JP2017093745A - Composite sheet and absorbent article having the same, manufacturing apparatus of composite sheet and manufacturing method of composite sheet - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a composite sheet capable of stably controlling fluid diffusion of a body fluid.SOLUTION: A composite sheet 1 is formed of a laminate of a first sheet 1u and a second sheet 1d. The composite sheet 1 has a plurality of joining parts 2 between the first sheet 1u and the second sheet 1d, and the first sheet 1u forms a plurality of convex parts 3 projecting in a direction away from the second sheet 1d in portions other than the joining parts 2. The convex parts 3 form convex part rows 3R intermittently arranged in a direction inclined relative to a longitudinal direction X and a lateral direction Y respectively from a central portion of the composite sheet 1 in the lateral direction Y toward both end parts in the lateral direction Y. A plurality of convex part rows 3R are arranged at a certain interval in the longitudinal direction X. In the convex parts 3 constituting each convex part row 3R, the basis weight of an apex of the convex part 3 gradually increases from the central portion in the lateral direction Y toward both end portions in the lateral direction Y.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a composite sheet, an absorbent article including the composite sheet, a composite sheet manufacturing apparatus, and a composite sheet manufacturing method.

  The surface sheet of an absorbent article such as a disposable diaper or a sanitary napkin is a body fluid liquid in order to maximize the performance of the absorbent article by using the absorbent body constituting the absorbent article to the maximum. Control of diffusivity is an important factor. As a means for imparting control of the liquid diffusibility of body fluid to the surface sheet, it is conceivable to apply an oil agent to the surface sheet. Generally, however, the oil agent is likely to cause aging and deterioration over time and is applied to the surface sheet. It is difficult to stably maintain control of the liquid diffusibility of body fluids.

  From the viewpoint of imparting liquid diffusibility control of body fluid to the top sheet, the applicant firstly formed a plurality of concave portions by partially joining the first sheet and the second sheet, and The first sheet is a composite sheet in which convex portions are formed between the concave portions, and the convex portions adjacent to each other in the width direction of the first sheet are shifted in the length direction of the first sheet. Proposed a composite sheet (Patent Document 1). Patent Document 1 also describes an apparatus for manufacturing such a composite sheet.

JP 2009-153754 A

  As described above, if the three-dimensional composite sheet described in Patent Document 1 is used for the top sheet of the absorbent article, the liquid diffusibility of the body fluid can be controlled from the structure of the top sheet. However, there has been a need to further control the fluid diffusibility of body fluids in order to improve the effect of preventing leakage of loose stool and urine.

  Therefore, this invention is providing the composite sheet which can eliminate the fault which the prior art mentioned above has. Moreover, this invention is providing the manufacturing apparatus of the said composite sheet. Furthermore, this invention is providing the manufacturing method of the composite sheet which can eliminate the fault which the prior art mentioned above has.

  The present invention is a composite sheet comprising a laminate of a first sheet and a second sheet, having a first direction and a second direction orthogonal to the first direction, the laminate comprising: The first sheet and the second sheet have a plurality of joint portions, and the first sheet forms a plurality of convex portions projecting in a direction away from the second sheet at a portion other than the joint portion. The convex portion is intermittent in directions inclined from the first direction and the second direction toward both ends of the second direction from a central portion of the composite sheet in the second direction. The convex portions are arranged side by side, and a plurality of the convex portions are arranged at regular intervals in the first direction, and the convex portions constituting the respective convex portions are arranged. The portion extends from the center portion in the second direction of the composite sheet toward both end portions in the second direction. , The basis weight of the top portion of the convex portion, there is provided a composite sheet which is gradually increased.

  Moreover, this invention is a manufacturing apparatus of the said composite sheet | seat, Comprising: The 1st roll of uneven | corrugated shape which has a some roll recessed part and roll convex part in a surrounding surface, This roll recessed part and this roll convex part of this 1st roll And a plurality of concave and convex second rolls having a roll convex portion on the peripheral surface, and the manufacturing apparatus includes the first roll and the second roll at a meshing portion of the first roll and the second roll. 1 sheet is supplied, and the roll convex part of the second roll enters the roll concave part of the first roll, whereby the first sheet is pushed into the roll concave part of the first roll, and the composite The apparatus performs three-dimensional shaping corresponding to the convex portion of the sheet, and the first roll has the roll concave portion in a rotational direction from a central portion in the axial direction of the first roll toward both end portions in the axial direction. And in each axial direction And a plurality of roll recess rows are arranged at regular intervals in the rotation direction on the first roll. An adjustment unit that changes a supply speed of supplying the first sheet to the meshing portion of the first roll and the second roll according to the basis weight of the top of the convex portion of the composite sheet to be formed, The adjustment unit is formed by increasing the supply speed of the first sheet when the first sheet is pushed into the roll concave portion of the first roll to form the top of the convex portion of the composite sheet. An apparatus for manufacturing a composite sheet is provided that adjusts to lower the basis weight of the top of the projection formed by increasing the basis weight of the top of the projection and reducing the supply speed of the first sheet. To do.

  Further, the present invention comprises a laminate of a first sheet and a second sheet, and the laminate has a plurality of joint portions between the first sheet and the second sheet, and the first sheet comprises A method of manufacturing a composite sheet having a plurality of protrusions protruding in a direction away from the second sheet in a portion other than a joint portion, and having an uneven shape having a plurality of roll recesses and roll protrusions on a peripheral surface Using the first roll and the second roll having a concave and convex shape having a plurality of roll concave portions and roll convex portions meshing with the roll concave portions and the roll convex portions of the first roll on the circumferential surface, The first sheet is supplied to the meshing portion of one roll and the second roll, and the first sheet is moved to the first groove by the roll convex part of the second roll entering the roll concave part of the first roll. Is pushed into the roll recess of the roll. The meshing of the first roll and the second roll according to the three-dimensional shaping step for performing the three-dimensional shaping corresponding to the convex portion of the composite sheet and the basis weight of the top of the convex portion of the composite sheet to be formed An adjustment step of changing a supply speed for supplying the first sheet to the part, and the first roll has the roll recess from a central part in the axial direction of the first roll to both ends in the axial direction. The first and second rolls are arranged at intervals with a constant interval in the rotation direction. The adjustment step provides a method for producing a composite sheet in which the feeding speed of the first sheet is increased as the basis weight of the top of the convex portion to be formed is higher.

  The present invention also provides an absorbent article comprising a surface sheet made of the above composite sheet, wherein the composite sheet is disposed so that the first sheet of the composite sheet is located on the skin side of the wearer. is there.

  According to the composite sheet of the present invention, the liquid diffusibility of body fluid can be further controlled. Moreover, according to this invention, the said composite sheet can be manufactured efficiently.

FIG. 1 is a partially broken perspective view showing an enlarged main part of an embodiment of the composite sheet of the present invention. FIG. 2 is a plan view of the composite sheet shown in FIG. FIG. 3 is a schematic view showing a manufacturing apparatus suitably used for manufacturing the composite sheet shown in FIG. FIG. 4 is a perspective view in a state where the first roll of the manufacturing apparatus of FIG. 3 is disassembled. FIG. 5 is a perspective view of a first roll included in the manufacturing apparatus of FIG. 3. 6 is a diagram in which the peripheral surface of the first roll of the manufacturing apparatus of FIG. 3 is developed in a plane.

  Hereinafter, the composite sheet of the present invention will be described based on preferred embodiments with reference to the drawings. 1 and 2 show a composite sheet 1 which is an embodiment of the composite sheet of the present invention. The composite sheet 1 is composed of a laminate of a first sheet 1u and a second sheet 1d. For example, when the composite sheet 1 is used as a surface sheet that forms the skin-facing surface of the absorbent article, the first sheet 1u is used so as to be positioned on the wearer's body side when the absorbent article is worn. It is preferable to do this. And it is preferable to use the 2nd sheet | seat 1d so that it may be located in the absorber side in the wearing condition of this absorbent article. The composite sheet 1 has a first direction and a second direction orthogonal to the first direction. In the present embodiment, the first direction is the longitudinal direction X coinciding with the fiber orientation of the fibers constituting the first sheet 1u, and the second direction is the transverse direction Y orthogonal to the longitudinal direction X. . In the composite sheet 1, the longitudinal direction X coincides with the fiber orientation of the fibers constituting the second sheet 1d, and the transverse direction Y coincides with the direction orthogonal to the fiber orientation of the fibers constituting the second sheet 1d. ing.

  In the composite sheet 1, the longitudinal direction X coincides with the conveyance direction (MD) when the first roll is rotated in the rotation direction U and the composite sheet 1 is manufactured. Further, in the composite sheet 1, the lateral direction Y also coincides with the axial direction V of the first roll, as will be described later.

  As shown in FIGS. 1 and 2, the composite sheet 1 is symmetrical with respect to a center line CL extending in the longitudinal direction X. Accordingly, in the following description, only one of the symmetrical parts will be mainly described.

  As shown in FIG. 1, the composite sheet 1 that is a laminate has a plurality of joint portions 2 by partial joining of the first sheet 1 u and the second sheet 1 d, and the first sheet 1 u is a portion other than the joint portion 2. Are formed with a plurality of protrusions 3 protruding in a direction away from the second sheet 1d. In the composite sheet 1, the second sheet 1 d is substantially flat, and the first sheet 1 u is formed with irregularities with large undulations, so that a plurality of convex portions 3 are formed.

  The joint portion 2 can be formed by various means. In the case where the first sheet 1u and the second sheet 1d are made of, for example, a heat-sealable material, it is possible to use heat, ultrasonic waves, high-frequency fusion, or the like. Regardless of the material of the first sheet 1u and the second sheet 1d, adhesion by an adhesive can also be used. In the joint portion 2 of the composite sheet 1, the first sheet 1u and the second sheet 1d are integrally pressed, and both the sheets 1u and 1d are higher in density than the other parts, preferably The sheets 1u and 1d are thermally fused by melting of the constituent resin of one or both sheets and subsequent solidification.

  The first sheet 1u and the second sheet 1d are made of a sheet material. As the sheet material, for example, a fiber sheet such as a nonwoven fabric, a woven fabric, and a knitted fabric, a film, and the like can be used. From the viewpoint of touch and the like, it is preferable to use a fiber sheet, and it is particularly preferable to use a nonwoven fabric. The types of sheet materials constituting the first sheet 1u and the second sheet 1d may be the same or different.

Examples of the nonwoven fabric in the case of using a nonwoven fabric as the sheet material constituting the first sheet 1u and the second sheet 1d include an air-through nonwoven fabric, a spunbond nonwoven fabric, a spunlace nonwoven fabric, a meltblown nonwoven fabric, a resin bond nonwoven fabric, and a needle punch nonwoven fabric. Can be mentioned. A laminate obtained by combining two or more of these nonwoven fabrics, or a laminate obtained by combining these nonwoven fabrics and a film can also be used. Among these, it is preferable to use an air-through nonwoven fabric or a spunbonded nonwoven fabric. The basis weight of the nonwoven fabric used as the sheet material constituting the first sheet 1u and the second sheet 1d is preferably 10 g / m ² or more, more preferably 15 g / m ² or more, and preferably 40 g / m ² or less. More preferably, it is 35 g / m ² or less. The basis weight of the nonwoven fabric is preferably 10 g / m ² or more and 40 g / m ² or less, and more preferably 15 g / m ² or more and 35 g / m ² or less.

  As the fibers constituting the nonwoven fabric, fibers made of various thermoplastic resins can be used. Examples of the thermoplastic resin include polyolefins such as polyethylene and polypropylene, polyesters such as polyethylene terephthalate, polyamides such as nylon 6 and nylon 66, polyacrylic acid, polymethacrylic acid alkyl ester, polyvinyl chloride, and polyvinylidene chloride. These resins can be used alone or as a blend of two or more. Further, it can be used in the form of a composite fiber such as a core-sheath type or a side-by-side type.

  In the composite sheet 1, as shown in FIG. 2, the joint portion 2 is a rectangular first joint portion 21 having a length L1 along the longitudinal direction X that is longer in the longitudinal direction X than a length L2 along the transverse direction Y. And the length L3 along the vertical direction X has the same square-shaped second joining part 22 as the length L4 along the horizontal direction Y. Each of the first joint portion 21 and the second joint portion 22 has a rectangular shape, and each side of the rectangle coincides with the vertical direction X or the horizontal direction Y. In the composite sheet 1, the length L <b> 2 along the lateral direction Y of the first joint portion 21 matches the length L <b> 3 along the longitudinal direction X and the length L <b> 4 along the lateral direction Y of the second joint portion 22.

  In the composite sheet 1, as shown in FIG. 2, the first joint portions 21 are regularly arranged along the center line CL extending in the longitudinal direction X with a constant interval L5. And, with each first joint 21 arranged on the center line CL as a reference, another first joint 21 is intermittently arranged at a constant interval L6 in the lateral direction Y left and right outwards, In addition, the first joint portions 21 and 21 adjacent to each other in the horizontal direction Y are arranged such that the center portions 21G and 21G are shifted in the vertical direction X at a constant interval L7.

  In the composite sheet 1, as shown in FIG. 2, the second bonding portion 22 is based on each first bonding portion 21 disposed on the center line CL, and each end in the lateral direction Y of the first bonding portion 21. The pair of second joint portions 22 and 22 are arranged at a certain distance L8 in the lateral direction Y on the left and right outer sides. Then, with each second joint portion 22 as a reference, another second joint portion 22 is intermittently arranged with a constant interval L9 outward in the lateral direction Y and adjacent to the lateral direction Y. The second joint portions 22 and 22 are arranged such that the center portions 22G and 22G are shifted from each other in the vertical direction X at a constant interval L10. In the composite sheet 1, the distance L <b> 8 between the first joint portion 21 and the second joint portion 22 is a length L <b> 2 in the lateral direction Y of the first joint portion 21 and a length L <b> 4 in the lateral direction Y of the second joint portion 22. Match. In addition, the distance L9 between the second joint portions 22 and 22 adjacent in the horizontal direction Y coincides with the distance L6 between the first joint portions 21 and 21 adjacent in the horizontal direction Y. Further, the distance L10 between the central portions 22G and 22G of the second joint portion 22 adjacent in the vertical direction X coincides with the distance L7 between the central portions 21G and 21G of the first joint portion 21 adjacent in the vertical direction X. Yes.

  In the composite sheet 1, the convex portion 3 includes a first convex portion 31 disposed along a center line CL extending in the longitudinal direction X, as shown in FIGS. 1 and 2, and the first convex portion 31. It has the 2nd convex part 32 distribute | arranged to the horizontal direction Y right and left outward, and the same bottom area as this 1st convex part 31. Here, the bottom area of the convex part 3 means the area of the region surrounded by the joint part 2 that forms the convex part 3 in the second sheet 1d. In the composite sheet 1, a rectangular area surrounding the convex part 3 is used. It means the area of a rectangular region surrounded by an extension line when each side of the joint portion 2 on the convex portion 3 side is extended.

  In the composite sheet 1, the first convex portion 31 is formed in a region surrounded by a total of six joint portions 2 as shown in FIG. 2. Preferably, in the composite sheet 1, the first convex portion 31 is a region surrounded by a total of six joint portions 2 including two first joint portions 21 and four second joint portions 22 arranged at the above-described positions. Is formed inside. In the composite sheet 1, the second convex portion 32 is formed in a region surrounded by a total of five joint portions 2. Preferably, in the composite sheet 1, the second convex portion 32 is a region surrounded by a total of five joint portions 2 including two first joint portions 21 and three second joint portions 22 arranged at the above-described positions. Is formed inside.

  In the composite sheet 1, as shown in FIGS. 1 and 2, the protrusions 3 are respectively in the longitudinal direction X and the lateral direction Y from the central portion in the lateral direction Y of the composite sheet 1 toward both ends in the lateral direction Y. And a convex row 3R in which the convex portions 3 are arranged so as to be shifted in the vertical direction X so as not to be seen when the composite sheet 1 is viewed from the lateral direction Y. ing. Preferably, in the composite sheet 1 shown in FIG. 2, the second convex portion is based on one first convex portion 31 that is located at the center portion in the horizontal direction Y and is disposed on the center line CL extending in the vertical direction X. 32 is a convex row 3R extending in the horizontal direction Y, which is inclined with respect to each of the vertical direction X and the horizontal direction Y toward both ends in the horizontal direction Y and is arranged intermittently side by side on the upper side of FIG. Is forming. That is, the convex row 3R has a line-symmetric shape with the center line CL extending in the vertical direction X as the symmetry axis. In the composite sheet 1 shown in FIG. 2, the first convex portion 31 and the second convex portion 32 adjacent to each other in the lateral direction Y are arranged so that the convex portion row 3 </ b> R cannot be seen when the composite sheet 1 is viewed from the lateral direction Y. The second convex portions 32 and 32 adjacent to each other in the vertical direction X and shifted in the horizontal direction Y are shifted in the vertical direction X upward.

  In the composite sheet 1, as shown in FIGS. 1 and 2, a plurality of convex portion rows 3 </ b> R extending in the horizontal direction Y are arranged at certain intervals in the vertical direction X. Preferably, in the composite sheet 1, the protrusion rows 3R and 3R adjacent in the longitudinal direction X include the first protrusion 31 constituting the upper protrusion row 3R shown in FIG. 2 and the lower protrusion. Each convex row 3R has a certain gap L11 in the vertical direction X so as to provide a gap L11 between the second convex portion 32 arranged at the extreme end in the lateral direction Y constituting the partial row 3R. Several are arranged. In other words, the protrusion rows 3R and 3R adjacent in the vertical direction X do not overlap when the composite sheet 1 is viewed from the horizontal direction Y, and are arranged independently. That is, the convex portion rows 3R and 3R adjacent in the vertical direction X do not overlap when the composite sheet 1 is viewed from the horizontal direction Y. Moreover, the arrangement | sequence of the convex part in the composite sheet 1 becomes a line-symmetrical arrangement | sequence with the line (center line CL in FIG. 2) which connects the 1st convex parts 31 which comprise each convex part row | line | column 3R as a symmetry axis. Yes.

  In the composite sheet 1, the convex portions 3 constituting each convex portion row 3 </ b> R have a basis weight at the top of the convex portion 3 from the central portion in the lateral direction Y of the composite sheet 1 toward both ends in the lateral direction Y. It is getting higher gradually. Here, the top of the convex portion 3 means the highest portion of the convex portion 3. In addition, when it is difficult to determine the highest portion of the convex portion 3, the top portion of the convex portion 3 is the joint portion 2 farthest in the vertical direction X among the plurality of joint portions 2 surrounding the convex portion 3. It means the central part when the distance in the longitudinal direction X connecting the two is divided into three equal parts. Specifically, in the second convex portion 32X shown in FIG. 2, among the total five joint portions 2 of the two first joint portions 21 and the three second joint portions 22 surrounding the second convex portion 32X, This means the central portion CT when the distance in the vertical direction X connecting the first joints 21 and 21 farthest apart in the vertical direction X is divided into three equal parts. In the composite sheet 1, the first convex portion 31 and the plurality of second convex portions 32 constituting each convex portion row 3 </ b> R are such that the basis weight of the top portion of the first convex portion 31 is greater than the basis weight of the top portion of the second convex portion 32. The basis weight of the top of the second convex portion 32 from the first convex portion 31 located at the central portion in the lateral direction Y of the composite sheet 1 toward the second convex portion 32 at both end portions in the lateral direction Y, It is getting higher gradually. That is, the basis weight of the top of the second convex portion 32 at the extreme end in the lateral direction Y is formed highest. The basis weight is measured by the following method.

<Measurement method of basis weight>
The sheet is cut in the thickness direction along the lateral direction Y using a feather razor (product number FAS-10, manufactured by Feather Safety Razor Co., Ltd.) so as to cross the top of the convex portion 3.
The cut surface of the composite sheet 1 is adjusted to a magnification capable of measuring about 30 to 60 fiber cross sections using a scanning electron microscope (JCM-5100 (trade name) manufactured by JEOL Ltd.); 150 to 500 times) and the number of cross sections of the fibers cut by the cut surface per fixed area (about 0.5 mm 2) is counted. Next, it is converted into the number of cross-sections of fibers per 1 mm ² and this is the basis weight. The measurement is performed at three locations, and the average value is the basis weight at the top of the convex portion of the sample.

  Next, the composite sheet manufacturing apparatus of the present invention will be described with reference to FIGS. 3 to 6 by taking the composite sheet 1 manufacturing apparatus 100 described above as an example. FIG. 3 shows an overall configuration of the composite sheet 1 manufacturing apparatus 100.

  As shown in FIG. 3, the manufacturing apparatus 100 for the composite sheet 1 includes a concave-convex first roll 11 having a plurality of roll concave portions 11 c and roll convex portions 11 t on the peripheral surface, and a roll concave portion 11 c of the first roll 11. There are provided a plurality of roll concave portions 12c meshing with the roll convex portions 11t and a concave-convex second roll 12 having the roll convex portions 12t on the peripheral surface. The manufacturing apparatus 100 includes a drive roll 15 that unwinds the first sheet 1u from a raw roll (not shown) of the belt-shaped first sheet 1u, and the first roll 11 and the second roll 12 are provided downstream of the drive roll 15. I have. Furthermore, the manufacturing apparatus 100 includes a first heat roll 13 and a second heat roll 14 that join the first sheet 1 u and the second sheet 1 d together with the first roll 11 at the joint portion 2. In the manufacturing apparatus 100, the second roll 12, the first heat roll 13, and the first roll 11 are arranged to face the roll peripheral surface of the first roll 11, from the upstream side in the rotation direction U of the first roll 11 toward the downstream side. Two heat rolls 14 are arranged in this order.

  The manufacturing apparatus 100 supplies the first sheet 1u fed from the raw roll (not shown) of the first sheet 1u via the drive roll 15 to the meshing portion of the first roll 11 and the second roll 12, The roll convex portion 12 t of the second roll 12 enters the roll concave portion 11 c of the one roll 11, whereby the first sheet 1 u is pushed into the roll concave portion 11 c of the first roll 11, and the convex portion 3 of the composite sheet 1 It is an apparatus which performs the corresponding three-dimensional shaping. Further, the manufacturing apparatus 100 retains the first three-dimensionally shaped sheet 1u along the peripheral surface portion of the first roll 11 and moves it from the meshing portion, and then three-dimensionally shapes the second sheet 1d. The two sheets 1u and 1d are supplied so as to be superimposed on the first sheet 1u, and are sandwiched between the roll convex portion 11t of the first roll 11 and the first heat roll 13 and the second heat roll 14 under heating. This is an apparatus for forming the joint portion 2 and manufacturing the composite sheet 1.

  The rotation speed of the drive roll 15 is controlled by the control unit 16. The manufacturing apparatus 100 includes an adjustment unit 17 that controls the rotation speed of the drive roll 15 by the control unit 16 and changes the supply speed of supplying the first sheet 1 u to the meshing portion of the first roll 11 and the second roll 12. doing. In response to a command from the control unit 16 of the adjustment unit 17, the first sheet 1 u is pushed into the roll concave portion 11 c of the first roll 11 to form the top of the convex portion 3 of the composite sheet 1. Adjustment is made to increase the basis weight of the top of the convex portion 3 formed by increasing the supply speed and to decrease the basis weight of the top of the convex portion 3 formed by decreasing the supply speed of the first sheet 1u. Is done.

  As shown in FIGS. 3 and 4, the first roll 11 is a combination of a plurality of first gears 111, second gears 112, and spacers 113 that are concentrically attached to the shaft center and integrated in a roll shape. is there. The first gear 111, the second gear 112, and the spacer 113 may have different widths (tooth widths), but in the manufacturing apparatus 100 that manufactures the composite sheet 1, the widths (tooth widths) are the same. Each of the first gear 111, the second gear 112, and the spacer 113 has an opening at its axis, and a rotating shaft (not shown) is inserted into the opening. Cutouts 114 are formed in the openings of the first gear 111, the second gear 112 and the spacer 113, respectively, and a key (not shown) is inserted into the cutout 114. As a result, idle rotation of a combination of a plurality of first gears 111, second gears 112 and spacers 113 can be prevented.

  The spacer 113 has a shape having a beam 115 which is a large number of protrusions extending radially from the center of the annular spacer 113. Each beam 115 in the spacer 113 has the same length. When the diameter of the circle formed virtually by connecting the tips of the beams 115 is defined as the tooth tip circle diameter for convenience, the spacer 113 has the tip circle diameter of the first gear 111 and the first gear 111. It is smaller than the root circle diameter of the two gears 112.

The first gear 111 and the second gear 112 have the same tip diameter, and the modules are different. The first gear 111 has a first module m ₁ . The second gear 112 has a second module _{m 2.} The first module m ₁ is twice the second module m ₂ . That is, the relationship is m ₁ = 2m ₂ . Module m (mm) is a value defined by m = d / z. In the formula, d is a pitch circle diameter (mm), and z is the number of teeth. By using the first gear 111 having a large module value, it is possible to increase the shaping height (depth) of the first sheet 1u to be unevenly shaped. Moreover, the area of the junction part 2 in the composite sheet 1 can be increased. The ability to increase the area of the joint portion 2 contributes to an increase in the bottom area of the convex portion 3 formed on the composite sheet 1. In addition, since a tooth tip circle diameter changes with modules, the peripheral surface is match | combined by grinding the tooth tip of the 1st gearwheel 111 and the 2nd gearwheel 112 accumulated in roll shape, and a tooth tip circle diameter is unified.

  A plurality of openings 116 are formed in the first gear 111 and the second gear 112 so as to surround a central opening into which a rotation shaft (not shown) is inserted. Each opening 116 has the same diameter, and is formed at a position equidistant from the center of the gear. The arrangement positions of the openings 116 formed in the plurality of first gears 111 and the plurality of second gears 112 are the same, and the openings 116 are provided in the openings into which the rotation shafts (not shown) are inserted. The positions corresponding to the notches 114 are arranged at equal intervals in the circumferential direction with reference to the positions corresponding to the notches 114. The number of openings 116 of the first gear 111 and the second gear 112 is the same as the number of beams 115 in the spacer 113 described above. When the spacer 113 is assembled between the first gear 111 and the second gear 112, the first gear is set so that each opening 116 is positioned between the adjacent beams 115 and 115 in the spacer 113. 111, the spacer 113, and the second gear 112 are arranged in this order. That is, the openings 116 of the first gear 111 and the second gear 112 are positioned in a substantially V-shaped region formed by the two beams 115 and 115 adjacent to each other in the circumferential direction of the spacer 113 and the central portion of the spacer 113. To do. This substantially V-shaped portion corresponds to the roll recess 11c in the first roll 11 whose peripheral surface has an uneven shape. On the other hand, the uneven roll convex portion 11t corresponds to a tooth 111a portion of the first gear 111 and a tooth 112a portion of the second gear 112, which will be described later.

  As described above, when a plurality of gear groups that are combined in the order of the first gear 111, the spacer 113, and the second gear 112 are assembled, the opening 116 of the first gear 111 and the opening 116 of the second gear 112 become the first roll. 11, a plurality of suction paths (not shown) extending in the axial direction V are formed in the first roll 11. This suction path is connected to a suction device (not shown) installed outside the first roll 11, and the suction device (not shown) is operated so that the first roll 11 is formed on the peripheral surface thereof. The first sheet 1u can be sucked from the recess 11c toward the inside.

  FIG. 6 shows a state in which the peripheral surface of the first roll 11 is developed on a plane. In the figure, the direction indicated by the arrow U is the rotation direction of the first roll 11, and the direction indicated by the arrow V is the axial direction of the first roll 11. Further, in the same figure, rectangular areas indicated by dots indicate the tooth tip surfaces of the first gear 111 and the second gear 112. As shown in FIG. 6, the tooth tip surface 111 f of the tooth 111 a of the first gear 111 corresponds to the first joint portion 21 (see FIG. 2) of the composite sheet 1 to be manufactured, and the first joint portion 21 is formed. The planned position. The tooth tip surface 112f of the tooth 112a of the second gear 112 corresponds to the second joint portion 22 (see FIG. 2) of the composite sheet 1 to be manufactured, and is a position where the second joint portion 22 is to be formed.

  In the composite sheet 1 manufacturing apparatus 100, as shown in FIG. 6, the tooth tip surface 111 f of the first gear 111 corresponding to the first joint portion 21 has a length L <b> 1 ′ in the rotational direction U of the axial center direction V. The rectangular shape is longer in the rotational direction U than the length L2 ′. Here, the length L1 ′ in the rotation direction U of the tooth tip surface 111f corresponds to the length L1 in the longitudinal direction X of the first joint portion 21, and the length L2 in the axial direction V of the tooth tip surface 111f. 'Corresponds to the length L2 of the first joint portion 21 in the horizontal direction Y. The tooth tip surface 112f of the second gear 112 corresponding to the second joint portion 22 has a square shape in which the length L3 'in the rotational direction U and the length L4' in the axial direction V are the same. Here, the length L3 ′ in the rotation direction U of the tooth tip surface 112f corresponds to the length L3 in the longitudinal direction X of the second joint portion 22, and the length L4 in the axial direction V of the tooth tip surface 112f. 'Corresponds to the length L4 of the second joint portion 22 in the horizontal direction Y. That is, in the manufacturing apparatus 100, the tooth width of the first gear 111 matches the tooth width of the second gear 112.

  In the first roll 11 of the manufacturing apparatus 100 for the composite sheet 1, as shown in FIG. 6, the tooth tip surface 111 f of the first gear 111 extends in the rotational direction U from the central portion of the axial direction V of the first roll 11. They are regularly arranged along the center line CL ′ with a predetermined interval L5 ′. This interval L5 'corresponds to the interval L5 between the first joint portions 21 and 21 arranged on the center line CL. Then, with reference to the tooth tip surface 111f of each first gear 111 arranged on the center line CL ′, a constant distance L6 ′ (first joint adjacent to the lateral direction Y) on the left and right outer sides in the axial direction V The tooth tip surface 111f of another first gear 111 is intermittently arranged with a gap L6 between 21 and 21), and the tooth tip surface of the first gear 111 adjacent in the axial direction V is provided. 111f and 111f have a constant interval L7 ′ between the central portions 111G and 111G in the rotation direction U (corresponding to the interval L7 between the central portions 21G and 21G of the first joint portion 21 adjacent in the vertical direction X). Are arranged.

  In the first roll 11 of the manufacturing apparatus 100 for the composite sheet 1, as shown in FIG. 6, the tooth tip surface 112 f of the second gear 112 is the tooth tip surface of each first gear 111 arranged on the center line CL ′. With reference to 111f, the tooth tip surface 111f is located at each end on the upstream and downstream sides in the rotation direction U, and has a constant distance L8 ′ (on the first joint 21 and the left and right outer sides in the axial direction V). A pair of addendum surfaces 112f and 112f are arranged with a gap (corresponding to a distance L8 from the second joint portion 22). Then, with reference to the tooth tip surface 112f of each second gear 112, a constant distance L9 ′ outward in the axial direction V (corresponding to the distance L9 between the second joint portions 22 and 22 adjacent in the lateral direction Y). The tooth tip surfaces 112f of the other second gear 112 are intermittently arranged with a gap between them, and the tooth tip surfaces 112f and 112f of the second gear 112 adjacent to each other in the axial direction V are center portions 112G. 112G are arranged with a certain interval L10 ′ in the vertical direction X (corresponding to the interval L10 between the central portions 22G and 22G of the second joint 22 adjacent in the vertical direction X). In the manufacturing apparatus 100 for the composite sheet 1, the tooth tip surface 111f of the first gear 111 arranged on the center line CL ′ and the tooth tip of the second gear 112 adjacent to the outer side in the axial direction V of the tooth tip surface 111f. An interval L8 ′ with the surface 112f (corresponding to the interval L8) matches the width of the spacer 113. That is, the width of the spacer 113 matches the tooth width of the first gear 111 and the tooth width of the second gear 112. Further, the interval L9 ′ between the tooth tip surfaces 112f and 112f of the second gear 112 adjacent to each other in the axial direction V (corresponding to the interval L9) is the tooth tip surface 111f of the first gear 111 adjacent to the axial direction V. It is equal to the interval L6 ′ between 111f (corresponding to the interval L6). Further, a distance L10 ′ (corresponding to the distance L10) between the center portions 112G and 112G of the tooth tip surface of the second gear 112 adjacent in the rotation direction U is the tooth tip surface 111f of the first gear 111 adjacent in the rotation direction U. Is equal to an interval L7 ′ (corresponding to the interval L7) between the central portions 111G and 111G.

  In the first roll 11 of the composite sheet 1 manufacturing apparatus 100, a region surrounded by the tooth 111 a portion of the first gear 111 and the tooth 112 a portion of the second gear 112 becomes the roll recess 11 c. The roll concave portion 11c is a total of six tooth tip surfaces including the tooth tip surfaces 111f of the teeth 111a of the two first gears 111 and the tooth tip surfaces 112f of the teeth 112a of the four second gears 112 arranged at the positions described above. The first roll first recess 11c1 in the enclosed area, the tooth tip surface 111f of the tooth 111a of the two first gears 111 and the tooth tip surface of the tooth 112a of the three second gears 112 arranged at the positions described above. The first roll second recess 11c2 is provided in a region surrounded by a total of five tooth tips with 112f. The area of the first roll first recess 11c1 (area of a region surrounded by a total of six tooth tips shown by hatching in FIG. 6) and the area of the first roll second recess 11c2 (total 5 shown by hatching in FIG. 6) Area of a region surrounded by one tooth tip surface) is the same area.

  As for the 1st roll 11 of the manufacturing apparatus 100 of the composite sheet 1, the roll recessed part 11c rotates toward the both ends of the axial direction V from the center part of the axial direction V of the 1st roll 11, as shown in FIG. Roll recesses disposed in an inclined manner with respect to each of the direction U and the axial direction V, and shifted in the rotational direction U so that the first roll 11 cannot be seen when viewed from the axial direction V. It has a column 11cR. In the manufacturing apparatus 100 for the composite sheet 1, the roll recess row 11 c </ b> R of the first roll 11 is rotated in the direction from the center portion of the first roll 11 in the axial direction V toward both ends in the axial direction V. It is formed so as to be inclined with respect to each of the U and axial direction V and intermittently arranged downstream in the rotational direction U.

  Preferably, in the first roll 11 of the manufacturing apparatus 100 for the composite sheet 1, from the first roll first recess 11c1 located on the center line CL ′ extending in the rotation direction U, toward both ends in the axial direction V and The first roll second concave portion 11c2 is intermittently inclined toward the downstream side in the rotational direction U while being inclined with respect to the rotational direction U and the axial direction V, and a roll concave portion row 11cR extending in the axial direction V is formed. Has been. In the roll recess row 11cR formed in this way, the end of the first roll first recess 11c1 and the end of the first roll second recess 11c2 adjacent to each other in the axial direction V connect the first roll 11 in the axial direction V. And the end of the first roll second recess 11c2 and the end of the first roll second recess 11c2 that are adjacent to each other in the axial direction V connect the first roll 11 from the axial direction V. It overlaps when seen. Therefore, the roll recess row 11cR is formed so as not to be seen when viewed from the axial direction V.

  In the first roll 11 of the composite sheet manufacturing apparatus 100, as shown in FIG. 6, a plurality of roll recess rows 11 c R extending in the axial direction V are arranged in the rotational direction U with a constant interval. Preferably, in the first roll 11 of the composite sheet manufacturing apparatus 100, the roll recess rows 11cR and 11cR adjacent in the rotation direction U constitute the first roll recess row 11cR on the downstream side shown in FIG. In order to provide a gap L11 ′ between the first recess 11c1 and the first roll second recess 11c2 disposed at the outermost end in the axial direction V that constitutes the other upstream roll recess row 11cR, A plurality of roll recess rows 11cR are arranged in the rotation direction U with a constant interval L11 ′. In other words, the roll recess rows 11cR and 11cR adjacent to each other in the rotation direction U do not overlap each other when viewed from the axial direction V of the first roll 11, and are arranged independently. Here, the interval L11 'corresponds to the gap L11 between the protrusion rows 3R and 3R adjacent in the vertical direction X.

  In the manufacturing apparatus 100 for the composite sheet 1, as shown in FIG. 3, the second roll 12 has a roll concave portion 12c and a roll convex portion 12t that are meshed with the roll concave portion 11c and the roll convex portion 11t of the first roll 11. On the peripheral surface. Similarly to the first roll 11, the second roll 12 is formed by combining a plurality of gears so that the roll concave portion 12c and the roll convex portion 12t are formed, but a plurality of suctions extending in the axial direction. The road is not formed inside. Since the second roll 12 does not have a suction mechanism, the opening 116 formed in the first gear 111 and the second gear 112 of the first roll 11 is not necessary for the gear constituting the second roll 12. is there. Further, it is not necessary to form the beam 115 of the spacer 113 of the first roll 11 on the spacer constituting the second roll 12. Therefore, the circle diameter of the tooth tip of each gear constituting the second roll 12 is smaller than that of the first roll 11, and the number of the roll convex portions 12t is reduced accordingly.

  In the manufacturing apparatus 100 for the composite sheet 1, the roll convex portion 12 t of the second roll 12 is in the position where the first sheet 1 u is pushed by the roll convex portion 12 t of the second roll 12 into the roll concave portion 11 c of the first roll 11. It arrange | positions so that it may have a clearance gap in the perimeter of the tooth-tip surface of the roll convex part 12t so that the roll recessed part 11c of 1 roll 11 may not be contacted. Moreover, the 1st roll 11 and the 2nd roll 12 are arrange | positioned so that it may rotate in a non-contact state also in parts other than this.

  In the composite sheet 1 manufacturing apparatus 100, as shown in FIG. 3, the first heat roll 13 and the second heat roll 14 are flat anvil rolls each having no unevenness on the peripheral surface. The 1st heat roll 13 and the 2nd heat roll 14 are provided with the heating means (not shown). The first sheet 1u and the second sheet 1d are sandwiched between the circumferential surfaces of the first heat roll 13 and the second heat roll 14 heated by the heating means and the roll convex portion 11t of the first roll 11. Sometimes, the two sheets 1u and 1d are joined to each other by thermal fusion to form the joint portion 2.

Next, referring to FIGS. 3 and 6, a preferred embodiment of the method for producing a composite sheet of the present invention will be described with reference to FIGS. 3 and 6, taking as an example the production of the sheet-like material 1 having the above-described configuration using the above-described production apparatus 100. While explaining.
The manufacturing method of the composite sheet 1 of this embodiment supplies the 1st sheet 1u to the meshing part of the 1st roll 11 and the 2nd roll 12, and the roll convex part of the 2nd roll 12 to the roll recessed part 11c of the 1st roll 11 When the 12t enters, the first sheet 1u is pushed into the roll concave portion 11c of the first roll 11, and the three-dimensional shaping process for performing the three-dimensional shaping corresponding to the convex portion 3 of the composite sheet 1, and the composite sheet to be formed An adjustment step of changing the supply speed of supplying the first sheet 1u to the meshing portion of the first roll 11 and the second roll 12 according to the basis weight of the top of the first convex portion 3. In an adjustment process, it adjusts so that the supply speed of the 1st sheet 1u may become quick, so that the basic weight of the top part of convex part 3 to form is high.

  In the manufacturing method of the sheet-like object 1 according to this embodiment, first, a plurality of suctions extending in the axial direction V of the first roll 11 by operating a suction device (not shown) installed outside the first roll 11. Negative pressure is applied to the passage (not shown).

  Next, in the method for manufacturing the sheet-like material 1 of the present embodiment, as shown in FIG. 3, the first heat is driven by driving the drive roll 15, rotating the first roll 11 and the second roll 12, and heating to a predetermined temperature. The roll 13 and the second heat roll 14 are rotated.

  By driving the driving roll 15, the first sheet 1 u is fed out from the raw roll (not shown) of the first sheet 1 u via the driving roll 15. Separately from this, the second sheet 1d is fed out from an original roll (not shown) of the second sheet 1d. Then, the first sheet 1 u fed out by the drive roll 15 is supplied to the meshing portion of the first roll 11 and the second roll 12.

  In the adjustment process of the manufacturing method of this embodiment using the manufacturing apparatus 100 of the composite sheet 1 including the first roll 11 and the second roll 12 having the roll recess row 11cR described above, the first sheet 1u is attached to the first roll 11. The supply speed of the first sheet 1u when the top part of the convex part 3 of the composite sheet 1 is formed by being pushed into the roll concave part 11c is defined as the both ends of each roll concave part row 11cR of the first roll 11 in the axial direction V. From the roll concave portion 11c (first roll second concave portion 11c2) of the portion toward the roll concave portion 11c (first roll first concave portion 11c1) in the central portion in the axial direction V, the adjustment is made in a stepwise manner. Preferably, the convex portions 3 constituting each convex portion row 3R of the composite sheet 1 to be manufactured are top portions of the convex portions 3 from the central portion in the lateral direction Y of the composite sheet 1 toward both ends in the lateral direction Y. The basis weight of is gradually increased. Therefore, in the adjustment process of the manufacturing method of the present embodiment using the manufacturing apparatus 100, the horizontal basis with the highest basis weight of the top of the convex portion 3 of the composite sheet 1 to be manufactured by the command from the control unit 16 of the adjustment unit 17. The distance in the rotational direction U of the first roll second concave portion 11c2 at the endmost portion in the axial direction V, which forms the top of the convex portion 3 (second convex portion 32) at the end in the direction Y, is approximately divided into three. The first sheet 1u is supplied at the fastest supply speed v1 to the meshing portion in the center portion T1.

  Next, in the adjustment process of the manufacturing method of the present embodiment using the manufacturing apparatus 100, it is adjacent to the convex portion 3 (second convex portion 32) at the lateral end Y in accordance with a command from the control unit 16 of the adjustment unit 17. The first roll first in the axial direction V adjacent to the first roll second recess 11c2 at the extreme end in the axial direction V, which forms the top of the convex part 3 (second convex part 32) in the lateral direction Y. The first sheet 1u is supplied at a supply speed v2 that is slower than the supply speed v1 to the meshing portion in the central portion T2 when the distance in the rotational direction U of the two concave portions 11c2 is divided into approximately three equal parts. In this way, the supply speed of the first sheet 1u is gradually reduced. And finally, in the adjustment process of the manufacturing method of the present embodiment, according to the command from the control unit 16 of the adjustment unit 17, the lateral direction Y having the lowest basis weight of the top of the convex portion 3 of the composite sheet 1 to be manufactured. The central portion T3 when the distance in the rotational direction U of the first roll first concave portion 11c1 of the central portion in the axial direction V that forms the top of the convex portion 3 (first convex portion 31) in the central portion is equally divided into three. The first sheet 1u is supplied to the meshing part at the slowest supply speed v3.

  In the adjustment process of the manufacturing method of the present embodiment using the manufacturing apparatus 100, the adjustment unit 17 adjusts such a supply speed for each roll recess row 11 c R that is intermittently arranged in the rotation direction U of the first roll 11. Repeat. In the adjustment process of the manufacturing method of this embodiment, in the first roll 11 provided in the manufacturing apparatus 100, the roll recess rows 11cR and 11cR adjacent to each other in the rotation direction U are viewed from the axial direction V of the first roll 11, They do not overlap and are arranged independently. Therefore, in the adjustment step of the manufacturing method of the present embodiment, as shown in FIG. 6, after adjusting the supply speed of the first sheet 1 u in a stepwise manner in the roll recess row 11 cR on the downstream side in the rotation direction U, Returning from the slowest supply speed v3 to the fastest supply speed v1, the supply speed of the first sheet 1u is adjusted to be gradually reduced again in the same manner in the roll recess row 11cR on the upstream side in the rotation direction U. In the adjustment process of the manufacturing method of the present embodiment, such adjustment of the supply speed of the first sheet 1u is repeated for each roll recess row 11cR.

  While adjusting the supply speed of the first sheet 1 u as described above, as shown in FIG. 3, the first sheet 1 u is engaged with the engagement portion between the first roll 11 and the second roll 12, and the first sheet 1 u is engaged. 1u is unevenly shaped (three-dimensional shaping process). At this time, in the three-dimensional shaping process of the manufacturing method of the present embodiment, the first roll 11 is sucked from the peripheral surface toward the inside of the first roll 11 to promote the uneven shaping of the first sheet 1u. Yes.

  Next, in the manufacturing method of this embodiment using the manufacturing apparatus 100, as shown in FIG. 3, the first sheet 1u is continuously sucked to the peripheral surface of the first roll 11, and the second sheet is maintained while the shaped state is maintained. 1d is superposed, and the superposed one is sandwiched between the first roll 11 and the first heat roll 13 heated to a predetermined temperature. Thereby, the 1st sheet | seat 1u and the 2nd sheet | seat 1d which are located on the tooth-tip surface 111f, 112f of the roll convex part 11t in the 1st roll 11 are joined by thermal fusion, and the junction part 2 is formed.

  Next, in the manufacturing method of the present embodiment using the manufacturing apparatus 100, as shown in FIG. 3, the superposed body of the first sheet 1 u and the second sheet 1 d bonded by thermal fusion is used to surround the first roll 11. The superposed body is moved under the state of being sucked and held on the surface, and the superposed body is sandwiched between the first roll 11 and the second heat roll 14 heated to a predetermined temperature. As a result, the first sheet 1u and the second sheet 1d positioned on the tooth top surfaces 111f and 112f of the roll protrusion 11t of the first roll 11 are further firmly bonded by thermal fusion to form the bonded portion 2. .

  As described above, in the manufacturing method of this embodiment using the manufacturing apparatus 100, the target composite sheet 1 can be manufactured continuously and efficiently.

  If the manufactured composite sheet 1 is used, for example, as a surface sheet of an absorbent article such as a disposable diaper or a sanitary napkin, the convex portion 3 extends from the central portion in the lateral direction Y of the composite sheet 1 to both ends in the lateral direction Y. The convex portions 3R arranged intermittently in a direction inclined with respect to the longitudinal direction X and the lateral direction Y toward the surface are formed, and the convex portions 3 constituting each convex portion row 3R are formed of the composite sheet 1. From the central portion of the horizontal direction Y toward the both ends of the horizontal direction Y, the basis weight of the top of the convex portion 3 gradually increases. That is, when the composite sheet 1 is used as a top sheet of an absorbent article, the second convex portions 32 are located at both ends in the lateral direction Y with reference to the first convex portion 31 located in the central portion in the lateral direction of the absorbent article. A convex row 3R is formed that is intermittently arranged in a direction inclined with respect to the vertical direction X and the horizontal direction Y toward the portion. And the arrangement | sequence of the convex part 3 in a surface sheet is a line symmetrical arrangement | sequence which made the line which connects the 1st convex part 31 located in the center part of the horizontal direction in an absorbent article a symmetry axis. Therefore, the wearer's bodily fluid is likely to spread in the surface direction, the liquid diffusibility of the bodily fluid is likely to be stably improved, and the performance of the absorbent article is maximized by using the lower layer collector to the maximum. be able to.

From the viewpoint of further achieving the effects described above, the following composite sheet 1 preferably satisfies the following requirements.
The length L1 in the longitudinal direction X of the first joint portion 21 is preferably 1.2 mm or more and 2.0 mm or less, and more preferably 1.4 mm or more and 1.8 mm or less.
The length L2 along the lateral direction Y of the first joint portion 21 is preferably 0.5 mm or more and 1.5 mm or less, and more preferably 0.7 mm or more and 1.2 mm or less.
The length L3 along the longitudinal direction X of the second joint portion 22 is preferably 0.8 mm or more and 1.5 mm or less, and more preferably 0.9 mm or more and 1.1 mm or less.
The length L4 along the lateral direction Y of the second joint portion 22 is preferably 0.5 mm or more and 1.5 mm or less, and more preferably 0.7 mm or more and 1.2 mm or less.
The distance L5 between the first joint portions 21 and 21 arranged on the center line CL is preferably 2 mm or more and 8 mm or less, and more preferably 4 mm or more and 6 mm or less.
The distance L6 between the first joint portions 21 and 21 adjacent in the lateral direction Y is preferably 1 mm or more and 5 mm or less, and more preferably 2 mm or more and 4 mm or less.
The distance L7 between the central portions 21G and 21G of the first joint portions 21 adjacent in the longitudinal direction X is preferably 0.1 mm or greater and 1 mm or less, and more preferably 0.2 mm or greater and 0.9 mm or less.
The distance L8 between the first joint portion 21 and the second joint portion 22 is preferably not less than 0.5 mm and not more than 1.5 mm, and more preferably not less than 0.8 mm and not more than 1.2 mm. The distance L9 between the second joint portions 22 adjacent to each other in the lateral direction Y is preferably 1 mm or more and 5 mm or less, and more preferably 2 mm or more and 4 mm or less.
The distance L10 between the central portions 22G and 22G of the second joint portion 22 adjacent in the longitudinal direction X is preferably 0.1 mm or more and 1 mm or less, and more preferably 0.2 mm or more and 0.9 mm or less.
The gap L11 between the protrusion rows 3R and 3R adjacent in the vertical direction X is preferably 0.4 mm or more and 2 mm or less, and more preferably 0.8 mm or more and 1.6 mm or less.
The first convex portion 31 and the second convex portion 32 of the composite sheet 1 each preferably have a height of 0.5 mm to 2 mm, and more preferably 0.7 mm to 1.8 mm.
The basis weight of the top portion of the first convex portion 31 in the central portion of the lateral direction Y where the basis weight of the top portion of the convex portion 3 of the composite sheet 1 is lowest is preferably 10 g / m ² or more and 28 g / m ² or less, and 16 g. / M ² or more and 22 g / m ² or less is more preferable.
The basis weight of the top part of the second convex part 32 in the lateral direction Y endmost part having the highest basis weight of the top part of the convex part 3 of the composite sheet 1 is preferably 12 g / m ² or more and 30 g / m ² or less. More preferably, it is 18 g / m ² or more and 24 g / m ² or less.

  As mentioned above, although this invention was demonstrated based on the preferable embodiment, the composite sheet of this invention is not restrict | limited to the composite sheet 1 of embodiment mentioned above at all, and can be changed suitably.

  For example, in the composite sheet 1 of the above-described embodiment, as shown in FIG. 1, the convex portion 3 includes the first convex portion 31 and the second convex portion 32 having the same bottom area. In addition to the part 31 and the 2nd convex part 32, you may have another convex part with a small bottom area, for example.

  Moreover, in the manufacturing apparatus 100 of the composite sheet 1, the roll recess row 11 c </ i> R of the first roll 11 is arranged so that the roll recess 11 c starts from the central portion in the axial direction V of the first roll 11 as shown in FIGS. 5 and 6. Inclined with respect to each of the rotational direction U and the axial direction V toward both ends in the axial direction V and is intermittently arranged toward the downstream side in the rotational direction U. The first roll 11 is intermittently disposed toward the upstream side in the rotational direction U while being inclined with respect to the rotational direction U and the axial direction V from the central portion in the axial direction V toward both ends of the axial direction V. May be formed.

  The first roll 11 in which the roll recess 11c is inclined from the center portion in the axial direction V of the first roll 11 toward both ends in the axial direction V and is intermittently arranged upstream in the rotational direction U. Then, the first roll first recess 11c1 positioned on the center line CL ′ extending in the rotation direction U is inclined toward both end portions in the axial direction V and with respect to the rotation direction U and the axial direction V, respectively. The first roll second recess 11c2 is intermittently arranged toward the upstream side in the rotation direction U, and a roll recess array 11cR extending in the axial direction V is formed. In the roll recess row 11cR formed in this way, the end of the first roll first recess 11c1 and the end of the first roll second recess 11c2 adjacent to each other in the axial direction V connect the first roll 11 in the axial direction V. And the end of the first roll second recess 11c2 and the end of the first roll second recess 11c2 that are adjacent to each other in the axial direction V connect the first roll 11 from the axial direction V. It overlaps when seen. Therefore, the roll recess row 11cR is formed so as not to be seen when viewed from the axial direction V.

  The first roll 11 in which the roll recess 11c is inclined from the center portion in the axial direction V of the first roll 11 toward both ends in the axial direction V and is intermittently arranged upstream in the rotational direction U. In the adjustment process of the manufacturing method using the first sheet 1u, the first sheet 1u is pushed into the roll recess 11c of the first roll 11 to form the top of the projection 3 of the composite sheet 1 and the supply speed of the first sheet 1u The roll recess 11c (first roll first) in the central portion in the axial direction V from the roll recess 11c (first roll second recess 11c2) at both ends in the axial direction V of each roll recess row 11cR of the first roll 11. What is necessary is just to make it adjust in steps gradually toward the recessed part 11c1).

  The following composite sheet, composite sheet manufacturing apparatus, and composite sheet manufacturing method are disclosed in relation to the above-described embodiment of the present invention.

<1>
A composite sheet comprising a laminate of a first sheet and a second sheet and having a first direction and a second direction orthogonal to the first direction, wherein the laminate is the first sheet A plurality of joints between the first sheet and the second sheet, and the first sheet forms a plurality of convex parts protruding in a direction away from the second sheet at a portion other than the joint parts, Are intermittently arranged in a direction inclined with respect to each of the first direction and the second direction from the center portion in the second direction of the composite sheet toward both ends of the second direction. A plurality of the convex portion rows are arranged at a certain interval in the first direction, and the convex portions constituting each convex portion row are The convex portion from the center portion of the composite sheet in the second direction toward both end portions in the second direction Composite sheet basis weight of the top portion, becomes gradually higher.
<2>
The convex row is arranged with a first convex portion located in a central portion in the second direction and intermittently arranged toward both end portions in the second direction on the basis of the first convex portion. And the array of the convex portions of the composite sheet is a line-symmetrical array with a line connecting the first convex portions constituting each convex portion row as an axis of symmetry. The composite sheet according to <1>.
<3>
The composite sheet according to <1> or <2>, wherein the joint portion has a rectangular shape.
<4>
<1> to <3, wherein the first direction is a longitudinal direction coinciding with a fiber orientation of fibers constituting the first sheet, and the second direction is a transverse direction orthogonal to the longitudinal direction. The composite sheet according to>.
<5>
The composite sheet according to any one of <1> to <4>, in which the plurality of convex portion rows adjacent to each other in the first direction do not overlap each other when the composite sheet is viewed from the second direction.
<6>
The joint portion has a rectangular first joint portion whose length along the first direction is longer than the length along the second direction, and the length along the first direction is the second direction. The composite sheet according to <1> to <5>, including the second joining portion 22 having the same square shape as the length L4 along the line.
<7>
The first joints are regularly arranged at a certain interval along a center line extending in the first direction, and the first joints are defined on the basis of the first joints arranged on the center line. The other first joints are intermittently arranged at a certain distance L6 on the left and right outwards in the direction of 2, and the first joints adjacent to each other in the second direction are centered with each other. The composite sheet according to <6>, in which are arranged with a certain distance L7 shifted in the first direction.
<8>
The second joint portion is positioned at each end portion in the second direction of the first joint portion with respect to each first joint portion arranged on the center line, and is arranged in the left and right directions in the second direction. A pair of second joints are arranged on the outer side with a certain gap, and another second joint with a certain gap on the outer side in the second direction on the basis of each second joint. Are arranged intermittently, and the second joints adjacent to each other in the second direction are arranged such that their center portions are arranged with a certain distance L10 shifted in the first direction <6 > Or <7>.
<9>
The distance between the first joint and the second joint is equal to the length of the first joint in the second direction and the length of the second joint in the second direction. The composite sheet according to any one of <6> to <8>.
<10>
The interval between the second joints adjacent in the second direction is the same as the interval between the first joints adjacent in the second direction, any one of <6> to <9>. The composite sheet described.

<11>
<6> to <10, wherein an interval between the central portions of the second joint portions adjacent to each other in the first direction coincides with an interval between the central portions of the first joint portions adjacent to each other in the first direction. > The composite sheet according to any one of
<12>
The length of the first joint portion in the first direction is preferably 1.2 mm or more and 2.0 mm or less, more preferably 1.4 mm or more and 1.8 mm or less. > The composite sheet according to any one of
<13>
The length along the second direction of the first joint portion is preferably 0.5 mm or more and 1.5 mm or less, and more preferably 0.7 mm or more and 1.2 mm or less. The composite sheet according to any one of <12>.
<14>
The length along the first direction of the second joint portion is preferably 0.8 mm or more and 1.5 mm or less, and more preferably 0.9 mm or more and 1.1 mm or less. The composite sheet according to any one of <13>.
<15>
The length along the second direction of the second joint portion is preferably 0.5 mm or more and 1.5 mm or less, and more preferably 0.7 mm or more and 1.2 mm or less. The composite sheet according to any one of <14>.
<16>
The interval between the first joints arranged on the center line is preferably 2 mm or more and 8 mm or less, and more preferably 4 mm or more and 6 mm or less, according to any one of the above items <6> to <15>. Composite sheet.
<17>
The interval between the first joint portions adjacent to each other in the second direction is preferably 1 mm or more and 5 mm or less, and more preferably 2 mm or more and 4 mm or less, in any one of the above items <6> to <16> The composite sheet described.
<18>
The interval between the central portions of the first joint portions adjacent to each other in the first direction is preferably 0.1 mm or more and 1 mm or less, and more preferably 0.2 mm or more and 0.9 mm or less <6> The composite sheet according to any one of ~ <17>.
<19>
An interval L8 between the first joint and the second joint is preferably 0.5 mm or greater and 1.5 mm or less, more preferably 0.8 mm or greater and 1.2 mm or less, and the second The composite sheet according to any one of <6> to <18>, wherein an interval between the second joint portions adjacent to each other in the direction is preferably 1 mm or more and 5 mm or less, and more preferably 2 mm or more and 4 mm or less. .
<20>
The interval between the central portions of the second joint portions adjacent to each other in the first direction is preferably 0.1 mm or more and 1 mm or less, and more preferably 0.2 mm or more and 0.9 mm or less <6> The composite sheet according to any one of to <19>.

<21>
<1> to <20> The gap between the convex rows adjacent to each other in the first direction is preferably 0.4 mm or more and 2 mm or less, and more preferably 0.8 mm or more and 1.6 mm or less. The composite sheet according to any one of the above.
<22>
The first convex portion arranged along the center line extending in the first direction of the composite sheet and the left and right outer sides in the second direction than the first convex portion, the first convex portion Each of the second protrusions having the same bottom area as the bottom area preferably has a height of 0.5 mm or more and 2 mm or less, and more preferably 0.7 mm or more and 1.8 mm or less. The composite sheet according to any one of <21>.
<23>
The basis weight of the top of the first convex portion at the center of the second direction having the lowest basis weight of the top of the convex portion of the composite sheet is preferably 10 g / m ² or more and 28 g / m ² or less. The composite sheet according to <22>, more preferably 16 g / m ² or more and 22 g / m ² or less.
<24>
The basis weight of the top part of the second convex part at the extreme end in the second direction having the highest basis weight of the top part of the convex part of the composite sheet may be 12 g / m ² or more and 30 g / m ² or less. The composite sheet according to <22> or <23>, preferably 18 g / m ² or more and 24 g / m ² or less.
<25>
The composite sheet manufacturing apparatus according to any one of <1> to <24>, wherein a first roll having an uneven shape having a plurality of roll concave portions and roll convex portions on a peripheral surface, and the first roll A plurality of roll recesses and a second roll having an uneven shape that has a roll projection on the peripheral surface, and the manufacturing apparatus includes the first roll and the first roll. The first sheet is supplied to the meshing part of two rolls, and the roll convex part of the second roll enters the roll concave part of the first roll, so that the first sheet becomes the roll concave part of the first roll. The first roll is a device that is pressed into the three-dimensional shape corresponding to the convex portion of the composite sheet, and the first roll has the roll concave portion in the axial direction from the central portion in the axial direction of the first roll. Direction of rotation and axis towards both ends Roll recess rows arranged intermittently in a direction inclined with respect to each direction, and the first roll has a plurality of roll recess rows arranged at regular intervals in the rotation direction. And an adjusting unit that changes a supply speed of supplying the first sheet to the meshing portion of the first roll and the second roll according to the basis weight of the top of the convex portion of the composite sheet to be formed. And the adjustment unit increases the supply speed of the first sheet when the top of the convex portion of the composite sheet is formed by pushing the first sheet into the roll concave portion of the first roll. Production of a composite sheet, which is adjusted to increase the basis weight of the top portion of the convex portion formed by the above, and to reduce the basis weight of the top portion of the convex portion formed by slowing the supply speed of the first sheet. apparatus.
<26>
In the roll recess row of the first roll, the roll recess is inclined with respect to the rotational direction and the axial direction from the central portion in the axial direction of the first roll toward both ends in the axial direction. It is formed by being intermittently arranged toward the downstream side in the rotation direction, and the adjustment section pushes the first sheet into the roll recess of the first roll to form the top of the projection of the composite sheet. The supply speed of the first sheet when the roll is being moved, from the roll recesses at both axial end portions of the roll recess rows of the first roll toward the roll recesses in the central portion in the axial direction, The apparatus for producing a composite sheet according to <25>, wherein the adjustment is performed slowly and the adjustment of the supply speed is repeated for each of the roll recess rows arranged intermittently in the rotation direction of the first roll. .
<27>
In the roll recess row of the first roll, the roll recess is inclined with respect to the rotational direction and the axial direction from the central portion in the axial direction of the first roll toward both ends in the axial direction. It is formed by being intermittently arranged toward the upstream side in the rotation direction, and the adjustment unit pushes the first sheet into the roll concave portion of the first roll to form the top of the convex portion of the composite sheet. The supply speed of the first sheet when the roll is being moved from the roll recess at the axial center portion of each roll recess row of the first roll toward the roll recess at both axial ends. The apparatus for producing a composite sheet according to <25>, wherein the adjustment is performed quickly and the adjustment of the supply speed is repeated for each of the roll recess rows arranged intermittently in the rotation direction of the first roll. .
<28>
The heat roll disposed to face the roll peripheral surface of the first roll, and the joint is formed by pressing between the roll convex portion and the heat roll in the first roll under heating. The apparatus for producing a composite sheet according to any one of <25> to <27>.
<29>
The said heat roll is a manufacturing apparatus of the composite sheet as described in said <28> which consists of a flat anvil roll which does not have an unevenness | corrugation in the surrounding surface.
<30>
It consists of a laminated body of a first sheet and a second sheet, and the laminated body has a plurality of joint portions between the first sheet and the second sheet, and the first sheet is in a part other than the joint portion. A method of manufacturing a composite sheet forming a plurality of convex portions protruding in a direction away from the second sheet, the first roll having an uneven shape having a plurality of roll concave portions and roll convex portions on a peripheral surface, The first roll and the second roll are formed by using a plurality of roll concave portions and roll convex portions that are meshed with the roll concave portions and the roll convex portions of the first roll. The first sheet is supplied to the meshing portion of the roll, and the roll convex portion of the second roll enters the roll concave portion of the first roll, so that the first sheet is in the roll concave portion of the first roll. Pushed into the composite sheet And three-dimensional shaping step of performing a three-dimensional shaping which corresponds to the convex portion of the,
An adjustment step of changing a supply speed for supplying the first sheet to the meshing portion of the first roll and the second roll according to the basis weight of the top of the convex portion of the composite sheet to be formed, In the first roll, the roll concave portion is intermittently arranged with an inclination with respect to each of the rotational direction and the axial direction from the central portion in the axial direction of the first roll toward both ends in the axial direction. The first roll has a plurality of roll recess rows arranged at regular intervals in the rotation direction, and the adjustment step is performed at the top of the convex portion to be formed. The method for producing a composite sheet, wherein the higher the basis weight, the faster the supply speed of the first sheet.
<31>
In the roll recess row of the first roll used in the three-dimensional shaping step, the roll recess has a rotation direction and an axial direction from the central portion in the axial direction of the first roll toward both ends in the axial direction. The composite sheet is formed so as to be inclined relative to each other and intermittently disposed toward the downstream side in the rotation direction, and in the adjusting step, the first sheet is pushed into the roll recess of the first roll. The feeding speed of the first sheet when forming the top of the convex portion is from the roll concave portion at both axial end portions of each roll concave row of the first roll to the axial central portion. The adjustment is performed in a stepwise manner toward the roll concave portion, and the adjustment of the supply speed is repeated for each roll concave row arranged intermittently in the rotation direction of the first roll. A method for producing a composite sheet.
<32>
In the roll recess row of the first roll used in the three-dimensional shaping step, the roll recess has a rotation direction and an axial direction from the central portion in the axial direction of the first roll toward both ends in the axial direction. The composite sheet is formed so as to be inclined with respect to each other and intermittently arranged toward the upstream side in the rotation direction, and the adjusting step pushes the first sheet into the roll recess of the first roll. The feeding speed of the first sheet when forming the top of the convex portion of the first concave portion is set to the axial direction from the roll concave portion at the central portion in the axial direction of each roll concave portion row of the first roll. The adjustment is performed in a stepwise manner toward the roll recesses, and the adjustment of the supply speed is repeated for each roll recess row arranged intermittently in the rotation direction of the first roll. A method for producing a composite sheet.
<33>
Absorption which is provided with the surface sheet which consists of a composite sheet given in any 1 of the above <1>-<24>, and is arranged so that the 1st sheet of this composite sheet may be located in a wearer's skin side Sex goods.

DESCRIPTION OF SYMBOLS 1 Composite sheet 1u 1st sheet 1d 2nd sheet 2 Joint part 21 1st joint part 22 2nd joint part 3 Convex part 31 1st convex part 32 2nd convex part 3R Convex part row | line 100 Manufacturing apparatus 11 1st roll 11t roll Convex part 11c Roll concave part 11c1 First roll first concave part 11c2 First roll second concave part 11cR Roll concave part row 111 First gear 111a tooth 111f tooth tip surface 112 second gear 112a tooth 112f tooth tip surface 113 spacer 114 notch 115 Beam 116 Opening X Vertical direction Y Horizontal direction

Claims (10)

A composite sheet comprising a laminate of a first sheet and a second sheet, having a first direction and a second direction orthogonal to the first direction,
The laminate includes a plurality of joints between the first sheet and the second sheet, and the first sheet protrudes in a direction away from the second sheet at a portion other than the joint. Forming
The convex portion is intermittent in a direction inclined with respect to each of the first direction and the second direction from a central portion in the second direction of the composite sheet toward both end portions in the second direction. Forming a row of convex portions arranged side by side,
A plurality of the convex portion rows are arranged at regular intervals in the first direction,
As for the said convex part which comprises each said convex part row | line | column, the basic weight of the top part of this convex part becomes high gradually toward the both ends of the said 2nd direction from the center part of the said 2nd direction of the said composite sheet. Composite sheet.   The convex row is arranged with a first convex portion located in a central portion in the second direction and intermittently arranged toward both end portions in the second direction on the basis of the first convex portion. And an array of convex portions of the composite sheet is a line-symmetrical arrangement with a line connecting the first convex portions constituting each convex portion row as an axis of symmetry. Item 2. A composite sheet according to Item 1.   3. The composite sheet according to claim 1, wherein the plurality of convex portion rows adjacent to each other in the first direction do not overlap each other when the composite sheet is viewed from the second direction. The composite sheet manufacturing apparatus according to any one of claims 1 to 3,
An uneven first roll having a plurality of roll recesses and roll protrusions on the peripheral surface, and a plurality of roll recesses and roll protrusions meshing with the roll recesses and the roll protrusions of the first roll. A concave-convex second roll on the peripheral surface,
The manufacturing apparatus supplies the first sheet to the meshing portion of the first roll and the second roll, and the roll convex portion of the second roll enters the roll concave portion of the first roll, The first sheet is pressed into the roll recess of the first roll, and is a device that performs three-dimensional shaping corresponding to the convex portion of the composite sheet,
In the first roll, the roll recesses are intermittently arranged in a direction inclined with respect to the rotational direction and the axial direction from the central portion in the axial direction of the first roll toward both ends in the axial direction. And has a roll recess array arranged in
In the first roll, a plurality of the roll recess rows are arranged at regular intervals in the rotation direction,
In accordance with the basis weight of the top of the convex portion of the composite sheet to be formed, an adjustment unit is provided that changes a supply speed for supplying the first sheet to the meshing portion of the first roll and the second roll,
The adjusting portion is formed by increasing the supply speed of the first sheet when the top of the convex portion of the composite sheet is formed by pushing the first sheet into the roll concave portion of the first roll. The composite sheet manufacturing apparatus is adjusted to increase the basis weight of the top portion of the convex portion and to reduce the basis weight of the top portion of the convex portion formed by slowing the supply speed of the first sheet. In the roll recess row of the first roll, the roll recess is inclined with respect to the rotational direction and the axial direction from the central portion in the axial direction of the first roll toward both ends in the axial direction. It is formed by being intermittently arranged toward the downstream side in the rotation direction,
The adjusting section pushes the supply speed of the first sheet when the first sheet is pushed into the roll concave portion of the first roll to form the top of the convex portion of the composite sheet. The roll recesses are adjusted in a stepwise manner from the roll recesses at both ends in the axial direction of the roll recess rows toward the roll recesses in the central part in the axial direction, and the adjustment of the supply speed is The composite sheet manufacturing apparatus according to claim 4, wherein the apparatus is repeated for each of the roll recess rows arranged intermittently in the rotation direction of the first roll. In the roll recess row of the first roll, the roll recess is inclined with respect to the rotational direction and the axial direction from the central portion in the axial direction of the first roll toward both ends in the axial direction. It is formed by being intermittently arranged toward the upstream in the rotational direction,
The adjusting section pushes the supply speed of the first sheet when the first sheet is pushed into the roll concave portion of the first roll to form the top of the convex portion of the composite sheet. The roll recesses are adjusted in a stepwise manner from the roll recesses at the axially central portion of each of the roll recess rows toward the roll recesses at both ends in the axial center direction, and the adjustment of the supply speed is performed in the first step. The composite sheet manufacturing apparatus according to claim 4, wherein the apparatus is repeated for each of the roll recess rows arranged intermittently in the roll rotation direction. It consists of a laminated body of a first sheet and a second sheet, and the laminated body has a plurality of joint portions between the first sheet and the second sheet, and the first sheet is in a part other than the joint portion. A method for producing a composite sheet that forms a plurality of convex portions projecting away from the second sheet,
An uneven first roll having a plurality of roll recesses and roll protrusions on the peripheral surface, and a plurality of roll recesses and roll protrusions meshing with the roll recesses and the roll protrusions of the first roll. Using the concave and convex second roll on the peripheral surface,
The first sheet is supplied to the meshing portion of the first roll and the second roll, and the roll convex portion of the second roll enters the roll concave portion of the first roll, whereby the first sheet is A three-dimensional shaping step of performing a three-dimensional shaping corresponding to the convex portion of the composite sheet, being pushed into the roll concave portion of the first roll;
According to the basis weight of the top of the convex portion of the composite sheet to be formed, an adjustment step of changing a supply speed for supplying the first sheet to the meshing portion of the first roll and the second roll,
The first roll is intermittently arranged with the roll recess inclined from the central portion of the first roll in the axial direction toward both ends in the axial direction with respect to the rotational direction and the axial direction. Roll recess rows
In the first roll, a plurality of the roll recess rows are arranged at regular intervals in the rotation direction,
The said adjustment process is a manufacturing method of the composite sheet which makes the supply speed | rate of a said 1st sheet quick, so that the basic weight of the top part of the said convex part to form is high. In the roll recess row of the first roll used in the three-dimensional shaping step, the roll recess has a rotation direction and an axial direction from the central portion in the axial direction of the first roll toward both ends in the axial direction. Inclined with respect to each and formed intermittently toward the downstream side in the rotational direction,
In the adjusting step, the supply speed of the first sheet when the first sheet is pushed into the roll concave portion of the first roll to form the top of the convex portion of the composite sheet is determined by the first roll. The roll recesses are adjusted in a stepwise manner from the roll recesses at both ends in the axial direction of the roll recess rows toward the roll recesses in the central part in the axial direction. The method for producing a composite sheet according to claim 7, wherein the method is repeated for each roll recess row arranged intermittently in the rotation direction of one roll. In the roll recess row of the first roll used in the three-dimensional shaping step, the roll recess has a rotation direction and an axial direction from the central portion in the axial direction of the first roll toward both ends in the axial direction. Inclined with respect to each, it is arranged intermittently toward the upstream in the rotational direction,
In the adjusting step, the supply speed of the first sheet when the first sheet is pushed into the roll concave portion of the first roll to form the top of the convex portion of the composite sheet is determined by the first roll. The roll recesses are adjusted in a stepwise manner from the roll recesses at the axially central portion of each of the roll recess rows toward the roll recesses at both ends in the axial center direction, and the adjustment of the supply speed is performed in the first step. The method for producing a composite sheet according to claim 7, wherein the method is repeated for each of the roll recess rows arranged intermittently in the roll rotation direction.   An absorbent article comprising a surface sheet comprising the composite sheet according to any one of claims 1 to 3, wherein the composite sheet is disposed so that the first sheet of the composite sheet is positioned on the skin side of the wearer. .

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