Patent Grant
8763196
This application claims the priority of GB 1104024.3 filed 9 Mar. 2011, which is incorporated herein in its entirety.
This invention relates to toothbrushes, in particular to toothbrushes having a flexible region in their handle.
Toothbrushes generally comprise a head and a grip handle arranged to define a toothbrush longitudinal direction (not necessarily a straight line) between them, with a neck region longitudinally between the grip handle and the head. Typically toothbrush handles and heads are made of a hard plastic material such as polypropylene. Tooth-cleaning elements such as bristles, e.g. typically filaments made from nylon, are mounted in the head and project in a transverse direction relative to this longitudinal direction from the head.
It is known to provide toothbrushes with a resiliently flexible region in their structure to absorb excessive brushing pressures during use and thereby reduce the likelihood of damage to teeth and soft oral tissues such as gums resulting from such excessive pressure. U.S. Pat. No. 5,054,154 discloses a toothbrush with an elastic segment between its handle and its head, in the form of widthways cut-outs across the toothbrush containing an elastic rubbery material. Another known form of such a flexible region is that disclosed in EP-A-0 336 641A being in the form of an S-bend undulating region longitudinally between the head and the handle, comprising limbs extending in the transverse direction and integrally linked by folds with troughs between the limbs, and preferably made more rigid by means of a longitudinal rib through the folds. A modification of such a region of limbs and folds is disclosed in WO-A-01/43580 in which there is a thermoplastic elastomer material in the folds between the limbs, and in which the flexibility can be controlled by a longitudinally moveable slider which intersects the limbs.
Since these early publications toothbrushes have been sold by the present applicant under the trademarks AQUAFRESH™ and DrBEST™ incorporating such an undulating region and attempting to optimize flexibility. The solution adopted in such commercial embodiments has always been the incorporation of a longitudinal rib as described in EP-A-0 336 641. Such toothbrushes have also been sold incorporating additionally a flexible link between the toothbrush head and the neck region of the toothbrush, or located in the neck region of the toothbrush itself. Such toothbrushes are for example disclosed in WO-A-98/37788.
The incorporation of elastomer material parts into toothbrush heads and handles to modify flexibility and for other purposes is also known. For example WO-A-96/28993 discloses an S-bend undulating region longitudinally penetrated by an elastomer material core. WO-A-97/25899 discloses elastomer segments in the toothbrush head to modify flexibility and in the handle to enhance grip and for aesthetic purposes. WO-A-98/05241 discloses elastomer-filled grooves in a toothbrush head to modify flexibility. EP-A-1350442 discloses a toothbrush head made flexible by means of an elastomer-containing hinge. US-D-450928 S discloses a toothbrush handle with an S-bend undulating region in which the troughs of the S-bend undulating region contain an elastomer material, but for an undisclosed technical purpose.
A problem has been encountered with toothbrushes incorporating such an undulating region, especially such toothbrushes which also include the above-mentioned flexible link between the toothbrush head and the neck region of the toothbrush. The problem is that with the prior undulating region incorporating the longitudinal rib the stress experienced by the toothbrush during tooth brushing is not optimally distributed and the toothbrush is prone to breakage during use. In toothbrushes which also include a flexible link between the toothbrush head and the neck region of the toothbrush it has been found that undulating regions of limbs and folds can be so rigid that the flexible link between the toothbrush head and the neck region can be subject to excessive stress during use, resulting in breakage and shortening of useful life. It is an object of the present invention to address these problems. Other objects and advantages of the present invention will be apparent from the following description.
According to this invention a toothbrush is provided comprising a head and a grip handle integrally made of a plastics material and arranged along a head-handle longitudinal direction, with a neck region between the grip handle and the head, with bristles projecting from the head in a transverse direction relative to this longitudinal direction, the toothbrush having a width direction perpendicular to the longitudinal direction and to the transverse direction, wherein longitudinally between the neck region and the grip handle is an undulating region, comprising limbs extending in the transverse direction and integrally linked by folds with troughs longitudinally between the limbs, the troughs between the limbs having a transverse depth direction and containing a thermoplastic elastomer material bonded to the plastics material of said limbs, characterized in that
the thermoplastic elastomer material has a ShoreA hardness of 60-70.
It is inventively found that use of such a thermoplastic elastomer material optimizes the resilient flexibility of the undulating region, especially in the proportions referred to above.
Preferably there are four such limbs.
Preferably the thermoplastic elastomer material occupies at least 60% of the depth “D” and at least 60% of the width of at least one, preferably each, trough, more preferably 75-90% of the depth “D” and 75-90% of the width. Preferably the thermoplastic elastomer material occupies at least 60% of the volume of at least one, preferably each, trough, more preferably 65-80%.
The term “transverse” as used herein includes perpendicular, and refers to a direction at an angle between 45° and 90° to the longitudinal direction. Preferably the transverse directions, i.e. the direction of a plane midway between longitudinally opposite surfaces of the limb, of longitudinally adjacent pairs of limbs are aligned at an angle of 0-15° to each other.
Preferably each of the four limbs has a longitudinal thickness “T” of 1.2-2.2 mm, and a transversely extending length “L” of 9-13 mm between transversely opposite folds, and a width “W” of 9-14 mm in the width direction, the four limbs defining longitudinally between longitudinally adjacent pairs of the limbs three troughs each with a transverse depth “D” of 6-11 mm, a longitudinal breadth “B” of 1-2 mm for at least 60% of the lower depth of the trough, each trough containing the thermoplastic elastomer material of ShoreA hardness 60-70 bonded to the plastic material of the limbs between which the trough is situated.
It is inventively found that such alignments, dimensions and proportions optimize the resilient flexibility of the undulating region, without any need for a longitudinally extending rib penetrating the limbs to modify the flexibility of the undulating region. Such optimization of flexibility is relative to the ability of the toothbrush to resiliently absorb excessive toothbrushing pressures whilst also being ergonomically rigid and providing the user with a sense of “feedback” through the handle during use.
Typically the toothbrush of this invention has a length of 190-200 mm from the extreme longitudinal end of its grip handle to the extreme opposite longitudinal end of its head.
Typically the head has a length of 33-35 mm from the point where the neck region begins to widen widthways to form the head to the end of the head longitudinally furthest from the grip handle.
Typically the grip handle has a length of 105-115 mm from the longitudinal end of the grip handle remotest from the head to the start of the undulating region.
Typically the undulating region has an overall length of 15-20 mm.
Typically the neck region has a length of 30-40 mm from the end of the undulating region closest to the head to the point where the neck region begins to widen widthways to form the head. Typically the neck region may have a thickness in the transverse direction of 5.5-3.5 mm, and typically the thickness may taper, decreasing toward the toothbrush head. The cross section of the neck region may be any convenient or conventional shape, e.g. semicircular, rectangular (optionally with rounded corners). The neck region may incorporate longitudinal flow channels to enable elastomer injected at points adjacent the handle during an injection moulding manufacturing process to flow along the neck toward the head, or vice versa.
Preferably the transverse directions of longitudinally adjacent pairs of limbs are aligned at an angle of 7-10° to each other. The transverse directions may be parallel to each other.
Preferably as viewed in the longitudinal direction the limbs may have a generally rectangular (the term includes square) shape, preferably with rounded corners.
In a preferred embodiment the longitudinal thickness “T” of the limbs is 1.5-2.0 mm.
In another preferred embodiment the transversely extending length “L” of the limbs is 9-12 mm between the extremities of transversely opposite folds.
In another preferred embodiment the width “W” of the limbs is 9-12 mm in the width direction. Suitably the width W of the limbs decreases toward the head of the toothbrush. For example the two limbs closest to the handle of the toothbrush may have substantially the same width “W”, and the two limbs closer to the head may be progressively less wide. Such narrowing of the width may improve the flexibility of the undulating region by concentrating flexibility at the end of the undulating region closest to the toothbrush head at which pressure is applied during tooth brushing.
In another preferred embodiment, the depth “D” of the troughs is 6-11 mm. For example the three troughs may vary in depth, with the longitudinally middle of the three troughs being the deepest.
In another preferred embodiment the longitudinal breadth “B” of the troughs tapers, narrowing toward the bottom of the trough, and being 1-1.5 mm for at least 60% of the depth of the trough.
In a preferred embodiment the folds are in the form of an arc of a circle with an outer radius of curvature defining the extremity of the fold of 2.0-2.5 mm, more preferably 2.25-2.35 mm. In a preferred embodiment the thickness of the folds in the radial direction is 1.5-2.0 mm. It is found that such a radius of curvature and thickness of the folds can optimize the flexibility of the undulating region whilst reducing the tendency for the undulating region to break during use.
In a preferred embodiment, at each longitudinal end of the undulating region there is an end trough in the plastics material, bounded on one longitudinal side by an adjacent limb and on the other longitudinal side by an adjacent surface of the grip handle or head, these end troughs also containing the thermoplastic elastomer material of ShoreA hardness 60-70 and bonded to the plastic material.
Such an end trough can act as a force-absorbing buffer between the neck region at one longitudinal end of the undulating region, and the grip handle at the other. Preferably such end troughs may have a transverse depth “E” of 5-7 mm, a longitudinal breadth “B” of 1-2 mm for at least 60% of the lower depth of the trough. Preferably the thermoplastic elastomer material occupies at least 60% of the transverse depth “D” and at least 60% of the width of each trough.
The neck region is preferably flattened in the transverse direction. Typically the neck region has a thickness “TN” in the transverse direction of 3.5-4.5 mm, for example ca. 4.0 mm. Typically the neck region has a width in the range 5-10 mm, and typically the neck tapers, narrowing toward the head, for example ca. 9.5 mm wide at its end closest to the undulating region and ca. 6.0 mm at the point where the neck region begins to widen widthways to form the head. Various cross sectional shapes as cut across the longitudinal direction may be used for the neck region, for example rectangular, trapezoidal, semicircular, or such aforementioned shapes cut into by longitudinally extending moulding channels for the flow of fluid elastomer material during an injection moulding process in which thermoplastic elastomer is injected to form spaced apart thermoplastic elastomer parts of the toothbrush.
In a preferred embodiment the toothbrush of the invention also includes a flexible link situated longitudinally between the undulating region and the toothbrush head.
Preferably such a flexible link is situated in the neck region thereby dividing the neck region into two longitudinally separate parts, one on each longitudinal side of the flexible link, being a first part closer to the grip handle and a second part closer to the head. The relative longitudinal proportions of the first part:second part may suitably be in the range 8.5-8.0:1. Such proportions have been found to optimize the distribution of forces between the flexible undulating region and the flexible link.
Suitably such a flexible link comprises a thinned part, integral with the neck region, which is transversely and/or widthways thinned relative to longitudinally immediately adjacent parts of the neck region or relative to longitudinally immediately adjacent parts of the neck region and the toothbrush head.
Alternatively such a flexible link may be situated between the neck region and the toothbrush head. Suitably such a flexible link comprises a part, integral with the neck region and toothbrush head, which is transversely and/or widthways thinned relative to longitudinally immediately adjacent parts of the neck region and toothbrush head.
Preferably the thinned part is in the form of a longitudinally extending spine of plastics material having a longitudinal dimension of 1-2 mm, a widthways dimension of 2-3 mm, and a transverse dimension of 1.5-2.5 mm. Suitably the cross section of such a spine cut across its longitudinal direction is circular or oval.
In a preferred embodiment such a spine is surrounded around all of its transversely- and widthways-facing surfaces by a thermoplastic elastomer material, suitably having a spherical symmetry, suitably with a spherical diameter of 6-7 mm. Suitably such a thermoplastic material may be the same thermoplastic elastomer material that is situated in the troughs, so that the same thermoplastic elastomer material may be used in all locations. This may be achieved by providing one or more flow channel in the plastic material of the toothbrush via which thermoplastic elastomer material injected at an injection port in an injection mould enclosing the plastic material part of the toothbrush may flow from one location to the other. The use of such flow channels to convey thermoplastic elastomer from one location on a toothbrush to another during manufacture is conventional in the toothbrush art. Alternatively multiple injection points may be used to inject the thermoplastic elastomer material into separated positions on the toothbrush.
In a preferred embodiment the end of such a flexible link closest to the undulating region is located within 30 mm of the end of the undulating region closest to the undulating region.
When the toothbrush of this invention includes such a flexible link it is preferred that the part of the neck region between the flexible link and the undulating region (herein the “first part”) is constructed such that under the forces encountered during tooth brushing this first part remains rigid relative to the flexibility of the flexible link and the undulating region. For example this may be provided by a first part which has a transverse thickness of at least 3.5 mm, preferably at least 4 mm, and a widthways width of at least 5 mm, preferably at least 5.5 mm. Such a construction helps to transmit force from the toothbrush head to the undulating region during use, so that the undulating region can absorb much of the forces of toothbrushing and protect the flexible link when present from such forces to thereby reduce the likelihood of breakage of the flexible link.
It is found that the above-mentioned dimensions and construction can provide a toothbrush in which flexibility during tooth brushing is improved relative to known toothbrushes, and in which the tendency to break of a flexible link in the neck region is reduced. It is believed that this advantage is achieved by means of the above-mentioned S-bend undulating region having an optimized flexibility which spreads stress out along the toothbrush, reducing breaking stress in the region of the flexible link.
Suitable plastic materials for the toothbrush of this invention include those with a modulus of elasticity of at least about 500 Mpa, preferably at least about 1000 Mpa, these being conventional in the toothbrush art. Suitable materials include for example, polyamides and polypropylenes. An example of a suitable polyamide is the material Ultramid B3™ (marketed by BASF, Federal Republic of Germany), having a modulus of elasticity (DIN 53452) of 3000. An example of a suitable polypropylene is the material Novolene 1100 HX™ (marketed by BASF, Federal Republic of Germany), which is a homopolymer and has a modulus of elasticity (DIN 53457) of 1400. Such a polypropylene homopolymer may optionally be used in admixture with a polypropylene block co-polymer, such as the material Novolene 2500 HX™ (marketed by BASF, Federal Republic of Germany), for example in an 80:20 mixture by weight (1100 HX:2500 HX). Other suitable polypropylenes include Polypropylene PM 1600™ (marketed by Shell) and having a modulus of elasticity (ISO 178) of 1500 Mpa and Apryl 3400 MAI™ from Elf Atochem, Novolen 2400 H and 1106, and Borealis HG 365 P. A preferred plastics material is polypropylene, especially the commercially available polypropylene material 100-GA04 supplied by Ineos.
Suitable thermoplastic elastomer materials for the toothbrush of this invention include those available under the trade names Megol™ and Santoprene™, and silicone elastomeric materials may also be used. Other suitable elastomeric polymers include styrene-based thermoplastic elastomers (for example styrene ethylene butadiene styrene, or styrene butadiene styrene). Preferred thermoplastic elastomer materials are the commercially available materials TF7 GST and TH7 GSN supplied by Kraiburg.
The toothbrush of this invention may be made using a known injection moulding process in which the plastics material part of the toothbrush is made in a first stage by injection moulding as an integral single part, and including one or more space defining the position and shape of the thermoplastic elastomer material part(s) of the toothbrush, including the position and shape of the thermoplastic elastomer material between the limbs. Then in a second stage the so formed plastics material part is enclosed in a cavity of a second injection mould which defines the outer profile of the thermoplastic elastomer part(s) of the toothbrush, including the shape of the thermoplastic elastomer material between the limbs. Thermoplastic elastomer material is then injected into the cavity of this second injection mould to thereby occupy the space(s) and thereby form the thermoplastic elastomer material part(s). Injection of this thermoplastic elastomer material is suitably under temperature and pressure conditions such that the thermoplastic elastomer material bonds tightly to the plastics material. Suitable temperature and pressure conditions are known in the art.
Bristles and/or other oral cleaning elements may be mounted in the head of the toothbrush of this invention in various known, conventional, ways. In one way socket holes may be formed in the plastics material of the head of the toothbrush during the first stage of injection moulding, and tufts of bristles may be held in these socket holes using small metal collars around the ends of the tufts in a well-known manner. In another way the ends of tufts of bristles may be inserted into the part of the cavity of the first injection mould which defines the toothbrush head, so that plastics material injected into the cavity flows around these ends, and when the plastics material solidifies around the ends of the tufts holds the tufts in place.
The toothbrush of this invention will now be described by way of example only with reference to the accompanying drawings.
Referring to
Longitudinally between the neck region 13 and the grip handle 12 is an undulating region 16. This region 16 is seen enlarged in
The toothbrush 20 of this invention has a length of ca. 195 mm from the extreme longitudinal end of its grip handle 12 to the extreme opposite longitudinal end of its head 11.
The head 11 has a length of ca. 34 mm from the point 132 where the neck 13 region begins to widen widthways to form the head 11 to the end 111 of the head 11 longitudinally furthest from the grip handle 12.
The grip handle 12 has a length of ca. 110 mm from the longitudinal end of the grip handle 12 remotest from the head 11 to the start of the undulating region 16.
The undulating region 16 has an overall length of ca. 17 mm.
The neck region 13 has a length of ca. 35 mm from the end 131 of the neck 13 closest to undulating region 16 to the point 132 where the neck region 13 begins to widen widthways to form the head 11. The neck region 13 is flattened in its transverse direction B-B. The thickness in the transverse direction B-B of the neck region is ca. 4.0 mm along its length, for example the thickness may be ca. 5 mm at the point 131 and ca. 4 mm at the point 132. The width of the neck 13 region tapers from ca. 9.5 mm wide at its end at the point 131 closest to the undulating region 16 to ca. 6.0 mm at the point 132 where the neck region 13 begins to widen widthways to form the head 11. The cross section of the neck region 13 as cut across the longitudinal direction A-A may for example be a generally rectangular shape, or for example be semicircular or other cross sectional shapes, and the neck region may include longitudinal flow channels for elastomer material.
As seen more clearly in
The three troughs 181, 182, 183 each have a transverse depth “D” of 6-9 mm. The measurement of the depths of the troughs 181, 182, 183 is seen most clearly in
The three troughs vary in depth. The trough 183 closest to the head 11 has a depth D3 of 7.0 mm, the middle trough 182 has a depth D2 of 10.0 mm, and the trough 181 closest to the grip handle 12 has a depth D1 8.0 mm, i.e. the middle trough 182 is the deepest.
The three troughs 181, 182, 183 have a longitudinal breadth “b” of 1-2 mm for at least 60% of the depth of each trough 181, 182, 183. The longitudinal breadth “b” tapers, narrowing toward the bottom of the trough 181, 182, 183, and being 1-1.5 mm for at least 60% of the depth of the trough 181, 182, 183.
Each of the folds 171, 172, 173 is externally in the form of an arc of a circle with an outer radius of curvature of 2.25-2.35 mm. The thickness of the folds measured in the radial direction of this circle is 1.5-2.0 mm.
The plastic material part 10 is made of the polypropylene plastics material 100-GA04 supplied by Ineos.
Each trough 181, 182, 183 contains thermoplastic elastomer material 21 seen in
At each longitudinal end of the undulating region 16 there is an end trough 184, 185 in the plastics material, which also contain thermoplastic elastomer material 21. These end troughs 184, 185 can act as a force-absorbing buffer between the neck region 13 at one longitudinal end of the undulating region 16, and the grip handle 12 at the other. The end trough 184 between the undulating region 16 and the grip handle 12 has a transverse depth “E1” of 5.5-6.5 mm, preferably ca. 6 mm, measured as shown in
As seen in
The toothbrush 20 of the invention also includes a flexible link 30 (overall) seen fully in
The flexible link 30 comprises a plastics material part 31 seen clearly in
The relative longitudinal proportions of the first part 133:second part 134, are approximately 8.25:1. These proportions are based respectively as the length of the first part 133 being the longitudinal distance from the edge of the end trough 185 closest to the head 11, to the end of the thinned part 31 closest to the grip handle 12 (this distance is ca. 28 mm), and the length of the second part 134 as the longitudinal distance from the end of the thinned part 31 closest to the head 11, to the point 131 where the neck region 13 begins to widen to form the head 11, this distance is ca. 3.5 mm. As seen in
The first part 133 of the neck region between the flexible link 30 and the undulating region 16 is constructed such that under the forces encountered during tooth brushing this first part 133 remains rigid relative to the flexibility of the flexible link 30 and the undulating region 16. This is achieved by the first part 133 having a transverse thickness “T” of at least 3.5 mm, being ca. 5 mm at the point 131 where the part 133 meets the undulating region 16 and 4-4.5 mm at the end of the first part 133 adjacent to the link 30. The first part 133 has a widthways width of at least 5 mm, being a width of ca. 9 mm at the point 131, and ca. 5.9 mm at the end of the first part 133 adjacent to the link 30.
In various places in the plastic material part 10, are apertures and moulding channels such as 40 into and through which the elastomer material 21 can flow from a single or multiple injection points to reach other parts of the plastic material part 10 of the toothbrush 20.
A toothbrush according to the above example was subjected to bending forces applied to the head and the stresses at various points in the toothbrush were measured. It was found that the structure and dimensions of the toothbrush described in the above example showed an acceptable degree of deformation in response to tooth brushing pressures. This toothbrush showed more deformation in its S-bend undulating region than in its brush head region thereby reducing potential breaking stress in the link between the head and handle. The deformation in the 5-bend undulating region during use was greater than in the S-bend region disclosed in the prior references mentioned above, with deformation concentrated in the limb 164 and fold 173 closest to the toothbrush head 11.
| Number | Date | Country | Kind |
|---|---|---|---|
| 1104024.3 | Mar 2011 | GB | national |
| Number | Name | Date | Kind |
|---|---|---|---|
| 5054154 | Schiffer et al. | Oct 1991 | A |
| 5758383 | Hohlbein | Jun 1998 | A |
| 5903949 | Halm | May 1999 | A |
| 6101659 | Halm | Aug 2000 | A |
| D450928 | Weisbarth | Nov 2001 | S |
| 6675428 | Halm | Jan 2004 | B2 |
| 6990706 | Broecker et al. | Jan 2006 | B2 |
| 8046864 | Baertschi et al. | Nov 2011 | B2 |
| Number | Date | Country |
|---|---|---|
| 2 004 029 | May 1990 | CA |
| A 0 336 641 | Mar 1989 | EP |
| A-11350442 | Jun 1989 | EP |
| WO 9628993 | Sep 1996 | WO |
| WO 9725899 | Jul 1997 | WO |
| WO 9805241 | Feb 1998 | WO |
| WO 9837788 | Sep 1998 | WO |
| WO 0143580 | Jun 2001 | WO |
| WO2008025443 | Mar 2008 | WO |
| Number | Date | Country | |
|---|---|---|---|
| 20120227200 A1 | Sep 2012 | US |
