JP7055009B2 - Wiping sheet and cleaning tools - Google Patents

Description

The present invention relates to a wiping sheet and a cleaning tool using the same.

In recent years, ultrafine fibers having a fiber diameter of about 1 μm have been used for various purposes in the form of a non-woven fabric in which the fibers are entangled. For example, Patent Document 1 discloses a cleaning tool including ultrafine fibers having a fiber diameter of 1 to 9 μm in at least a part of the fibers and a non-woven fabric in which the ultrafine fibers are exposed on both the front and back surfaces.

Further, Patent Document 2 describes a surface layer containing 30 to 100% by mass of hydrophobic fibers of 1.0 decitex or less, hydrophilic fibers sandwiched between the surface layers, and hydrophobic fibers of 1.0 to 10 decitex. A non-woven wiper with an intermediate layer comprising the above is disclosed. Further, it is described in the same document that the surface layer and the intermediate layer have a three-layer structure integrated by confounding or the like.

Japanese Unexamined Patent Publication No. 10-225407 Japanese Unexamined Patent Publication No. 2010-17418

According to the non-woven fabrics of Patent Documents 1 and 2, the presence of small-diameter fibers on the surface can improve the collection property of dirt containing fine particles, but on the other hand, the non-woven fabric and the surface to be wiped The frictional resistance of the non-woven fabric becomes large, and there is a possibility that the operability at the time of cleaning is inferior.

Therefore, an object of the present invention is to provide a wiping sheet that solves the shortcomings of the prior art.

The present invention comprises at least a first fiber and a second fiber having a diameter smaller than that of the first fiber, and comprises a fiber aggregate formed by entwining these fibers, and the first surface and the first surface thereof. A wiping sheet having a second surface located on the opposite side.
The abundance ratio of the first fiber increases from each of the first surface and the second surface toward the central portion in the thickness direction of the wiping sheet, and the abundance ratio of the second fiber is the wiping sheet. It increases from the central part in the thickness direction toward the first surface and the second surface, respectively.
It is intended to provide a wiping sheet in which the abundance ratio of the second fiber is higher than that of the first fiber on each of the first surface and the second surface.

The present invention also provides a cleaning tool having the wiping sheet and a cleaning tool provided with a head portion to which the wiping sheet can be attached.

According to the present invention, there is provided a wiping sheet and a cleaning tool that have both improved dust collection and improved operability during wiping.

FIG. 1A is a schematic cross-sectional view showing an embodiment of the wiping sheet of the present invention, and FIG. 1B is a scanning electron microscope image of a vertical cross section of the wiping sheet of the present invention. FIG. 2 is a graph obtained by measuring the abundance ratio of fibers in the wiping sheet in FIG. 1 (b). FIG. 3A is a scanning electron microscope image of the first surface of the wiping sheet of the present invention, and FIG. 3B is a scanning electron microscope image of the second surface of the wiping sheet of the present invention. FIG. 4 is a schematic view showing an embodiment of an uneven portion of a macroscopic pattern on the first surface of the wiping sheet of the present invention. FIG. 5 is a schematic view of a manufacturing apparatus suitably used for manufacturing the wiping sheet of the present invention. FIG. 6 is a schematic view of the uneven portion forming member in the manufacturing apparatus shown in FIG. FIG. 7 is a schematic view showing an embodiment of the cleaning tool of the present invention. FIG. 8 is a graph showing the dust collection rate in the wiping sheets of Examples, Reference Examples and Comparative Examples.

Hereinafter, the wiping sheet of the present invention will be described based on the preferred embodiment thereof with reference to the drawings. Wiping in the present invention includes both meanings of cleaning and cleaning, for example, cleaning of buildings such as floors, walls, ceilings and pillars, cleaning of fittings and fixtures, wiping of articles, body and body. Includes cleaning of equipment related to. In addition, in this specification, the term "wiping sheet" simply refers to one in which a cleaning liquid is supported and one in which a cleaning liquid is not supported, depending on the context.

The wiping sheet of the present invention is made of a fiber aggregate. The fibers constituting the fiber aggregate include at least a first fiber and a second fiber having a smaller diameter than the first fiber. The first fiber and the second fiber are entangled with each other by the first fiber, the second fiber, and the first fiber and the second fiber to form the above-mentioned fiber aggregate. That is, the fiber aggregate used for the wiping sheet is a composite fiber aggregate mainly composed of the entanglement of the first and second fibers. In addition to this, the wiping sheet may have other members.

1 (a) and 1 (b) show a vertical cross section of a fiber assembly provided in the wiping sheet of the present invention. As shown in the figure, the fiber aggregate 1A in the wiping sheet 1 includes a first fiber 11 and a second fiber 12 having a diameter smaller than that of the first fiber. Further, the wiping sheet 1 has a first surface 1F and a second surface 1R located on the opposite side of the first surface 1F. Both the first surface 1F and the second surface 1R of the wiping sheet are provided as the wiping surface when the wiping sheet is used (hereinafter, the first surface 1F and the second surface 1R are also collectively referred to as "wiping surface"). .. As shown in FIG. 1, in the wiping sheet 1, the second fiber 12, which is a fiber having a small fiber diameter, is mainly present on the first surface 1F and the second surface 1R of the figure, and the center of the thickness direction Z. In part C, the first fiber 11 is mainly present. In addition, "mainly present" means that the second fiber among the fibers on any surface parallel to the first surface 1F when the wiping sheet 1 is viewed in a vertical cross section along the thickness direction Z. It means that the abundance ratio of 12 is the highest.

As shown in FIGS. 1A and 1B, in the wiping sheet 1, the locations where the first fiber 11 and the second fiber 12 are present are unevenly distributed in the vertical cross-sectional view along the thickness direction Z thereof. .. Specifically, in the wiping sheet 1, in the vertical cross-sectional view in the thickness direction Z, the presence ratio of the first fiber 11 is the thickness of the wiping sheet from each of the first surface 1F and the second surface 1R provided as the wiping surface. It increases toward the central portion C in the longitudinal direction Z. On the other hand, with respect to the second fiber 12, in the vertical cross-sectional view along the thickness direction Z of the wiping sheet 1, the presence ratio of the second fiber 12 is first from the central portion C in the thickness direction Z of the wiping sheet 1. It is increasing toward the surface 1F and the second surface 1R, respectively. Further, on the first surface 1F and the second surface 1R, which are the wiping surfaces, the second fiber 12 exists over the surface direction while maintaining a state in which the abundance ratio thereof is high. By adopting this configuration, it is possible to increase the collection rate of dust such as fine particles, and it is possible to reduce the frictional resistance at the time of wiping and improve the operability.

In detail, the locations where the first fiber 11 and the second fiber 12 are present are as follows. That is, when the wiping sheet 1 is virtually divided into a plurality of parts in the plane direction parallel to the first plane 1F with the first plane 1F as a reference (0%) in the vertical cross-sectional view along the thickness direction Z, The area ratio of the second fiber 12 in the virtual surface parallel to the first surface 1F is the first fiber for the part covering 0% or more and 10% or less and the part covering 90% or more and 100% or less of the thickness of the wiping sheet 1. It is preferably configured to be higher than 11. Similarly, when the wiping sheet 1 is virtually divided into a plurality of parts in a plane direction parallel to the first surface 1F with the first surface 1F as a reference (0%) in a vertical cross-sectional view along the thickness direction Z. In addition, it is preferable that the area ratio of the first fiber 11 in the virtual surface parallel to the first surface 1F is high for the portion of the thickness of the wiping sheet 1 over 10 or more and less than 90%. ..

In particular, it collects fine particle dust with a dense and low porosity structure formed by the second fiber having a small diameter, and is contaminated with a high porosity structure formed by the first fiber having a large diameter. From the viewpoint of facilitating holding between the constituent fibers of the wiping sheet, the abundance ratio of the first fiber 11 is provided as the wiping surface in the vertical cross-sectional view along the thickness direction Z of the wiping sheet 1. It is preferable that the fibers are gradually increased from each of the 1F and the second surface 1R toward the central portion C in the thickness direction Z of the wiping sheet in a stepwise manner, continuously or in a combination thereof, and the second fiber 12 The abundance ratio of the wiping sheet 1 is gradually increased from the central portion C in the thickness direction Z of the wiping sheet 1 toward the first surface 1F and the second surface 1R, stepwise, continuously or in combination thereof. Is preferable.

In a vertical cross-sectional view along the thickness direction Z of the wiping sheet 1, the abundance ratio of the first fiber 11 and the second fiber 12 can be measured as an area ratio using, for example, a confocal laser scanning microscope. Specifically, with reference to the first surface 1F, the region defined by the first surface 1F and the second surface 1R in the thickness direction Z of the wiping sheet is virtually defined in the surface direction parallel to the first surface 1F. It is divided into a plurality of parts, these surfaces are observed by Raman imaging, and image data is acquired respectively. Each obtained image is binarized by setting a threshold value at the brightness boundary between the first fiber and the second fiber using image processing software such as ImageJ. Generally, when binarized with white and black, the first fiber becomes white and the second fiber becomes black. Therefore, the area having each color is calculated and the area ratio of each fiber is calculated. calculate.

FIG. 2 shows the results of measuring the abundance ratio of each fiber on an arbitrary surface by the above-mentioned method with the wiping sheet 1 shown in FIG. 1 (b) as a measurement target. The first surface 1F was used as a reference surface (first point), the second surface 1R was used as an end surface (tenth point), and the measurement was performed by virtually dividing the measurement into 10 points evenly in the thickness direction. As shown in FIG. 2, in the wiping sheet of the present invention, the abundance ratio of the first fiber 11 is from the first surface 1F and the second surface 1R, respectively, when viewed along the thickness direction Z of the wiping sheet. It can be seen that the wiping sheet decreases toward the center in the thickness direction. Further, the abundance ratio of the second fiber 12 increases from the central portion in the thickness direction of the wiping sheet 1 toward the first surface 1F and the second surface 1R, respectively, when viewed along the thickness direction Z. It turns out that there is.

In particular, it has a structure with a high void ratio formed by the first fiber having a large diameter while collecting fine particle dust with a structure having a dense and low void ratio formed by the second fiber having a small diameter. From the viewpoint of facilitating retention of dirt between the constituent fibers of the wiping sheet, among the fibers observed in the range of the 4th to 6th points located in the central portion C in the thickness direction Z, the virtual fibers at each point are virtual. The abundance ratio of the first fiber 11 on the plane (see FIG. 2) is preferably 70% or more, more preferably 75% or more in terms of area ratio. Further, from the same viewpoint, the presence of the first fiber 11 observed in the range of the fourth point to the sixth point among all the first fibers 11 observed in the range of the first point to the tenth point. The ratio is preferably 5% or more, and more preferably 10% or more.

Similarly, among the fibers observed in the range of the fourth to sixth points located in the central portion C in the thickness direction Z, the abundance ratio of the second fiber 12 in the virtual plane at each point (see FIG. 2). ) Is preferably less than 30%, more preferably less than 25% in terms of area ratio. Further, from the same viewpoint, the presence of the second fiber 12 observed in the range of the fourth point to the sixth point among all the second fibers 12 observed in the range of the first point to the tenth point. The ratio is preferably 10% or more, and more preferably 15% or more.

In the wiping sheet of the present invention, when focusing on the first surface 1F and the second surface 1R, it is preferable that the abundance ratio of the constituent fibers on each surface is within a predetermined range. Specifically, the abundance ratio of the second fiber 12 on the first surface 1F is preferably 40% or more, more preferably 50% or more, and more preferably 60% or more in terms of area ratio. It is more preferably 90% or less, more preferably 85% or less, still more preferably 83% or less. The abundance ratio of the second fiber 12 on the first surface 1F is preferably 40% or more and 90% or less, more preferably 50% or more and 85% or less, and 60% or more in terms of area ratio. It is more preferably 83% or less. Due to such an abundance ratio, the fine particle dust is collected by the structure having a dense and low porosity formed by the second fiber having a small diameter, and the first fiber having a large diameter is used. The high porosity structure formed by the above has the effect of facilitating retention of dirt between the constituent fibers of the wiping sheet.

From the same viewpoint, the abundance ratio of the first fiber 11 on the first surface 1F is preferably 1% or more, more preferably 5% or more, and 7% or more in terms of area ratio. It is more preferably 60% or less, more preferably 40% or less, still more preferably 35% or less. The abundance ratio of the first fiber 11 on the first surface 1F is preferably 1% or more and 60% or less, more preferably 5% or more and 40% or less, and 7% or more and 35 in terms of area ratio. % Or less is more preferable.

Similarly, the abundance ratio of the second fiber 12 on the second surface 1R is preferably 50% or more, more preferably 65% or more, and more preferably 70% or more in terms of area ratio. Is more preferably 90% or less, more preferably 87% or less, still more preferably 85% or less. The abundance ratio of the second fiber 12 in the second surface 1R is preferably 50% or more and 90% or less, more preferably 65% or more and 87% or less, and 70% or more in terms of area ratio. It is more preferably 85% or less.

Similarly, the abundance ratio of the first fiber 11 on the second surface 1R is preferably 1% or more, more preferably 3% or more, and 5% or more in terms of area ratio. It is more preferably 60% or less, more preferably 40% or less, still more preferably 35% or less. The abundance ratio of the first fiber 11 in the second surface 1R is preferably 1% or more and 60% or less, more preferably 3% or more and 40% or less, and 5% or more in terms of area ratio. It is more preferably 35% or less.

From the viewpoint of further enhancing the collectability of dust, it is preferable that there are voids in which none of the fibers are present on the first surface 1F and the second surface 1R when the abundance ratio of each fiber is expressed by the area ratio. .. For example, on the first surface 1F and the second surface 1R, the abundance ratio (area ratio) occupied by the first fiber 11 is set to 1%, which is the lower limit thereof, and the abundance ratio (area ratio) occupied by the second fiber 12 is set to 1%. When the upper limit is 90%, the remaining 9% is void. By having the voids, in addition to being able to effectively collect dust, the amount of cleaning liquid released can be suppressed to a required amount even when the wiping sheet is used in a mode in which the cleaning liquid is supported. In order to make such a void exist, for example, in the method for manufacturing a wiping sheet described later, the basis weight of the first fiber 11 and / or the second fiber 12 and the conditions of water flow entanglement such as water pressure and transfer speed are set. It can be adjusted as appropriate by changing it.

After wiping off the dirt on one surface, the second fiber 12 is mainly present on the first surface 1F and the second surface 1R from the viewpoint of facilitating the collection of fine particle dust on the other surface. As a condition, of the first surface 1F and the second surface 1R of the wiping sheet including the void, the area ratio occupied by the first fiber 11 on the first surface 1F and the area occupied by the first fiber 11 on the second surface 1R. It is preferable that the area ratios are different from each other. Specifically, the area ratio occupied by the first fiber 11 on the first surface 1F is preferably larger than the area ratio occupied by the first fiber 11 on the second surface 1R, and the first fiber on the first surface 1F. It is more preferable that the difference between the area ratio occupied by 11 and the area ratio occupied by the first fiber 11 on the second surface 1R is 3% or more.

As described above, the area ratio occupied by the first fiber 11 on the first surface 1F and the area ratio occupied by the first fiber 11 on the second surface 1R are different from each other, so that the first surface 1F It is preferable that the area ratio occupied by the second fiber 12 in the second surface 1R and the area ratio occupied by the second fiber 12 in the second surface 1R are different from each other. Specifically, the area ratio occupied by the second fiber 12 on the second surface 1R is preferably larger than the area ratio occupied by the second fiber 12 on the first surface 1F, and the first fiber on the second surface 1R. It is more preferable that the difference between the area ratio occupied by 11 and the area ratio occupied by the first fiber 11 on the second surface 1R is 3% or more.

From the same viewpoint, it is preferable that the area ratio occupied by the first fiber 11 on the first surface 1F and the area ratio occupied by the second fiber 12 on the same surface are different from each other. Specifically, as described above, the first surface on the first surface 1F is provided on the condition that the area ratio occupied by the second fiber 12 on the first surface 1F is larger than the area ratio occupied by the first fiber 11 on the same surface. The difference between the area ratio occupied by the fiber 12 of 2 and the area ratio occupied by the first fiber 11 on the same surface is preferably 5% or more, and more preferably 10% or more.

Similarly, it is also preferable that the area ratio occupied by the first fiber 11 on the second surface 1R and the area ratio occupied by the second fiber 12 on the same surface are different from each other. Specifically, as described above, the first on the second surface 1R, provided that the area ratio occupied by the second fiber 12 on the second surface 1R is larger than the area ratio occupied by the first fiber 11 on the same surface. The difference between the area ratio occupied by the fiber 12 of 2 and the area ratio occupied by the first fiber 11 on the same surface is preferably 7% or more, and more preferably 12% or more.

For example, when the area ratio occupied by the first fiber is measured according to the above method using the wiping sheet shown in FIG. 1 (b) as a measurement target, the area ratio of the first fiber 11 on the first surface 1F shown in FIG. 3 (a) is measured. The area ratio occupied by the second fiber 12 is 26%, the area ratio occupied by the second fiber 12 is 70%, and the remaining 4% is void. Similarly, the area ratio of the first fiber 11 on the second surface 1R shown in FIG. 3B is 15%, the area ratio of the second fiber 12 is 82%, and the remaining 3% is void. A wiping sheet having such an area ratio can be manufactured by a manufacturing method described later.

In the wiping sheet of the present invention, it is preferable that the entanglement strength of the fibers constituting the first surface 1F and the entanglement strength of the fibers constituting the second surface 1R are different from each other. Specifically, it is preferable that the entanglement strength of the constituent fibers on the first surface 1F is higher than the entanglement strength of the constituent fibers on the second surface 1R. When the entanglement strength of the fibers is high, the friction between the constituent fibers is strong and the structure is dense, so that the constituent fibers are difficult to move with respect to an external force. As a result, dust having a fine particle size can be easily collected by being entangled between the constituent fibers. In this way, since the first surface 1F and the second surface 1R of the wiping sheet have different entanglement strengths, it is possible to use each surface properly according to the wiping target and the accumulated dirt, and the dust collection property. Can be enhanced. The strength of such entanglement strength can be appropriately adjusted, for example, by changing the conditions of water flow entanglement such as water pressure and transport speed in the method for manufacturing a wiping sheet described later.

The entanglement strength of the constituent fibers can be measured, for example, as follows. That is, with a load of 5.5 N / m ² applied to the wiping sheet to be evaluated, one surface of the sheet is brought into contact with a circular urethane foam rotating at a rotation speed of 2.3 m / s. Rub for 1.5 minutes. Then, the fibers adhering to the urethane foam are collected with an adhesive tape, and the mass of the fibers is measured. The smaller the mass of the collected fibers, the higher the entanglement strength of the fibers.

The first fiber 11 and the second fiber 12 constituting the fiber aggregate 1A may be either synthetic fibers or natural fibers. Examples of the synthetic fiber include polyolefin fibers such as polyethylene and polypropylene, polyester fibers such as polyethylene terephthalate, polyolefin / polyester mixed fibers such as polyethylene / polyethylene terephthalate and polypropylene / polyethylene terephthalate, polyamide fibers such as nylon 6 and nylon 66, and poly. Examples thereof include vinyl fibers such as vinyl chloride and polystyrene, and acrylic fibers such as polyacrylic acid and polymethyl methacrylate. Examples of natural fibers include various cellulose fibers such as pulp, cotton, rayon, lyocell and tencel. These fibers may be used alone or in combination of two or more.

From the viewpoint of improving dust collection and operability during wiping, the fiber diameter (diameter) of the first fiber 11 is preferably 10 μm or more and 30 μm or less, and more preferably 15 μm or more and 25 μm or less. The fiber diameter (diameter) of the second fiber 12 is preferably 0.1 μm or more and 9 μm or less, and more preferably 0.5 μm or more and 5 μm or less. The fibers constituting the fiber aggregate 1A may be continuous filaments or staple fibers depending on the method for producing the fiber aggregate 1A. In the case of staple fibers, the average fiber length is generally preferably 1 mm or more and 100 mm or less, more preferably 10 mm or more and 90 mm or less, and further preferably 20 mm or more and 60 mm or less. By having such a fiber diameter and a fiber length, it is possible to obtain a fiber aggregate 1A having a high degree of flexibility and a high degree of freedom of the fiber.

As described above, the fiber aggregate 1A is a non-woven fabric formed by entwining the fibers constituting the fiber aggregate 1A. From the viewpoint of increasing the degree of freedom of the constituent fibers of the fiber aggregate 1A and enhancing the dust collection property, it is preferable that the constituent fibers of the fiber aggregate 1A are not fused to each other.

The basis weight of the fiber aggregate 1A formed by entwining the first fiber 11 and the second fiber 12 constituting the wiping sheet is preferably 16 g / m ² or more, more preferably 26 g / m ² or more, and 36 g / m. ² or more is more preferable. The basis weight of the fiber aggregate 1A is preferably 156 g / m ² or less, more preferably 86 g / m ² or less, and even more preferably 81 g / m ² or less. Specifically, the basis weight of the fiber aggregate 1A formed by entwining the first fiber 11 and the second fiber 12 constituting the wiping sheet is preferably 16 g / m ² or more and 156 g / m ² or less, preferably 26 g / m. More preferably, m ² or more and 86 g / m ² or less, and even more preferably 36 g / m ² or more and 86 g / m ² or less.

From the viewpoint of suppressing frictional resistance during wiping, it is preferable that at least the first surface 1F of the wiping sheet 1 has an uneven portion of a macroscopic pattern having a curved portion, as shown in FIG. Specifically, on the first surface 1F of the wiping sheet 1, a convex portion 3 and a concave portion 4 constituting the uneven portion are formed, and the boundary line between the convex portion 3 and the concave portion 4 is viewed macroscopically. It has a curved part. As long as it has such a configuration, it is not limited to the macroscopic pattern shown in FIG. 4, and for example, the macroscopic pattern shown in Japanese Patent Application Laid-Open No. 2017-11328 and figures such as straight lines, curves, circles, and polygons are appropriately used. It may be a combined macroscopic pattern. From a macroscopic point of view, the curved shape is a figure that constitutes an uneven portion except for a curve that constitutes a microscopic fine hole and a curve that constitutes a drainage hole having a diameter of about 1.5 to 2 mm. It means that it can be visually confirmed that a part of the side of is a curve. Having such an uneven portion of a macroscopic pattern also has an advantage of enhancing the design of the wiping sheet itself.

The wiping sheet of the present invention may further include a scrim that supports the fiber aggregate 1A constituting the sheet. The scrim can be integrally entangled with the constituent fibers of the fiber aggregate 1A, and may have a net-like shape, a strand-like shape, or the like. By providing the wiping sheet with a scrim, the wiping sheet 1 is provided with sufficient strength for practical use even when the degree of entanglement between the constituent fibers is weakened in order to increase the degree of freedom of the constituent fibers of the fiber aggregate. It has the advantage of being able to.

Examples of the raw materials constituting the scrim include polyolefin resins such as polyethylene and polypropylene, polyester resins such as polyethylene terephthalate, polyamide resins such as nylon 6 and nylon 66, acrylonitrile resins such as polyvinylidene chloride, and vinyl such as polyvinyl chloride and polystyrene. A vinylidene-based resin, a vinylidene-based resin such as polyvinylidene chloride, or the like can be used.

From the viewpoint of achieving both the entanglement of the fiber aggregate 1A and the scrim and the strength of the wiping sheet 1, the wire diameter (diameter in the cross section) of the scrim is appropriately adjusted according to the degree of entanglement with the fiber aggregate 1A. However, it is preferably 10 μm or more, more preferably 500 μm or more, more preferably 2000 μm or less, still more preferably 1000 μm or less. The wire diameters of the scrims may be partially different or the same, and when the wire diameters are partially different, the wire diameters of the scrims shall be the average value.

In the wiping sheet 1, the fiber aggregate 1A may be used as it is (so-called dry type) at the time of wiping, or the fiber aggregate 1A is coated, sprayed, supported or impregnated with a cleaning liquid (so-called wet mode). ) May be used. These modes can be selected according to the type of dirt adhering to the surface to be wiped and the physical properties of the object to be wiped. From the viewpoint of increasing the efficiency of removing stains on the surface to be wiped, it is preferable that the cleaning liquid is supported on the fiber aggregate constituting the wiping sheet.

When the wiping sheet is used in a wet mode at the time of wiping, the cleaning liquid supported on the sheet should be water alone or an aqueous solution containing an additive, which has a general composition used for a wet wiping sheet. Can be done. Examples of the additive used in the cleaning liquid include surfactants, bactericides, fragrances, fragrances, deodorants, pH adjusters, alcohols and abrasive particles.

The above has been described with respect to one embodiment of the wiping sheet of the present invention, and the manufacturing apparatus 10 suitably used for manufacturing the wiping sheet will be described below. FIG. 5 shows a manufacturing apparatus 10 preferably used for manufacturing the wiping sheet 1. The manufacturing apparatus 10 includes a web forming portion 20, a first water flow entanglement portion 30, a second water flow entanglement portion 40, an entanglement body inversion portion 50, and a third water flow entanglement portion 60 in this order.

The web forming unit 20 forms the web of the first fiber 11. The web forming unit 20 includes a card machine 21 for forming a web of the fiber from the first fiber 11 which is a constituent raw material of the wiping sheet 1, and a guide roll 22. When manufacturing a wiping sheet provided with a scrim, a scrim roll 25 for feeding out the scrim 15 may be further provided.

The first water flow entanglement portion 30 entangles the webs of the first fibers 11 with each other, or the webs of the first fibers 11 and the scrim 15 with a water flow to form an entanglement of the first fibers. The first water flow entanglement portion 30 includes a first water flow nozzle 31 that blows a water flow onto the web side of the first fiber 11, and a first support belt 32 made of an endless belt. The first water flow nozzle 31 is located above the first support belt 32, and can blow a high-pressure water flow over the entire width direction (direction orthogonal to the transport direction MD) of the web of the first fiber. ing. The first support belt 32 is arranged so as to face the first water flow nozzle 31, and has a structure in which holes are formed in various patterns such as a grid pattern in order to allow the sprayed water to pass through (see the figure). figure).

The second water flow entanglement portion 40 is formed by laminating the entanglement body 12A of the second fiber 12 on the upper surface of the entanglement body of the first fiber 11 to form the laminate 5, and the water flow is sprayed onto the laminate to form the laminate 5. It forms a fiber entanglement body 1P. The second water flow entanglement portion 40 includes a raw fabric roll 41 and a second guide roll 42 that unwind the entanglement body 12A of the sheet-shaped second fiber 12, and a second water flow nozzle 43 that blows a water flow to the second fiber 12 side. A second support belt 44 made of an endless belt is provided. The second water flow nozzle 43 and the second support belt 44 have the same structure as the first water flow nozzle 31 and the first support belt 32.

The entangled body inversion portion 50 inverts the upper and lower surfaces of the two-fiber entanglement body 1P formed by the second water flow entanglement portion 40, and transports the confounding body 11 side to the downstream process with the first fiber 11 side as the upper surface. The configuration of the entangled body reversing portion 50 is not particularly limited as long as the upper and lower surfaces of the two-fiber entangled body 1P can be inverted, and for example, a human hand or an inverted roll can be used. Further, instead of the entangled body inversion portion 50, the two-fiber entanglement body 1P is once collected by a take-up roll (not shown) or the like, and then the upper and lower surfaces of the two-fiber entanglement body 1P are inverted to perform the downstream process again. May be supplied.

The third water flow entanglement portion 60 is a second laminated body in which the second entanglement body 12B of the second fiber 12 is laminated on the two fiber entanglement body 1P which is conveyed with the first fiber 11 side as the upper surface. 7 is formed, and a water stream is blown onto the laminated body 7 to form a fiber aggregate 1A. The third water flow entanglement portion 60 is a third which sprays a water flow on the second entanglement roll 61 and the third guide roll 62 for feeding out the second entanglement body 12B of the sheet-shaped second fiber 12, and the second entanglement body 12B side. It includes a water flow nozzle 63 and a third support belt 64 made of an endless belt. Further, in the case of manufacturing a wiping sheet in which an uneven portion having a macroscopic pattern as shown in FIG. 4 is formed on the entire surface of the first surface 1F, for example, a concave-convex portion forming member 65 having a shape as shown in FIG. 6 is used. It is preferable to provide between the two laminated bodies 7 and the third support belt 64. As another example of the uneven portion forming member 65, a punching metal, a plastic net, or the like can be used. Further, the third water flow nozzle 63 and the third support belt 64 have the same structure as the first water flow nozzle 31, the second water flow nozzle 43, the first support belt 32, and the second support belt 44.

The method for manufacturing the wiping sheet using the manufacturing apparatus 10 shown in FIG. 5 is as described below. In this manufacturing method, a step of forming an entanglement of the first fiber 11 by water flow entanglement and a step of laminating the entanglement body 12A of the second fiber 12 on the upper surface of the entanglement of the first fiber 11 and two by water flow entanglement. The step of forming the fiber entanglement 1P and the second entanglement 12B of the second fiber 12 are laminated on the two fiber entanglement 1P whose upper surface is on the first fiber 11 side, and the fiber assembly 1A is formed by water flow entanglement. It is roughly divided into three steps.

First, the web of the first fiber 11 is unwound from the card machine 21 in the web forming unit 20 via the guide roll 23. When the wiping sheet is provided with a scrim, the scrim 15 is unwound from the scrim roll 25 together with the web of the first fiber 11. By these feedings, the web and scrim of the first fiber are laminated.

Next, in the first water flow confounding portion 30, the web of the first fiber 11 (or the laminate of the web of the first fiber 11 and the scrim 15) is first conveyed in the MD direction by the first support belt 32. The entanglement process is performed by the high-pressure water flow ejected from the water flow nozzle 31 (first entanglement step). By going through this step, the first fibers are entangled with each other to form an entanglement of the first fibers 11. When the scrim is provided, this step causes the first fibers 11 to be entangled with each other, and the first fibers 11 and the scrim 15 are integrally entangled to form an entangled body. In this step, the water pressure sprayed from the first water flow nozzle 31 is preferably 30 kg / cm ² or more and 80 kg / cm ² or less, more preferably 40 kg / cm ² or more and 60 kg / cm ² or less, and the web of the first fiber 11. It can be manufactured by preferably setting the transport speed in the MD direction to 2 m / min or more and 10 m / min or less, and more preferably 4 m / min or more and 8 m / min or less.

The basis weight of the entanglement of the first fiber 11 is preferably 14 g / m ² or more, more preferably 23 g / m ² or more, and even more preferably 32 g / m ² or more. The basis weight of the entanglement body of the first fiber is preferably 140 g / m ² or less, more preferably 77 g / m ² or less, and further preferably 73 g / m ² or less. Specifically, the basis weight of the confounding body of the first fiber 11 is preferably 14 g / m ² or more and 140 g / m ² or less, more preferably 23 g / m ² or more and 77 g / m ² or less, and 32 g / m ² or more. 73 g / m ² or less is more preferable.

After the entanglement of the first fiber 11 is formed, the entanglement body 12A of the second fiber 12 is laminated on the upper surface thereof, and the two-fiber entanglement body 1P is formed by water flow entanglement (second entanglement step). Specifically, the entanglement body of the first fiber 11 is conveyed in the MD direction, and the entanglement body 12A of the sheet-shaped second fiber 12 unwound from the raw fabric roll 41 is placed on the upper surface of the entanglement body. Laminate to form a laminated body 5. By blowing a high-pressure water flow from the second water flow nozzle 43 onto the laminated body 5, the constituent fibers of each entanglement body are three-dimensionally entangled to form a two-fiber entanglement body 1P. The water pressure sprayed from the second water flow nozzle 43 and the transport speed of the laminated body 5 can be in the same range as in the first entanglement step. In the two-fiber entanglement body 1P formed in this step, the second fiber 12 is mainly present on the upper surface thereof, and the first fiber 11 (or the entanglement of the first fiber 11 and the scrim 15) is present on the lower surface thereof. ) Is mainly present.

The basis weight of the entanglement body 12A of the second fiber 12 is preferably 2 g / m ² or more, more preferably 3 g / m ² or more, and even more preferably 4 g / m ² or more. The basis weight of the entanglement body 12A of the first fiber is preferably 20 g / m ² or less, more preferably 15 g / m ² or less, still more preferably 10 g / m ² or less. Specifically, the basis weight of the confounding body 12A of the second fiber 12 is preferably 2 g / m ² or more and 20 g / m ² or less, more preferably 3 g / m ² or more and 15 g / m ² or less, and 4 g / m ² . More preferably 10 g / m ² or less.

Subsequently, the upper and lower surfaces of the two-fiber entanglement body 1P are inverted by the entanglement body inversion portion 50. By going through this step, in the two-fiber entanglement body 1P, the first fiber 11 (or the entanglement of the first fiber 11 and the scrim 15) is mainly present on the upper surface thereof, and the second fiber entanglement body 1P is on the lower surface thereof. The arrangement is such that the fibers 12 of 2 are mainly present.

After inverting the upper and lower surfaces of the two-fiber entanglement body 1P, the second entanglement body 12B of the second fiber 12 is laminated on the upper surface of the two-fiber entanglement body 1P, and the fiber assembly 1A is formed by water flow entanglement (third). Entanglement process). Specifically, the two-fiber entanglement body 1P is conveyed in the MD direction, and the sheet-like first unwound from the second raw fabric roll 61 on the first fiber 11 side located on the upper surface of the two-fiber entanglement body 1P. The second entanglement body 12B of the fibers 12 of 2 is laminated to form the second laminated body 7. By blowing a high-pressure water flow from the third water flow nozzle 63 onto the second laminated body 7, the constituent fibers of each entanglement body are three-dimensionally entangled to form a fiber aggregate 1A. The water pressure sprayed from the third water flow nozzle 63 and the transport speed of the second laminated body 7 can be in the same range as in the first entanglement step. Further, the basis weight of the second entanglement body 12B of the second fiber 12 can be in the same range as the entanglement body 12A of the second fiber 12 described above. When the two-fiber entanglement body 1P is provided with the scrim 15, the constituent fibers of the fiber aggregate 1A and the scrim 15 form an integral entangled state. In the fiber aggregate 1A thus formed, the upper surface of the aggregate 1A is the second surface 1R, and the lower surface of the aggregate 1A is the first surface 1F having a higher entanglement strength than the constituent fibers of the second surface 1R. Become.

Further, among the fiber aggregates 1A, the two-fiber entanglement body 1P constitutes the two-fiber entanglement body 1P because it has undergone two water flow entanglements by the second water flow nozzle 43 and the third water flow nozzle 63. The entanglement of the entanglement of the fiber 11 of 1 and the entanglement 12A of the second fiber 12 is more advanced, and the presence ratio (area ratio) of the first fiber 11 is higher on the first surface 1F in the fiber assembly 1A. It is higher than the abundance ratio (area ratio) of the first fiber 11 on the second surface 1R. Along with this, in the first surface 1F of the fiber aggregate 1A, the abundance ratio (area ratio) of the second fiber 12 is lower than the abundance ratio (area ratio) of the second fiber 12 in the second surface 1R. It has become a thing.

In the third entanglement step, as shown in FIG. 5, when the uneven portion forming member 65 shown in FIG. 6 is provided between the second laminated body 7 and the third support belt 64, by spraying a high-pressure water flow. A convex portion 3 and a concave portion 4 complementary to the uneven shape of the uneven portion forming member 65 are formed on the first surface 1F of the fiber aggregate 1A while three-dimensionally entwining the constituent fibers of each entangled body. Can be done. Specifically, the water flow sprayed from the third water flow nozzle 63 toward the upper surface side of the second laminated body 7 presses the lower surface thereof so as to be in close contact with the upper surface of the concave portion forming convex portion 65a of the uneven portion forming member 65. .. At the same time, the constituent fibers of the second laminated body 7 located in the convex portion forming concave portion 65b of the uneven portion forming member 65 are projected into the concave portion 65b, and the concave portion forming convex portion 65a of the uneven portion forming member 65 is formed. The constituent fibers of the second laminated body 7 located are depressed in the thickness direction of the laminated body. The water sprayed in the water flow confounding is permeated downward through the concave portion 65b for forming the convex portion in the concave-convex portion forming member 65 and the drain holes 65c provided in the convex portion 65a for forming the concave portion. Thereby, the uneven portion of the macroscopic pattern having the curved portion can be formed on the first surface 1F of the wiping sheet.

The fiber aggregate 1A produced through the above steps may be used as it is as a dry wiping sheet, or the cleaning liquid may be supported on the fiber aggregate 1A (supporting step) and used as a wet wiping sheet. You can also. In the step of supporting the cleaning liquid, the amount of the cleaning liquid supported on the fiber aggregate 1A is preferably 1 g / sheet or more when the dimensions of the wiping sheet 1 are 285 mm × 205 mm, for example, as described in Examples described later. 10 g / sheet or more is further preferable, 40 g / sheet or less is preferable, and 25 g / sheet or less is further preferable. In other words, 17 g / m ² or more is preferable, 117 g / m ² or more is more preferable, 690 g / m ² or less is preferable, and 430 g / m ² or less is further preferable.

The wiping sheet manufactured in this way can be used for wiping by itself. Alternatively, as shown in FIG. 7, it can be used for wiping as an embodiment of the cleaning tool 100 mounted on the cleaning tool 120 provided with the head portion 110 to which the wiping sheet 1 can be mounted. As such a cleaning tool 120, a member generally used as a cleaning tool can be used, for example, a rod-shaped member that can be expanded and contracted or can be extended by assembly, a member having a handle, or a member combining these.

When the wiping sheet and cleaning tool of the present invention are used, the surface to be wiped includes buildings such as floors and walls, fittings such as cupboards, windowpanes, mirrors, doors and doorknobs, and furniture such as rugs, carpets and desks and dining tables. It can also be used in kitchens, toilets, human or animal bodies, etc. In particular, in the wiping sheet of the present invention, both the first surface 1F and the second surface 1R can be used as the wiping surface, so that the wiping target surface can be wiped without waste with one wiping sheet.

Although the present invention has been described above based on the preferred embodiment thereof, the present invention is not limited to the above embodiment. For example, although the uneven portion of the macroscopic pattern was formed on the first surface, it may be further formed on the second surface in addition to the first surface.

Hereinafter, the present invention will be described in more detail by way of examples. However, the scope of the invention is not limited to such examples.

[Example 1]
The wiping sheet was manufactured according to the manufacturing method described above. As the first fiber 11, a mixed staple fiber (fiber length 50 mm) having an average fiber diameter of 11.4 μm containing PET: acrylic: rayon = 7: 1.5: 1.5 in a mass ratio was used. As the second fiber 12, polypropylene fiber having an average fiber diameter of 1 μm obtained by the melt blown method was used. The basis weight of the fiber aggregate is 74 g / m ² , the basis weight of the first fiber is 60 g / m ² , and the basis weight of the second fiber on the first surface and the second surface is 6 g / m ² , respectively. It was set to 8 g / m ² .

The abundance ratio (area ratio) of the second fiber on the first surface (the surface formed by the water flow confounding by the second water flow nozzle 43 and the third water flow nozzle 63) is 70%, and the second surface (third water flow). The abundance ratio (area ratio) of the second fiber in the surface formed by the water flow confounding only by the nozzle 63 was 80%. The wiping sheet was rectangular and had dimensions of 285 mm x 205 mm. As the cleaning liquid, a 0.01% by mass aqueous solution of a surfactant (Emulgen (registered trademark) 108, manufactured by Kao Corporation) was used and supported on the fiber aggregate. The amount of the washing liquid supported was 20 g / sheet.

[Reference Example 1]
In this reference example, the wiping sheet was produced in the same manner as in Example 1 except that the fiber aggregate in which the abundance ratio of the second fiber was higher on the first surface than on the second surface was used. That is, in the wiping sheet of this reference example, the second fiber is mainly present on the first surface, and the first fiber is mainly present on the second surface. The abundance ratio (area ratio) of the second fiber on the first surface was 73%, and the abundance ratio (area ratio) of the second fiber on the second surface was 10%.

[Comparative Example 1]
A wiping sheet was produced in the same manner as in Example 1 except that the fiber aggregate composed of only the first fiber was used.

[Comparative Example 2]
A wiping sheet was produced in the same manner as in Example 1 except that the fiber aggregate composed of only the second fiber was used.

[Evaluation of dust collection performance]
First, a flooring floor in which 11 kinds of test powders specified in JIS Z 8901 are sprayed by 0.6 g per tatami mat (1820 mm × 910 mm) using the first surface of the wiping sheets of Examples, Reference Examples and Comparative Examples. (Combit New Advance 101, manufactured by Wood One Co., Ltd.) was wiped for 6 tatami mats. Subsequently, using the second surface of the same sheet, the flooring floor wiped on the first surface was wiped again for 6 tatami mats. The sheet mass before, after using the first surface, and after using the second surface were measured, respectively, and the dust collection rate (%) was calculated from the following formula. The results are shown in FIG.

Dust collection rate after use of the first surface (%) = 100 × ((mass of wiping sheet after use of first surface [g])-(mass of wiping sheet before use of sheet [g])) /0.6 [G])
Dust collection rate after use of the second surface (%) = 100 × ((mass of wiping sheet after use of second surface [g])-(mass of wiping sheet before use of sheet [g])) /0.6 [G])

[Evaluation of wiping resistance]
As the operability at the time of wiping, the wiping resistance in the wet wiping sheets of Examples, Reference Examples and Comparative Examples was evaluated. A pressure of 55 N / m ² was applied to the wet wiping sheet to be evaluated, and an area of 1.8 m ² was wiped with the flooring floor (Combit New Advance 101, manufactured by Wood One Co., Ltd.) as the surface to be wiped. The resistance (N) was measured. To measure resistance, a quickle wiper (manufactured by Kao Corporation) with an alligator-shaped clip attached to the tip of a push-pull gauge (RX-20, manufactured by Aiko Engineering Co., Ltd.) and a wiping sheet to be evaluated attached to the clip. Attach the head part of. The maximum load recorded on the push-pull gauge when this head portion was scanned for 1 m at a speed of 1 cm / sec on the flooring floor was defined as the resistance force. The lower the wiping resistance, the more preferable, but if it is 4N or less, the operability at the time of wiping is high. The results are shown in Table 1.

As shown in FIGS. 8 and 1, the wiping sheet of Example 1 catches dust regardless of whether the first surface or the second surface is used as compared with Reference Example 1 and Comparative Example 1. The collectability is equal to or higher than that, the wiping resistance is low, and the operability at the time of wiping is high. On the other hand, the wiping sheet of Comparative Example 2 made of only small-diameter fibers had a dust collection rate similar to that of the wiping sheet of Example 1, but had high wiping resistance and low operability during wiping. there were. As described above, it can be seen that the wiping sheet of the present invention has both an improvement in dust collection property and an improvement in operability during wiping.

1 Wiping sheet 1A Fiber aggregate 1F 1st surface 1R 2nd surface 1P 2 fiber entanglement 10 Manufacturing equipment 11 1st fiber 12 2nd fiber 20 Web forming part 30 1st water flow entanglement part 40 2nd water flow entanglement part 50 Confounding body reversing part 60 Third water flow confounding part 65 Confounding part forming member 100 Cleaning tool 110 Head part 120 Cleaning tool C Thickness direction Central part Z Thickness direction MD Transport direction

Claims (6)

It comprises at least a first fiber and a second fiber having a smaller diameter than the first fiber, and has a fiber aggregate formed by entwining these fibers, and is located on the first surface and the opposite side of the first surface. A wiping sheet having a second surface to be used.
The abundance ratio of the first fiber increases from each of the first surface and the second surface toward the central portion in the thickness direction of the wiping sheet, and the abundance ratio of the second fiber is the wiping sheet. It increases from the central part in the thickness direction toward the first surface and the second surface, respectively.
The abundance ratio of the second fiber is higher than that of the first fiber on each of the first surface and the second surface.
The area ratio occupied by the first fiber on the first surface and the area ratio occupied by the first fiber on the second surface are different from each other, and the area occupied by the second fiber on the first surface. The ratio and the area ratio occupied by the second fiber on the second surface are different from each other.
The area ratio occupied by the first fiber on the first surface is larger than the area ratio occupied by the first fiber on the second surface.
The area ratio occupied by the second fiber on the second surface is larger than the area ratio occupied by the second fiber on the first surface.
A wiping sheet in which the entanglement strength of the constituent fibers on the first surface is higher than the entanglement strength of the constituent fibers on the second surface . The wiping sheet according to claim 1, further comprising an uneven portion of a macroscopic pattern having a curved portion on the first surface. The wiping sheet according to claim 1 or 2 , wherein the constituent fibers of the fiber aggregate are not fused to each other. The wiping sheet according to any one of claims 1 to 3 , further comprising a scrim that supports the fiber aggregate, and the fiber aggregate and the scrim form an integral entangled state. The wiping sheet according to any one of claims 1 to 4 , wherein the cleaning liquid is supported on the fiber aggregate. A cleaning tool having the wiping sheet according to any one of claims 1 to 5 and a cleaning tool provided with a head portion to which the wiping sheet can be attached.

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