JP6456688B2 - Entangled nonwoven fabric, wiping sheet and wettable sheet using the same - Google Patents

Description

  The present invention relates to an entangled nonwoven fabric in which a low compression region and a high compression region are arranged in a specific pattern in a water entanglement process. More specifically, the present invention is an entangled nonwoven fabric excellent in design and nonwoven fabric strength balance and functionality having a certain repetitive pattern, and is used for interpersonal purposes such as sanitary materials, packaging materials, kitchen paper, etc. Dry or wet wiping sheets used for sebum, cosmetics, other soiled skin, or the surface of objects, wettable sheets that can impart functional agents such as moisturizing or antiperspirant ingredients to the skin It is related with the entangled nonwoven fabric suitable for the above.

  Conventionally, as a surface sheet of a sanitary material, a nonwoven fabric in which a fiber web is placed on an opening portion forming support and an opening portion is formed by a hydroentanglement process is used. In addition, non-woven fabrics having various functionalities used for wet tissues or disposable towels are used. Such non-woven fabrics include non-woven fabrics that have been subjected to high-pressure water flow treatment on fiber webs made of hydrophilic fibers such as rayon or a mixture of hydrophilic fibers and heat-adhesive conjugate fibers, or various types of non-woven fabrics that have been functionally improved. Non-woven fabrics have been proposed. For example, Patent Document 1 (Patent No. 3559533) discloses a nonwoven fabric in which a fiber material is hydroentangled on a support of a herb weave or a spiral weave, and the high compression region on the nonwoven fabric surface is the machine direction of the nonwoven fabric (hereinafter referred to as the nonwoven fabric). The pattern (A) row extending in the MD direction existing at an angle of 5 to 60 ° with respect to the MD direction) and the pattern (B) row extending in the MD direction obtained by inverting the pattern (A) row are MD An entangled nonwoven fabric excellent in design properties, nonwoven fabric strength balance, and functionality having a certain repeating pattern has been proposed by being alternately and repeatedly present in a direction perpendicular to the direction (hereinafter referred to as CD direction).

However, the following problems are mentioned in the said nonwoven fabric.
That is, for example, when a fiber web is usually placed on a herringbone net and subjected to a hydroentanglement process, a portion where the columnar flow injected from the nozzle penetrates the fiber web becomes a high compression region, and a low compression region. High compression regions are alternately formed in a straight line in parallel. Furthermore, in the case of the cedar weave as described above, a pattern in which the low compression area intersects at an acute angle is formed, and when this sharp angle part is used for an application that directly touches soft skin such as a personal wipe sheet, the feeling of use is improved. There is a problem that it is bad, and there is also a problem that it gives an image that a sharp angle part sticks in appearance.

  In general, the whole nonwoven fabric has a strength directionality in which the strength in the CD direction is lower than the strength in the MD direction. Even in the cedar weave, the strength in the CD direction is governed by the tensile strength in the lateral direction of the high compression region, so that sufficient strength is not obtained as compared with the MD direction. There also exists a problem that the use of a nonwoven fabric may be restrict | limited by such directionality of intensity | strength.

Japanese Patent No. 3559533

An object of this invention is to provide the novel entangled nonwoven fabric which has a specific repeating pattern pattern.
In particular, an object of the present invention is to provide an entangled nonwoven fabric, a wiping sheet, and a wettable sheet having a low strength directionality.

  Furthermore, the present invention is a non-woven fabric having a predetermined repeating pattern, which has a good balance of strength in the MD direction and CD direction, is thick and has a soft touch, and can be wiped evenly even if the number of wiping is small. An object of the present invention is to provide an entangled nonwoven fabric having wiping properties.

  Furthermore, the present invention provides a wiping sheet having the above-described excellent characteristics, and even when this entangled nonwoven fabric is impregnated with a wiping liquid, there is little stickiness, thickness, and excellent softness. It is an object to provide a wettable sheet.

The entangled nonwoven fabric of the present invention is an entangled nonwoven fabric formed by hydroentangling a fiber material on a support,
The entangled nonwoven fabric is composed of a substantially triangular low-compression region and a high-compression region formed between the substantially triangular low-compression regions,
Each side of the substantially triangular low compression region is arcuate,
It is arranged so that the base of the six low compression regions of the substantially triangular shape touches uniformly in the inscribed virtual circle,
The virtual circle C located at the center is formed overlapping with the virtual circle I to the virtual circle VI formed around the periphery,
The virtual circle I includes two adjacent low compression regions included in the virtual circle C, one low compression region included in the adjacent virtual circle II, and one low compression region included in the virtual circle VI. The virtual circle II to the virtual circle VI are formed so as to have two low-compression regions that are not included,
The virtual circle II includes two adjacent low compression regions included in the virtual circle C, one low compression region included in the adjacent virtual circle I, and one low compression region included in the virtual circle III. The virtual circle I, the virtual circle III to the virtual circle VI are formed so as to have two low-compression regions that are not included,
The virtual circle III includes two adjacent low compression regions included in the virtual circle C, one low compression region included in the adjacent virtual circle II, and one low compression region included in the virtual circle IV. The virtual circle I, the virtual circle II, the virtual circle IV, the virtual circle V, and the virtual circle VI are formed to have two low-compression regions that are not included,
The virtual circle IV includes two adjacent low compression regions included in the virtual circle C, one low compression region included in the adjacent virtual circle III, and one low compression region included in the virtual circle V. The virtual circle I, the virtual circle II, the virtual circle III, the virtual circle V, and the virtual circle VI are formed to have two low-compression regions that are not included,
The virtual circle V includes two adjacent low compression regions included in the virtual circle C, one low compression region included in the adjacent virtual circle IV, and one low compression region included in the virtual circle VI. The virtual circle I, the virtual circle II, the virtual circle III, the virtual circle IV, and the virtual circle VI are formed to have two low-compression regions that are not included,
The virtual circle VI includes two adjacent low compression regions included in the virtual circle C, one low compression region included in the adjacent virtual circle V, and one low compression region included in the virtual circle I. The virtual circle I, the virtual circle II, the virtual circle III, the virtual circle IV, and the virtual circle V are formed to have two low-compression regions that are not included,
Even when the virtual circle C moves to an adjacent virtual circle, the relationship between the moved new virtual circle C and the new virtual circles I to VI is maintained.
Moreover, the wiping sheet and wettable sheet of the present invention are characterized by comprising the above-described entangled nonwoven fabric.

  According to the present invention, a novel entangled nonwoven fabric can be provided. The entangled nonwoven fabric of the present invention has a predetermined pattern in which imaginary circles (hereinafter sometimes referred to as “six petal flowers”) having six low compression regions in a substantially triangular shape are overlapped. Since the low compression region is formed by tilting by 60 ° in the virtual circle, the high compression region having high strength is uniformly distributed in the MD direction and the CD direction, and the high compression region is arranged in this way. The entangled nonwoven fabric does not cause a significant difference between the strength in the MD direction and the strength in the CD direction.

In addition, the formation angle of the low compression region is obtuse than that of the cedar weave.
Furthermore, the entangled nonwoven fabric of the present invention can be used as a dry or wet wiping sheet because it has a large area of a low compression region that is highly useful during wiping.

  Furthermore, since the entangled nonwoven fabric of the present invention is excellent in the ability to hold functional agents such as a moisturizing component and an antiperspirant component, it can be used effectively as a wettable sheet containing such a functional agent.

  The entangled nonwoven fabric of the present invention has a constant repeating pattern by combining substantially two triangular low-compression areas based on a specific law and repeating substantially rhombic low-compression areas at regular intervals. Excellent design and strength balance of nonwoven fabric and functionality. Furthermore, when there are alternating substantially rhombic low compression regions formed by combining two triangles on the nonwoven fabric surface by alternately presenting approximately rhombus low compression regions formed by combining two triangles, Six adjacent triangles form a six-valve pattern, the circumference is imaged at any part of the nonwoven fabric, and it has a design that has various appearances while being a constant repeating pattern. In addition, a relatively orderly concavo-convex pattern is formed, which is excellent in aesthetics and various functions.

  For example, in the case of a sanitary material, when used as a top sheet, the contact area with the skin is small, there is a dry feeling, the thickness of the base fabric is high, and the soft feeling is excellent. If it is used for a hygiene material backsheet, etc., it has design properties and excellent dimensional stability.

  The entangled nonwoven fabric of the present invention is also suitable as a wiping sheet, and the substantially triangular edge formed by the low-compression region and the high-compression region efficiently collects dirt without unevenness and holds it in the high-compression region. be able to. Further, in a normal wiping operation, the wiping direction can be sufficiently wiped even if the number of wiping operations is small, without worrying about the wiping direction.

Drawing 1 is a mimetic diagram showing typically an example of a pattern formed in a entangled nonwoven fabric of the present invention by a low compression field and a high compression field. FIG. 2 is an enlarged schematic view showing a pattern of six-petal flowers formed on the entangled nonwoven fabric of the present invention. FIG. 3 shows the result of the wiping test for pseudo dirt. FIG. 4 shows the results of a pseudo-stain wiping test. FIG. 5 shows the result of the wiping test for pseudo dirt.

Next, the entangled nonwoven fabric of the present invention will be specifically described with reference to the drawings.
As shown in FIGS. 1 and 2, the entangled nonwoven fabric of the present invention is an entangled nonwoven fabric formed by hydroentangling a fiber material on a support.

The entangled nonwoven fabric of the present invention is formed from a large number of substantially triangular low-compression regions 10 and a high-compression region 12 formed between the substantially triangular low-compression regions 10.
In the entangled nonwoven fabric 1 of the present invention, the bases of six substantially triangular low-compression regions having the same shape are arranged so as to uniformly contact the inscribed virtual circle C, and each of the six low-compression regions is 60 The bottom of the low compression region is formed in contact with the virtual circle C with an angle of °.

The virtual circle C located at the center is formed to overlap with the centers of the virtual circles I to VI formed around it at an angle of 60 °.
Therefore, the substantially triangular low-compression region formed in the virtual circle C corresponds to the virtual circle C and the overlapping portion of the virtual circle I to the virtual circle VI formed at an angle of 60 ° around the virtual circle C. It has a form.

For example, the substantially triangular low-compression region C1 formed in the virtual circle C is a substantially triangular portion corresponding to a portion where the virtual circle C overlaps with the virtual circle I and the virtual circle VI.
For example, the substantially triangular low-compression region C2 formed in the virtual circle C is a substantially triangular portion corresponding to a portion where the virtual circle C, the virtual circle I, and the virtual circle II overlap.

Similarly, the substantially triangular low-compression region C3 formed in the virtual circle C is a substantially triangular portion corresponding to a portion where the virtual circle C overlaps with the virtual circle II and the virtual circle III.
Similarly, the substantially triangular low-compression region C4 formed in the virtual circle C is a substantially triangular portion corresponding to a portion where the virtual circle C overlaps with the virtual circle III and the virtual circle IV.

Further, the substantially triangular high fiber density C5 formed in the virtual circle C is a substantially triangular portion corresponding to a portion where the virtual circle C overlaps with the virtual circle IV and the virtual circle V.
The substantially triangular low-compression region C6 formed in the virtual circle C is a substantially triangular portion corresponding to a portion where the virtual circle C overlaps with the virtual circle V and the virtual circle VI.

  In the entangled nonwoven fabric of the present invention, in the virtual circle I, the substantially triangular low-compression region is formed in a portion where the virtual circle C and the virtual circle and the virtual circle adjacent to the virtual circle C overlap with each other. Each side of the region has a form formed by an arc of a virtual circle C and an arc of two adjacent virtual circles overlapping therewith.

  The virtual circle I includes two adjacent low-compression regions included in the virtual circle C and one low-compression region included in the virtual circle II adjacent to the virtual circle I and a virtual circle adjacent to the virtual circle I. It is formed so as to have one low compression region included in VI and two low compression regions not included in the virtual circle II to virtual circle VI.

  The virtual circle II is composed of two adjacent low compression regions included in the virtual circle C and one low compression region included in the adjacent virtual circle I and one low compression region included in the adjacent virtual circle III. It is formed so as to have a compression region and two low compression regions not included in the virtual circle I and the virtual circle III to the virtual circle VI.

  Furthermore, the virtual circle III is composed of two adjacent low compression regions included in the virtual circle C and one low compression region included in the adjacent virtual circle II and one low compression included in the adjacent virtual circle IV. The region is formed so as to have a virtual circle I, a virtual circle II, a virtual circle IV, a virtual circle V, and two low-compression regions that are not included in the virtual circle VI.

  In addition, the virtual circle IV is composed of two adjacent low compression regions included in the virtual circle C and one low compression region included in the adjacent virtual circle III and one low compression included in the adjacent virtual circle V. The region is formed so as to have two low-compression regions that are not included in the virtual circle I, virtual circle II, virtual circle III, virtual circle V, and virtual circle VI.

  Furthermore, the virtual circle V is composed of two adjacent low compression regions included in the virtual circle C and one low compression region included in the adjacent virtual circle IV and one low compression region included in the adjacent virtual circle VI. It is formed to have a compression region and two low compression regions that are not included in the virtual circle I, virtual circle II, virtual circle III, virtual circle IV, and virtual circle VI.

  In addition, the virtual circle VI is composed of two adjacent low compression regions included in the virtual circle C and one low compression region included in the adjacent virtual circle V and one low compression region included in the adjacent virtual circle I. It is formed to have a compression region and two low compression regions that are not included in the virtual circle I, virtual circle II, virtual circle III, virtual circle IV, and virtual circle V.

  That is, in the present invention, the two low compression regions C1 to C6 formed in the virtual circle C assumed at the center are included in the virtual circles I to VI assumed in the periphery. Such low compression regions C1 to C6 have the same shape.

  The high compression region 12 forms the gap of the low compression region 10 forming the six-valve flower pattern as described above. Usually, the minimum width S of the high compression region sandwiched between the low compression regions 10 is 0. It is 2 to 10.0 mm, preferably 1.0 to 5.0 mm. Moreover, it is preferable that the opening part is not formed in the high compression area | region in the entangled nonwoven fabric of this invention.

In addition to the virtual circle assumed at the center as described above, the six virtual circles are arranged at an angle of 60 ° with the virtual circle C assumed at the center as the center.
And in the entangled nonwoven fabric of the present invention, even when the virtual circle C moves to an adjacent virtual circle, the relationship between the moved new virtual circle C and the new virtual circles I to VI is maintained as a whole. As a six-piece flower is arranged as a uniform.

  Moreover, the diameter D1 of the virtual circle which comprises the entangled nonwoven fabric of this invention is 10-30 mm normally, Preferably it is 16-19 mm. Of the six substantially triangular low-compression regions forming the six-valve flower, the width D2 occupied by the four substantially triangular low-compression regions is usually 10 to 15 mm, preferably 11 to 13 mm.

Furthermore basis weight of the entangled nonwoven fabric of the present invention is 35 g / m ² or more, preferably 40 to 50 g / m ^2. If the basis weight is less than 35 g / m ² , the nonwoven fabric itself is too thin and inferior in strength, so that not only the handleability is bad, but the constituent fiber amount itself is small, so that a desired pattern is hardly formed.

  That is, the wiping sheet comprising the entangled nonwoven fabric of the present invention is formed using the above-described entangled nonwoven fabric, has a thick and soft touch, and can be wiped evenly even if the number of times of wiping is small. It has the property of being excellent in wiping properties.

  In addition, the wettable sheet made of the entangled nonwoven fabric of the present invention is characterized by having the above-described configuration, which is excellent in liquid impregnation properties, has little stickiness, has a thickness, and has excellent softness. Have

  The fiber forming the entangled nonwoven fabric of the present invention is not particularly limited as long as the fiber material has a fiber form, for example, natural fibers such as pulp, cotton, silk, wool, rayon, cupra, tencel, etc. Recycled fibers, polyester fibers such as polyethylene terephthalate and polybutylene terephthalate, polyamide fibers such as nylon 6 and nylon 66, acrylic fibers, polyolefin fibers made of polyethylene, polypropylene, etc., or a combination of two or more of these resins One type or two or more types of fibers such as a composite fiber having a sheath-core type, an eccentric sheath-core type, a parallel type, a split type, and a sea-island type cross section can be used. The form of the cross section of the fiber is not particularly limited, and may be any shape such as circular, irregular, hollow.

  The entangled nonwoven fabric containing 30 mass% or more of hydrophilic fibers such as pulp, cotton, rayon, etc. as the fiber material is excellent in water absorption, for example, when used as a dry cleaning sheet, Of these, liquid components as well as solid components can be wiped off. Moreover, since it is excellent in the wettability, when using as a wettable wipe sheet or a wettable sheet, it is preferable. More preferably, it is 40-80 mass% of hydrophilic fiber. If it is within the above range, other fibers may be contained, and generally known, for example, in order to obtain bulkiness, a polyester fiber may be contained, and a wiping sheet or a wet sheet. Hydrophobic synthetic fibers should be included if the stickiness and excessive liquid remaining after use are suppressed, and thermal adhesive fibers should be included if high strength is obtained. The content of other fibers is preferably 60 to 20 mass%. Of the hydrophilic fibers, rayon fibers are preferably used from the viewpoints of handleability and versatility. The fineness of the hydrophilic fiber is preferably 0.9 to 3.5 dtex. More preferably, it is 1.5 to 2.5 dtex. When the fineness is less than 0.9 dtex, the card passing property is poor, and when it exceeds 3.5 dtex, the flexibility of the nonwoven fabric tends to be impaired.

  The fiber web form of the fiber material is not particularly limited, for example, a parallel web made of staple fibers, a cross web, a semi-random web, a random web, an air lay web made of short fibers, a wet papermaking web, and a span made of long fibers. A bond web, a melt blow web, or the like can be arbitrarily used. Moreover, the laminated web which laminated | stacked two or more layers of the said fiber web may be sufficient. Especially, in order to obtain the entanglement property by a water flow mentioned later and a clear constant repeating pattern, it is preferable to use the fiber web which consists of staple fibers with a fiber length of 25 to 100 mm. This is because when the fiber length is less than 25 mm, not only the intertwining property is inferior but also in terms of strength, and when the fiber length exceeds 100 mm, not only the tactile sensation is hardened but also the intertwining property is poor.

  In the present invention, it may be a fiber web single layer made of staple fibers or a laminated web laminated by changing the constitution of the staple fibers, a fiber web made of staple fibers / wet paper making web, a fiber web made of staple fibers / A spunbond web, a fiber web / meltblown web made of staple fibers, or a combination of different fiber webs such as a wet papermaking web, a spunbond web, a meltblown web sandwiched between fiber fibers made of staple fibers is preferable. . As a specific configuration of the laminated web, at least one type of fiber web selected from a parallel web made of staple fibers, a cross web, a semi-random web, and a random web is laminated on both surfaces of a tissue layer made of pulp fibers. Is mentioned.

  And the said fiber material makes a nonwoven fabric form by intertwining structural fibers. The term “entanglement” as used herein refers to a state in which fibers are intertwined, such as intertwining by a normal fiber web, or intertwining obtained by a three-dimensional intertwining process such as needle punching or hydroentanglement. Among these, those intertwined three-dimensionally are preferable because they have excellent functionality when used as a non-woven fabric touch, flexibility, wiping sheet or wettable sheet.

Next, an example of the manufacturing method of the entangled nonwoven fabric of this invention is demonstrated. In producing the entangled nonwoven fabric of the present invention, according to a known technique, first, a fiber web made of the above fiber material is prepared. Then, the fiber web can be placed on a metal support, and the constituent fibers can be entangled three-dimensionally and rearranged by a hydroentanglement device to form a desired pattern.
What is necessary is just to set the conditions of a water-entanglement process according to the fabric weight, the softness | flexibility, functionality, etc. of the nonwoven fabric which is going to be finally obtained.

  The entangled non-woven fabric obtained in this way can be used for sanitary materials, packaging materials, kitchen papers, and other humans / objects. It can be used for a wet wiping sheet, a wettable sheet capable of imparting a functional agent such as a moisturizing component or an antiperspirant component to the skin. When the entangled nonwoven fabric of the present invention is used as a wet wiping sheet or wettable sheet, depending on the purpose, wetting agents such as water, ethylene glycol, propylene glycol, alcohols, antibacterial agents, fungicides, fragrances and the like, etc. The desired liquid may be applied by a known method. The liquid retention rate may be set as appropriate depending on the purpose, but it may be usually 100 to 300 mass% with respect to the mass of the nonwoven fabric.

Hereinafter, the contents of the present invention will be described with reference to examples. In addition, the thickness of the obtained nonwoven fabric, tensile strength, and elongation rate were measured with the following method.
[Thickness]
According to EDANA 30.5-99, measurement was performed with a load of 20 g per 1 cm ² of the sample.
[Tensile strength, elongation]
In accordance with EDANA 20.2-89, a sample piece having a width of 5 cm and a length of 15 cm is gripped at a spacing of 10 cm and stretched at a tensile speed of 30 cm / min using a constant-speed stretch type tensile tester. Were defined as tensile strength and elongation, respectively.

[Example 1]
As Example 1, a hydrophilic fiber was mixed with 50 mass% of rayon fiber having a fineness of 1.7 dtex and a fiber length of 40 mm, and a hydrophobic synthetic fiber was mixed with 50 mass% of polyester fiber having a fineness of 1.7 dtex and a fiber length of 38 mm to obtain a fiber. Material was used. A non-woven fabric having a six-valve flower pattern as shown in FIG. 1 was produced using the fiber material. The basis weight of this nonwoven fabric is 40 g / m ² .

[Comparative Example 1]
As a comparative example, a hydrophilic fiber is mixed with 50 mass% of rayon fiber having a fineness of 1.7 dtex and a fiber length of 40 mm, and a hydrophobic synthetic fiber is mixed with 50 mass% of polyester fiber having a fineness of 1.7 dtex and a fiber length of 38 mm to obtain a fiber material. It was. The basis weight of this nonwoven fabric is 40 g / m ² and is unpatterned.

In the nonwoven fabric of the same composition and the same basis weight, the aspect ratio of the strength is smaller in Example 1 and the strength balance is achieved.
The physical properties described above are shown in Table 1.

It can be seen from Table 1 that even with the same composition, the thickness increases as a whole when the six-valve flower pattern is applied. Thereby, there is no sense of see-through, and the wiping operation can be performed with confidence without worrying about penetration into the hand during wiping.
Further, when attention is focused on strength and elongation, it can be seen that the embodiment has a balanced strength because the difference between the MD direction and the CD direction is smaller than that of the comparative example.

[Comparative Example 2]
Further, as Comparative Example 2, 35 mass% of rayon fiber, which is a hydrophilic fiber, 40 mass% of polyester fiber, which is a hydrophobic synthetic fiber, 25% of polyethylene / polyester divided fiber, and a herringbone-processed weight of 35 g / The non-woven fabric of m ² was used as the fiber material.
And the nonwoven fabric of Example 1 and Comparative Example 2 was used as a wiping sheet, and the following items were evaluated.

[Wipeability]
As a pseudo-stain, 0.1 g of ink was spread evenly over an area of 3 cm × 3 cm on the PP sheet and then dried with a dryer at 40 ° C. for a predetermined time. A sheet sample wound around a melamine sponge (wiping area length 10 cm × width 10 cm) was uniformly wiped while applying a weight of 200 gf. The number of times of wiping until the pseudo-stain was eliminated was compared. The results are shown in FIG. 4 and FIG.

In FIG. 4, the left side is a wiping test result using a hexalobal-patterned nonwoven fabric, and the right is a wiping test result using a herringbone-patterned nonwoven fabric.
Moreover, in FIG. 5, three examples from the top are the results of the wiping test using the six-petal flower-patterned nonwoven fabric of the present invention, and the lower three examples are the results of the wiping test using the herringbone-patterned nonwoven fabric.
Moreover, the wettability sheet | seat which impregnated the nonwoven fabric of Example 1 and the comparative example 1 with 240 mass% of chemical | medical solutions with respect to the nonwoven fabric mass was evaluated by the following item.

[Wiping test 1]
0.1 g of pseudo soil (inkbrush) was spread evenly in the range of a PP sheet (3 cm × 3 cm) and dried for 5 minutes with a dryer at 40 ° C.

This pseudo soil was wiped off with a sample sheet (WET product) wound around a 10 cm × 10 cm melamine sponge at a constant weight (200 g load), and the soil remaining on the PP sheet was compared.
The results are shown in FIG.
As is clear from FIG. 3, it can be seen that the non-woven fabric having a six-valve flower pattern of the present invention can wipe off pseudo-stains better than the non-woven fabric having a herringbone pattern.

[Wiping test 2]
0.1 g of pseudo soil (inkbrush) was spread evenly in the range of a PP sheet (3 cm × 3 cm) and dried for 1 hour in a dryer at 40 ° C.

This pseudo soil was wiped off with a sample sheet (WET product) wound around a 10 cm × 10 cm melamine sponge at a constant weight (200 g load), and the soil remaining on the PP sheet was compared.
In the wiping test samples arranged side by side, the left side uses a non-woven fabric with a hexalobal pattern, and the right side uses a non-woven fabric with a herringbone pattern.
The results are shown in FIG.
As is apparent from FIG. 4, it can be seen that the wiping property using the non-woven fabric of the left six-valve pattern is superior to the wiping property of the non-woven fabric of the right herringbone pattern.

[Repeated wipe test]
0.05 g of pseudo soil (inkbrush) was spread evenly in the range of a PP sheet (3 cm × 3 cm) and dried in a dryer at 40 ° C. for about 30 minutes.

This pseudo-stain was wiped several times with a constant weight (200 g load) with a sample sheet (WET product) wrapped around a 10 cm × 10 cm melamine sponge.
The stains remaining on the PP sheet were compared, and the number of times of wiping when the stain was completely removed was counted.
The results are shown in FIG.

  As is clear from FIG. 5, the hexalobal pattern nonwoven fabric of the present invention was able to wipe off pseudo stains by wiping 6 times, but the herringbone pattern non-woven fabric produced in Comparative Example 1 similarly had pseudo stains. Ten wiping operations were necessary before wiping.

[Tactile feel, softness]
The wettable sheet was grasped by hand, and the touch feeling at that time was evaluated by 108 monitors.
The non-woven fabric with a hexalobal pattern of the present invention feels softer than the non-woven fabric with a herringbone pattern, and the non-woven fabric with a six-petal pattern has a 1% risk than the non-woven fabric with a herringbone pattern. Is also excellent.

[Tactile feeling, good touch]
The wettable sheet was grasped by hand, and the touch feeling at that time was evaluated by 108 monitors.
It is an evaluation that the non-woven fabric with a hexalobal pattern of the present invention is better than the non-woven fabric with a herringbone pattern, and the non-woven fabric with a six-valve pattern has a herringbone pattern at a risk level of 1%. Better than non-woven fabrics.

[Tactile feeling, soft feeling]
The wettable sheet was grasped by hand, and the touch feeling at that time was evaluated by 108 monitors.
It is evaluated that the non-woven fabric with a hexalobal pattern according to the present invention has a softer feeling than the non-woven fabric with a herringbone pattern. Superior to patterned nonwovens.

[Stickness]
The wettable sheet was cut into 30 cm in the MD direction and 30 cm in the CD direction, the sheet was folded in four, and the amount of liquid remaining on the skin when the skin was wiped once was observed.

  Regarding the appropriateness of moisture, no difference was found between the non-woven fabric of the six-petal flower pattern of the present invention and the non-woven cloth of the herringbone pattern. It is evaluated that it is easier to remove dirt than a patterned nonwoven fabric. With regard to the ease of removing dirt, the non-woven fabric with a six-valve flower pattern is superior to the nonwoven fabric with a herringbone pattern at a risk of 1%.

  The entangled nonwoven fabric of the present invention is also suitable as a wettable sheet, and the substantially triangular shape formed by the low compression region and the high compression region is efficiently uniform and an appropriate amount of liquid is applied to an object such as skin. It is possible to obtain a wettable sheet having dimensional stability, excellent liquid impregnation, less stickiness, touch and thickness, and excellent soft touch.

  The entangled nonwoven fabric of the present invention is excellent in wiping properties when used as a wiping sheet, and also has a thickness when used as a wettable sheet, is flexible despite having a soft feeling, and forms a low compression region. Due to the approximately rhombus, the skin contact area was small, and there was no stickiness and was good. On the other hand, the non-woven fabric of cedar weave was inferior in wiping property. Moreover, the non-woven fabric of cedar weave had a hard texture, a large contact area with the skin, and a sticky feeling.

Claims (5)

An entangled nonwoven fabric formed by hydroentangling a fiber material on a support,
The entangled nonwoven fabric is composed of a substantially triangular low-compression region and a high-compression region formed between the substantially triangular low-compression regions,
Each side of the substantially triangular low compression region is arcuate,
It is arranged so that the base of the six low compression regions of the substantially triangular shape touches uniformly in the inscribed virtual circle,
The virtual circle C located at the center is formed overlapping with the virtual circle I to the virtual circle VI formed around the periphery,
The virtual circle I includes two adjacent low compression regions included in the virtual circle C, one low compression region included in the adjacent virtual circle II, and one low compression region included in the virtual circle VI. The virtual circle II to the virtual circle VI are formed so as to have two low-compression regions that are not included,
The virtual circle II includes two adjacent low compression regions included in the virtual circle C, one low compression region included in the adjacent virtual circle I, and one low compression region included in the virtual circle III. The virtual circle I, the virtual circle III to the virtual circle VI are formed so as to have two low-compression regions that are not included,
The virtual circle III includes two adjacent low compression regions included in the virtual circle C, one low compression region included in the adjacent virtual circle II, and one low compression region included in the virtual circle IV. The virtual circle I, the virtual circle II, the virtual circle IV, the virtual circle V, and the virtual circle VI are formed to have two low-compression regions that are not included,
The virtual circle IV includes two adjacent low compression regions included in the virtual circle C, one low compression region included in the adjacent virtual circle III, and one low compression region included in the virtual circle V. The virtual circle I, the virtual circle II, the virtual circle III, the virtual circle V, and the virtual circle VI are formed to have two low-compression regions that are not included,
The virtual circle V includes two adjacent low compression regions included in the virtual circle C, one low compression region included in the adjacent virtual circle IV, and one low compression region included in the virtual circle VI. The virtual circle I, the virtual circle II, the virtual circle III, the virtual circle IV, and the virtual circle VI are formed to have two low-compression regions that are not included,
The virtual circle VI includes two adjacent low compression regions included in the virtual circle C, one low compression region included in the adjacent virtual circle V, and one low compression region included in the virtual circle I. The virtual circle I, the virtual circle II, the virtual circle III, the virtual circle IV, and the virtual circle V are formed to have two low-compression regions that are not included,
The entangled nonwoven fabric, wherein the relationship between the moved new virtual circle C and the new virtual circles I to VI is maintained even when the virtual circle C moves to an adjacent virtual circle.   6. The entangled nonwoven fabric according to claim 1, wherein six low-compression regions are uniformly arranged in the virtual circle C with an angle of 60 °. Basis weight of the entangled nonwoven fabric, entangled nonwoven fabric according to claim 1, characterized in that in the range of 35~60g / m ^2.   The wiping sheet using the entangled nonwoven fabric shown in any one of Claims 1-3.   The wettable sheet | seat using the entangled nonwoven fabric shown in any one of Claims 1-3.