JP2018191903A - Manufacturing method and manufacturing apparatus for sanitary article - Google Patents

Abstract

To improve the quality of a sanitary article.SOLUTION: In a manufacturing method for a sanitary article, a tensioning step, an application step, and an embossing step are performed. In the tensioning step, a creped sheet is pulled. In the application step, the sheet pulled in the tensioning step is applied with a chemical solution. In the embossing step, the sheet applied with the chemical solution in the application step is embossed. Further, the sheet embossed in the embossing step is layered without being wound up, and folded up.SELECTED DRAWING: Figure 5

Description

  The present invention relates to a method and an apparatus for manufacturing a sanitary product from a belt-shaped papermaking product to be conveyed.

Conventionally, functional sanitary paper in which chemicals such as a moisturizing agent and a fragrance agent are coated on a base paper is known. For example, moisturizing tissue paper has been commercialized.
As one method for manufacturing such sanitary paper, it has been proposed to perform the following steps 1 to 3 (see, for example, Patent Document 1).
Step 1: Making a strip-shaped base paper from slurry Step 2: Overlaying strip-shaped base papers and applying a drug and then cutting to a predetermined width direction Step 3: Folding the cut base paper to a predetermined transport direction dimension Divide and wrap

In the above step 1, the slurry in which the pulp is suspended is made into a belt-shaped wet paper, and the wet paper is dried with a drying roll (so-called Yankee roll). The dried base paper is peeled off from the drying roll by a doctor blade abutted against the base roll, and becomes a crimped base paper (so-called crepe base paper) and wound up on the take-up roll. And the 1st original fabric is manufactured.
In step 2 described above, two first original fabrics are installed, and the raw papers fed from the first original fabrics are overlapped. Thereafter, the medicine is applied to the overlapped base paper and cut into a predetermined width direction dimension. And it is wound up by a winding roll and a 2nd original fabric is manufactured.
In step 3 described above, the base paper fed out from the second raw fabric is folded. And it is divided | segmented into a predetermined conveyance direction dimension and packaged in a tissue box.

Japanese Patent No.4676564

However, as in the manufacturing method described above, after the chemical is applied to the base paper, various processes such as a step of cutting the base paper into a predetermined width direction dimension, a step of winding the base paper, and a step of feeding out the base paper are performed. There is a risk of product function degradation or damage.
Thus, the sanitary goods manufactured from the papermaking body to which the medicine is applied have room for improvement in order to improve the quality.

  This case has been developed in view of the above problems, and one of the purposes is to improve the quality of sanitary products.

  In the sanitary article manufacturing method disclosed herein, a tension process, a coating process, and an embossing process are performed. In the tensioning step, the sheet on which the crepe is formed is pulled. In the application step, a chemical solution is applied to the sheet pulled in the tension step. In the embossing process, embossing is applied to the sheet on which the chemical solution has been applied in the application process. Furthermore, the sheet to which the embossing has been applied in the embossing process is stacked and folded without being wound.

  According to this case, the quality of sanitary goods can be improved.

It is a schematic diagram which shows the outline | summary of the process which manufactures tissue paper. It is a schematic diagram which shows a paper machine. It is a schematic diagram which shows a lamination machine. It is a schematic diagram which shows a folding machine, (A) is a XX arrow directional view of (B). It is a flowchart which shows the procedure which manufactures tissue paper. It is a figure which shows the modification of a folding machine.

A mode for carrying out this case will be described. The following embodiments are merely examples, and are not intended to exclude various modifications and application of techniques that are not explicitly described in the embodiments. Each configuration of this embodiment can be implemented with various modifications without departing from the spirit thereof. Further, it can be selected as necessary, and can be appropriately combined.
[I. One Embodiment]

The sanitary article manufactured by the apparatus and method of the present embodiment is a papermaking body.
A papermaking product is a product made from paper. Examples of the papermaking body include paper made from pulp fibers and non-woven fabric made from resin fibers. For example, the papermaking body includes sanitary articles such as sanitary paper such as tissue paper and paper towels as well as sanitary non-woven fabrics.

In the following embodiments, as an example of the above-described sanitary article, a sheet-like (sheet-like) tissue paper manufactured from a strip-shaped base paper (papermaking) to be conveyed is given.
In the following embodiment, upstream and downstream are defined based on the direction in which the base paper is transported (hereinafter abbreviated as “transport direction”). Further, for the base paper, three directions are defined: a longitudinal direction, a width direction, and a thickness direction. The longitudinal direction is a direction extending in a strip shape on the extending surface of the base paper. This longitudinal direction is along the conveying direction. The width direction is a direction orthogonal to the longitudinal direction on the extending surface of the base paper. The thickness direction is a direction orthogonal to both the longitudinal direction and the width direction.

[1. manufacturing device]
The configuration of the apparatus for manufacturing tissue paper will be outlined.
As shown in FIG. 1, the tissue paper manufacturing apparatus is roughly divided into three parts P ₁ , P ₂ , and P ₃ .
In the first part P ₁ , a strip-shaped base paper W (papermaking body, sheet) is made (papermaking) by the papermaking machine 1 shown in FIG.

In the second part P ₂ , the base papers W made in the first part P ₁ are overlapped by the laminator 3 shown in FIG.
The base paper W after being superposed has a two-layer structure (so-called two-ply) and is different in structure from the single-layer base paper W before superposition (so-called one-ply), but considers readability. Simply referred to as “base paper W”.

In the third part P ₃ , the base paper W superimposed in the second part P ₂ is folded by the folding machine 5 shown in FIG.
Then, the base paper W is divided into predetermined transport direction dimensions. The base paper W until it is divided in this way is conveyed in a stretched state. Here, the “stretched state” means a state in which tension (tension) along the transport direction is applied and a state where the tension is stretched between the rolls. The base paper W is also stored in a state in which the tension applied during conveyance is maintained. From these, the base paper W from paper making to separation is kept in a state where tension is applied.

In the first part P ₁ , the stencil paper W is wound up. Paper W is conveyed to the second part P _2. Then, the base paper W is fed out. Similarly, in the second part P ₂ , the superposed base paper W is wound up. Paper W is conveyed to the third part P _3. Then, the base paper W is fed out.

That is, first volume preparative Part 15 (see FIG. 2) is provided downstream of the first part P _1, a first feeding part 30 (see FIG. 3) is provided upstream of the second part P _2. Further, the second volume collected by part 38 (see FIG. 3) is provided downstream of the second part P _2, the second feeding part 50 (see FIG. 4) is provided upstream of the third part P _3. Further, a first transport part P ₁₂ (first transport part) is provided between the first part P ₁ and the second part P _2, and a _second transport part between the second part P ₂ and the third part P ₃ is provided. A transport part P ₂₃ (second transport part) is provided.

A tension is applied to the transported base paper W by being wound by the first part P ₁ and the second part P ₂ . In other words, the base paper W is pulled along the transport direction by winding the first part P ₁ and the second part P ₂ .
Hereinafter, each structure of the paper machine 1, the laminator 3, and the folder 5 will be described.

[1-1. Paper machine]
The configuration of the paper machine 1 will be described in detail with reference to FIG.
The paper machine 1 is a tissue machine that forms a strip-shaped base paper W from raw materials.
The paper machine 1 is provided with a paper making part 10 (paper making section) for making the base paper W. In addition, a first winding part 15 (first winding part) for winding the base paper W made by the paper making part 10 is also provided.

The paper making part 10 includes a wire part 11 for making a wet base paper W (wet paper) from a raw material, a press part 12 for pressing moisture from the wet base paper W, and a dryer for drying the base paper W compressed with water. Part 13 is subdivided into a calendar part 14 that increases the smoothness of the dried base paper W. The base paper W whose smoothness is increased by the calendar part 14 is taken up by the first take-up part 15.
Hereinafter, the parts 11, 12, 13, 14, and 15 of the paper machine 1 will be described in the order of the manufacturing process.

<Wire part>
The wire part 11 is provided with a head box H for injecting slurry as a raw material of the base paper W. A raw material liquid in which pulp fibers are suspended is used for the slurry.
The wire part 11 is provided with two types of wire belts B _T and B _C partially wound around the outer periphery of the forming roll _RT .

The wire belts B _T and B _C are mesh-like endless belts wound around a belt conveyance roll. The forming wire belt B _T is wound around the slurry on the opposite side (outer peripheral side) from the forming roll _RT side, and the conveying wire belt B _C is formed on the forming roll _RT side (inner peripheral side) with respect to the slurry. Wrapped around.
The slurry injected between the wire belts B _T and B _{C on} the outer periphery of the forming roll R _T is dehydrated, so that the wet base paper W is made.

As shown in FIG. 2, the headbox H, forming wire belt B _T side with the first injection port H _E1 for emitting a first raw material liquid (outer circumferential side), conveying the wire belt B _C side (inner circumferential side) And a second injection port _HE2 for injecting the second raw material liquid. The fiber length of the pulp in which the first raw material liquid is suspended is set shorter than that of the second raw material liquid.

Since the base paper W is made from the slurry when transported on the transported wire belts B _T and B _C , the pulp is oriented along the transport direction. Therefore, the base paper W has a tear strength directivity that is difficult to tear along the width direction and easy to tear along the longitudinal direction.
Base paper W is the delivery wire belt B _C, it is conveyed to the next press part 12.

<Press part>
The press part 12, the conveying belt B _A water-absorbent is provided wound on a belt conveyor roll. An endless belt made of a material that absorbs water (for example, felt) is used as the transport belt B _A.
Site upstream side of the conveying belt B _A is provided in a state that it is pressed against sheet W conveyed by the conveying wire belt B _C described above.

Of the belt transport roll, the roll conveyor wire belt B _C places is wound to bias against the base paper W, and built-in suction roll R _A suction mechanism M _S is provided for sucking the sheet W Yes. The suction roll R _A, the conveyance path of the sheet W is switched on the conveying belt B _A from the delivery wire belt B _C.
In urging portions of the conveyor wire belt B _C against sheet W, water is squeezed from the sheet W. The base paper W thus dehydrated is transported to the next dryer part 13 by the transport belt B _A.

<Dryer part>
The dryer part 13 is provided with a drying roll R _D (also referred to as “yankee roll”) that dries the base paper W.
_A downstream portion of the transport belt B _A is urged to the drying roll _RD via the base paper W. The base paper W transported by the transport belt B _A moves so as to stick to the outer peripheral surface of the rotating drying roll _RD . The drying roll _RD heats the cylinder surface by, for example, steam introduced into the cylinder, and dries the base paper W on the cylinder surface.

The dryer part 13, the doctor blade D _D is provided for peeling the dried sheet W from the drying roll R _D.
Doctor blade D _D is the cutting edge against the cylinder face of the drying roll R _D are disposed in abutting been posture. Doctor blade D _D is the base paper W is peeled from the drying roll R _D imparts crepe (crepe-like wrinkles). The base paper W is provided with a crepe having a mixture of densely gathered portions and loosely gathered portions.

Drying rolls R in accordance with the conveyance speed of the abutment angle or exfoliated sheet W of the doctor blade D _D for _D, crepe condition applied to the base paper W changes. Conversely, by controlling the conveying speed of the doctor blade D _D abutment angle and drying roll R _D fiberboard W peeled from, it is possible to adjust the state of crepe imparted to the base paper W .
The base paper W thus peeled from the drying roll _RD is conveyed to the next calendar part 14.

<Calendar part>
The calendar part 14 is provided with a pair of calendar rolls _RL . The calendar rolls _RL rotate at a speed corresponding to the transport speed of the base paper W, and are arranged to face each other with the transported base paper W sandwiched therebetween. The base paper W is compressed in the thickness direction between the calendar rolls _RL .
The base paper W that has been calendered in this way is conveyed to the next first winding part 15.

<First winding part>
The first winding part 15 is provided with a first winding roll R _W1 for winding the base paper W. The first original fabric roll W _R1 is wound band-shaped sheet W is produced on the roll R _W1 preparative first volume. The first winding part 15 can be said to be a first tension part (first tension part) or a first tension application part (first tension application part) because the base paper W is pulled and taken up.
In the following description, in order to prevent the semi-finished product (intermediate) first raw fabric roll W _R1 from being confused with the rolls constituting the device structure, the “first original fabric roll W _R1 ” is referred to as “first raw fabric W _R1. ".

[1-2. Laminating machine]
The configuration of the laminator 3 will be described in detail with reference to FIG.
The laminating machine 3 is a ply machine that superimposes the base papers W. In the laminating machine 3, two first original webs W _R1 and W _R1 are installed, and the raw papers W fed out from the first original webs W _R1 and W _R1 are laminated. That is, the base paper W has a two-layer structure.

The laminating machine 3 includes a first feeding part 30 (first feeding part) for feeding the raw paper W from each first raw fabric W _R1 and a second winding part 38 (second winding part) for winding the raw paper W. Thus, there is provided a lamination part 32 (lamination part) for overlapping the base papers W fed out by the first feeding part 30. The laminating machine 3 is provided with an engaging part 35 (engaging portion) for engaging two layers of base paper W overlapped by the stacking part 32, and a cutting part 36 (for cutting the engaged base paper W). A cutting section) is also provided. A calendar part 33 is provided between the stacked part 32 and the engaging part 35.
Hereinafter, each part 30, 32, 33, 35, 36, 38 of the laminating machine 3 will be described in the order of the manufacturing process.

<First delivery part>
In the first feeding part 30, two first feeding rolls R _U1 and R _U1 each having a first original fabric W _R1 are provided, and each raw paper from the first original roll W _{R1 of} the first feeding roll R _U1 . W is paid out.
The base paper W fed out in this way is conveyed to the next lamination part 32.

<Laminated part>
The laminate part 32, laminating roll R _P is provided with two sheet W is wound by superimposing a part of the outer periphery. Two of the base paper W is superimposed in a stacked roll R _P.
This way the imbricated sheet W is the one of the two surfaces facing outward from the first surface F ₁ (surface F _F of one of the base paper W), while the second surface F ₂ (the other of the base paper W Surface F _F ).
The base paper W laminated as described above is conveyed to the next calendar part 33.

<Calendar part>
The calendar part 33 is provided with two sets of calendar rolls R _L1 and R _L2 similar to the calendar part 14, and performs the calendar process on the base paper W in two stages.
The base paper W that has been calendered in this way is conveyed to the next engagement part 35.

<Engagement part>
The engagement part 35 is provided with an engagement roll _RC that engages a part of the base paper W in the thickness direction. The engaging roll R _C, convex roll R _C1 and receiving roll R _C2 are provided. The convex roll R _C1 and the receiving roll R _C2 rotate at a speed corresponding to the conveyance speed of the base paper W, and are arranged to face each other with the base paper W interposed therebetween. The convex roll R _C1 is provided with a convex portion on the outer periphery corresponding to the location along the edge of the base paper W. This convex part is abutted against the outer periphery of the receiving roll R _C2 and received.

The convex portion of the convex roll R _C1 is abutted against the outer periphery of the receiving roll R _C2 through the sheet W, a state in which the base paper W is entangled in the thickness direction. In other words, the two layers of the base paper W are engaged with each other, and the layers having the two-layer structure are integrally engaged with each other.
The outer periphery of the receiving roll R _C2 is made of metal, and a structure in which the convex portion of the convex roll R _C1 does not easily protrude toward the receiving roll R _{C2 with} respect to the base paper W is adopted. For this reason, the base paper W that has been subjected to the engagement process by the engagement part 35 has a concave portion on the convex roll R _C1 side (for example, a linear portion along the transport direction), and the receiving roll R _C2 side is substantially flat. Eggplant. Such an engagement structure is also referred to as “crimper” or “contactor embossing”, and is structurally different from embossing having unevenness on both sides.
The base paper W subjected to the engagement process as described above is conveyed to the next cutting part 36.

<Cutting part>
The cutting part 36 is provided with a slitter S for cutting the base paper W along the longitudinal direction. The slitter S can cut the base paper W into various widthwise dimensions according to the widthwise position of the cutting location. For example, the slitter S is provided with a blade (cutter) and a blade receiving roll provided so that the position in the width direction with respect to the base paper W can be adjusted.

In the cutting part 36, the cutting dimension of the base paper W is set to a predetermined width direction dimension.
The “predetermined width direction dimension” means a width direction dimension of the base paper W installed in the folding machine 5 (see FIG. 4). As the dimension in the width direction, a dimension of an end side (long side or short side) (that is, a product width) of the finished tissue paper, a dimension that is an integral multiple of this, and the like can be given.
Each base paper W cut to such a width direction dimension is conveyed to the next second winding part 38.

<2nd winding part>
The second volume collected by part 38, similarly to the first volume preparative Part 15, the roll R _W2 preparative second volume for taking up the sheet W is provided. The second bulk roll W _R2 is produced on the roll R _W2 preparative second volume is wound band-shaped sheet W. In the second winding part 38, similarly to the first winding part 15, since the base paper W is wound while being pulled, the second tension part (second tension part) and the second tension application part (second tension) It can also be said to be an application unit. The second original fabric roll W _R2 is also abbreviated as “second original fabric W _R2 ” in order to prevent confusion with the roll forming the device structure.

[1-3. Folding machine]
The configuration of the folding machine 5 will be described in detail with reference to FIG.
The folder 5 is an interfolder that folds the base paper W. The folding machine 5 employs a so-called multi-stand type interfolder (also referred to as “multiple machine”), which corresponds to the number of sheets packed in the product state (the number of sheets accommodated in the tissue box). A number of second webs W _R2 are installed.

The folding machine 5 includes a second feeding part 50 (second feeding part) that feeds the base paper W from each second raw fabric W _R2 and a folding part 54 (folding part) that folds the base paper W. An application part 52 (application part) that applies the medicine to the base paper W after being fed by the feeding part 50 and before being folded by the folding part 54 is provided. The folding machine 5 is also provided with a dividing part 56 (dividing part) for dividing the base paper W folded by the folding part 54 and a packaging part 58 (packing part) for the base paper W divided by the dividing part 56. .

Two second raw fabrics W _R2 are installed (for example, juxtaposed) in one second feeding part 50. When a set of tissue is manufactured with two sheets that are packaged in a product state, each of the two second raw fabrics W _R2 installed in the second feeding part 50 has a two-layer structure. A pair of tissue (a state in which two base papers W are overlapped) is manufactured from the two raw fabrics W _R2 . That is, two sets of tissue are manufactured from one second feeding part 50. That is, the same number of second feeding parts 50 as the half of the total number of pairs of tissue (one box of tissue) packaged in a product state are installed.
The application part 52 and the folding part 54 are provided at a number of locations in the same manner as the second feeding part 50. On the other hand, the dividing part 56 and the packaging part 58 are provided at one location downstream of the folding machine 5.

Hereinafter, each part 50, 52, 54, 56, 58 of the folding machine 5 will be described in the order of the manufacturing process.
The upstream parts 50, 52 and 54 will be described in detail with reference to FIG. 4A, and the downstream parts 56 and 58 will be described in detail with reference to FIG. 4B.

<Second delivery part>
In the second feeding part 50, the second feed roll R _U2 of the second original fabric W _R2 is installed is provided, the base paper W is fed out from the second original fabric W _R2 of the second feed roll R _U2.
The base paper W fed out in this way is conveyed (derived) to the next coating part 52.

<Application part>
In the application part 52, the medicine is applied to the base paper W.
Examples of the drug include various liquid agents such as a moisturizer and a fragrance, a medical ingredient, a refreshing agent, and a pigment. For example, a moisturizing liquid (chemical solution) in which glycerin or sorbitol is dissolved in water is used as a functional drug that enhances the moisturizing function of the base paper W.

The application part 52 is provided with two application parts 52A and 52B (multi-application parts) for applying both surfaces F ₁ and F ₂ of the base paper W, respectively. The first surface F ₁ of the base paper W is applied by the first application part 52A (first application part). The second surface F ₂ of the base paper W is applied by the second application part 52B (second application part).
In the application parts 52A and 52B, the application direction of the medicine to the base paper W is set to the same direction. In other words, the application parts 52A and 52B apply the medicine to the base paper W from a predetermined direction. Here, a predetermined direction related to drug application is exemplified from the lower side in the vertical direction (that is, drug application from below).

The application part 52 is provided with reversing rollers R _R1 and R _R2 (surface turning portions) for reversing the direction of the base paper W, and both surfaces F ₁ and F ₂ face downward (one direction) in each of the application parts 52A and 52B. The above-described application is possible.
The front / back reversing roller R _R1 is disposed between the second feeding part 50 and the first application part 52A, and the front / reverse reversing roller R _R2 is disposed between the first application part 52A and the second application part 52B.
FIG. 4A illustrates two front and back reversing rollers R _R1 and two front and back reversing rollers R _R2 . However, the number of the reversing rollers R _R1 and R _R2 may be set according to the transport path of the base paper W, the surrounding configuration, the required specifications, and the like, and may be one or more than three. .

The reversing rollers R _R1 and R _R2 reverse the direction of the base paper W as follows.
The base paper W immediately before entering the front / back reversing roller R _R1 has the first surface F ₁ facing upward and the second surface F ₂ facing downward. Subsequently, the directions of both surfaces F ₁ and F ₂ are reversed by the front and back reversing rollers R _R1 , the first surface F ₁ faces downward and the second surface F ₂ faces upward, and the first coating part 52A starts from the bottom. agent is applied to one surface F _1. Thereafter, the orientations of both surfaces F ₁ and F ₂ are reversed again by the front and back reversing rollers R _R2 , the first surface F ₁ faces upward and the second surface F ₂ faces downward, and the second coating part 52B starts from the bottom. agent is applied to two surfaces F _2.

For the coating parts 52A and 52B, a method (so-called gravure method) in which coating is performed with gravure rolls R _G1 and R _{G2 in} which a plate (concave portion) is formed on the peripheral surface is used.
The first coating part 52A is adopted first coating mechanism M _1A offset gravure method, the second coating mechanism M _2A of the direct gravure method to a second coating part 52B is employed.

The first application mechanism M _1A is a roll coater that indirectly applies a drug from the gravure roll R _G1 to the base paper W via the offset roll R _O1 .
In addition to the offset roll R _O1 (also referred to as “transfer roll”) and the gravure roll R _G1 , the first coating mechanism M _1A is provided with a supply roll R _F1 that supplies the stored chemical to the gravure roll R _G1. It has been. Also referred gravure roll R doctor blade scrapes off the excess of the supply drug into _G1 D _G1 and the gravure roll through a sheet W R _G1 are disposed facing the backup roll R _B1 ( "pressing roll" ) And are provided.

The gravure roll R _G1 is disposed in contact with the offset roll R _O1 . The offset roll R _O1 is arranged in a state where it is in contact with the backup roll R _B1 with the base paper W interposed therebetween. Supplied from the supply roll R _F1 to gravure roll R _G1 agent is transferred to an offset roll R _O1, applied against the base paper W passing between the offset roll R _O1 of the offset roll R _O1 and the backup roll R _B1 Is done.

Second coating mechanism M _2A is a roll coater to directly apply the agent to the base paper W from the gravure roll R _G2.
The second coating mechanism M _2A is similar to the first coating mechanism M _1A except that the offset roll R _O1 is not provided. In addition to the gravure roll R _G2 , the supply roll R _F2 , doctor blade D _G2 , backup A roll _RB2 is provided.
The base paper W coated with the medicine as described above is conveyed to the next emboss formation part 53.

<Emboss formation part>
The embossing part 53 are arranged opposite to each other pair of embossing rolls R _E for forming irregularities on the base paper W is across the sheet W. The peripheral surface of the embossing roll R _E, irregularities corresponding to the irregularities formed on the base paper W is engraved.
In embossing part 53, the unevenness of the embossing roll R _E is pressed against the sheet W, irregularities are formed on the base paper W.

The embossing part 53 employs a double-sided embossing system, and includes a first embossing roll R _E1 that forms irregularities on the first surface F ₁ and a second embossing roll R _E2 that forms irregularities on the second surface F _2. It is done. As illustrated in FIG. 4 (A), the unevenness of the first embossing roll R _E1 and the second embossing roll R _E2 at the location where the irregularity is formed on the base paper W (nip location of the embossing rolls R _E1 and R _E2 ). A double-sided embossing system is used in which the base paper W is pressed alternately with the unevenness.

However, a double-sided embossing method in which convex portions are abutted among the unevenness of the embossing roll may be used, or a single-sided embossing method in which only one embossing roll has unevenness may be used. In the single-sided embossing method, a rubber roll is used for the other embossing roll, and unevenness is formed on the surface opposite to the unevenness forming surface of the base paper.
Since the emboss formation part 53 forms an unevenness | corrugation in the base paper W and provides emboss, it can be said that it is an emboss provision part (emboss provision part).
The base paper W on which the unevenness is formed as described above is conveyed to the next folding part 54.

<Folding part>
The folding part 54 employs a mechanism for folding the base paper W using the folding plate P as a folding mechanism (folding plate type, the folding form of the base paper W is a pop-up type).
The folding part 54 includes a folding plate P that folds the base paper W, and a separation roll that separates the inclined rolls CR _I1 and _CRI2 and the pair of base papers W and W that are arranged to intersect the width direction of the base paper W. Various transport rolls such as CR _S1 and CR _S2 are provided.

The folding part 54 folds the base paper W with the first surface F ₁ on the outside and the second surface F ₂ on the inside, and forms a fold by the folding plate P along the conveying direction of the base paper W.
The base paper W folded as described above is stacked with the base paper W folded through the other second feeding part 50, the coating part 52, the embossing part 53, and the folding part 54 that are arranged side by side. _I is conveyed to the next dividing part 56 by _I.

<Parting part>
The cutting part 56 is provided with a cutter C that cuts the base paper W along the width direction. The base paper W cut in this way is divided continuously in the longitudinal direction. By being divided in this way, the tension along the transport direction applied to the base paper W is released. From this, it can be said that the base paper W to which the medicine is applied is laminated and folded without being wound. The first winding part 15 of the first part P ₁ , the second part P ₂ (parts 30, 32, 33, 35, 36, 38), the second transport part P ₂₃ , and the second delivery part 50 of the third part P ₃ Since the tension applied to the base paper W is held on the upstream side of the dividing part 56 such as the above, it can be said to be a tension holding part (tension holding part).

The cutter C can cut the base paper W into various dimensions in the conveyance direction according to the cutting timing (here, the vertical movement control interval). For example, the longer the cutting interval of the cutter C is, the longer the distance that the base paper W is transported after the cutting is, so that the base paper W having a long transport direction dimension is cut.
Since the cutting part 56 cuts the base paper W downstream of the cutting part 36 described above, it can be said to be a second cutting part. Conversely, the cutting part 36 can also be said to be the first cutting part.

The cutting dimension of the base paper W is set to a predetermined conveyance direction dimension.
The “predetermined transport direction dimension” means a dimension of an end side orthogonal to an end side of the completed tissue paper cut to the above-described predetermined width direction dimension. Specifically, the dimension set as the length of the edge along the longitudinal direction of the tissue box in the tissue paper is set as a predetermined transport direction dimension.

The base paper W (sheet-like sanitary article) divided by the dividing part 56 in this way is a tissue paper before packaging, and is conveyed to the next packaging part 58.
<Packaging part>
In the packaging part 58, the base paper W divided by the dividing part 56 is accommodated in a packaging carton 59 (tissue box).
When packaging is completed in this way, a boxed tissue paper is completed.

[2. Production method]
A method for manufacturing tissue paper using the above-described manufacturing apparatus will be described.
In this method, as shown in FIG. 5, first, the first process (steps S10 and S15) corresponding to the manufacturing method of the paper machine 1 is performed. Then, the 1st conveyance process (step S20) which conveys the 1st original fabric W _R1 wound up with the paper machine 1 to the laminating machine 3 is implemented.
Then, the 2nd process (Steps S30-S38) corresponding to the manufacturing method of lamination machine 3 is carried out. Then, the second transportation process for transporting the second original fabric W _R2 taken up by the laminating machine 3 to the folding machine 5 (step S40) is performed.
Thus, the conveyance process which moves the raw fabrics W _R1 and W _R2 is performed between the processes of the first process, the second process, and the third process.
And the 3rd process (Steps S50-S58) corresponding to the manufacturing method of folding machine 5 is carried out.

In the first process, a papermaking process (step S10) corresponding to the manufacturing method of the papermaking part 10 is performed. In the paper making process, the base paper W in a wet state is dried from the raw material slurry, and crepe is applied to the base paper W.
And the 1st winding process (step S15) which winds up the base paper W by the 1st winding part 15 is implemented. This first winding process can be said to be a first tension process or a first tension applying process, following the alias of the first winding part 15.

In the second process, a first feeding process (step S30) for feeding the base paper W by the first feeding part 30 is performed. Subsequently, a stacking step (step S32) is performed in which the base paper W is overlapped by the stacking part 32.
Then, after calendering the base paper W with the calendar part 33, an engaging step (step S35) for engaging the base papers W with the engaging part 35 is performed. Thereafter, a cutting step (step S36) is performed in which the base paper W is cut into a predetermined width direction dimension by the cutting part 36.
And the 2nd winding process (step S38) which winds up the base paper W of a two-layer structure by the 2nd winding part 20 is implemented. This second winding process can be said to be a second tension process or a second tension applying process, following the alias of the second winding part 38.

In the third step, a second feeding step (step S50) for feeding the raw paper W by the second feeding part 50 is performed. Then, an application process (step S52) is performed in which the medicine is applied to the base paper W by the application part 52. Specifically, a multi-coating process (step S52) is performed in which the medicine is applied to both surfaces F ₁ and F ₂ of the base paper W.
In this multi-coating process, first, a first surface turning process (step S522) is performed in which the direction of the base paper W is reversed by the front and back reversing rollers R _R1 . Then, the first coating step of coating the drug on the first surface F ₁ of the base paper W the first coating part 52A (step S524) is performed.

Thereafter, a second surface turning step (step S526) is performed in which the orientation of the base paper W is reversed again by the front and back reversing rollers R _R2 . Then, the second applying step of applying an agent to the second surface F ₂ of the base paper W at the second coating part 52B (step S528) is performed.
The first application process is an indirect application process because the drug is applied to the base paper W by an offset gravure method. In addition, the second coating process is a direct coating process because the drug is applied to the base paper W by the direct gravure method. Since these surface turning processes change the surface to which the medicine is applied, they can also be called surface changing processes.

Then, the embossing forming step of forming irregularities on the base paper W with an embossing roll R _E (step S53) is performed. This embossing process forms an unevenness on the base paper W that has been cut to a predetermined width direction dimension, so it can be said to be an “embossing process after cutting”. In addition, the embossing process is an embossing process because the embossing process is performed by forming irregularities on the base paper W.

Subsequently, a folding step (step S54) of folding the base paper W by the folding part 54 is performed.
Thereafter, a dividing step (step S56) is performed in which the base paper W folded by the dividing part 56 is divided into a predetermined conveyance direction dimension.
In this way, the base paper W is folded and stacked without winding the base paper W coated with the medicine.

Then, the base paper W (tissue paper) is packaged in a carton 59.
The tissue paper is manufactured in such a procedure.

[3. Action and effect]
Since the tissue paper manufacturing method and manufacturing apparatus disclosed in the present embodiment are configured as described above, the following operations and effects can be obtained.

Hereinafter, operations and effects mainly relating to the production method will be described.
(1) In a conventional manufacturing method in which a medicine is applied to a base paper in a laminating machine, a number of processes including a winding process and a feeding process are performed from the medicine application to the division and packaging of the base paper.

On the other hand, in this manufacturing method, the medicine is applied to the base paper W by the folding machine 5 downstream of the laminating machine 3. Therefore, since the winding process, the conveyance process, and the delivery process are not set, the number of processes from the application of the medicine to the base paper W to the packaging is suppressed from the number of processes of the conventional manufacturing method described above.
Therefore, the period during which the base paper W is wet and tension is applied can be suppressed. In this way, the period during which the base paper W tends to grow is shortened. Therefore, the thickness reduction of the base paper W can be suppressed. Therefore, the thickness of the tissue paper can be ensured, and the touch and texture can be enhanced. In this way, the quality of tissue paper can be improved.

Conventionally, in a manufacturing method in which a medicine is applied to a base paper before being cut into a predetermined width direction dimension, it is difficult to apply a different medicine to each of the cut base paper as long as a kind of medicine is used. If the medicines are separately applied to each width direction region to be cut on the base paper, different medicines are applied to the base paper after cutting, but the mechanism for applying the medicine is complicated.
On the other hand, in this manufacturing method, the chemical | medical agent is apply | coated to the base paper W after the cutting | judging to a predetermined width direction dimension. Therefore, if various medicines are used properly for each folder 5, the tissue paper can have various functions with a simple configuration.

Here, the physical properties of the base paper W coated with the medicine will be described.
When the base paper W is moistened by chemical application, the crepe-shaped wrinkles that form a crepe are unwound, and the entanglement of the fibers weakens due to a decrease in the hydrogen bonding force (intermolecular force). In other words, the base paper W has a physical property that gradually elongates as moisture penetrates. If measures are not taken for the base paper W in such a state, wrinkles and twists will occur.

  On the other hand, in this manufacturing method, unevenness is formed in the embossing process on the base paper W in which the fiber entanglement has been weakened by the chemical application. The concavo-convexity of the fibers in the base paper W is reinforced by the unevenness. Therefore, generation of wrinkles and twists on the base paper W can be suppressed. Moreover, generation | occurrence | production of a wrinkle or twist can also be suppressed by the base paper W being extended in the thickness direction by the unevenness | corrugation formed in an emboss formation process. Therefore, the quality of tissue paper can be improved.

Furthermore, since the fiber entanglement of the base paper W on which the unevenness is formed is weakened, the unevenness can be clearly formed according to the embossing process performed after the coating process. Thereby, the appearance of the base paper W and the wiping property by the base paper W can also be improved.
In addition, in the conventional manufacturing method in which the base paper wet in the coating process is wound, transported, and fed, a load such as vibration or rubbing is applied to the base paper with weak fiber entanglement, which may cause damage to the base paper. On the other hand, in this manufacturing method, since the winding process, the transporting process, and the feeding process are set before the coating process, damage to the base paper W can be suppressed.

  In particular, since the winding process for winding the base paper W while being pulled is set upstream of the application process, the base paper W can be reliably prevented from being damaged. In other words, the manufacturing method and the manufacturing apparatus disclosed herein do not set the coating process in the first process (paper machine 1) or the second process (lamination machine 3), but the third downstream of these. The coating process is set in the process (folding machine 5)-the process in which the winding process as the main application source of the tension on the base paper W is not set--. Thus, the quality of the tissue paper can be improved by setting the coating process on the downstream side.

(2) The offset gravure method is adopted in the first application process (indirect application process), and the medicine is applied to the base paper W through the offset roll R _O1 . Therefore, the plate-th gravure roll R _G1 on the first surface F ₁ which is folded outwardly is not easily transferred in the base paper W. Therefore, tissue paper having a good appearance can be manufactured.
Further, the second coating step (direct coating process) is direct gravure method employed, the agent is directly applied to the doctor blade D _G2 of attached been gravure roll R _G2 from sheet W. Therefore, the medicine can be reliably applied to the base paper W.

(5) As described above, in the application process of the present manufacturing method, a multi-application process for applying the medicine to both surfaces F ₁ and F ₂ of the base paper W is set, so that the amount of medicine applied to the base paper W is ensured. be able to. Therefore, the function added to the tissue paper can be enhanced.
Between the first coating process and the second coating process in which both surfaces F ₁ and F ₂ are applied in this multi-coating process, a second surface turning process is set. Therefore, it is possible to employ a coating method in which the application direction of the medicine to the base paper W is limited to one direction. Specifically, the gravure method of coating from below can be applied to both the first coating process and the second coating process.

(6) If the drug is applied to only one side of the overlapped base paper, the base paper may be wrinkled or twisted due to the difference in the degree of expansion between the layers. When the base paper layers are engaged, there is a concern about the occurrence of larger wrinkles and twists.
In contrast, in the present process, since the drug is coated on both surfaces F _1, F ₂ of the engaging treated base paper W, it is possible to suppress the occurrence of wrinkles and twisting. From this point, the quality of tissue paper can be ensured.

(7) The base paper W to which the crepe is imparted in the paper making process is freed from the crimped wrinkles that form the crepe by wetting due to the chemical application in the coating process. By applying the medicine and embossing as described above to the base paper W having a precondition that is easy to stretch as described above, generation of wrinkles and twists on the base paper W can be suppressed.
(8) The above-described operations and effects can be obtained also by this manufacturing apparatus.

[II. Others]
Finally, other modifications will be described.
A gravure roll may be provided at least with a gravure roll.
The drug application method is not limited to the gravure method described above, and a known roll coating method such as a kiss coating method or a die coating method may be used. Furthermore, the present invention is not limited to the roll coat method, and other methods such as spraying a medicine on a base paper and immersing the base paper in a medicine may be used.

The form in which the base paper is reversed at the time of double-sided application of the medicine is not limited to the form in which the base paper is reversed in the direction orthogonal to the vertical plane, but may be a form in which the base paper changes to various postures. For example, it may be reversed using a reversing roller that is inclined with respect to the width direction so that the base paper is twisted.
The base paper may be superimposed on three layers (three plies) or more. Conversely, one layer of tissue paper may be manufactured by omitting the lamination step. In this case, the engagement step is also omitted.

  As long as the coating process for applying the drug to the base paper is set after the cutting process, the other processes except the paper making process and the embossing process may be omitted. For example, the second application step may be omitted to manufacture a single-sided tissue paper. In this case, the surface turning process is also omitted. Further, the tissue paper may be continuously manufactured by omitting the winding process, the transporting process, and the feeding process. According to such an in-line manufacturing method, the production efficiency of tissue paper can be increased.

Other types such as a long net type and a circular net type may be used for the wire part, and a multi-cylinder (cylinder dryer) roll may be used for the dryer part.
As shown in FIG. 6, a rotary interfolder may be used for the folding machine 5 '. In this folding machine 5 ′, a set of base papers W ′ and W ′ are folded and stacked, and a fold along the width direction of the base paper W ′ is formed. Thus, according to the folding machine 5 'on which a set of base papers W', W 'is installed, the number of application units installed can be reduced as compared with the above-described multi-stand type folding machine 5. The apparatus cost can be reduced.

DESCRIPTION OF SYMBOLS 1 Paper machine 3 Laminating machine 5,5 'Folding machine 10 Paper making part (paper making part)
15 First winding part (first winding part)
30 First payout part (first payout part)
32 Lamination part
35 Engagement part (engagement part)
36 Cutting part (Cutting part)
38 Second winding part (second winding part)
50 Second delivery part (second delivery part)
52 Application part (application part)
52A First application part (first application part)
52B Second application part (second application part)
53 Embossing part (embossing part)
54 Folding part (folding part)
56 Dividing part (dividing part)
C cutter D _D doctor blade D _G1 doctor blade D _G2 doctor blade F _F surface F _B backside F ₁ first surface F ₂ second side M _1A first coating mechanism M _2A second application mechanism P ₁ first part P ₂ first 2nd part P ₃ 3rd part P ₁₂ 1st transport part P ₂₃ 2nd transport part R _C engagement roll R _D drying roll
R _E embossing roll
R _E1 first embossing roll
R _E2 second embossing roll R _G1 , R _G2 gravure roll R _O1 offset roll R _P laminating roll R _R1 front and back reversing roller R _R2 back and front reversing roller R _T forming roll R _U1 , R _U2 feeding roll R _W1 , R _W2 winding roll S slitter W, W 'base paper (papermaking)
W _R1 first fabric (roll)
W _R2 2nd roll (roll)

Claims (12)

A tension step of pulling the sheet on which the crepe is formed;
An application step of applying a chemical to the sheet pulled in the tension step;
An embossing step for embossing the sheet on which the chemical solution has been applied in the application step,
The sheet to which the embossing has been applied in the embossing step is stacked without being wound and folded.
Manufacturing method of sanitary goods. The application step is a step of applying the chemical solution supplied to the gravure roll to the sheet.
A method for manufacturing a sanitary article according to claim 1. The application step is a step of transferring the chemical solution supplied to the gravure roll to a transfer roll and applying the chemical solution from the transfer roll to the sheet.
A method for manufacturing a sanitary article according to claim 1. Further comprising a laminating step of laminating the sheet before the coating step,
The application step is a step of applying the chemical solution to each of both surfaces of the sheet laminated in the lamination step.
The manufacturing method of the sanitary goods described in any one of Claims 1-3. An engagement step for engaging the sheets stacked in the stacking step between the stacking step and the coating step;
A method for manufacturing a sanitary article according to claim 4. Further comprising a surface changing step of changing the surface on the lower side in the vertical direction of the sheet,
The application step applies the chemical solution from the lower side in the vertical direction of the sheets stacked in the stacking step before the surface on the lower side in the vertical direction is changed in the surface change step, and further changes the surface. It is a step of applying the chemical from the lower side in the vertical direction of the sheet even after the surface on the lower side in the vertical direction is changed in the step.
A method for manufacturing a sanitary article according to claim 4 or 5. The tension step is a step of creating a roll by winding while applying tension to the sheet,
Between the tension process and the coating process,
An unwinding step of unwinding the sheet from the roll created in the tensioning step and deriving it to the coating step;
A transporting step of moving the roll created in the tensioning step to the feeding step,
The manufacturing method of the sanitary goods described in any one of Claims 1-6. An apparatus for producing a sanitary product having a predetermined width direction dimension from a belt-shaped paper product conveyed in a stretched state,
An application unit for applying a drug to the papermaking body cut to the predetermined width direction dimension;
An apparatus for manufacturing sanitary goods, comprising: an emboss forming part for forming irregularities on the papermaking body on which the drug is applied in the application part. The application unit applies the drug to both sides of the papermaking body, applies the drug from one side of the both sides from a predetermined direction, and applies the drug from the predetermined direction to the other side of the both sides. The sanitary article according to claim 8, comprising a second application part to be applied, and a surface turning part that is provided between the first application part and the second application part and reverses the direction of the papermaking body. manufacturing device. The sanitary article manufacturing apparatus according to claim 8 or 9, further comprising a stacking section that stacks the papermaking bodies upstream of the application section. The sanitary article manufacturing apparatus according to claim 10, further comprising an engaging portion that engages the papermaking bodies laminated in the laminating portion. The sanitary article manufacturing apparatus according to any one of claims 8 to 11, further comprising a papermaking section that papermaking the papermaking body in a state where a crepe is applied.

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