JP2020111845A - Apertured nonwoven fabric and manufacturing method thereof - Google Patents

Abstract

To provide an apertured nonwoven fabric excellent in flexibility and liquid permeability, having bulkiness and improved prevention for return of liquid.SOLUTION: An nonwoven fabric containing a thermally fusible composite fiber has apertures through from the front face to the rear face of the nonwoven fabric. The apertured nonwoven fabric has an aperture area in the front face of 0.2 to 20 mm2, and a specific volume of 40 to 200 cm3/g.SELECTED DRAWING: Figure 1

Description

TECHNICAL FIELD The present invention relates to a nonwoven fabric having openings and a method for producing the nonwoven fabric having openings.

Nonwoven fabrics used for sanitary materials such as disposable diapers and sanitary napkins have been continuously improved in search of more comfort. In particular, as a surface material for sanitary materials, a special non-woven fabric is used to reduce skin irritation, stuffiness caused by urine and menstrual blood. For example, a non-woven fabric shaped to reduce the contact area with the skin (hereinafter referred to as a shaped non-woven fabric) or a non-woven fabric having pores to increase the absorption rate of liquid such as urine and menstrual blood (hereinafter referred to as “non-woven fabric”). , A non-woven fabric having pores), a non-woven fabric having both shaping and pores (hereinafter referred to as shaped non-woven fabric), and the like.

As an apertured nonwoven fabric, an apertured nonwoven fabric is known in which apertures are formed by piercing the nonwoven fabric with a heated needle of a needle roll while sandwiching the nonwoven fabric with a needle roll and a hole roll that receives it (for example, Patent Document 1). In Patent Document 1, a nonwoven fabric is sandwiched between a pin roll having a large number of pins arranged on the surface and a ridge roll provided with a ridge for forming a shape between the pin rows. It is disclosed that a three-dimensional shape is imparted by conveying under pressure. However, when this method is used, the non-woven fabric is sandwiched between the rolls and crushed, so that the bulk of the non-woven fabric may be lowered and the flexibility may be lowered. In addition, since the non-woven fabric is compacted except for the open pores, the bulk becomes low and the liquid permeability may be deteriorated. When such a non-woven fabric is used as a sanitary material, problems such as easy liquid return may occur.

Further, in Patent Document 2, in order to manufacture a nonwoven fabric that is bulky and has shaping on the surface, a fiber web of thermoplastic fibers is placed on a breathable conveyor having irregularities, and the fiber web is placed. Injecting a gas on the surface of the web during conveyance by, to form a shape by following the fiber web to the concave portion of the air permeable conveyor, heating the fiber web to fuse and integrate the thermoplastic fibers. It is disclosed. The non-woven fabric of Patent Document 2 is a non-woven fabric having a high fiber density in the convex portion and a low fiber density in the concave portion, and the convex portion has a soft touch, and a liquid or a viscous substance is discharged from the concave portion having a low fiber density. It is to pass. Further, it is disclosed that the concave portion may not only have a low fiber density but may also be open. On the other hand, in the method for manufacturing a nonwoven fabric of Patent Document 2, since fibers are biased by gas injection to form a concave portion or an opening, it is difficult to form a small-diameter opening in a bulky nonwoven fabric. Met.

In order to solve these problems, a shaped apertured nonwoven fabric that has been both apertured and shaped by an aperture device that combines a convex roll and a piercing pin roll has been studied (for example, Patent Document 3). Patent Document 3 discloses a non-woven fabric having a ridge portion and a groove portion alternately, and having an opening in the groove portion. In order to form this shape, first, an uneven shape is formed on the surface by a mesh or the like. The fluid is sprayed on the surface of the fluid permeable support (mesh roll) while passing through a bulky material such as a card web to localize the fibers to give a groove ridge structure to the card web. .. Next, it is disclosed that the card web is passed between a pin roll and a ridge roll to form an opening, and the peripheral edge portion of the opening is melted and fixed by heating.
The nonwoven fabric of Patent Document 3 has a higher fiber density in the peripheral edge of the opening formed in the groove portion than in the top portion of the ridge portion, and as a result, liquid is guided from the top portion of the ridge portion to the peripheral edge of the opening. It is disclosed that it has become easier. However, it cannot be said that it still has sufficient liquid permeability and liquid return prevention property.

JP-A-6-330443 Japanese Examined Patent Publication No. 7-91764 JP, 2009-215667, A

In view of these circumstances, it is an object of the present invention to provide a perforated nonwoven fabric that is bulky, has excellent flexibility, has good liquid permeability, and further has improved liquid return prevention property. Moreover, when shaping|molding is further provided to a perforated nonwoven fabric, it makes it a subject to provide a perforated nonwoven fabric with high shape retention.

The present inventor has conducted extensive studies in order to solve the above problems, and has come up with the idea of producing a nonwoven fabric in which the entire nonwoven fabric is bulky and has pores of a small diameter. However, it is difficult to maintain open pores due to the bulkiness and flexibility of the non-woven fabric when it is attempted to provide small-sized pores in the bulky and flexible non-woven fabric. It has been found that it is easy and the liquid return prevention property deteriorates. On the other hand, on the other hand, it was confirmed that although a small-diameter hole can be formed by the conventional method of passing between the rolls, if the non-woven fabric is sandwiched between the rolls, the non-woven fabric is somewhat compressed. In view of these circumstances, the inventors further studied a method for producing a small-diameter hole without including a step of sandwiching a bulky nonwoven fabric between rolls.

As a result, a breathable needle plate or needle roll in which a large number of needles are erected on the surface of a punching or mesh perforating member is adopted, and a web containing thermoplastic fibers is placed on the breathable needle plate or the like. Then, the web is pressed against a needle plate or a needle roll by wind pressure for perforation, and subsequently, a method in which fibers of the web are fused and fixed by heating is fixed, and the bulkiness (ratio It was found that a non-woven fabric having a large volume) and in which small-diameter pores are retained can be produced, and the present invention for solving the above problems was completed.

That is, the present invention has the following configurations.
[1] A non-woven fabric containing heat-fusible composite fibers, having perforations from the front surface to the back surface of the non-woven fabric, having an opening area of 0.2 to ²⁰ mm ² on the surface, and a specific volume of 40. An open-pore nonwoven fabric, which is ˜200 cm ³ /g.
[2] The open-pore nonwoven fabric according to [1] above, which further has shaping on the surface of the open-pore nonwoven fabric.
[3] The open-hole nonwoven fabric according to [2], wherein a plurality of the above-mentioned shapes are arranged on the surface of the above-mentioned open-hole nonwoven fabric, and each of them is a convex shape protruding independently.
[4] In the non-woven fabric having open pores, the open pores are present in a base portion located between a convex shape and an adjacent convex shape, [2] or [3]. Open-hole non-woven fabric.
[5] In the above-mentioned [3] or [4], wherein the ratio of the thickness of the convex shaped top portion to the thickness of the base portion is 10:1 to 1:10 in the open-pore nonwoven fabric. The perforated nonwoven fabric described.
[6] In the open-pore nonwoven fabric, the thickness of the convex shaped top portion is 0.3 to 4.0 mm, and the thickness of the base portion is 0.3 to 3.0 mm, [3] ~ The open-pore nonwoven fabric according to any one of [5].
[7] a step of producing a web of thermoplastic fibers,
The web is placed on a breathable needle plate or a roll of breathable needles in which a large number of needles are erected on the surface of a punching or mesh perforated member, and the needles penetrate the web by an air flow. And the process of
Heating the web penetrated by the needle with heated air to melt at least a part of the thermoplastic fibers constituting the web to form a nonwoven fabric,
A method for producing an open-pore nonwoven fabric, comprising:

The open-pore nonwoven fabric of the present invention is bulky and excellent in flexibility as a whole, and has pores penetrating the nonwoven fabric in the thickness direction in a direction substantially perpendicular to the face of the nonwoven fabric. The liquid time is short (that is, the absorption speed is fast) and the liquid permeability is good. In addition, since the openings have a small diameter and the nonwoven fabric is bulky, the liquid return prevention property is also excellent. Furthermore, among the open-hole nonwoven fabrics of the present invention, those having a convex shape that independently protrudes on the surface of the nonwoven fabric have a small contact area with the skin and are particularly excellent in skin contact.

Further, according to the production method of the present invention, since a nonwoven fabric is produced without being subjected to compression by a roll or the like, it is possible to produce a bulky nonwoven fabric without a compressed portion on the surface of the nonwoven fabric. In addition, since pores are formed by a needle sheet or needle roll in the state of the web, and a part of the web is melted and fixed by heating while the needle penetrates the web to form a nonwoven fabric, it is bulky and formed. It is possible to obtain an open-pore nonwoven fabric in which the formed pores are maintained without being crushed.

It is an appearance of the open-pore nonwoven fabric which is Example 2 of the present invention. 3 is an appearance of the open-pore nonwoven fabric of Comparative Example 1. It is a schematic diagram which shows the cross section of the open-hole nonwoven fabric which is an Example of this invention. It is a photograph of a needle plate used for manufacturing the open-pore nonwoven fabric of the present invention.

(Open-pore non-woven fabric)
The perforated nonwoven fabric of the present invention is a non-woven fabric containing a heat-fusible composite fiber, and has perforations that penetrate from the front surface to the back surface of the non-woven fabric and have an opening area of 0.2 to ²⁰ mm ² on the surface. The specific volume is 40 to 200 cm ³ /g. The open-hole nonwoven fabric of the present invention is a bulky nonwoven fabric without a heat-compressed portion. When the specific volume is 40 cm ³ /g or more, sufficient bulkiness can be obtained, and the liquid return is small, and when the specific volume is 200 cm ³ /g or less, the liquid does not stay in the nonwoven fabric, so the liquid return is small. Become.

In addition, the open-pore nonwoven fabric of the present invention is characterized in that a small-diameter hole penetrates through a bulky nonwoven fabric, and the open-pore area on the surface can be 0.2 to ²⁰ mm ^2, and 0.5 to 3 preferably if .5mm ^2, more preferably if 0.7~2.0mm ^2. In the present specification, the open area means the area of each opening of a large number of holes provided in the nonwoven fabric. The open area is taken, for example, with a Keyence Corp. microscope VHX-6000 so that the open area of the nonwoven surface is photographed at 4 points. It can be measured from the surface area connecting the openings. The openings may be provided on the nonwoven fabric at regular intervals or irregular intervals, but it is preferable that the apertures are regularly provided at regular intervals. For example, in a nonwoven fabric, openings can be provided in series, in parallel, in a staggered arrangement, and the like. The number of openings is appropriately selected depending on the intended use and function and is not particularly limited. For example, it is preferable that 1 to 5 openings are dispersed per cm ^{2 of} the nonwoven fabric.

It is also preferable that the apertured nonwoven fabric of the present invention further has a shape. The shape of the shape is not particularly limited, but shapes such as a convex shape, a dome shape, and a ridge shape can be exemplified, and among them, it is preferable that each shape is a convex shape protruding independently. If the shape is an independent convex shape, the aperture may be located at the convex top, and is at the base located between the convex shape and the adjacent convex shape. Is also preferable. With such a structure, liquid permeability becomes good.

The thickness of the open-pore nonwoven fabric can be 1.0 to 5.0 mm, preferably 1.5 to 4.0 mm, and more preferably 2.0 to 3.5 mm. In the present specification, the thickness of the perforated nonwoven fabric refers to the thickness from the base portion to the top portion of the shaping when the shaping is applied to the nonwoven fabric (Fig. 3, W ₁ ). The open-hole nonwoven fabric of the present invention is characterized in that the bulkiness (thickness) of the nonwoven fabric is maintained at both the shaped portion and the open-hole portion, and the nonwoven fabric has a large specific volume (that is, a low nonwoven fabric density). The thickness of the nonwoven fabric or the thickness of each part is not particularly limited, but for example, the thickness of the top of the shaped part (FIG. 3, W ₂ ) is preferably 0.3 to 4.0 mm, The thickness of the part (FIG. 3, W ₃ ) is preferably 0.3 to 3.0 mm. Moreover, it is preferable that an opening is formed in the base portion. The thickness ratio between the top portion and the base portion of the shaped object is preferably 1:10 to 10:1, more preferably 3:7 to 7:3, and is 4:6 to 6:4. Is more preferable.

FIG. 3 shows a schematic view of a cross section of the open-hole nonwoven fabric of the present invention. The open-pore nonwoven fabric 1 has a plurality of openings 2 and is shaped as a whole. In the shaping, independent convex portions 3 are regularly arranged, and the openings 2 are located in the base portion 4 between the convex portions 3. The thickness W ₁ of a perforated nonwoven cloth 1, refers to the thickness from the top of the convex portion 3 to the bottom of the base unit 4. In addition, in the open-pore nonwoven fabric 1, neither the shape-imparting portion (convex portion 3) nor the base portion 4 is consolidated, and both the top portion thickness W ₂ and the base portion thickness W _{3 of} the shape-imparting portion are kept bulky. ..

The open-pore nonwoven fabric of the present invention is composed of heat-fusible composite fibers. Examples of the heat-fusible conjugate fibers include heat-fusible sheath-core type conjugate fibers, heat-fusible eccentric sheath-core type conjugate fibers, and heat-fusible parallel type conjugate fibers. Examples of the thermoplastic resin that constitutes the heat-fusible conjugate fiber include polyethylene (PE) such as low density polyethylene (LDPE), linear low density polyethylene (LLDPE), and high density polyethylene (HDPE), crystalline polypropylene, propylene. (PET) such as polypropylene (PP) such as a copolymer of propylene and ethylene or an α-olefin whose main component is (Co-PP), polyethylene terephthalate, polybutylene terephthalate, polyester copolymer (Co-PET), etc. Etc. can be illustrated. A heat-fusible composite fiber obtained by combining these thermoplastic resins can be used. Specific examples of the combination of thermoplastic resins include PP/PE, PP/Co-PP, PET/PE, PET/LLDPE, and PET/Co-PET. In order for the heat-fusible conjugate fiber to have the heat-fusible property, it is preferable to dispose a low melting point thermoplastic resin on the surface of the conjugate fiber.

The fineness of the heat-fusible composite fiber used in the present invention is preferably 0.8 to 20 dtex, and more preferably 1.0 to 10 dtex. In particular, when the open-pore nonwoven fabric is used for the surface layer (on the side that comes into contact with the skin) of a paper diaper or the like, the flexibility of the nonwoven fabric becomes good by making the heat-fusible composite fiber constituting the nonwoven fabric finer. Further, if the fineness is small, the smoothness is improved, so that the friction with the skin is reduced and the rash is reduced. Generally, a non-woven fabric composed of heat-fusible composite fibers having a fineness tends to make it difficult for a liquid to pass due to an increase in the number of fiber constituents. Therefore, the liquid permeability is maintained. In the present invention, it is preferable to use the heat-fusible conjugate fiber within the above-mentioned fineness range from the viewpoint of the balance between liquid permeability and flexibility, and productivity in processing.

Further, the open-hole nonwoven fabric of the present invention may be composed of one type (single layer) of nonwoven fabric, or may be a nonwoven fabric in which two or more types of nonwoven fabrics having different compositions, fineness, density and the like are laminated. .. In any case, it is characterized by having openings penetrating from the front side to the back side of the nonwoven fabric. When two or more kinds of nonwoven fabrics are laminated, it is preferable that the laminated layers are integrated by fusion, adhesion, or the like. In the case of a multi-layered non-woven fabric, for example, by laminating non-woven fabric layers having different fineness, the size of the pores formed between the fibers can be changed in the thickness direction of the non-woven fabric to further improve liquid permeability. it can. In addition, by laminating nonwoven fabric layers having different compositions, it is possible to obtain a nonwoven fabric in which hydrophilicity and hydrophobicity of the nonwoven fabric change in the thickness direction of the nonwoven fabric, which further improves liquid permeability or liquid permeability. ..

When the open-pore nonwoven fabric has a laminated structure, the combination thereof is not particularly limited, but for example, a plurality of layers composed of PET/PE heat-fusible composite fibers and differing only in fineness can be laminated. Also, fibers having a spiral crimp can be laminated.

Although woven cloth is not particularly limited, for example, when the nonwoven fabric is a single layer, basis weight is preferably ^{10~100g / m 2, 15~70g / m} 2 is more preferable. Within the above range, the nonwoven fabric has good bulk or absorption performance. Even if the nonwoven fabric is a multilayer, basis weight (total weight of the plurality of layers constituting the nonwoven fabric) is preferably from 10 to 100 g / ^{m 2,} more preferably 15~70g / ^{m 2.}

(Method for manufacturing open-pore nonwoven fabric)
The open-hole nonwoven fabric of the present invention generally has, for example, a card web placed on a punching roll or a punching plate on which a large number of pins are erected, and the card web is pierced into the pins by cold air or hot air to form small holes. Then, it can be manufactured by a method in which the web is bonded and fixed to a nonwoven fabric by hot air. FIG. 4 shows a photograph of a needle plate used for producing the open-pore nonwoven fabric of the present invention. FIG. 4 is a view of the needle plate viewed from above, in which pins are vertically provided on a surface of a punching plate in which circular holes are regularly formed.

The number of pins standing on the punching roll or punching plate is preferably 1 or more and 10 or less, and more preferably 2 or more and 8 or less per 1 cm ² . When the number of pins is 10 or less, the pin density does not become too high and the web can be pierced by the cold and hot air, and when piercing with a stronger air flow, the web is disturbed and the texture is damaged. There is no. Further, by setting the number of pins to 2 or more, it is easy to pierce the web with the pins due to the appropriate needle density and the air permeability of punching in the processing of the nonwoven fabric, and the absorption performance of the resulting nonwoven fabric is well balanced. Therefore, it is preferable.

The diameter of the pin standing on the punching roll or punching plate is not particularly limited, but is preferably 0.5 to 5 mm, more preferably 1 to 3 mm. If the diameter of the pin is 0.5 mm or more, the pores of the obtained non-woven fabric will not be blocked, and if it is 5 mm or less, the area of the non-woven fabric aperture will not be too large. It is preferable because the liquid return can be suppressed in the absorption performance.
The height or length of the pin is not particularly limited as long as it is not less than the thickness of the web used.

The opening area of the single hole of the punching roll or punching plate is preferably 5 mm ² or more, more preferably 7 mm ² or more. When the opening area of the single hole of the punching roll is 5 mm ² or more, cold air or hot air is likely to escape when the web is pierced, the web is less likely to be disturbed, and it is easy to give the nonwoven fabric a shaped shape, which is preferable. .. The shape of the opening of the punching roll or the punching plate is not particularly selected, such as a circle, an ellipse, a triangle, and a square. Further, the positions of the pins and openings may be selected in series, in parallel, in a staggered manner.

In the production of the open-pore nonwoven fabric of the present invention, first, a web of thermoplastic fibers forming the nonwoven fabric is prepared. A publicly known process can be appropriately selected and used for the production of the web and is not particularly limited. For example, the thermoplastic fiber obtained by the melt spinning method is stretched, cut, and put into a card machine. , A staple fiber web can be obtained. As another method, a spunbond method can be used to obtain a spunbond web. A particularly effective spinning method is a melt blow method. The melt-blowing method, a molten thermoplastic resin extruded from the spinning hole in the machine direction or the length direction is blown to a collecting conveyor net or the like by a high-temperature high-speed gas blown from around the spinning hole to obtain an ultrafine fiber web. Is the way.

Then, the web is placed on a punching roll having a large number of pins erected (hereinafter sometimes referred to as punching needle roll) or a punching plate having pins erected (hereinafter sometimes referred to as punching needle plate). Then, the web is fixed to the pin by piercing the pin with cold air. The amount of air, the speed of air, etc. can be appropriately selected depending on the basis weight of the web and the like, and are not particularly limited, but in order to prevent the web from penetrating the pins, and preventing the web from being consolidated due to wind pressure and the deviation of the fibers. Can be set to a wind speed of 2 to 20 m/s, and more preferably 5 to 15 m/s.

Then, with the pin pierced into the web, hot air having a temperature equal to or higher than the melting point of the low melting point component of the heat fusible composite fibers is applied to fuse the heat fusible composite fibers. The temperature or amount of hot air is not particularly limited as long as heat fusion occurs and the web is not consolidated or biased by wind pressure. For example, the temperature is 125 to 150° C., and the wind speed is 2 to 20 m/s. Can give hot air. Then, by cooling and solidifying, an open-pore nonwoven fabric having bulkiness and small openings can be obtained.

In the case of shaping into a perforated nonwoven fabric, in the process of penetrating the web into the pins or in the process of fusing the heat-fusible composite fibers with hot air, the web is not only penetrated into the pins but also punched. The web is pressed along the edge of the opening of the needle roll or the punching needle plate so as to be deformed, and the web is fused or cooled and solidified in this state, whereby a perforated nonwoven fabric having a shape can be obtained. On the other hand, when making a flat open-hole nonwoven fabric without shaping, a punching needle roll in which the punching needle roll or the punching part (air through hole) of the punching needle plate is closed with a mesh net or a mesh that does not obstruct air through Etc. can be used to process by the above method.

In another manufacturing process, the web is placed on a punching needle roll or punching needle plate, and the web is pierced by a cold air to pierce the pin to fix the web.At this time, hot air is blown directly instead of cold air to pierce and melt. May be performed at the same time.
The above-described manufacturing method shows the outline of the steps, and may include various known steps, if necessary, that is, arbitrary steps such as surface treatment, washing, cutting, molding, sterilization, and packaging.

The open-pore nonwoven fabric having the shape of the present invention is not particularly limited in its surface to be used, but when used as a surface material for sanitary materials such as disposable diapers and sanitary napkins, the surface that comes into contact with the skin is caused by the fluff generated by the raising of the nonwoven fabric. Due to the problem of rash, the raised surface is suppressed by applying the contact surface with the punching roll to the conveyor surface of the circulating hot air heat treatment machine and performing reheat treatment near the melting point of the sheath component of the heat-sealable sheath-core type composite fiber. In addition to the above, the annealing effect makes it possible to obtain a perforated nonwoven fabric having a bulky shape.

Hereinafter, the present invention will be described in more detail with reference to Examples, but the scope of the present invention is not limited thereto.

The performance of the open-pore nonwoven fabric of the present invention was evaluated by the following method.
<Measurement of non-woven fabric>
-Nonwoven fabric thickness: The thickness was measured under a load of 3.5 gf/cm ² using a thickness measuring instrument Digithic Tester manufactured by Toyo Seiki Co., Ltd. to obtain the nonwoven fabric thickness.
-Shaped portion thickness: Using a KEYENCE-made microscope VHX-6000, the thickness of the non-woven fabric layer in the cross-section of the non-woven fabric cut perpendicularly from the surface was measured and used as the shaped portion thickness.
-Aperture area: The surface of the non-woven fabric was photographed with a microscope VHX-6000 manufactured by KEYENCE, the diameter was measured at n=6 from the obtained photograph (x20), and the average value was measured for the pores of the non-woven fabric surface. It was defined as the open area.

<Method for evaluating bulkiness of non-woven fabric>
A non-woven fabric cut into a square of 100 mm×100 mm is used as a sample, the weight of the non-woven fabric is measured, and the basis weight is calculated from the value, which is defined as A (g/m ² ).
The non-woven fabric thickness of the sample for which the basis weight is measured is measured at four points using a Digithic tester, and the arithmetic mean value is B (mm).
The specific volume (nonwoven fabric density) is calculated from these values by the following formula. The higher the specific volume, the higher the bulkiness.
Specific volume=B/A (m ³ /kg)=B/A×1000 (cm ³ /g)

<Evaluation method of absorption performance>
The absorption performance was comprehensively judged from (1) evaluation of initial liquid permeability and repeated liquid permeability, and (2) evaluation of liquid return prevention property.
(1) Evaluation of initial liquid permeability and repeated liquid permeability Based on the method for measuring liquid passage time of EDANA ERT 150.3-96, measure the time for liquid to pass through the nonwoven fabric sample (liquid passage time). The liquid permeability was evaluated by. As a concrete method, 4 pieces of absorbent paper (Kim towel (trade name) manufactured by Crecia Co., Ltd.) is placed on an acrylic plate holder and folded in 4 pieces, and a 100 mm×100 mm square non-woven fabric is placed thereon. Place the sample. The solution was set in a holder, and 10 mL of physiological saline (for saline, 9 g of NaCl was completely melted in ion-exchanged water and an aqueous solution of 1000 g was used) was poured with a buret, and the passage time was measured ( First time). After the first liquid-passing measurement was completed, the sample was allowed to stand for 1 minute. Then, the sample was sandwiched between 8 sheets of absorbent paper, and a load of 35 g/cm ² was placed on it for 1 minute. The liquid time was measured (second time). Further, the sample after the second liquid passage measurement was measured for the third liquid passage time by the same procedure as the second liquid passage measurement (third time). It is shown that the shorter the interval between the initial (first) liquid passage time and the third liquid passage time, the better the liquid permeability.
(2) Evaluation of liquid return prevention property Evaluation was carried out by a method according to EDANA-ERT 151.1-96. The absorbent paper used was a towel made by Crecia Co., Ltd. (trade name) cut into a square (adjusted to be 5.00 to 5.05 g) of about 90 mm x 90 mm, and the physiology measured with a buret was used. 17 mL of saline was permeated and absorbed. The liquid return amount was evaluated according to the following criteria. The smaller the amount of liquid returned, the better the nonwoven fabric with less liquid returned.
◯: less than 4 g Δ: 4 g or more, less than 4.5 g x: 4.5 g or more

<Flexibility evaluation method>
The flexibility of the nonwoven fabric was evaluated by 10 panelists according to the following evaluation criteria.
◯: Extremely high flexibility.
Δ: High flexibility
X: Insufficient flexibility
In this evaluation method, ◯ was evaluated as having extremely high flexibility, Δ was evaluated as having high flexibility, and × was evaluated as insufficient flexibility.

<Cushion evaluation method>
The cushioning property of the nonwoven fabric was evaluated by 10 panelists according to the following evaluation criteria.
◯: Repulsion is extremely high.
Δ: Highly repulsive.
X: Repulsion is insufficient.
In this evaluation method, ○ indicates that the cushioning property is extremely high, Δ indicates that the cushioning property is high, and × indicates that the cushioning property is insufficient.

In the examples and comparative examples of the present invention, the following PE was used as polyethylene and the following PET was used as polyester.
PE: Keiyo Polyethylene M6900 (trade name)
PET: CZ5022 (trade name) manufactured by Sanbo Co., Ltd.

<Sample 1>
A web having a basis weight of 25 g/m ^{2 made} of a heat-sealable sheath-core type composite fiber having a fineness of 1.7 dtex, a sheath-core area ratio of 50/50 of PE, and a core component of PET was punched needle plate (needle diameter 1. 4 mm ² , needle length 4 mm, needle density 4 needles/cm ² ) and pierce the needle with cold air of 11.5 m/s, followed by fusion solidification with hot air of 11.3 m/s at 130° C. To obtain a non-woven fabric. Then, using a circulating hot-air dryer, it was reheated at a processing temperature of 130° C. to suppress fluff on the surface.
The obtained sample 1 was a non-woven fabric having a nonwoven fabric thickness of 2.55 mm, a shaped portion thickness of 1.40 mm, a specific volume of 102.0 cm ³ /g, and an open area of 0.54 mm ^2. It was

<Sample 2>
3. A fineness of 4. A web having a basis weight of 12.5 g/m ^{2 made} of a heat-fusible sheath-core type composite fiber having a fineness of 1.7 dtex, a sheath-core area ratio of 50/50 of PE, and a core of PET, and a core of PET. 4dtex, sheath core area ratio 50/50 sheath component PE, the core component is a heat-fusible sheath-core type composite fiber of PET is a two-layer laminated web having a web of 12.5 g/m ² as a lower layer, The nonwoven fabric was placed on a punching needle plate (the same punching plate as in Sample 1), pierced with a needle by cold air, and then fused and solidified by hot air at 130° C. to give a nonwoven fabric. Then, using a circulating hot-air dryer, it was reheated at a processing temperature of 130° C. to suppress fluff on the surface.
The obtained sample 2 had a non-woven fabric thickness of 3.17 m, a shaped part thickness of 1.45 mm, a specific volume of 126.8 cm ³ /g, and an open area having a shape of 0.54 mm ^2. It was a perforated nonwoven fabric. The appearance of Sample 2 is shown in FIG.

<Sample 3>
A non-woven fabric having a basis weight of 25 g/m ^{2 made} of a heat-sealable sheath-core type composite fiber having a fineness of 1.7 dtex, a sheath-core area ratio of 50/50 of PE, and a core component of PET, and a heat roll (with a pin roll) ( Opening was performed at a roll upper and lower temperature of 115° C.).
The obtained sample 3 was a non-woven fabric having a nonwoven fabric thickness of 0.74 mm, a shaped portion thickness of 0.35 mm, a specific volume of 29.6 cm ³ /g, and an open area of 0.95 mm ^2. It was The appearance of Sample 3 is shown in FIG.

<Sample 4>
A fineness of 4.75 dtex, a sheath component having a sheath-core area ratio of 50/50 is PE, and a core component is PET, and a nonwoven fabric having a basis weight of 12.5 g/m ^{2 made} of a heat-fusible sheath-core type composite fiber is used as an upper layer. 4 dtex, sheath/core area ratio 50/50, sheath component is PE, core component is PET, and heat-fusible sheath-core type composite fiber having a basis weight of 12.5 g/m ² is used as a lower layer, and an uneven embossing roll (roll After the upper layer was shaped at an upper and lower temperature of 80° C.), the lower layer and the lower layer were point-bonded by an ultrasonic bonding machine in order to fix the shape of the upper layer.
The obtained sample 4 was a non-woven shaped non-woven fabric having a non-woven fabric thickness of 1.23 mm, a shaped portion thickness of 0.53 mm, and a specific volume of 49.2 cm ³ /g.

(Evaluation of prepared sample)
Samples 1 to 4 were evaluated for bulkiness, flexibility, cushioning property, and absorbability. Table 1 shows the evaluation results collectively.

[Example 1]
Sample 1 has a high liquid permeability due to the effect of the pores and the bulkiness of the nonwoven fabric in the evaluation method of the absorption performance, and has a high effect of the initial (first) liquid permeability and the repeated liquid permeability, and the liquid return prevention property. In Example 1, since the volume was high, the amount of liquid returned was small and good.
In addition, Sample 1 was a good evaluation result with 8 panelists evaluated to be flexible in the flexibility evaluation method and 8 panelists evaluated to be repulsive in the cushioning property evaluation method.
Further, since there was no heat-compressed portion on the surface of the nonwoven fabric, the nonwoven fabric had a high specific volume (102.0 cm ³ /g) and was bulky.

[Example 2]
In the evaluation method of the absorption performance, Sample 2 has a high liquid permeability due to the effect of the pores, a high initial liquid permeability (first time) and a high repetitive liquid permeability, and a liquid return prevention property. Since the convex portion of the shape was bulky, the amount of liquid returned was small and good.
Further, in Sample 2, the panelists evaluated to be flexible in the flexibility evaluation method, and the panelists evaluated to be repulsive in the cushioning property evaluation method were 9 persons, which was a good evaluation result.
Further, since there was no heat-compressed portion on the surface of the nonwoven fabric, the nonwoven fabric was bulky and had a high specific volume (126.8 cm ³ /g).

[Comparative Example 1]
In the evaluation method of the absorption performance, Sample 3 had the effect of initial liquid permeability and repeated liquid permeability due to the effect of the opening, but the liquid return amount was relatively large and was poor. It was considered that the large amount of liquid returned was due to insufficient bulkiness.
Further, in the sample 3, the number of panelists who felt that they were flexible in the flexibility evaluation method was 6 and the number of panelists who evaluated that they were repulsive in the cushion property evaluation method was 0.
The open-hole nonwoven fabric of Sample 3 was a non-woven fabric having a low specific volume (29.6 cm ³ /g) and a low bulk since the whole nonwoven fabric was compacted.

[Comparative example 2]
Sample 4 had a very low initial liquid permeability, particularly, repeated liquid permeability in the evaluation method of absorption performance.
Further, in the sample 4, the number of panelists who felt that it was flexible in the flexibility evaluation method was 5 and the number of panelists who felt that it was repulsive in the cushioning property evaluation method was 7.
Sample 4 is a two-layer non-woven fabric in which a non-woven fabric having an upper surface shaped by uneven embossing is fixed by the lower layer. Sample 4 was a bulky non-woven fabric having a high specific volume (49.2 cm ³ /g), and although it had shape-maintainability due to the effect of the lower layer, it was easy to be crushed because the convex portion was hollow.

The open-pore nonwoven fabric of the present invention is bulky and has excellent flexibility, and since it has small-diameter pores penetrating the nonwoven fabric, it is excellent in absorption performance and liquid return prevention. Further, among the open-pore nonwoven fabrics of the present invention, those having a convex shape which independently protrudes on the surface of the nonwoven fabric have a small contact area with the skin and are particularly excellent in contact with the skin. From these things, the shaped nonwoven fabric obtained by the present invention can be used conveniently for surface materials for hygiene materials, such as a disposable diaper and a sanitary napkin.
Further, according to the production method of the present invention, the pores are formed by a needle sheet or a needle roll in the state of the web, and a part of the web is melted and fixed by heating in that state, thereby making it bulky and fine. This is to obtain a perforated non-woven fabric in which pores are formed, and a non-woven fabric having the above-mentioned constitution and effect can be manufactured without requiring special steps or conditions. It is suitable for manufacturing non-woven fabrics for sanitary materials and other non-woven fabrics having both bulkiness and absorbency.

1 Open-hole nonwoven fabric 2 Open-hole 3 Top part 4 Base part

Claims (7)

A non-woven fabric containing heat-fusible composite fibers, having perforations from the front surface to the back surface of the non-woven fabric, having an opening area of the front surface of 0.2 to ²⁰ mm ² , and a specific volume of 40 to 200 cm ^3. /G, open-pore nonwoven fabric. The perforated nonwoven fabric according to claim 1, further having a shaping on the surface of the perforated nonwoven fabric. The open-pore nonwoven fabric according to claim 2, wherein a large number of the shapes are arranged on the surface of the open-pore nonwoven fabric, and each of the shapes is a convex shape that independently protrudes. The open-pore nonwoven fabric according to claim 2 or 3, wherein in the open-pore nonwoven fabric, the pores are present in a base portion located between a convex shape and an adjacent convex shape. The open-hole nonwoven fabric according to claim 3 or 4, wherein in the open-hole nonwoven fabric, the ratio of the thickness of the convex shaped top portion to the thickness of the base portion is 10:1 to 1:10. In the said open-pore nonwoven fabric, the thickness of the top part of the said convex-shaped shaping|molding is 0.3-4.0 mm, and the thickness of the said base part is 0.3-3.0 mm, either of Claim 3-5. 2. The open-pore nonwoven fabric according to item 1. Making a web of thermoplastic fibers,
The web is placed on a breathable needle plate or a roll of breathable needles in which a large number of needles are erected on the surface of a punching or mesh perforated member, and the needles penetrate the web by an air flow. And the process of
Heating the web penetrated by the needle with heated air to melt at least a part of the thermoplastic fibers constituting the web to form a nonwoven fabric,
A method for producing an open-pore nonwoven fabric, comprising: