Patent Grant
9750384
This patent application is the national phase of PCT/EP2012/002110, filed May 16, 2012, which claims the benefit of German Patent Application No. 10 2011 107 648.8, filed Jul. 12, 2011.
The invention relates to flat wiping cloths.
WO 02/071 914 A1 discloses a textile layer that may be used as a covering for a dust mop. This textile layer has yarns into which silver is incorporated. The layer particularly has loops which protrude out of the layer.
DE 20 2004 020 313 U1 discloses a flat wiping cloth that is provided with an active ingredient for inhibiting or suppressing the growth of bacteria and/or viruses. Silver ions having antibacterial and antimicrobial properties are proposed in very specific terms. The disclosed flat wiping cloth has fibers coated with silver.
One disadvantage of the flat wiping cloths disclosed in these references is that the antimicrobial active agent is released relatively easily into the environment. After only a few washing operations, the silver coating has been removed almost completely from the fibers. As a result, the coating can no longer provide any antimicrobial and/or antibacterial effects.
A general object of the present invention is to provide a flat wiping cloth having an antimicrobial active ingredient that remains in the flat wiping cloth for as long as possible and configured so that the flat wiping cloth picks up soiling from moist surfaces particularly rapidly.
A flat wiping cloth for arrangement on a wiping cloth holder is provided that includes an elongated base body and an active ingredient which inhibits or suppresses the growth of bacteria and/or viruses that is allocated to the base body. Fibers, yarn or fringe are also allocated to the base body and the active ingredient is distributed in the material made up of fibers, yarns or fringe and/or distributed in a component of the base body. The fibers, yarns or fringe have a free end, which may be turned to face the surface to be cleaned.
According to the invention, it was first recognized that the active ingredient must be distributed within the material comprised of the fibers, yarns or fringe in order for it to remain on the flat wiping cloth as long as possible. Additionally, or alternatively, the active ingredient can be absorbed within the component, namely by being incorporated into it.
Washing operations then release the active ingredient incorporated in this way out of the matrix of fibers, yarns or fringe and/or the component only very slowly. Advantageously, a flat wiping cloth according to the invention can still exhibit an antimicrobial effect even after 200-1300 washing cycles at 60° C., in particular in disinfectant washings.
In addition, it has been recognized that fibers, yarns or fringe having a free end act as a type of wick, along which dirt dissolved in water can be easily transported and/or with which the dirt dissolved with water may bond. If the free ends are facing a moist surface to be cleaned, the dirt particles are absorbed surprisingly easily by the fibers, yarns or fringe.
The dirt absorbed and/or the dirt particles absorbed come in contact with the antimicrobial active ingredient so that the formation of unpleasant odors, mold or fungi is effectively suppressed or reduced even before the disinfectant washing which is usually performed daily.
The free ends, in contrast with closed ends and/or loops, not only produces a wick effect which accelerates the transport of soiling and water in the flat wiping cloth, but also prevents the catching of fibers, yarns or fringe on rough structures. Such rough structures may occur when cleaning wooden floors having splinters or nails and/or when cleaning safety tiles.
The flat wiping cloth according to the invention therefore allows problem-free cleaning of floors. The flat wiping cloth according to the invention picks up soiling from a moist surface with no problem and is characterized by a permanent wash-fastness.
The active ingredient can be homogeneously distributed within the material. To do so, the active ingredient could be introduced into a melt of polyester, polyamide, polypropylene or the like for fiber production or a similar material conventionally used for fiber production. The fibers, in particular microfibers, can be produced by extrusion after the active ingredient is homogeneously distributed in the melt. The active ingredient is then uniformly and homogeneously distributed within the fiber body. This ensures a gradual release of the active ingredient to the environment.
Against this background, the active ingredient could be present in a nanoscale form. A nanoscale active ingredient has particles whose maximum diameter is less than or equal to 1 μm. A nanoscale active ingredient makes available a particularly large surface area and may therefore interact particularly well with bacteria, viruses or microorganisms.
The active ingredient might comprise elemental silver or some other subgroup element. The active ingredient might be present as elemental silver. Elemental silver can be processed in a melt particularly easily. The active ingredient might comprise at least one subgroup element. Subgroup elements are characterized by an antimicrobial effect. In view of this, it is conceivable that multiple subgroup elements might be present jointly in the active ingredient to selectively counteract different bacterial species. In a series of experiments, it has been found that, with respect to the antimicrobial efficacy, there is a ranking of the substances used. In addition to silver, known options include mercury, copper, cadmium, chromium, lead, cobalt, gold, zinc and iron and manganese. Based on this, main group elements which have an antimicrobial effect could also be used.
The antimicrobial active ingredient might comprise a gold-silver mixture or might contain only a gold-silver mixture. Mixtures of this type have a particularly high antimicrobial efficacy. It has surprisingly been found that the presence of gold further increases the antimicrobial effect of silver. In view of this, silver can be doped with gold. Islands or clusters comprising either only gold or only silver or also mixtures of these substances also can be formed. Islands or clusters of various compositions may also be present concurrently.
Aluminum may also be added to the active ingredient. Aluminum produces a long-term brightening effect and/or an improved visual appearance, for example, because silver turns brown due to oxidation processes. Aluminum also modifies the rate of release of the antimicrobial active ingredient.
The active ingredient might be present in the form of a silver salt. Silver salts can be easily dissolved and processed.
The active ingredient might be accommodated in a ceramic carrier. The active ingredient can preferably be accommodated in a ceramic ball. The ceramic carrier ensures that the active ingredient can be easily dispersed within a melt. Mixing problems can be prevented by using a ceramic carrier.
The active ingredient might be present in a fiber, a yarn or a fringe in an amount by weight of 0.0001% to 2%, preferably from 0.001% to 0.05%. The first range ensures that an adequate antimicrobial effect is achieved, while enabling the flat wiping cloth to be washed approximately 200 to 1300 times at 60° C. without losing its antimicrobial effect. The second range from 0.001% to 0.05% ensures that, although there is an antimicrobial effect, only a relatively small amount of antimicrobial active ingredient is released to the environment.
The active ingredient might be present in a fiber, a yarn or a fringe in an amount by weight of greater than 0.001%. A flat wiping cloth of such configuration may be used as a disposable product. Such a flat wiping cloth may be used only a few times, max. 100 times, but has no stable antimicrobial effect after 100-1500 washing cycles.
The flat wiping coating might have at least one base layer to which the fibers, yarns or fringe are attached and an active ingredient which inhibits or suppresses the growth of bacteria and/or viruses distributed in and/or on the base layer. Such an embodiment of the wiping coating ensures that the development of mold or fungus is prevented even in the range of the base layer. The active ingredient used in the base layer may be present in the aforementioned concentrations and properties. After the end of a cleaning operation, the fibers, yarns or fringe are often present on the base layer. In the case of a base layer finished with an antimicrobial active ingredient, the fibers, yarns or fringe may also be protected from the development of mold by the base layer in addition to their own intrinsic antimicrobial finish.
The active ingredient which is allocated to the base layer can manifest its antimicrobial effect in a wet or moist environment, even over a certain distance. Tests have shown that additional parts of the flat wiping cloth, which were not provided with an antimicrobial finish as part of the test setup, are also protected from microbial growth in this way. In view of this, it is also possible that the wiping cloth holder may also be at least partially protected from microbial growth by contact with the flat wiping cloth having the antimicrobial finish. The flat wiping cloth creates a type of an extended antimicrobial effect in a moist environment for small distances, namely in the millimeter range, by releasing the silver ions into the moist environment.
The active ingredient might be allocated to the base body in some zones, such that the zones in which the active ingredient is present form a pattern. With this specific embodiment, regions of the base body which are under greater stress may be finished with the active ingredient to a greater extent.
The fibers, yarns or fringe may also comprise microfibers. Microfibers have diameters in the range of 1 to 100 μm. Microfibers may be created by extrusion. In addition, microfibers may be created by splitting multicomponent fibers.
At least one pocket into which a receptacle of a wiping cloth holder can be inserted might be provided on the base body. With this specific embodiment, a so-called “butterfly” mop or “pocket” mop may be connected to the flat wiping cloth. Such a wiping cloth holder has two supporting wings, which can be pivoted in relation to one another that are insertable into two pockets of the flat wiping cloth. The pockets can be arranged on the longitudinal ends of the elongated base body of the flat wiping cloth.
Straps which can be inserted in a form-fitting or force-locking manner into receptacle devices of a wiping cloth holder may be provided on the base body. The straps can be arranged for this purpose in the region of the longitudinal ends of the elongated base body. The straps may be placed around a supporting wing of a wiping cloth holder in such a way that the flat wiping cloth is under tension. The straps may be inserted into clamp-like gaps or slots on the supporting wings of a wiping cloth holder. Thus, a form-fitting connection between the straps and a supporting wing of a wiping cloth holder can be achieved.
Flat regions which may be applied in a form-fitting manner to receiving regions of a wiping cloth holder could be allocated to the base body. With such an arrangement, receptacle regions can be formed on the underside of a supporting wing of a wiping cloth holder. The receptacle regions might cooperate with the flat regions on the base body in such a way as to form a hook-and-loop closure. In addition, so-called Velcro-type connecting elements also could be provided on the flat regions as well as on the receiving regions.
A wiping cloth holder might have a flat wiping cloth according to the invention. Such a wiping cloth holder may have a pronounced antimicrobial effect. The active ingredient incorporated into the fringe of the flat wiping cloth manifests its antimicrobial effect in a moist or wet environment, even over a certain distance.
Tests have shown that additional parts of the flat wiping cloth, for example, the base layer, the straps or the flat regions, which were not finished with an antimicrobial finish as part of the test setup, are also protected from microbial growth in this way.
The wiping cloth holder can also be protected at least partially from microbial growth by contact with the flat wiping cloth having the antimicrobial finish. The flat wiping cloth creates a type of extended antimicrobial effect in a moist environment for small distances, namely in the millimeter range, by releasing the silver ions into the moist environment.
The flat wiping cloth might be embodied as a flat wiping velour cloth. Velour is a material that is manufactured by allocating a yarn of multiple fibers to a base layer.
The flat wiping cloth might have a fringe. Such a flat wiping cloth may be produced by forming tufts or trim. Such flat wiping cloths may be produced relatively easily. In forming a trim, fringe or strands of multiple yarns, preferably six entangled yarns, are sewn onto a base layer.
There are various options for designing and refining the teaching of the present invention in an advantageous manner. To do so, reference is made to the following discussion of preferred specific embodiments of the flat wiping cloth according to the invention and to the drawings.
Two pockets 8 into which a receptacle and/or a supporting wing 2 of the wiping cloth holder 1 can be inserted are arranged on the base body 4. Specifically, a pocket 8 is formed on each of the longitudinal ends of the base body 4.
This assembly is shown in
As shown in
A base layer 13 is shown in
In all the flat wiping cloths 3 shown in
The active ingredient is present in a nanoscale form. The active ingredient may be present as elemental silver, as a silver salt or accommodated in a ceramic carrier.
The active ingredient is preferably present in a fiber 5, a yarn 6 or a fringe 7 in an amount by weight of 0.0001% to 2%, preferably from 0.001% to 0.05%.
The fibers 5, yarns 6 or fringe 7 are secured on a base layer 13 with the active ingredient distributed in and/or on the base layer 13 which inhibits or suppresses the growth of bacteria and/or viruses.
The active ingredient may be allocated to the base body 4 in zones in such a way that the zones in which the active ingredient is present form a pattern.
Embedding the active ingredient in the fibers 5, yarns 6 or fringe 7 allows for the dyeing of the fibers 5, yarns 6 or fringe 7 without losing the antibacterial or antimicrobial effects.
The base layer 13 as a component of the base body 4 may also be dyed without losing its antibacterial or antimicrobial effects.
The active ingredient may also be present only in the fringe 7. However, the active ingredient also may be present only in the base layer 13, which constitutes a component of the base body 4. However, the remote effect described previously would be established then only if the base layer 13 were relatively highly loaded with the active ingredient. Finally, it is possible that the active ingredient is present in the base layer 13 and in the fringe 7.
The active ingredient may also be present in a textile element applied separately to the base body 4, this textile element not fulfilling any function required for cleaning. In this way, the textile element is designed only as a carrier of the antimicrobial active ingredient but nevertheless is a component of the base body 4. With such an arrangement, it is essential that the active ingredient is accommodated within the component, namely being incorporated into it.
With regard to additional embodiments and refinements of the teaching according to the invention, reference is made first to the general part of the description and second to the accompanying patent claims.
| Number | Date | Country | Kind |
|---|---|---|---|
| 10 2011 107 648 | Jul 2011 | DE | national |
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/EP2012/002110 | 5/16/2012 | WO | 00 | 4/24/2014 |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2013/007327 | 1/17/2013 | WO | A |
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| 20140373296 A1 | Dec 2014 | US |
