The invention relates to a toothbrush and to a process which is intended for producing the same.
Toothbrushes with a conventional bristle arrangement comprising clusters of bristle filaments, e.g. made of polyamide (PA) or polyester (PBT), and additional flexible cleaning elements are known, for example, from WO-A-00/64307 and WO-A-01/21036. The conventional bristles here serve for customary teeth-cleaning purposes, while the flexible cleaning elements can perform different functions, e.g. massaging the gums, damping the cleaning movement, removing plaque or polishing the surface of the teeth. According to WO-A-00/64307, the flexible cleaning elements are rod-like, are of approximately the same length as the conventional clusters of bristles and are arranged on the periphery of the head part of the toothbrush. In the case of the embodiments disclosed in WO-A-01/21036, the elastic cleaning elements are of sheet-like, e.g. undulating, configuration and are arranged within the conventional bristle arrangement. According to WO-A-00/64307, a plurality of the flexible cleaning elements are connected to one another via a material bridge made of the same material. U.S. Pat. No. 5,628,082 describes a process for producing a toothbrush having conventional bristles and additional flexible cleaning elements.
In accordance with the production process described in U.S. Pat. No. 5,628,082, following the operation of covering the head part of the toothbrush with conventional bristles, the cleaning elements are produced by virtue of the head part being encapsulated by injection molding. The disadvantage here is that the bristle filaments have to be prepared for use, e.g. by virtue of the clusters of bristles being rounded or of a predetermined profiling being produced, before the flexible structure is produced. Renewed insertion into the injection mold is then necessary in order to produce the flexible cleaning element. It is possible for the clusters of bristles to be damaged or soiled during this subsequent machining operation.
The object is achieved by a toothbrush having a brush body, which has neck part, and/or adjoining head part; a separately-formed carrier element made of hard plastic with bristles fitted on the separately-formed carrier element; a non-bristle-containing flexible cleaning element connected to the brush body via a mount located on the head part, said mount being adapted to receive the separately-formed carrier element, and said flexible cleaning element being arranged on the head part and non-releasably connected to the brush body by multi-component injection molding. The term toothbrush covers both conventional manual toothbrushes and electric teeth-cleaning appliances. The latter may be plug-on parts for electric teeth-cleaning appliances or single-piece electric toothbrushes. Advantageous developments can be gathered from the dependent claims, the description and the drawings.
The object of the invention is thus to provide a toothbrush which has conventional bristles and at least one flexible cleaning element and can be produced such that it is possible to avoid subsequent machining of the bristle-covered toothbrush head. The intention is also to specify a corresponding production process.
The object is achieved by a toothbrush having the features of claim 1 and by a process which is intended for producing such a toothbrush and has the features of claim 10. The term toothbrush covers both conventional manual toothbrushes and electric teeth-cleaning appliances. The latter may be plug-on parts for electric teeth-cleaning appliances or single-piece electric toothbrushes. Advantageous developments can be gathered from the dependent claims, the description and the drawings.
According to the invention, in the case of a toothbrush of the type mentioned in the introduction, at least one flexible cleaning element is connected directly to the brush body on the head part. The conventional bristles are fitted on a carrier element made of hard plastic, this carrier element being produced separately and being provided with conventional bristles before it is connected in a releasable or non-releasable manner to the head part of the brush body. In the connected state, the flexible cleaning element is preferably in close proximity to the carrier element with the conventional bristles. In order to achieve an optimum cleaning performance, and to keep the brush-head dimensions as small as possible, the distance between adjacent conventional bristles on the carrier element and the flexible cleaning elements on the brush body is preferably less than 5 mm. Both the conventional bristles and the flexible cleaning element are thus effective during use. The carrier element and the head part of the brush body are connected via a mount. Depending on the configuration of the carrier element, the mount may be a counter part which complements the carrier element or a coupling element arranged thereon. For example, a shallow cut-out, a pin, a hole or a groove may be used as the mount. A cut-out adapted to the outer shape of the carrier element is recommended, in particular, if a non-releasable connection between the carrier element and brush body is desired. The cleaning elements here are preferably arranged in the border region around the cut-out on the head part. A releasable connection between the carrier element and brush body is desirable in particular in the case of exchangeable-head toothbrushes.
In accordance with the production process according to the invention, the carrier element is produced, and covered with bristles, separately from the rest of the brush body, on which the at least one flexible cleaning element is arranged. The bristles are then preferably cut, rounded or prepared for use in some other way. There are no restrictions as far as the bristle-covering method which is to be selected is concerned, with the result that it is possible to use all the known processes, for example AFT (Anchor Free Tufting), as is known for example from DE-U-200 06 311, IMT (In Mould Tufting), as is known for example from DE-A-38 20 372, or conventional stuffing.
The production of the brush body with at least one flexible cleaning element, and optionally further flexible elements, takes place at a different time and location from the production of the carrier element. In contrast to the conventional bristles, the at least one flexible cleaning element and optionally further flexible elements are connected to the brush body directly, that is to say not via an additional carrier element. The further flexible elements can be used, for example, for the ergonomic adaptation of the handle to the surface of the hand or for providing an elastic region between the head part and neck part. The production of the brush body with one or more flexible cleaning elements and optionally further flexible elements preferably takes place by two-component or multi-component injection molding, it being possible to mold on the various flexible elements, and connect them to the hard component of the brush body, in one step. A non-releasable connection between the components is preferably produced here. The flexible cleaning elements may also be produced via dedicated injection points, in particular if the flexible cleaning elements are to have a color or Shore A hardness which differs from the rest of the flexible elements.
Conventional bristles consist, for example, of polyamide (PA) or polyester (PBT) and have a diameter of 0.1 mm to 0.25 mm. They are combined, for example, in clusters with 10 to 100 individual filaments. For reasons of stability, the flexible cleaning elements, which consist for example of thermoplastic elastomer (TPE), have greater material thicknesses. The smallest dimension of a cross section (for example at 90% of the height of the cleaning element) through such a cleaning element is preferably between 0.5 mm and 3 mm.
The material for the flexible cleaning elements and optionally further flexible elements is preferably fed via a material-distributing channel in the handle or in the neck part. The flexible material here is fed at those points at which the flexible cleaning elements and, if appropriate, further flexible elements are provided. These are formed in corresponding cavities of the injection mold. It is possible for the flexible material, injected for example into a mount intended for accommodating the carrier element, to be guided from the mouth opening of the material-distributing channel to the points of attachment for the flexible cleaning elements. In order to make it possible for the cleaning elements to be injection molded satisfactorily, the material-distributing channel, on the neck part, preferably has a minimal cross section of at least 0.5 mm2. The flexible material is concealed by the carrier element once the latter has been fitted onto the head part of the brush body. The advantage of this production process is that the rear side of the head part does not have any undesirable gate marks or distributing channels. Recesses located in that region on which the carrier plate is to be fitted are preferably used as retaining points for the brush body for transportation between various mold cavities, corresponding to the individual components, during the two-component or multi-component injection molding of the brush body. This may be advantageous in the case of the brush bodies being transported both in a linear manner and in a rotary manner within the injection mold. These recesses in the hard component of the brush body are preferably filled with the material component which is injected last.
In a straightforward further step, the carrier element is connected to the head part of the brush body. It is possible, for example, for connection to take place directly downstream of the injection-molding machine of the brush body, in which case the orientation of the brush bodies following injection molding is maintained and the carrier elements are fed by means of conveyors and fitted. The connection can take place mechanically in a releasable or non-releasable manner. For example, the connection may be produced by clamping, snap-fitting or riveting. The connection may also be produced chemically by adhesive bonding, thermally by welding, in particular ultrasonic welding, or some other supply of heat. It is preferred, in production terms, if the carrier element consists of the same material as the hard components of the brush body since, in this case, only one hard component has to be kept in stock for producing the brush and there is no need to ensure compatibility of materials. This is advantageous, in particular, in the case of ultrasonic welding. It is particularly preferred for the carrier element to be covered with bristles in accordance with AFT (Anchor Free Tufting) technology and to be fully machined before it is connected, by means of ultrasonic welding, to the brush body provided with at least one flexible cleaning element.
The materials used for the carrier element and the hard components of the brush body are, in particular, polypropylene, styrene-acrylonitrile, polyester, polystyrene (PS), acrylonitrile-butadiene-styrene (ABS) or Isoplast®. The flexible elements preferably consist of an, in particular, thermoplastic elastomer, e.g. of natural or synthetic rubber. The Shore A hardness of the soft component is preferably less than 90, and is particularly preferably less than 40. Depending on the type of hard component, a compatible flexible material which connects during injection molding is preferably to be selected.
If a non-releasable connection between the carrier element and brush body is desired, then, once the carrier element has been fitted, the toothbrush is preferably subjected to the action of a testing device installed in the fitting or assembly device. In this case, the carrier element is subjected to a compressive force by means of a pin or of a similar element. If the connection between the carrier element and the brush body is insufficient, it is separated during this step. The brush body may contain regions of flexible material which transmit to the carrier element the compressive force to which they are subjected. It is thus also possible for the consumer, following a relatively long period of use, to check the adherence between the carrier element and brush body, for example by means of pressure applied by a finger or by a simple tool such as a pen. In order that the region made of flexible material is not damaged during testing, its thinnest point preferably has a thickness of at least 0.5 mm.
The testing methods described can also be used on toothbrushes without flexible elements. This is advantageous, in particular, in the case of toothbrushes produced by means of AFT, in order to check the connection between the carrier element and brush body.
The above described production process does away with the problems which arise in the production of toothbrushes with conventional bristles and flexible cleaning elements as a result of the head part being encapsulated by injection molding once bristle covering has taken place. If the flexible cleaning elements are already located in the bristle arrangement as the conventional bristles are machined, then, in accordance with the above-described production process, it is additionally possible to prevent the situation where the flexible cleaning elements are damaged, or contaminated by abrasive dust, during machining of the bristles.
A further advantage in the separate production of the brush body with cleaning element and carrier element with conventional bristles is that it is possible to realize a wide range of shapes for the flexible cleaning elements. For example, it is possible to realize shapes which, in the finally assembled state, are in contact with the conventional bristles or which are displaced when the carrier element is inserted. The separate production means that demolding of the flexible structure does not pose any problems.
In addition, a toothbrush according to the present invention also has advantages from an ecological point of view since, in the case of embodiments in which the carrier element is connected in a releasable manner to the brush body, in particular exchangeable-head toothbrushes, it is easily possible to be exchanged, with the carrier element, that part which wears more quickly. The flexible cleaning elements tend to wear less quickly than the conventional bristles and, thanks to their greater dimensions, are easier to clean. It is thus possible for the flexible cleaning elements to outlast a number of carrier elements without sustaining any damage.
In an advantageous further development, it is possible, in the case of electric teeth-cleaning appliances, for at least one flexible cleaning element to be arranged on the brush body such that the flexible cleaning element is made to move, in particular vibrate, relative to the brush body by the movement of the rotatably mounted carrier element. This can be brought about, for example, in that the carrier element has at least one lateral indent and the cleaning element is positioned in the region of the indent. The cleaning element is thus made to vibrate relative to the brush body by the movement of the carrier element. In a further type of configuration, the cleaning elements are bent such that they project, by way of their region adjacent to the free end, into the bristle arrangement formed by the bristles and, in this way, are made to move relative to the brush body during movement of the bristles. In order to achieve optimum vibration action, and to keep the wear to the flexible cleaning elements minimal, the angle of the latter relative to the axis of rotation of the carrier element is preferably less than 20°. In order that the moving flexible cleaning elements are not subjected to excessive wear at the base, the maximum angle of rotation of the carrier element in relation to the flexible cleaning elements is preferably less than 75°, particularly preferably less than 45°.
Since electrical teeth-cleaning appliances have a weight of up to 300 g and are a number of times heavier than manual toothbrushes, the end zone made of flexible material, this zone feeding in the cleaning elements, is preferably provided with a layer thickness of more than 1 mm, in order to provide a damping action during impact and to reduce the potential for damage.
Examples of toothbrushes according to the invention are described hereinbelow and illustrated in the drawing, in which, purely schematically:
a shows part of a brush body in side view, in which, for the sake of clarity, the flexible cleaning elements are not illustrated;
b shows the side view of a bristle-covered carrier element which is adapted to the brush body which is partially illustrated in
c shows a plan view of a front part of a toothbrush according to the invention which is made up of the components depicted in
d shows a side view of that part of the toothbrush according to the invention, made up of the components depicted in
a shows a side view of a front part of a brush body of an exchangeable-head toothbrush with flexible cleaning elements;
b shows a side view of an exchangeable head which is provided with conventional bristles and is intended for the brush body which is partially illustrated in
c shows a plan view of a front part of a toothbrush which is made up of the components illustrated in
a shows a side view of a bristle-covered carrier element for a plug-on part of an electric teeth-cleaning appliance;
b shows a side view of a brush body which is intended for combining with the carrier element according to
c shows a side view of a plug-on part according to the invention which is made up of the components illustrated in
d shows a plan view of the plug-on part which is illustrated in
a shows a side view of a bristle-covered carrier element corresponding to
b shows a side view of a brush body which is intended for combining with the carrier element according to
c shows a side view of a plug-on part according to the invention which is made up of the components illustrated in
d shows a plan view of the plug-on part according to the invention which is illustrated in
a shows a side view of a bristle-covered carrier element for a further plug-on part of an electric teeth-cleaning appliance, with recesses for flexible cleaning elements;
b shows a side view of a brush body which is intended for combining with the carrier element according to
c shows the side view of a plug-on part according to the invention made up of the components illustrated in
d shows a plan view of the plug-on part according to the invention illustrated in
a shows a plan view of a front part of a further embodiment of a plug-on part;
b shows a side view of the front part of the plug-on part which is depicted in
c shows a side view solely of the carrier element, provided with bristles, of the embodiment illustrated in
d shows a side view of a front part of the brush body of the embodiment illustrated in
a shows a side view of a bristle-covered carrier element for a further plug-on part of an electric teeth-cleaning appliance;
b shows a side view of a brush body which is intended for combining with the carrier element according to
c shows a side view of the plug-on part according to the invention made up of the components illustrated in
d shows a plan view of the plug-in part according to the invention illustrated in
a shows a side view of a further bristle-covered carrier element with indents for flexible cleaning elements;
b shows a plan view of the carrier element shown in
c shows a side view of a front part of a brush body intended for combining with the carrier element according to
d shows a side view of the front part of a toothbrush according to the invention which is made up of the components depicted in
e shows a plan view of that part of the brush body which is depicted in
a shows a plan view of a part of a toothbrush according to the invention with lateral extensions on the carrier element, the flexible cleaning elements, for the sake of clarity, not being illustrated;
b shows a section through the longitudinal center plane of that part of the toothbrush which is illustrated in
a shows a section through the longitudinal center plane of a part of a toothbrush according to the invention with a flexible zone in the brush body, the flexible cleaning elements, for the sake of clarity, not being illustrated;
b shows a section through the longitudinal center plane of that part of a toothbrush which is depicted in
a shows a section through the longitudinal center plane of a part of a toothbrush which corresponds to that from
b shows a section through the longitudinal center plane of that part of a toothbrush which is depicted in
a shows the plan view of a part of a brush body in which a flexible region is formed, the flexible cleaning elements, for the sake of clarity, not being shown;
b shows a section through the longitudinal center plane of a part of a toothbrush according to the invention which contains the brush body illustrated in
All the toothbrushes illustrated comprise, in the assembled state, a brush body 1 and a carrier element 2 provided with conventional bristles 4. In the case of the manual toothbrushes illustrated (FIGS. 1,2,8-13), the brush body 1 comprises a head part 1a′, a neck part 1c and an adjoining handle 1d, as is indicated, for example, in
a shows a front part of a brush body 1, which for the sake of clarity is illustrated without a flexible cleaning element, prior to being assembled with a carrier element 2 already provided with bristles 4. The carrier element 2 depicted in
a shows the front part of a brush body 1 of an exchangeable-head toothbrush. The flexible cleaning elements 3 here are arranged on that side of the head part 1a′ of the brush body 1 which is directed toward the neck part 1c. The corresponding carrier element 2, which is already provided with bristles 4 and constitutes the exchangeable head, is depicted in
The flexible cleaning elements 3 are arranged in a rod-like manner on that side of the head part 1a of the brush body 1 which is directed toward the neck part 1c. The neck part 1c and the handle ld are additionally profiled by a further flexible structure 7, which is preferably produced by two-component or multi-component injection molding, and connected to the hard component of the brush body 1, in the same step as the flexible cleaning elements 3.
a shows a carrier element 2, already provided with bristles 4, in the form of a circular plate prior to being fitted onto the brush body 1 which is depicted in
a shows a carrier element 2 which is provided with bristles 4 and is analogous to the carrier element in
a shows the side view of an essentially elliptical bristle-covered carrier element 2 with four lateral indents 9. The connection between the carrier element 2 and the rotary disc 5″ of the brush body 1, this rotary disc being illustrated in
In the case of that part of a plug-on part for an electric teeth-cleaning appliance which is illustrated in
a shows an essentially circular conventionally bristle-covered carrier element 2. The connection between the carrier element 2 and the rotary disc 5″ of the brush body 1, this rotary disc being illustrated in
a and b represent a side view and plan view of a carrier element 2 provided with bristles 4. The carrier element of this embodiment has clusters of bristles of different shapes and sizes. The round clusters serve for surface cleaning and the elongate clusters serve for cleaning in between the teeth. As can be seen from the plan view, the oval carrier element 2 has lateral indents 9′ for flexible cleaning elements.
a shows the front part of a toothbrush made up of the brush body 1 and carrier element 2, the flexible cleaning elements, for reasons of clarity, not being shown. The flexible material on the base of the mount 5 is fed in through a through-passage (not shown) at the end of the neck part 1c, this through-passage opening out into the mount 5. For this purpose, a through-passage is produced beforehand at an appropriate point in the hard component of the brush body 1. The toothbrush according to the invention is subjected to the action of a testing device installed in the fitting or assembly device, as is indicated in
Further possible ways of testing the fastening of the carrier element 2 in the mount 5 are illustrated in the following figures:
a shows the front part of a further toothbrush according to the invention, in the case of which, for reasons of clarity, the flexible cleaning elements are not shown. As can be seen from
a shows the front part of a toothbrush analogous to that in
a illustrates a front part of the brush body 1 of a toothbrush according to the invention, the flexible cleaning elements, for reasons of clarity, not being shown. In this case, part of the head part 1a′ of the brush body 1, in the region of the mount 5, consists of flexible material which forms a flexible zone 16. This is of mushroom-shaped configuration in plan view. The hard component of the brush body 1 extends, on the side 16a of the flexible zone 16, this side being directed toward the carrier element 2, into a sheet-like structure 17 which is t-shaped in plan view. The t-shaped structure 17 is connected to the rest of the hard component of the brush body via a film hinge 19. Formed at the ends of the shorter arms 17a of the t-shaped structure 17 are crosspiece-like extensions 18 which are oriented essentially parallel to the outer contour of the head part 1a and/or the side wall 2b of the carrier element 2 and orthogonally to the surface area of the mount 5. The compressive force is applied to the flexible zone 16 from the outside in the region of the t-shaped structure 17 and runs essentially orthogonally to the longitudinal axis of the head part 1a, as can be seen from
The above described testing methods may be integrated as a process step in an AFT (Anchor Free Tufting) installation. In this case, toothbrushes which exhibit insufficient adherence between the brush body and carrier element are separated out.
Number | Date | Country | Kind |
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102 16 641 | Apr 2002 | DE | national |
This is a Division of application Ser. No. 11/878,720 filed Jul. 26, 2007 now U.S. Pat. No. 7,574,765, which is a Continuation of application Ser. No. 10/964,731 filed Oct. 15, 2004, now U.S. Pat. No. 7,418,759, which in turn is a Continuation of International Patent Application No. PCT/CH03/00220 filed Apr. 2, 2003. The disclosures of the prior applications are hereby incorporated by reference herein in their entirety.
Number | Name | Date | Kind |
---|---|---|---|
1022920 | Anderson | Apr 1912 | A |
1142698 | Grove et al. | Jun 1915 | A |
1588785 | Van Sant | Jun 1926 | A |
1598224 | Van Sant | Aug 1926 | A |
1993763 | Touchstone | Mar 1935 | A |
2042239 | Planding | May 1936 | A |
2139245 | Ogden | Dec 1938 | A |
2266195 | Hallock | Dec 1941 | A |
2279355 | Wilensky | Apr 1942 | A |
2614556 | Martin | Oct 1952 | A |
3316576 | Urbush | May 1967 | A |
3553759 | Sober et al. | Jan 1971 | A |
4543679 | Rosofsky et al. | Oct 1985 | A |
D282318 | Herzfeld | Jan 1986 | S |
4972542 | Moshos et al. | Nov 1990 | A |
5283921 | Ng | Feb 1994 | A |
5604951 | Shipp | Feb 1997 | A |
5689850 | Shekalim | Nov 1997 | A |
5839148 | Volpenhein | Nov 1998 | A |
5864915 | Ra | Feb 1999 | A |
6681777 | Gueret | Jan 2004 | B2 |
Number | Date | Country |
---|---|---|
198 57 032 | Jul 1999 | DE |
438091 | Nov 1935 | GB |
Number | Date | Country | |
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20090265873 A1 | Oct 2009 | US |
Number | Date | Country | |
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Parent | 11878720 | Jul 2007 | US |
Child | 12457913 | US |
Number | Date | Country | |
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Parent | 10964731 | Oct 2004 | US |
Child | 11878720 | US | |
Parent | PCT/CH03/00220 | Apr 2003 | US |
Child | 10964731 | US |