This patent application is the national phase of PCT/EP2011/005199, filed Oct. 17, 2011 which claims the benefit of German Patent Application No. 10 2010 054 010.2, filed Dec. 9, 2010.
The invention concerns a mop including a mop head with at least one cleaning strip, which is attached at one end to the mop head and which has a free end. The cleaning strip has at least one cleaning surface, on which raised cleaning islands are disposed at distances from each other, the cleaning islands being surrounded on all sides by storage spaces for holding soil.
A mop such as generally described above is known. The cleaning surface of the mop has congruently shaped cleaning islands that are uniformly distributed. Congruently shaped storage spaces for holding soil are disposed around the cleaning islands.
However, it may be observed that the soil particles that are removed from the surface that is being cleaned have different sizes. Soil particles of different sizes cannot be held very effectively by the congruently shaped cleaning islands and the congruently shaped storage spaces. For example, larger soil particles, such as long hairs, cannot be held in small storage spaces, while fine dust is retained in large storage spaces. In each of these cases the cleaning result is not very satisfactory.
A general object of the invention is to provide an improved mop of the kind described above that enables soil particles of different sizes to be efficiently removed from the surface being cleaned and held and retained in the storage spaces.
To this end, the storage spaces may be configured such that they become steadily smaller starting from the end of the cleaning surface facing the mop head in the direction of mopping of the free end. Advantageously, when mopping a surface, larger soil particles, for example, long hairs, can be first held in the large storage spaces that lie at the front relatively closer to the mop head. Smaller soil particles, for example, dust, pass by the larger storage spaces largely unhindered and arrive at the smaller storage spaces that lie farther back in the direction of mopping. The smaller soil particles accumulate in these smaller storage spaces that are disposed relatively closer to the free end. The smallest soil particles, for example, very fine dust, pass by even these storage spaces and are held either in the smallest storage spaces or in the cleaning islands themselves. One mop is thus suitable for removing and holding soil particles of different sizes from a surface to be cleaned, thereby producing an especially good cleaning result.
The storage spaces that are adjacent to each other in a direction transverse to the direction of mopping can have a uniform size. As a result, the production of the mop is simple from the standpoint of manufacturing technology and is less costly with regard to economics.
To achieve a steady decrease in size of the storage spaces in the direction of mopping of the free end of the at least one cleaning strip, the cleaning islands can be configured so as to be steadily larger starting from the end of the cleaning surface facing the mop head in the direction of mopping of the free end. Advantageously, for holding very small soil particles (e.g., fine dust particles) large cleaning islands that bind the fine dust particles are provided in addition to the small storage spaces that surround the large cleaning islands.
In order to do a good job of mopping large, evenly soiled surfaces with uniform cleaning results in the direction of mopping, only the cleaning islands adjacent to each other in a direction transverse to the direction of mopping can be configured to have a uniform size. Through this, practically the same hitherto described effect is achieved as in the design in which the storage spaces adjacent to each other in the direction transverse to the direction of mopping have a uniform size.
The cleaning surface can have, in the area of the free end of the cleaning strip, only one central cleaning island disposed centrally in a direction transverse to the direction of mopping on the cleaning surface. The central island can be surrounded in a substantially arc shape by other cleaning islands in the direction of the mop head.
The radial distances between the adjacent cleaning islands can become steadily larger starting from the central cleaning island in the direction against or opposite the direction of mopping, thus in the direction of or towards the mop head. The direction of mopping extends in the radial direction relative to the central cleaning island. Even in the case of mopping movements in the form of a figure eight, as is conventional in cleaning with a mop, this arrangement results in the storage spaces lying around the central cleaning island being smaller than the storage spaces disposed radially further along in the direction of or towards the mop head.
Each of the cleaning islands and/or the central cleaning island can be configured substantially round. This can permit soil particles to easily pass by the islands without remaining attached to them. Attachment of the soil particles to the islands can prevent flow in the direction of or towards the free end/smaller storage spaces.
The cleaning islands disposed adjacent to each other in the direction transverse to the direction of mopping can form an island row, where the cleaning islands of the island row are staggered in the gaps between the cleaning islands of the adjacent island row in the direction of mopping. If the size of the cleaning islands is appropriately matched, this arrangement with the cleaning islands that are adjacent in the direction of mopping in gaps ensures that no un-mopped strips will remain even with a single pass of the mop over a surface to be cleaned.
The distances and/or the radial distances between the adjacent cleaning islands can be 0.1 mm to 50 mm. Such distances are advantageous in order to form storage spaces that are well suited for holding ordinary household soil.
The cleaning islands can cover 1% to 80% of the cleaning surface. More preferably, the cleaning islands can cover 5% to 50% of the cleaning surface. Coverage of up to 50% is sufficient for most uses. Such a design is advantageous because the material of which the cleaning islands are made is frequently costly. With such a configuration the cleaning device can be made relatively cheaply.
The cleaning islands can comprise flock fibers. Using flock fibers can produce a good cleaning performance. However, the flocking of carrier materials with flock fibers is expensive in comparison with the carrier material itself. A large portion of the costs for flocking is made up of the materials themselves, i.e., the flock fibers and the adhesive that is needed to affix the flock fibers to the carrier material. In combination with the arrangement of the storage spaces and the cleaning islands, only a comparably small amount of flock fibers is needed to achieve good cleaning performance, so the cleaning device can be made cheaply.
The flock fibers of each cleaning island can have different lengths and can be disposed substantially perpendicular to the cleaning surface. For example, a cleaning island can have flock fibers with only two different lengths. The lengths can be, for example, 1 mm and 3 mm. This arrangement provides an additional possibility of a three-dimensional structure for soil removal and soil accommodation. Each cleaning island thus has a more highly structured surface. It was found that when flock fibers of these lengths are used, standard household soil is picked up on average 23% better than when using a cleaning device that has cleaning islands with flock fibers of the same length.
The flock fibers of different lengths can be substantially homogeneously distributed for formation of the cleaning island.
The flock fibers of a cleaning island can be formed by viscose fibers and/or polyamide fibers. It is advantageous for the cleaning islands to retain their three-dimensional flocking structure even during wet mopping. A flock fiber mixture of viscose and polyamide has good water absorbency properties. The water absorbent viscose fibers would, without the additional use of fibers with a support effect, for example, polyamide fibers, lie against the carrier material in a wet state, in which the pronounced three-dimensional structure of the flocking would be lost. Flock fibers of polyamide, and also polypropylene or polyethylene, absorb only small amounts of water and thus remain in their perpendicular position standing out from the surface of the cleaning strip. Accordingly, these kinds of fibers provide a support structure for the viscose fibers, with a fraction of support fibers of ≧20% with respect to the viscose fibers being able to provide this support function. Depending on the particular application, especially how the surface to be cleaned is made and of what material it consists, and further depending on what kind of soil is supposed to be removed and held by the cleaning device, an advantageous for a mixture ratio of viscose fibers to polyamide fibers per cleaning island was found to be 80:20 to 20:80.
The cleaning strip also can be flocked with the flock fibers. Preferably, the cleaning strip consists of a nonwoven material. The flocking of the cleaning strip with flock fibers can, for example, take place electrostatically. The flock fibers can be attached generally perpendicularly relative to the cleaning strip material, with one end of the fibers being in an adhesive layer. With this configuration, the cleaning strip with the flocked fibers has a three-dimensional structure and an increase in surface area. This increase in surface area can permit soil to be removed from the cleaned surface and held in the storage spaces especially well both in dry mopping and in wet mopping. Electrostatic flocking has the advantage that it achieves a high flocking density. The coverage of the cleaning strip by the cleaning islands should not exceed 80% in order to achieve a sufficient three-dimensionality of the surface structure and to keep the production costs of the mop as low as possible.
An exemplary embodiment of a mop in accordance with the invention is described below in more detail with reference to
The cleaning islands 6 on the cleaning strips 2 are in each case spaced a distance 7 relative to each other. The cleaning islands 6 are surrounded on all sides by storage spaces 8 for holding soil particles. The distances 7 between the adjacent cleaning islands 6 in the illustrated embodiment are between 0.1 mm and 50 mm, with the cleaning islands 6 covering about 50% of the cleaning surface 5.
The cleaning islands 6 include flock fibers. The flock fibers of each individual island row 12 have different lengths in order to be able to make additional surface area available for holding soil particles. In the illustrated embodiment, the flock fibers of each cleaning island 6 include viscose fibers and polyamide fibers, where the mixture ratio per cleaning island 6 is about 50:50.
In the illustrated embodiment, the cleaning strips 2 are congruently shaped. Generally, however, the cleaning strips 2 could also be different from each other, for example by varying the size and/or the shape of the cleaning islands 6 and/or the storage spaces 5 from cleaning strip 2 to cleaning strip 2.
In the illustrated embodiment, the storage spaces 5 become steadily smaller starting from the end 3 of the cleaning surface 5 facing the mop head 1 in the mopping direction 9 of the free end 4. Also, the cleaning islands 6 become steadily larger in the mopping direction 9 of the free end 4 starting from the end 3 of the cleaning surface 5 facing the mop head 1.
As the mop is moved in the mopping direction 9, coarse soil particles like hairs or crumbs first reach the large storage spaces 8, and finer soil particles like dust or pollen pass by the larger storage spaces 8 defined by the smaller cleaning islands 6 and are held in the smaller storage spaces 8. Fine dust particles can be held not only in the smallest storage spaces 8, but also in the cleaning islands 6 themselves.
Several cleaning islands 6 are disposed adjacent to each other in the direction transverse to the direction of mopping 9 so as to form an island row 12. Several island rows 12 are adjacent to each other and extend transverse to the direction of mopping 9, with the cleaning islands 6 of each island row 12 being staggered in the gaps between the cleaning islands 6 of the adjacent island row 12 in the mopping direction 9. With this arrangement, when mopping in the mopping direction 9, no un-mopped strips remain on the surface that is to be cleaned (not shown).
As already stated, the reverse cleaning surface 5 of the cleaning strip 2 can also be flocked with flock fibers like the front side of the cleaning surface 5.
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Number | Date | Country | Kind |
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10 2010 054 010 | Dec 2010 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2011/005199 | 10/17/2011 | WO | 00 | 7/16/2013 |
Publishing Document | Publishing Date | Country | Kind |
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WO2012/076075 | 6/14/2012 | WO | A |
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