JP2018089124A - Article for cleaning - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an article for cleaning, which uses a long fiber assembly capable of obtaining a friendly soft feeling for a surface to be cleaned and capable of improving an actual cleaning feeling by evoking a powerful image during the cleaning.SOLUTION: An article 10 for cleaning is formed of a long fiber assembly 11 in which long fibers 12 are assembled together. The article for cleaning includes the long fiber assembly in which lightness in the Munsell color system is 4 or less. The article 10 for cleaning is formed by joining the long fiber assembly 11 to a surface of a base material sheet 13 that is made of a nonwoven fabric and the like. The article for cleaning is used by being attached to a cleaning part 22 of a cleaner 20 that comprises a handle part 21 and the cleaning part 22.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a cleaning article, and more particularly to a cleaning article using a long-fiber assembly.

  Conventionally, as a cleaning article using a long fiber assembly, for example, a cleaning sheet having a head part (cleaning part) and a cleaning tool having a handle part connected to the head part, mounted on the head part is used. Known (for example, refer to Patent Document 1 and Patent Document 2).

  In the cleaning article formed using these long fiber aggregates, preferably, the long fiber aggregates are three-dimensionally opened by manual (shaking with hand), air blow treatment, vacuum treatment, etc. By gently raising long fibers in three-dimensional directions and raising them into a three-dimensional shape, it becomes possible to obtain a gentle and soft feel to the surface to be cleaned, and to clean the narrow gap easily and to be wiped It is possible to three-dimensionally collect dust, dirt, etc. up to the inside of the raised three-dimensional long fiber assembly and efficiently clean the surface to be cleaned.

JP 2010-207469 A JP 2008-6260 A

  However, in a conventional cleaning article formed using a long fiber assembly, a soft and soft feel to the surface to be cleaned can be obtained by a raised solid fiber assembly that is preferably raised, while the soft and soft Since the feeling can be obtained, it becomes difficult to recall a powerful image at the time of cleaning, and the actual feeling of cleaning becomes poor.

  An object of the present invention is to provide a cleaning article using a long-fiber assembly that can provide a gentle and soft feel to a surface to be cleaned and can improve a cleaning feeling by recalling a powerful image at the time of cleaning. And

  The present invention provides a cleaning article formed by using a long fiber aggregate in which long fibers are aggregated, and includes a long fiber aggregate having a lightness of 4 or less in the Munsell color system. This achieves the above object.

  According to the cleaning article using the long-fiber assembly of the present invention, a gentle and soft feel to the surface to be cleaned can be obtained, and a cleaning image can be improved by recalling a powerful image at the time of cleaning.

It is a perspective view which shows the article | item for cleaning which concerns on preferable one Embodiment of this invention. It is a perspective view which shows the state which mounted | wore the cleaning tool with the cleaning article which concerns on preferable one Embodiment of this invention. 1 is a schematic plan view of a cleaning article according to a preferred embodiment of the present invention. It is a schematic diagram explaining the structure of a long fiber. (A) is a perspective view of the cleaning tool used for the cleaning article which concerns on other embodiment, (b) is a perspective view which shows the state which mounted | wore the cleaning tool which concerns on other embodiment, (c) ) Is a perspective view of a state in which a long fiber assembly is raised.

  As shown in FIG. 1, a cleaning article 10 according to a preferred embodiment of the present invention shown in FIG. 1 is formed using a long fiber assembly 11 composed of a large number of long fibers 12. The cleaning article 10 of the present embodiment is preferably used in a state in which the long fiber assembly 11 is integrally bonded to the surface of the base sheet 13 made of, for example, a nonwoven fabric. The cleaning article 10 of the present embodiment is preferably used by being mounted on the cleaning tool 20 (see FIG. 2). The cleaning article 10 of the present embodiment is preferably a disposable article. The cleaning article 10 of the present embodiment is preferably formed by raising a large number of long fibers 12 into a three-dimensional shape by three-dimensionally opening the long fiber aggregate 11 by, for example, manual operation, air blow processing, vacuum processing, or the like ( 1 and 5 (c)), in addition to providing a gentle and soft feel to the surface to be cleaned, a function that makes it possible to recall a powerful image during cleaning while maintaining a gentle and soft feel It has.

  The cleaning article 10 of the present embodiment is a cleaning article formed by using the long fiber assembly 11, and the lightness in the Munsell color system is 4 or less, preferably the lightness in the Munsell color system. The long fiber aggregate 11 which is 3 or less is included.

  In the present embodiment, the long fiber aggregate 11 is preferably formed by aggregating long fibers 12 oriented in one direction, and preferably a large number of long fibers 12 constituting the long fiber aggregate 11. Is a long fiber having a lightness of 4 or less in the Munsell color system, and preferably a long fiber having a lightness of 3 or less in the Munsell color system.

  Furthermore, the cleaning article 10 of the present embodiment is preferably formed by bonding the long fiber assembly 11 to the surface of the base sheet 13 made of a nonwoven fabric or the like, as described above. The cleaning part 20 of the cleaning tool 20 provided with the part 21 and the cleaning part (head part) 22 is mounted and used (see FIG. 2).

  The long fibers 12 having a lightness of 4 or less in the Munsell color system are preferably black with an achromatic color having no color, but may be black including chromatic colors such as blue black, purple black, and red black.

  In this embodiment, the long fiber aggregate 11 constituting the cleaning article 10 is formed by aggregating a large number (numerous) of long fibers 12 oriented substantially in one direction, as shown in FIGS. 1 and 3. The multiple long fibers 12 are used in the form of a fiber bundle in which a plurality of long fibers 12 are bundled. As the fiber bundle, for example, a so-called tow is generally used. A tow is a long fiber bundle composed of an extremely large number of filaments and is not twisted, and is a fiber bundle obtained by collecting a large number of spun yarns. The long fiber aggregate 11 is formed by cutting a fiber bundle into a predetermined length. A plurality of long fibers 12 are joined together by a plurality of fiber joining portions 14 extending linearly in a direction orthogonal to the orientation direction of the long fibers 12 (X direction). A long fiber aggregate 11 is formed. The fiber joined portions 14 are provided in a staggered manner alternately distributed over the entire long fiber assembly 11 of the long fibers 12.

  Moreover, in this embodiment, it comprises the base material sheet 13 which will be described later, and the long fiber aggregate 11 is joined to the base material sheet 13 through a plurality of sheet joining portions 15, thereby providing the base material sheet. 13 and the cleaning article 10 are formed. Each of the plurality of sheet joining portions 15 is provided so as to overlap a part of the fiber joining portion 14. The long fiber aggregate 11 has long fibers 12 cut by a plurality of linear cut portions 16. The plurality of linear cut portions 16 are respectively disposed in regions between adjacent fiber joining portions 14 in the direction X orthogonal to the orientation direction Y of the long fibers 12. The long fiber assembly 11 has uncut fibers that are not cut in the vicinity of the ends of the linear cut portions 16 in addition to the cut fibers in which the long fibers 12 are cut by the linear cut portions 16. . A plurality of long fiber assemblies 11 are formed by a plurality of linear cut portions 16. When a plurality of long fiber aggregates 11 are formed, it is preferable that at least one long fiber aggregate 11 has a lightness of 4 or less in the Munsell color system. In this embodiment, the lightness in the Munsell color system of all the long fiber aggregates 11 is 4 or less.

  A plurality of the long fibers 12 can be bonded to the base sheet 13 to form the long fiber aggregate 11, and the long fibers 12 are bonded together at the fiber bonding portion 14 as in this embodiment. Then, after the long fiber aggregate 11 is formed, it can be bonded to the base sheet 13 via the sheet bonding portion 15.

  In the present embodiment, the long fiber aggregate 11 has a rectangular shape, and the longitudinal direction along the orientation direction Y of the long fibers 12 is formed on the surface of the base sheet 13 having a rectangular shape. They are arranged so as to coincide with the longitudinal direction (Y direction). The long fiber aggregate 11 is formed so that the width of the rectangular shape in the short direction (X direction) is smaller than the width of the base sheet 13 in the short direction. In the base sheet 13, the flap portion 17, which is an outer region in the width direction (X direction) than the long fiber aggregate 11, attaches the cleaning article 10 to the cleaning portion 22 of the cleaning tool 20 as will be described later. It becomes the part used when.

As long fiber 12 which forms long fiber aggregate 11, synthetic fibers, such as polyethylene, polypropylene, nylon, polyester, rayon, can be used, for example. The synthetic fiber is preferably heat-fusible. The synthetic fiber may be a single fiber, and is preferably a composite fiber having a core part and a sheath part. As the composite fiber, the core is polyester / sheath polyethylene composite fiber, the core is polyethylene terephthalate / sheath polyethylene composite fiber, the core and sheath are polyethylene terephthalate composite fiber, the core is polyethylene terephthalate / sheath polypropylene composite fiber, A composite fiber in which the core and the sheath are polypropylene, and a composite fiber in which the core is polypropylene / sheath polyethylene are exemplified. The long fibers 12 may be crimped by machine or heat treatment, if necessary.
Further, the long fibers 12 may be provided with a dust-absorbing agent such as liquid paraffin as necessary, or may be subjected to an oil impregnation treatment, an antistatic treatment, a charging treatment, a hydrophilization treatment, an antiglare agent, or the like. Good.
The long fibers 12 are usually oriented in the conveying direction of the material during production. Here, “the long fibers 12 are oriented in one direction” means that the orientation direction Y of some of the long fibers 12 is caused by a manufacturing error, the crimping of the long fibers 12, etc. This means that it does not exclude the case of deviation from the orientation direction of the partial long fibers 12.

  1000 to 50000 long fibers 12 forming the long fiber aggregate 11 are provided on one side of the fiber bonding portion 14 per 1 cm of the fiber bonding portion 14 from the viewpoint of entanglement properties such as dust and dirt. It is more preferable that 5000 to 40,000 are provided. Further, the thickness of the long fiber 12 is not particularly critical, but is 0.1 to 200 dtex, particularly 2 to 30 dtex, from the viewpoint of entanglement of dust and dirt, etc. and prevention of damage to the surface to be cleaned. It is preferable. Moreover, it is preferable to use a crimpable fiber as the long fiber 12 because the entanglement property such as dust and dirt is further improved. The long fibers 12 forming the long fiber aggregate 11 have a brightness of 4 or less in the Munsell color system.

  The fiber joining portion 14 for joining a large number of long fibers 12 is for forming the long fiber aggregate 11, and not for joining the long fiber aggregate 11 to the base sheet 13. The fiber bonding portion 14 is formed by heat fusion using a heat seal method or an ultrasonic seal method, a hot melt adhesive, or the like. In this embodiment, the fiber bond portion 14 is formed by heat fusing the long fibers 12. Yes. As shown in FIG. 3, the fiber bonding portion 14 is formed to extend linearly in the direction X perpendicular to the orientation direction Y of the long fibers 12, that is, in the width direction of the base sheet 13.

  The sheet joining portion 15 for joining the long fiber aggregate 11 to the base sheet 13 is formed by heat fusion, a hot melt adhesive or the like as in the fiber joining portion 14. In this embodiment, the long fiber assembly It is formed by thermally fusing the long fibers 12 of the body 11 to the base sheet 13. The sheet joining portion 15 is provided so as to overlap a part of the fiber joining portion 14. The sheet bonding portion 15 is formed long in the orientation direction Y of the long fibers 12.

  In this embodiment, as the base material sheet 13 which comprises the cleaning article 10 with the long fiber aggregate 11, fiber sheets, such as a nonwoven fabric, used for the conventional cleaning sheet can be used. In particular, in order to easily follow the surface to be cleaned, it is preferable to use an air-through nonwoven fabric or a spunbonded nonwoven fabric having flexibility in the longitudinal direction (Y direction). Moreover, the forming material of the base material sheet 13 may be a non-woven fabric, a net-like sheet, a film, synthetic paper, or a composite material thereof. The base sheet 13 preferably includes a heat-fusible material from the viewpoint of bondability with the long fiber aggregate 11.

  As shown in FIG. 3, the base sheet 13 has a rectangular shape, and the length in the longitudinal direction (Y direction) of the base sheet 13 is preferably 10 cm to 60 cm. It is preferable that the width | variety of the transversal direction (X direction) of the base material sheet 13 is 5 cm-40 cm. In the present embodiment, the base sheet 13 is disposed so that the longitudinal direction of the rectangular shape coincides with the orientation direction Y of the long fibers 12. The orientation direction Y of the long fibers 12 and the longitudinal direction of the base sheet 13 are the same as the Y direction in FIG. 3, and the direction X perpendicular to the orientation direction Y of the long fibers 12 and the short direction of the base sheet 13 are The same direction as the X direction in FIG.

  Further, it is preferable that the base sheet 13 has a higher brightness in the Munsell color system than the long fiber aggregate 11. The base sheet 13 is preferably a sheet having a lightness of 4 to 9.5 in the Munsell color system. As a result, it is possible to improve the design by contrast with the long fibers 12 and to improve the mounting property of the cleaning tool 20 to the cleaning unit 22. From the viewpoint of visibility, the difference in brightness in the Munsell color system between the base sheet 13 and the long fiber aggregate 11 is preferably 1 or more, more preferably 2 or more, and even more preferably 3 or more.

  Further, the base sheet 13 is a fiber sheet such as a non-woven fabric, which is made of the same fibers as the long fibers 12 forming the long fiber aggregate 11, preferably using short fibers having a core-sheath structure. It is preferable that it is colored with the same dye, pigment and the like as the long fiber 12. This makes it possible to improve the overall sense of unity of the cleaning article 10 and the productivity of the fibers. The base sheet 13 may have a lighter color than the long fibers 12 by containing 3% to 50% of fibers that are not colored with a dye, pigment, or the like. The base sheet preferably has a smaller basis weight than the long fiber assembly 11. This makes it possible to increase the lightness even when a fiber having the same fiber composition (with respect to coloring) as the long fibers 12 is used.

  And in this embodiment, many long fibers 12 which comprise the long-fiber assembly 11 are the long fibers whose brightness in the Munsell color system is 4 or less. As shown in FIG. 4, the long fiber 12 is preferably a resin fiber having a core-sheath structure composed of a core part 11a and a sheath part 11b, and the resin of the core part 11a is made of a dye, pigment, or the like. It is colored. Thereby, when the surface to be cleaned is cleaned with the cleaning article 10, it is possible to prevent color transfer due to dyes or pigments from occurring on the surface to be cleaned. Further, by making the resin of the sheath portion 11b transparent, it becomes possible to visually recognize the coloring of the core portion 11a well, and it is possible to obtain dark colored fibers by concentrating the coloring on the core portion 11a. It becomes possible. Thereby, it becomes possible to color the long fiber aggregate 11 in a favorable dark color as a whole.

  Here, the lightness in the Munsell color system is measured by comparison with a color sample. In this embodiment, the lightness in the Munsell color system is measured as compared with the color sample in the state of the cleaning article 10.

  More specifically, using the expanded ruler of the Munsell system color, preferably published by Nippon Color Research Co., Ltd., from the Munsell symbol, which is a numerical scale that is visually evenly spaced, what hue, brightness, and color It is judged visually by the color display. Hue is represented by different angles around the neutral axis, and the lightness level is determined by 18 levels only for achromatic colors and the saturation level is determined by 9 levels. The brightness is brighter as the value is larger, and the saturation is 0 as an achromatic color, and the brightness is brighter as the value is larger. The lightness in the Munsell color system can be measured visually by a healthy person who is not inconvenienced in daily life or working, and is in an unopened planar shape or three-dimensionally opened. Can be measured. For example, the cleaning tool 30 shown in FIG. 5A can be measured without changing the shape without being disassembled or cut. The determination of the color is made by standing the article on a paper of achromatic lightness 9 (white paper) and comparing it with the Munsell symbol (color sample).

  Moreover, as for the long fiber 12 provided with a core-sheath structure, the core part 11a consists of a polyethylene terephthalate, for example, and a polyester resin whose melting | fusing point is 200 degreeC or more, and the sheath part 11b consists of a polyethylene resin whose melting | fusing point is 120 degreeC or less, for example. Preferably it is. Since the polyester resin has a melting point higher than that of the polyethylene resin, the sheath portion 11b can be heat-sealed without melting the colored core portion 11a, and the fiber bonding portion 14 and the sheet bonding portion 15 can be bonded. It is possible to avoid contamination of the processing equipment and the like in the manufacturing process for forming.

  Furthermore, in this embodiment, while the long fiber 12 provided with a core-sheath structure is colored using the thing which mix | blended 0.8-30 weight% of dyes and pigments with the non-colored polyester resin, the core part 11a, It is preferable to form the sheath part 11b using a non-colored polyethylene resin. More preferably, the pigment is blended in the polyester resin by 1.5 to 15% by weight. Thereby, even if the core part 11a is covered with the sheath part 11b, it becomes possible to express a clear color.

  As a dye or pigment for coloring the core portion 11a of the long fiber 12, Pigment Black 1 or the like can be used by blending, for example, 5% by weight.

  As shown in FIG. 2, the cleaning article 10 having the above-described configuration can be used by being mounted on a cleaning unit 22 of a cleaning tool 20 that preferably includes a handle 21 and a cleaning unit 22. In this embodiment, the cleaning tool 20 has a rectangular bottom surface (cleaning surface) in plan view, the cleaning unit 22 on which the cleaning article 10 can be mounted, and a universal joint 23 on the upper surface of the cleaning unit 22. It is comprised including the rod-shaped handle | pattern part 21 connected via the.

  The long fiber aggregate 11 provided on the surface of the base material sheet 13 of the cleaning article 10 is formed in an area wider than the bottom surface of the cleaning part 22 of the cleaning tool 20. The cleaning article 10 has four locations having radial slits in which the flap portion 17 of the base sheet 13 is folded back to the upper surface portion side of the cleaning portion 22 and the folded flap portion 17 is provided on the upper surface portion of the cleaning portion 22. Each of the flexible sheet holding parts 24 is pushed into the cleaning part 22 of the cleaning tool 20. When attached to the cleaning unit 22, the long fiber aggregate 11 of the cleaning article 10 is also present on the side surface along the longitudinal direction of the cleaning unit 22 as shown in FIG. It becomes possible to effectively capture dust, dirt, and the like accumulated in the corners of the surface to be cleaned such as a flooring floor. In addition, the long fiber aggregate 11 having a brightness of 4 or less in the Munsell color system can be easily visually recognized on the side surface of the cleaning unit 22 with the cleaning article 10 mounted on the cleaning tool 20.

  In the present embodiment, the cleaning tool 20 is preferably colored in a color similar to that of the long fiber aggregate 11. In the present embodiment, at least the handle portion 21 of the cleaning tool 20 has a lightness in the Munsell color system of preferably 4 or less, and more preferably 3 or less. It is more preferable that at least the handle portion 21 of the cleaning tool 20 has a lightness lower than that of the long fiber assembly 11. Since at least the handle portion 21 of the cleaning tool 20 has a lightness in the Munsell color system of 4 or less, the sense of unity with the cleaning article 10, the design, and the cleaning feeling with a powerful image are further improved. It becomes possible. It is preferable that at least the entire handle portion 21 of the cleaning tool 20 includes a handle portion, and the lightness in the Munsell color system is 4 or less. There may be transparent parts in the part. The upper surface of the universal joint 23 and the cleaning unit 22 may have a lightness in the Munsell color system of 4 or less, and the surrounding area of the cleaning unit 22 and the cleaning surface may have a lightness of 4 or more. it can. The brightness of the sheet holding portion 24 may be 4 or more.

  Further, since the cleaning tool 20 and the cleaning article 10 have the same color tone, the sense of unity, unity and presence as the cleaning tool increase, and the cleaning article 10 can easily follow the surface to be cleaned far from the hand. Become. The effect which prevents the incorrect mounting | wearing which attaches the cleaning article 10 to another cleaning tool is also acquired. Furthermore, when placed in a living space such as a living room, the effect of not impairing the interior design is obtained.

  In the present embodiment, the cleaning article 10 can be used for cleaning a surface to be cleaned such as a flooring floor in the state where the cleaning article 10 is attached to the cleaning unit 22 of the cleaning tool 20, for example, like a normal mop cleaning tool. it can. The long fiber aggregate 11 of the cleaning article 10 is formed by aggregating a large number (innumerable) of long fibers 12, and preferably by three-dimensionally opening the large number of long fibers 12 in a three-dimensional direction at random. When the surface to be cleaned is cleaned by raising the fluff and raising it into a three-dimensional shape, a gentle and soft feel to the surface to be cleaned can be obtained. Further, while facilitating the cleaning of a narrow gap, and collecting dust and dirt on the surface to be cleaned wiped up into the raised three-dimensional long fiber assembly 11 in a three-dimensional manner, The surface to be cleaned will be cleaned.

  And according to the cleaning article 10 of the present embodiment, when cleaning the surface to be cleaned, the cleaning feeling is improved by recalling a powerful image at the time of cleaning while maintaining a gentle and soft feel to the surface to be cleaned. It becomes possible.

  That is, according to the present embodiment, the cleaning article 10 has a long length due to the action of the long fibers 12 constituting the long fiber assembly 11 being long fibers having a lightness of 4 or less in the Munsell color system. It is possible to perform cleaning on the surface to be cleaned with a substantial cleaning feeling while recalling a powerful image while maintaining a gentle and soft touch on the surface to be cleaned by the fiber assembly 11. The strong image of the long fiber aggregate 11 tends to increase the pressure applied to the cleaning article 10 and increase the contact time with the surface to be cleaned, thus improving the cleaning feeling. Become. Since the long fiber aggregate 11 can be visually recognized in the state of being mounted on the cleaning tool 20 as described above, the tendency becomes stronger when the long fiber assembly 11 is mounted on the cleaning unit 22 of the cleaning tool 20 and used.

  Further, according to the present embodiment, when the lightness in the Munsell color system of the long fiber aggregate 11 is 4 or less, the collection property is recovered by removing dust and dirt accumulated inside by shaking off. In this case, it is possible to effectively improve the ease of identifying the refreshability. Moreover, when the lightness in the Munsell color system of the long-fiber aggregate 11 is 4 or less, the cleaning article 10 can obtain an unprecedented high-class feeling. From these viewpoints, the lightness of the long fiber aggregate 11 in the Munsell color system is 4 or less, and more preferably 3 or less.

  The present invention is not limited to the above-described embodiment, and various modifications can be made. For example, the base sheet 13 may have the same brightness in the Munsell color system as the long fiber aggregate 11. Further, the cleaning article of the present invention is not necessarily formed by joining the long fiber aggregate to the base sheet, and only by using the long fiber aggregate by devising the shape of the long fiber aggregate. Cleaning articles can also be formed. The cleaning article of the present invention is not necessarily used by being mounted on the cleaning portion of the cleaning tool, and the surface to be cleaned can be cleaned using only the cleaning article. Further, the long fiber aggregate 11 may partially include long fibers having a lightness of 4 or more in the Munsell color system.

  Further, the cleaning article and the cleaning tool are not limited to those of the above-described embodiment. For example, as shown in FIGS. 5 (a) and 5 (b), a handy type cleaning tool 30 is used with a cleaning article 10 ′ made of a long-fiber assembly 11 ′ having a lightness of 4 or less in the Munsell color system. Thus, for example, a surface to be cleaned at a high position such as a wall, a ceiling, or a lighting fixture can be cleaned. The cleaning tool 30 of another form shown to Fig.5 (a) is provided with the handle | pattern part 31 and the insertion part 32, and the insertion part 32 was formed of the base material sheet 13 'for cleaning. It can be used in a state where it is inserted into the 10 'handle insertion portion 33 and the cleaning article 10' is mounted. Also in the cleaning tool 30 of another embodiment shown in FIG. 5, the base sheet 13 'has a higher brightness in the Munsell color system than the long fiber aggregate 11'. As in the cleaning tool 20 of the above embodiment, the brightness of the Munsell color system of at least the handle 31 is 4 or less and the cleaning tool 30 of the other embodiment is 3 or less. preferable.

  The cleaning article 10 ′ includes a fiber layer 34 made of a fiber bundle of long fibers 12 ′ on the outer surface opposite to the handle insertion portion 33 of each of the two base sheet 13 ′ forming the handle insertion portion 33. Are joined through one line-like sheet joining portion 15 ′ which also serves as a fiber joining portion, preferably one or more layers, so that the outer surface of each of these two base sheet 13 ′ It is formed in a state in which the long fiber aggregate 11 'is fixed to. The fiber bundles forming each fiber layer 34 are substantially oriented in the width direction of the handle insertion portion 33 by the base sheet 13 ′. Each fiber layer 34 has a substantially rectangular shape in plan view, and is substantially the same shape. The fiber length of the fiber bundle constituting each fiber layer 34 is preferably 30 to 150 mm, and more preferably 50 to 120 mm, from the viewpoint of dust entanglement. For example, the cleaning article 10 ′ by the long fiber aggregate 11 ′ having a lightness of 4 or less in the Munsell color system shown in FIG. 5 (b) can be sufficiently removed by using, for example, a known fiber opening device. By making the three-dimensional opening, the long fiber aggregate 11 ′ can be formed into a cylindrical three-dimensional shape as shown in FIG. 5C, for example.

  Also by the cleaning article 10 ′ shown in FIGS. 5 (b) and 5 (c), the long fiber aggregate 11 ′ has a lightness of 4 or less in the Munsell color system. It is possible to perform cleaning on the surface to be cleaned with a considerable cleaning feeling while recalling a powerful image while maintaining a gentle and soft feeling on the surface to be cleaned. In particular, while the walls and ceiling are often light-colored, the long-fiber aggregate 11 'is dark, so that the cleaning article 10' can be easily seen and the surface to be cleaned can be easily cleaned. Become. Since the long fiber aggregate 11 ′ is present on the outer surface of each of the two base sheet 13 ′, the long fiber aggregate 11 ′ is mounted with the cleaning article 10 ′ mounted on the cleaning tool 30. It can be easily visually recognized.

  Further, in the cleaning article 10 ′ shown in FIG. 5B, the brightness in the Munsell color system of at least the handle 31 of the cleaning tool 30 is 4 or less. In the case of the type, it is easy to see the arrival point of the cleaning article 10 ′, and it becomes easy to clean the surface to be cleaned. Here, in particular, the handy-type cleaning tool 30 includes a normal type and an expansion / contraction type, for example, an expansion / contraction type, and when the handle 31 has a direction switching button or the like. The part such as a button can have a lightness of 3 or more, and the part other than the button can have a lightness of 4 or less.

  Further, the lightness in the Munsell color system of at least one long fiber aggregate 11 ′ may be 4 or less. For example, as shown in FIG. 5B, the Munsell color of long fiber aggregates 11 ′ on both outer surfaces is used. The lightness in the system may be 4 or less, and the lightness in the Munsell color system of the long-fiber aggregate 11 ′ on the outer surface of one side may be 4 or less. In addition, the base sheet 13 'may have the same brightness in the Munsell color system as the long fiber aggregate 11'.

  Hereinafter, although the cleaning article of the present invention will be described in more detail with reference to Examples and Comparative Examples, the present invention is not limited by the description of the following Examples and Comparative Examples.

[Cleaning articles of Examples 1 and 2 and cleaning articles of Comparative Example 1]
A cleaning article having the same configuration as that of the cleaning article shown in FIGS. 5B and 5C and having the color tone, composition, and Munsell measurement values of the long fibers and the base sheet as shown in Table 1 was implemented. The cleaning articles of Example 1 and Example 2 were obtained. Except that the lightness in the Munsell color system is 9, it has the same structure as the cleaning article shown in FIGS. 5B and 5C, and the color tone, composition, and Munsell measurement values of the long fibers and the base sheet are displayed. The cleaning article as in 1 was used as the cleaning article of Comparative Example 1.

The long fibers forming the long fiber aggregates of the cleaning articles of Examples 1 and 2 and the cleaning article of Comparative Example 1 have a core portion made of an uncolored polyester resin having a melting point of 240 ° C., and a sheath portion. It consists of a non-colored polyethylene resin having a melting point of 100 ° C. The pigment is blended in the core. The fiber fineness of the long fibers was 3.3 dtex, and the basis weight was 466 g / m ² .

As for the fiber which comprises the base material sheet of the articles | goods for cleaning of Examples 1 and 2, a core part consists of a non-colored polyester resin whose melting | fusing point is 240 degreeC, and a sheath part consists of a non-colored polyethylene resin whose melting | fusing point is 100 degreeC. . The pigment is blended in the core. The base sheet is an air-through nonwoven fabric using short fibers with a fiber fineness of 3.3 dtex and a fiber length of 38 mm, and the basis weight was 120 g / m ² . As for the fiber which comprises the base material sheet of the comparative example 1, a core part consists of a non-colored polyester resin whose melting | fusing point is 240 degreeC, and a sheath part consists of a non-colored polyethylene resin whose melting | fusing point is 100 degreeC. The base sheet is an air-through nonwoven fabric using short fibers with a fiber fineness of 3.3 dtex and a fiber length of 38 mm, and the basis weight was 120 g / m ² .

  The cleaning articles of Examples 1 and 2 and the cleaning article of Comparative Example 1 are formed into a cylindrical three-dimensional shape as shown in FIG. 5C by three-dimensionally opening the long fiber assembly. The maximum load value was calculated by measuring the wiping load by the following method in the state where it was mounted on the handy type cleaning tool shown in FIG. Table 2 shows the calculation results.

[Cleaning load test method]
A 30 cm × 30 cm plate is placed on a detection table provided with four load cells whose electrical resistance changes according to the strain. Since a voltage signal corresponding to the strain is output from the plate on the detection table, the wiping load is detected by amplifying this voltage signal and digitizing it. The cleaning article of Examples 1 and 2 and the cleaning article of Comparative Example 1 are respectively attached to the cleaning tool shown in FIG. 5A, and three persons, an evaluator A, an evaluator B, and an evaluator C, are attached. The evaluator measured the wiping load (kgf) when the plate on the detection table was wiped, and calculated each maximum load value. The cleaning articles of Examples 1 and 2 and the cleaning article of Comparative Example 1 were tested eight times each by three evaluators. Table 2 shows the maximum load obtained by the eight tests. The average value is shown. The test conditions were a wiping stroke of 20 cm, a wiping frequency of 4 reciprocations in the horizontal direction, and a wiping time of 5 seconds.

  According to the calculation results shown in Table 2, when using the cleaning articles of Examples 1 and 2 according to the present invention, compared to the case of using the cleaning article of Comparative Example 1, a powerful image at the time of cleaning It can be inferred that the cleaning feeling can be improved by recalling the above.

10, 10 'Cleaning article 11, 11' Long fiber aggregate 11a Core part 11b Sheath part 12, 12 'Long fiber 13, 13' Base sheet 14 Fiber joined part 15, 15 'Sheet joined part 16 Linear cut part 17 Flap parts 20 and 30 Cleaning tool 21 Handle part 22 Cleaning part 23 Universal joint 24 Sheet holding part 31 Handle part 32 Insertion part 33 Handle insertion part 34 Fiber layer X Direction perpendicular to the orientation direction of long fibers Y Orientation direction of long fibers

Claims (10)

A cleaning article formed using a long fiber assembly in which long fibers are assembled,
A cleaning article comprising a long fiber aggregate having a lightness of 4 or less in the Munsell color system.   The cleaning article according to claim 1, wherein the long fiber aggregate is formed by aggregating long fibers oriented in one direction.   The cleaning article according to claim 1 or 2, comprising a base sheet, wherein the long-fiber aggregate is formed by being bonded to the base sheet.   The cleaning article according to claim 3, wherein the base sheet has a higher brightness in the Munsell color system than the long fiber aggregate.   The cleaning article according to any one of claims 1 to 4, wherein the long fiber is a resin-made fiber having a core-sheath structure including a core part and a sheath part.   The cleaning article according to claim 5, wherein the core is colored.   The cleaning article according to claim 5 or 6, wherein the core portion is made of a polyester resin, and the sheath portion is made of a polyethylene resin.   The cleaning article according to claim 1, wherein the long fibers are black.   The cleaning article according to any one of claims 1 to 8, wherein the cleaning article is used by being attached to a cleaning portion of a cleaning tool including a handle portion and a cleaning portion.   The cleaning article according to claim 9, wherein at least the handle portion of the cleaning tool has a brightness in the Munsell color system of 4 or less.