This invention relates to dental cleaning implements, especially to toothbrushes having a resiliently flexible region in their structure, particularly having such a structure situated in their handle or between their head and their handle.
Toothbrushes generally comprise a head carrying a dental cleaning tool, normally a cluster of bristles in a toothbrush, and a grip handle, arranged along a longitudinal head-handle direction. Often there is a thinned neck region between the head and the part of the handle which is gripped by the user during use. It is known to incorporate a resiliently flexible region in the handle or between the head and the handle to help to relieve excessive pressure from being applied to the teeth or other mouth tissues of the user during implementing. Examples of such resiliently flexible regions in toothbrushes are disclosed in EP 0 0336 641A (Lingner+Fischer GmbH) and DE 39 234 95 (M+C Schiffer GmbH).
Different users of toothbrushes may prefer or need toothbrushes having different degrees of resilient flexibility of such a region. At present the user has no option except to purchase a complete different implement having a selected degree of flexibility of such a region.
It is an object of this invention to provide a dental cleaning implement particularly a toothbrush having a resiliently flexible region in its structure wherein the resilience and/or flexibility of the region may be altered by the user.
According to this invention a dental cleaning implement is provided having a head which carries a dental cleaning tool, and a grip handle, the head and handle being disposed along a longitudinal head-handle direction, the implement comprising longitudinally disposed first and second parts which are joined together by means of a flexible link which allows the implement to bend about the link under the action of pressure applied in a direction sideways of the longitudinal direction, situated longitudinally between the first and second parts there is a member which is rotatable about the longitudinal direction of the implement, and such that when the implement bends about the flexible link the first and/or second parts adjacent to the member bear compressibly upon the member, the member comprising circumferentially disposed relatively less and more resiliently hard regions, so that as the member is rotated the first and second parts can be caused to bear compressibly upon selected less or more hard regions.
By “resiliently hard” herein is meant primarily that under the action of applied pressure, i.e. compression the region deforms, and upon release of the pressure the region returns to the position it had before the pressure was applied. By “relatively less resiliently hard” herein is meant primarily that for a unit of pressure the structure displaces more than a “relatively more resiliently hard” region, or that less pressure is required to cause a unit of displacement than is required for a “relatively more resiliently hard” region.
The dental cleaning implement may preferably be a toothbrush having a dental cleaning tool which comprises a cluster of bristles projecting from the head in the manner of a conventional toothbrush or may comprise a dental flossing tool.
The flexible link may for example be located in the handle of the implement, for example between the grip handle and the neck of the implement. Alternatively and preferably the flexible link may be located between the part of the grip handle which is held by the user and the neck.
A preferred form of link is a thin longitudinally extending spine of the construction material of the implement, e.g. a plastics material, and this may be made integrally with the first and/or second parts. Suitably this link may provide an axle about which the member can rotate. Such a spine may be of any suitable cross section and dimensions to provide flexibility.
The member may for example be of a wheel or cylinder shape which is mounted rotatably on such a link, and between the first and second parts. If the spine is of non-circular cross section, and the member has an axial channel through it of corresponding section through which the spine is threaded as an axle, then this construction can enable the member to seat itself in a selected rotational position on the axle with a selected region of the member adjacent to selected part of the first and second parts. For example such a member may snap into a selected rotational position on the axle.
The circumferentially disposed less and more resiliently hard regions of the member may be provided by various means. For example the member may be made of a plurality of circumferentially disposed regions of relatively less and more resiliently hard material, for example an elastomer material. The relatively less and more resiliently hardness of such a material as an elastomer may be provided by for example different materials, different grades (e.g. foamed and non-foamed), or different thicknesses of a resilient material such as a polymer above a hard substrate such as a hard plastics material.
For example the regions may be disposed circumferentially in the manner of “pie” segments divided by radii of a constructed circle, so that as the member is rotated the first and second parts can be caused to bear compressibly upon selected less or more hard segments.
For example alternatively the member may be of a generally cylinder shape mounted rotably on the link, and has a hard substrate one end surface of which is generally perpendicular to the longitudinal direction, but the other end surface is at a non perpendicular angle to the direction. A part of the member adjacent to the non-perpendicular end is made of a softer material above the underlying hard substrate, so that the depth of the softer material in the longitudinal direction above the end surface varies around the circumference of the member, so that as the member is rotated the first and second parts can be caused to bear compressibly upon more or less deep regions of the softer material.
The implement e.g. a toothbrush, of the present invention may be made of plastics and elastomer materials conventional in the art of toothbrush manufacture, as may other parts of the implement such as the head, grip handle and the dental cleansing tool such as a cluster of nylon bristles.
The implement of the present invention may be made of such materials by an injection moulding process, therefore in a further aspect the present invention provides an injection moulding process wherein a implement as described above is made, and furthermore the present invention provides one or more injection moulds suitable for use in such an injection moulding process.
The invention will now be described by way of example with references to the figures as follows.
Referring to
Longitudinally between the first and second parts 14, 15 there is a member 18 which is rotatable about the longitudinal direction of the toothbrush 10. The member 18 is of a generally cylinder shape tapering conically from a wider end facing the handle 13 toward a narrower end facing the head 11, and is mounted rotatably on the link 17. The spine 17 is of non-circular, i.e. trefoil, cross section as shown in
When the toothbrush 10 bends about the flexible link 17 the first 14 and/or second 15 parts adjacent to the member 18 bear compressibly upon the member at points 18A and 18B.
As shown in
This enables the flexibility of the toothbrush 20 as experienced by the user to be varied by the user by rotation of the member 18.
Referring to
Longitudinally between the first and second parts 24, 25 there is a member 28 which is rotatable about the longitudinal direction A—A of the toothbrush 20. The member 28 shown in
When the toothbrush 20 bends about the flexible link 27 the first 24 and/or second 25 parts adjacent to the member 28 bear compressibly upon the member at points 28A and 28B (see
As shown in
Referring to
This enables the flexibility of the toothbrush 20 as experienced by the user to be varied by the user by rotation of the member 28 or 30.
The toothbrushes 10 and 20 of
The members 18, 28, 30 may be made by known two-component injection moulding techniques.
Number | Date | Country | Kind |
---|---|---|---|
9929400.1 | Dec 1999 | GB | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/EP00/12081 | 11/30/2000 | WO | 00 | 11/13/2002 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO01/43581 | 6/21/2001 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
1694636 | Barker | Dec 1928 | A |
5054154 | Schiffer et al. | Oct 1991 | A |
5315732 | Huefner et al. | May 1994 | A |
5323504 | McCusker | Jun 1994 | A |
5630244 | Chang | May 1997 | A |
5673452 | Chang et al. | Oct 1997 | A |
6003189 | Falleiros | Dec 1999 | A |
Number | Date | Country |
---|---|---|
3923495 | Jan 1991 | DE |
2282959 | Apr 1995 | GB |
WO0030493 | Jun 2000 | WO |
Number | Date | Country | |
---|---|---|---|
20030163883 A1 | Sep 2003 | US |