Patent Grant
8973204
This is a U.S. national phase application under 35 U.S.C. §371 of International Patent Application No. PCT/JP2007/52111 filed Feb. 7, 2007 and claims the benefit of Japanese Application No. JP2006-031123 filed Feb. 8, 2006. The International Application was published in Japanese on Aug. 16, 2007 as International Publication No. WO 2007/091591 under PCT Article 21(2), the content of which is incorporated herein in its entirety.
The present invention relates to a cleaning tool, and more particularly to a cleaning tool having a cleaning element for cleaning a surface to be cleaned inside a room or a vehicle.
Various types of cleaning tools having a sheet-type cleaning element for wiping a surface to be cleaned are known. For example, Japanese non-examined laid-open Patent Publication No. 9-154791 discloses a cleaning tool having cleaning fabric and a holder that detachably holds the cleaning fabric inserted into a holding space of the cleaning fabric. This cleaning tool is capable of wiping a surface to be cleaned by using the cleaning fabric held via the holder. However, in designing a cleaning element or a cleaning tool of this type having the cleaning element, it is particularly required to provide an effective technique for enhancing its cleaning effect.
It is, accordingly, an object of the present invention to provide an effective technique for enhancing the cleaning effect in a cleaning tool having a cleaning element for cleaning a surface to be cleaned.
The above-described problem can be solved by the features of the claimed invention. This invention can be applied to the construction of cleaning tools for cleaning surfaces to be cleaned (floors, walls, ceilings, external walls, furniture, clothes, curtains, bedding, home electric appliances, etc.) inside and outside of houses, apartments, buildings, factories, vehicles, etc. or surfaces of human body parts to be cleaned. These surfaces to be cleaned may be either flat or curved, uneven or stepped or notched or otherwise irregular.
The cleaning element according to this invention is provided in order to solve the above-described problem. The cleaning element has a fiber bundle and a non-woven fabric laminated together. The cleaning element includes at least a tubular part, a receiving space, a brush part and a fiber extending region. In this invention, as for the structure having the fiber bundle and the non-woven fabric laminated together, two- or more-layer structure can be appropriately selected.
The non-woven fabric in this invention has a sheet-like configuration formed by fixing or entangling fibers by mechanical, chemical or heat treatment. Typically, the non-woven fabric partly includes thermoplastic fibers and thus can be fusion bonded.
The “fibers” in this invention are elements of yarn, textile or the like and defined as being thin and flexible fibers having a substantially longer length compared with the thickness. Typically, a long continuous fiber is defined as a filament and a short fiber as a staple. Further, the “fiber bundle” in this invention is a single fiber structure formed by the above-mentioned fibers, a fiber structure having the above-mentioned fibers aligned in the length direction and/or the radial direction (twist yarn, spun yarn, yarn to which a plurality of filaments are partially connected), or an assembly of the fiber structures. Typically, the fiber bundle is formed of polyethylene (PE), polypropylene (PP), polyethylene terephthalate (PET), nylon, rayon or the like. In practical use, an assembly of filaments formed by opening a tow is frequently used as the fiber bundle.
The tubular part in this invention is a long part formed by folding back the cleaning element into a tubular shape such that the non-woven fabric of the cleaning element is located inside. The sectional shape of the tubular part widely includes circular, elliptical, triangular, rectangular, polygonal and other various shapes. Further, the tubular part may have a closed section or an open section which is not completely closed.
The receiving space in this invention is defined inside the tubular part and configured as a region (space) in which a holding part for holding the cleaning element is removably received. When the holding part for holding the cleaning element is in the mounted state or in the state received in the receiving space, the cleaning element is held by the holding part. Further, the user can replace the cleaning element by removing the cleaning element from the holding part as necessary. The cleaning element according to this invention may be of disposable type designed for single use, disposable type designed for multiple use which can be used several times, while retaining dust which has been removed from the surface to be cleaned, on a brush part, or reusable type which can be reused by washing.
The brush part in this invention forms a brush-like cleaning area in a region of the cleaning element other than the tubular part. The brush part has the fiber bundle on the outer side (on the surface side) and the non-woven fabric on the inner side. The brush part having such a construction is effective in sweeping away dirt and dust on the surface to be cleaned. The non-woven fabric of the brush part may be preferably configured as strips, and more preferably, the strips of the non-woven fabric may have a zigzag shape which can easily trap dust.
The fiber extending region in this invention is configured as a region in which a plurality of fibers extend parallel in a predetermined direction in its entirety or part of the fiber bundle disposed on an outer surface of the tubular part. The fiber extending region forms a second cleaning area other than the brush part. Thus, in the cleaning element in this invention, fibers are arranged regularly in its extending direction in the fiber extending region. Therefore, in cleaning operation, dirt attached or stuck to the surface to be cleaned can be efficiently scrubbed or scraped away by moving the fiber extending region in contact with the surface to be cleaned and in a direction transverse to the extending direction of the fibers. Particularly by using a fiber bundle having higher rigidity, especially higher cleaning effect can be obtained.
With such a construction, in addition to the brush part, the fiber bundle which is disposed on the outer surface of the tubular part can also be provided with a cleaning function, so that the cleaning effect can be enhanced. Specifically, the cleaning element of this invention is rationally configured to have the tubular part having not only an inherent function of receiving the holding part for holding the cleaning element but an additional cleaning function.
In the fiber extending region, a plurality of fibers may extend parallel in a direction transverse to the extending direction of the long tubular part extending along the extending direction of the holding part.
With this construction, in cleaning operation, dirt attached or stuck to the surface to be cleaned can be efficiently scrubbed or scraped away by moving the fiber extending region in contact with the surface to be cleaned and along the extending direction of the tubular part.
The fibers extending in the fiber extending region may contain brush-like fibers forming the cleaning area. The brush-like fibers may be formed in the fiber bundle, in its entirety or in part, on the outer surface of the tubular part. Such brush-like fibers are effective in sweeping away dirt and dust on the surface to be cleaned. Further, the brush-like fibers may be formed by cutting the fiber bundle of the cleaning element. Alternatively, fibers may be subjected to a raising process to form the brush-like fibers in advance and thereafter joined to the fiber bundle.
With this construction, the fiber bundle on the outer surface of the tubular part is provided with the same function as the brush-like part, so that regions which can be used for cleaning operation can be increased. By forming the brush-like fibers over the entire fiber bundle on the outer surface of the tubular part, the function of sweeping away dirt and dust on the surface to be cleaned can be further enhanced. Further, by forming the brush-like fibers in the fiber bundle in part on the outer surface of the tubular part, the cleaning element having higher versatility can be realized which also has the function of sweeping away with the brush-like fibers of the fiber bundle and the function of scrubbing away with fibers other than the brush-like fibers of the fiber bundle.
Further, the brush part may extend from the long tubular part extending along the extending direction of the holding part, in a direction transverse to the extending direction of the tubular part. The “extending direction of the brush part” here is defined as a direction in which fibers of the fiber bundle forming the brush part extend. It is only necessary for the extending direction of the brush part to be a direction transverse to the extending direction of the tubular part. Therefore, the extending direction widely includes not only the direction generally perpendicular to the extending direction of the tubular part, but a direction inclined at a predetermined angle with respect to the extending direction of the tubular part.
With such a construction, when the tubular part is disposed horizontally, the brush part can be arranged to extend vertically downward from the tubular part. Therefore, the fibers of the brush part can be effectively used for cleaning, so that the action of sweeping away dirt and dust on the surface to be cleaned can be easily performed.
Further, in the above-described cleaning element, the fiber bundle may face the side of the brush part which faces the surface to be cleaned and the tubular part is disposed on the face of the brush part which faces away from the surface to be cleaned.
With this construction, the cleaning element is provided in which the tubular part is disposed on the side of the brush part opposite to the surface to be cleaned.
The long tubular part may be bent at a predetermined point in its longitudinal direction into a U-shape such that two receiving spaces for receiving the holding part are formed in both end portions of the tubular part. By using the two receiving spaces as spaces for receiving two holding parts, a construction in which the holding parts do not easily come off the receiving spaces can be realized. Further, an upper surface of the U-shaped area may form the fiber extending region. With this construction, the fiber extending region of the tubular part can be increased in area per unit length, so that the cleaning effect can be increased.
With this construction, the cleaning element can be provided in which the long tubular part is U-shaped such that two receiving spaces for receiving the holding part are formed in both end portions of the tubular part and an upper surface of the U-shaped area forms the fiber extending region.
Further, in the cleaning element, the cleaning element may have a two-layer structure consisting of two layers of the fiber bundle and the non-woven fabric.
With this construction in which the cleaning element has a two-layer structure, the number of materials can be reduced, so that the cleaning element can be provided with a rational construction which in turn reduces manufacturing costs.
Further, based on this invention, a cleaning tool is provided which includes at least a cleaning element, a receiving space, a holding part and a grip part. The cleaning element further includes at least a tubular part, a brush part and a fiber extending region.
In this case, the cleaning element has a fiber bundle and a non-woven fabric laminated together, and the receiving space is provided in the cleaning element. The holding part is removably received in the receiving space of the cleaning element and serves to hold the cleaning element. Further, the grip part is connected to the holding part and designed to be held by a user.
Particularly, the cleaning element includes a long tubular part which is formed into a tubular shape by folding back the cleaning element such that the non-woven fabric is located inside and thus forms the receiving space, and a brush part which forms a brush-like area in a region of the cleaning element other than the tubular part. Further, the fiber bundle disposed on an outer surface of the tubular part includes a fiber extending region in which a plurality of fibers extend parallel in a predetermined direction and the fiber extending region forms a second cleaning area other than the brush part.
With such a construction, in the cleaning element, in addition to the brush part, the fiber bundle which is disposed on the outer surface of the tubular part can also be provided with a cleaning function, so that the cleaning effect can be enhanced. Specifically, the cleaning tool of this invention has the cleaning element which is rationally configured to have the tubular part having not only an inherent function of receiving the holding part for holding the cleaning element but an additional cleaning function.
In the cleaning tool, the extending directions of the holding part, the grip part and the tubular part may generally coincide with each other. Further, in the fiber extending region of the cleaning element, a plurality of fibers may extend parallel in a direction transverse to the extending direction of the tubular part.
With this construction, when performing the cleaning operation, dirt attached or stuck to the surface to be cleaned can be efficiently scrubbed or scraped away by moving the fiber extending region in contact with the surface to be cleaned and along the extending direction of the tubular part.
In the cleaning tool, the fibers extending in the fiber extending region of the cleaning element may contain brush-like fibers forming the cleaning area.
With this construction, the fiber bundle on the outer surface of the tubular part is provided with the same function as the brush-like part in the cleaning element, regions which can be used for cleaning operation can be increased. By forming the brush-like fibers over the entire fiber bundle on the outer surface of the tubular part, the function of sweeping away dirt and dust on the surface to be cleaned can be further enhanced. Further, by forming the brush-like fibers in the fiber bundle in part on the outer surface of the tubular part, the cleaning tool having higher versatility can be realized which also has the function of sweeping away with the brush-like fibers of the fiber bundle and the function of scrubbing away with fibers other than the brush-like fibers of the fiber bundle.
In the cleaning tool, the extending directions of the holding part, the grip part and the tubular part may generally coincide with each other. Further, the brush part of the cleaning element may extend from the long tubular part in a direction transverse to the extending direction of the tubular part.
With this construction, when the tubular part of the cleaning element is disposed horizontally, the brush part can be arranged to extend vertically downward from the tubular part. Therefore, the fibers of the brush part can be effectively used for cleaning, so that the action of sweeping away dirt and dust on the surface to be cleaned can be easily performed.
In the cleaning tool, the fiber bundle may face the side of the brush part of the cleaning element which faces the surface to be cleaned and the tubular part may be disposed on the face of the brush part which faces away from the surface to be cleaned.
With this construction, the cleaning tool is provided with the cleaning element in which the tubular part is disposed on the side of the brush part opposite to the surface to be cleaned.
In the cleaning tool, the long tubular part of the cleaning element may be bent at a predetermined point in its longitudinal direction into a U-shape such that two receiving spaces are formed in both end portions of the tubular part. By using the two receiving spaces as spaces for receiving two holding parts, a construction in which the holding parts do not easily come off the receiving spaces can be realized. Further, an upper surface of the U-shaped area may form the fiber extending region. With this construction, the fiber extending region of the tubular part can be increased in area per unit length, so that the cleaning effect can be increased.
With this construction, the cleaning tool can be provided with the cleaning element in which the long tubular part is U-shaped such that two receiving spaces for receiving the holding part are formed in both end portions of the tubular part and an upper surface of the U-shaped area forms the fiber extending region.
In the cleaning tool, the cleaning element may have a two-layer structure consisting of two layers of the fiber bundle and the non-woven fabric.
With this construction in which the cleaning element has a two-layer structure, the number of materials can be reduced, so that the cleaning tool can be provided with a rational construction which is reduced in manufacturing costs.
As described above, according to this invention, in a cleaning tool having a cleaning element for cleaning a surface to be cleaned, particularly a fiber bundle on the outer surface of a tubular part of the cleaning element includes a fiber extending region in which a plurality of fibers extend parallel in a predetermined direction, and the fiber extending region forms a second cleaning area other than the brush part. By provision of this construction, a cleaning element and a cleaning tool which have higher cleaning effect can be provided.
A representative embodiment of the present invention is now described with reference to the drawings. First, the structure of a cleaning tool 10 according to this embodiment is explained with reference to
As shown in
Further, in this embodiment, the brush part 103 extends vertically downward from the tubular part 101 when the holder 200 extends horizontally or a holding part 210 and a grip part 220 which are described below extend substantially horizontally. This horizontally extending state of the holder 200 coincides with the state of the holder 200 with the grip part (the grip part 220 described below) held by the user for cleaning operation. Therefore, the brush part 103 tends to extend downward, which allows full use of the fibers of the brush part 103 and is thus effective in sweeping away dirt and dust on the surface to be cleaned.
(Constriction of the Fiber Bundle 110)
The fiber bundle 110 is a single fiber structure formed by fibers, a fiber structure having fibers aligned in the length direction and/or the radial direction (twist yarn, spun yarn, yarn to which a plurality of filaments are partially connected), or an assembly of the fiber structures. The fiber bundle 110 partially includes thermoplastic fibers and can be fusion bonded. The fibers forming the fiber bundle 110 are elements of yarn, textile or the like and defined as being thin and flexible fibers having a substantially longer length compared with the thickness. Typically, a long continuous fiber is defined as a filament and a short fiber as a staple. The fiber bundle 110 is a feature that corresponds to the “fiber bundle” according to this invention. The fiber bundle 110 is typically formed of polyethylene (PE), polypropylene (PP), polyethylene terephthalate (PET), nylon, rayon or the like. In practical use, an assembly of filaments formed by opening a tow is frequently used as the fiber bundle 110. It is particularly preferable that the fiber bundle 110 comprises conjugated fibers having a core of polypropylene (PP) or polyethylene (PE) and a core covering sheath of polyethylene (PE). Further, it is preferable for the filaments of the fiber bundle 110 to have a fineness of 1 to 50 dtex, and more preferably 2 to 10 dtex. The individual fiber bundle may contain fibers of generally the same fineness or of different finenesses. Further, in order to enhance the sweeping function, it is preferred to use a fiber bundle including fibers having higher rigidity or fibers having higher fineness.
Fibers forming the fiber bundle 110 are regularly arranged parallel to each other on the outer side of the tubular part 101. A fiber extending region in which the fiber bundle 110 extends is a feature that corresponds to the “fiber extending region” according to this invention. As shown in
Further, flat yarns or split yarns may be employed as the fiber bundle 110. The flat yarns are prepared by slitting a film into tapes and by stretching the tapes in the longitudinal direction. The split yarns are prepared by splitting a thermoplastic film resin in the direction perpendicular to the orientation direction of the resin so that the film is fibrillated and interconnected into a net shape. Alternatively, a non-woven fabric which is bulky and has low fiber density, such as a through-air bonded non-woven fabric, may be employed to form the fiber bundle 110.
Further, preferably, the fiber bundle 110 may be formed by using crimped fibers. Here, the crimped fibers are fibers subjected to a predetermined crimping process. With the fibers being crimped, the fiber bundle becomes bulky, and dust can be easily captured by the crimped portions. This structure can be realized especially by using crimped fibers opened from a tow.
With provision of the fiber bundle 110 having the above-described construction, the cleaning element 100 in this embodiment can perform a higher cleaning function since dirt is entangled between the fibers of the fiber bundle 110 or on the crimped portions of the fibers during cleaning operation using the cleaning element 100.
(Construction of the Non-Woven Fabric 120)
The non-woven fabric 120 has a sheet-like configuration formed by fixing or entangling fibers by mechanical, chemical or heat treatment. The non-woven fabric 120 partly includes thermoplastic fibers and thus can be fusion bonded. Further, the non-woven fabric 120 has a plurality of strips. The non-woven fabric 120 is a feature that corresponds to the “non-woven fabric” according to this embodiment. The non-woven fabric 120 may be manufactured by spun bonding, through-air bonding, thermal bonding, spun lacing, point bonding, melt blowing, stitch bonding, chemical bonding, needle punching or other similar processes. In order to enhance the sweeping function in cleaning operation, it is preferred to use a non-woven fabric having higher rigidity. The strips of the non-woven fabric 120 may have various shapes, such as zigzag and curved shapes. In order to enhance the cleaning function, preferably, the strips may have a zigzag shape which can easily trap dust.
Further, as an alternative to or in addition to the non-woven fabric, urethane, sponge, woven fabric, net, split cloth or other similar material may also be used in the form of strips.
With provision of the non-woven fabric 120 having the above-described construction, the cleaning element 100 in this embodiment can perform a higher cleaning function since dust is trapped between the strips or on the faces of the strips during cleaning operation using the cleaning element 100. Further, the non-woven fabric 120 has higher rigidity than the fiber bundle 110 and thus can perform a function of preventing the fiber bundle 120 from being fixed or entangled with each other. If the non-woven fabric 120 is formed by using crimped fibers, the non-woven fabric 120 disposed on the outer surface of the tubular part 101 can also be provided with a cleaning function.
The holder 200 has a function of holding the cleaning element 100 having the above-described function and includes at least an elongate holding part 210 and an elongate grip part 220. The holding part 210 is disposed on the front end of the grip part 220. The holding part 210 is removably inserted into the receiving space 102 of the tubular part 101 of the cleaning element 100 and serves to hold the cleaning element 100. In the embodiment shown in
Further, in this embodiment, in order to prevent the holding part 210 inserted into the receiving space 102 from easily coming off during use, stretch materials 130 are mounted on the both ends of the receiving space 102 of the tubular part 101. Each of the stretch materials 130 is non-woven fabric at least partly including thermoplastic fiber, or thermoplastic resin film, and is formed of materials having a stretching function, or of non-woven fabric containing a elastomer material, or of elastomer, urethane, rubber, etc.
The method of manufacturing the cleaning element 100 having the above construction is now described with reference to
(First Bonding Process)
As shown in
Further, as an alternative to the bonding line 142, a fusion-bonding face may be provided for surface fusion-bonding on the portion of the fiber bundle 110 which is surrounded by the bonding lines 140, 141. With this construction, the inner wall of the receiving space 102 of the tubular part 101 can be increased in rigidity and thus in smoothness. As a result, the operation of inserting the holding part 210 of the holder 200 into the receiving space 102 can be smoothly performed.
(Folding Process)
Next, as shown in
(Second Bonding Process)
Thereafter, the folded portions of the folded fiber sheet obtained by the folding process are fusion bonded together at the bonding line 145. As a result, the cleaning element 100 as shown in
As described above, the cleaning element 100 of this embodiment is of a two-layer structure consisting of the fiber bundle 110 and the non-woven fabric 120. Therefore, the number of parts and thus the manufacturing costs can be effectively reduced.
As for the construction of the holder 200, other than the construction in which the holding part 210 is configured as one rod-like or plate-like part as shown in
When the holder 300 as shown in
Further, as for the method of providing the two receiving spaces 102a, 102b in the tubular part 101, as alternatives to the method of dividing the one tubular portion of the tubular part 101 into two tubular portions as shown in
In the method shown in
In the cleaning element 100 formed by the methods shown in
Although the cleaning element 100 in the above embodiment is described as having a two-layer structure consisting of the fiber bundle 110 and the non-woven fabric 120, it can have a multilayer structure having another fiber layer in addition to the fiber bundle 110 and the non-woven fabric. For example, a three-layer structure can be used having the fiber bundle 110 and the non-woven fabrics 120 arranged on the both sides of the fiber bundle 110. With such a construction, the fiber bundle 110 which can easily contain air between fibers is sandwiched between the non-woven fabrics 120, so that the three layer can be fusion bonded while air inside the fiber bundle 110 is squeezed out as much as possible. Thus, the fusion bonding performance can be enhanced.
The cleaning tools 10, 20 having the above-described construction can be used in the same manner. Therefore, the usage of the cleaning tool 10 is explained here with reference to
(Sweeping Mode)
(Scrubbing Mode)
When the scrubbing part 101a gets dirty by the scrubbing movement of the tubular part 101, as shown in
Particularly, in this scrubbing mode, with the construction in which the fiber bundle 110 on the outer surface of the tubular part 101 is used to scrub away dirt, a higher cleaning effect can be obtained for the following reasons.
First, the fiber bundle 110 on the outer surface of the tubular part 101 has some rigidity and has a function of scrubbing tough dirt attached or stuck to the surface S to be cleaned.
Second, as explained by using
Third, the fiber bundle 110 has larger space between the fibers compared with the non-woven fabric 120. Therefore, scrubbed-away dirt can be introduced into this space and reliably caught there, and further a larger amount of dirt can be accumulated.
(Wiping Mode)
In wiping mode, the cleaning element 100 having the above-described construction which is further subjected to a cutting process is used.
As described above, by using the cleaning element 100 in this embodiment, cleaning operation can be performed at least in three modes. In this embodiment, not only the brush part 103 but the tubular part 101 is provided with a function as a cleaning area. As a result, a rational cleaning element can be realized in which regions of the cleaning element 100 to be used for cleaning operation can be maximized.
The present invention is not limited to the embodiment as described above, but rather, may be added to, changed, replaced with alternatives or otherwise modified. For example, the following provisions can be made in application of this embodiment.
In the above embodiment, the brush part 103 of the cleaning element 100 is described as extending vertically downward from the tubular part 101 when the holder 200 extends horizontally. However, in this invention, various changes can be made in the extending direction of the brush part 103. For example, the brush part 103 can be inclined a predetermined angle with respect to the extending direction of the tubular part 101, or the brush part 103 can extend laterally from the both sides of the tubular part 101.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2006-031123 | Feb 2006 | JP | national |
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/JP2007/052111 | 2/7/2007 | WO | 00 | 12/8/2008 |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2007/091591 | 8/16/2007 | WO | A |
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| Number | Date | Country |
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| 19835735 | Aug 1998 | DE |
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| Entry |
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| European Search Report from corresponding European Application No. 07708150.3, dated Jan. 22, 2010, 3 pages. |
| Number | Date | Country | |
|---|---|---|---|
| 20090172904 A1 | Jul 2009 | US |
