1 of the second sheet 9B (the front end of the second sheet 9B in the conveying direction MD) and the orthogonal conveying direction CD (of the tooth groove rolls 2 and 3) The angle θ (see FIG. 11) on the acute side of the angle formed with the axial direction) is preferably 15° or more, more preferably 30° or more, and preferably 75° or less, more preferably 60° or less. .
In the embodiment shown in FIG. 11(a), of the angles formed by the extending direction of the rows of the fused portions 93 and the orthogonal transport direction CD (the axial direction of the tooth groove rolls 2 and 3), the angle on the acute side is also It is preferably in the same range as the angle θ.

The planar view shape of the heating means according to the present invention is not limited to the planar view shape of the heating means 56 shown in FIGS. 8 and 9, and can be arbitrarily set within the scope of the present invention. 13 and 14 show another embodiment of the heating means according to the invention. In the embodiments described later, configurations different from those of the heating means 56 described above will be described, and configurations similar to those of the heating means 56 will be denoted by the same reference numerals, and description thereof will be omitted. The above-described description of the heating means 56 is appropriately applied to configurations that are not particularly described in the embodiments described later.

A heating means 56A shown in FIG. 13A and a heating means 56B shown in FIG. 14A are common to the heating means 56 described above in that they both have a zigzag shape in plan view. In the heating means 56, the distance G2 between the adjacent first heat generating parts 57 is constant over the entire length of the first heat generating part 57, whereas the distance G2 between the heating means 56A and 56B is equal to that of one second heat generating part. Focusing on a unit consisting of 58 and two first heat generating portions 57 connected to both ends thereof, the number gradually increases with increasing distance from the one second heat generating portion 58 . The plane view shape of the unit is a trapezoidal shape in the heating means 56A and a triangular shape in the heating means 56B.
FIG. 13(b) shows a state in which the overlapping portion 90 is heated using the heating means 56A in the above-described sheet splicing process, and FIG. 14(b) shows a case where the heating means 56B is used. belongs to. In either case, the fused portion 93 is formed in the portion heated by the first heat generating portion 57 (high temperature heated portion), and the fused portion 93 is formed in the portion heated by the second heat generating portion 58 (low temperature heated portion). Part 93 is not formed. The heating means 56A and 56B also have the same effect as the heating means 56.

1 elastic sheet manufacturing apparatus 2, 3 tooth gap rolls 20, 30 teeth 21, 31 groove 4 infeed roll 5 outfeed roll 9 base sheet 9a base sheet 9A stretched by tooth gap roll first sheet ( preceding sheet)
9AR1 End of first sheet 9B Second sheet (following sheet)
9BF1 Starting end 90 of second sheet Overlapping portions 91, 92 Original fabric 93 Fused portion 94 Perforated portion 10 Elastic sheets 11, 12 Fiber sheet 13 Elastic filament 14 High basis weight portion 15 Low basis weight portion 40 Sheet joining device 41, 42 Roll support shaft 50 Sheet joints 51, 52 Pressurizing member 53 Coolant supply pipes 54, 55 Cutting means 56, 56A, 56B Heating means 57 First heat generating part 58 Second heat generating part 59 Driving part 60 Storage device 61 Fixed roll unit 62 movable roll unit 63 roll

Claims (7)

A high basis weight portion having a relatively high basis weight and a low basis weight portion having a relatively low basis weight alternate in the one direction while being stretchable in at least one direction and stretched in the one direction. A method for manufacturing an elastic sheet in which the elastic sheet is arranged in
A base sheet continuous in one direction is conveyed so as to pass through the meshing portions of a pair of tooth groove rolls that mesh with each other with the one direction as the conveying direction, thereby stretching the base sheet in the conveying direction. A stretching step of forming the stretchable sheet;
The base sheet conveyed to the stretching step is a preceding sheet, and another base sheet conveyed to the stretching step next to the preceding sheet is a succeeding sheet, and the succeeding sheet is part of the preceding sheet. a sheet splicing step of superimposing and joining a part of the sheet, and supplying the joined succeeding sheet to the preceding sheet continuously to the stretching step;
In the sheet splicing step, the overlapping portion of the preceding sheet and the succeeding sheet is sandwiched between a pair of pressure members arranged to face each other, and pressure is applied to the overlapping portion in the thickness direction. By heating in the conveying cross direction that intersects the conveying direction using the provided heating means, both sheets in the overlapping portion are fused and joined,
The heating means is positioned between first heat-generating portions intermittently arranged in the cross-transport direction and adjacent first heat-generating portions in the cross-transport direction that generate heat at a lower temperature than the first heat generating portions. and a second heat generating portion,
The method for producing a stretchable sheet, wherein the length of the first heat-generating portion in the conveying direction is longer than the length of the repeating unit of the high basis weight portion and the low basis weight portion in the conveying direction. 2. The method according to claim 1, wherein in the sheet splicing step, the first heat generating section generates heat at a temperature higher than the melting point of the base sheet, and the second heat generating section generates heat at a temperature lower than the melting point of the base sheet. A method for producing the elastic sheet described. 3. The method for manufacturing a stretchable sheet according to claim 1, wherein the distance between the first heat generating portions adjacent to each other in the cross-transportation direction is longer than the length of the first heat-generating portions in the cross-transportation direction. A part of the succeeding sheet is overlapped and joined to a part of the preceding sheet conveyed on the conveying path toward a predetermined conveying destination, and the joined succeeding sheet is continued to the preceding sheet on the conveying path. A sheet splicing device for sending out,
a sheet joining portion for fusing and joining the sheets in the overlapping portion by heating the overlapping portion of the preceding sheet and the succeeding sheet while applying pressure in the thickness direction thereof;
The sheet joining portion includes a pair of pressure members arranged to face each other, and the overlapping portion is sandwiched between the pair of pressure members so that pressure can be applied,
At least one of the pair of pressurizing members is provided with heating means, and the overlapping portion sandwiched between the pair of pressurizing members can be heated by heat generated by the heating means,
The heating means includes first heat generating portions intermittently arranged in a conveying cross direction intersecting the conveying direction of the preceding sheet, and the first heat generating portions which generate heat at a lower temperature than the first heat generating portions and are adjacent in the conveying cross direction. and a second heat generating section positioned between the heat generating sections. The first heat-generating portion and the second heat-generating portion are part of one conductive member that is continuous in the conveying cross direction, and both the heat-generating portions generate heat by energizing the one conductive member. 5. The sheet splicing device according to claim 4. 6. The sheet splicing device according to claim 5, wherein said first heat generating portion and said second heat generating portion have different lengths in a direction orthogonal to a direction in which current flows when energized. cooling means for cooling the heated overlapped portion; and cutting means for cutting the preceding sheet disposed upstream of the sheet joining portion in the conveying direction,
Further, a storing means for storing the preceding sheet is provided between the sheet joining portion and the conveying destination, and the preceding sheet stored in the storing means is conveyed while the conveying of the preceding sheet is stopped. The sheet splicing device according to any one of claims 4 to 6, which can be sent out first.

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