BE857105A - MECHANICAL TOOTHBRUSH - Google Patents

Description

       

  Mechanical toothbrush

  
The present invention relates to a brush

  
mechanical teeth of the type comprising a head carrying tufts of movable bristles, connected to a handle.

  
Toothbrushes of the type described above are known. A serious drawback of these known toothbrushes lies in the fact that, during their use

  
it is practically impossible to prevent the dirt or waste detached from the surface of the teeth by the movement

  
brushing accumulate either in the gum-dental groove, or in the interstices between the teeth,

  
which can create inflammation or other pathological conditions in the user's jaws. Another drawback of known mechanical toothbrushes resides in the fact that they do not provide a gingival massage.

  
The present invention aims to remedy these drawbacks and relates to a mechanical toothbrush characterized essentially by the fact that its head has

  
 <EMI ID = 1.1>

  
extends in the direction of the brush handle and carries at least one row of tufts of bristles perpendicular to its longitudinal axis, this cylindrical element having at least one of its ends housed in a hole eccentrically made in one end of a cylindrical support rotary which also extends in the direction of the brush handle and is connected to means for driving said support and the cylindrical member

  
 <EMI ID = 2.1>

  
the meaning sinistrorsua.

  
 <EMI ID = 3.1>

  
before the invention, the user of this brush can

  
 <EMI ID = 4.1>

  
a direction going from the gum towards the occlusal end of the teeth, which makes it possible to avoid one of the drawbacks indicated above.

  
 <EMI ID = 5.1>

  
advantageously constituted by an electric motor which can be powered by any source of electric current, noted by the power distribution network.

  
 <EMI ID = 6.1>

  
 <EMI ID = 7.1>

  
However, one can use, within the framework of the invention, any other means capable of animating the assembly formed by the aforementioned support and the aforementioned cylindrical element of a. rotational movement.

  
In a preferred embodiment of the toothbrush according to the invention, this brush comprises three substantially cylindrical elements each carrying at least one row of tufts of bristles, these cylindrical elements preferably being tangent to one another. 'other and having each of their ends housed in eccentric holes formed in a base of two substantially cylindrical supports.

  
 <EMI ID = 8.1>

  
be driven in rotation by the electric motor or

  
i equivalent training means. Preferably, the two cylindrical supports are mechanically connected between

  
them to rotate simultaneously and at equal angular speeds.

  
According to another feature of the invention, the

  
 <EMI ID = 9.1> <EMI ID = 10.1> <EMI ID = 11.1>

  
According to yet another feature of the invention,:

  
 <EMI ID = 12.1>

  
 <EMI ID = 13.1>

  
 <EMI ID = 14.1>

  
 <EMI ID = 15.1>

  
relative to their support (s)) being limited by the contact of a row of tufts of bristles carried by one of the cylindrical elements, with another cylindrical element.

  
The rotation of the cylindrical elements with their supports, as well as the rotation of the cylindrical elements relative to each other are facilitated by a judicious choice of the constituent material of these parts, as well as by the lubricating effect of the toothpaste. used.

  
In order to be able to brush the teeth both in height and in width and to reach the intervals between these teeth, the or each cylindrical element carrying the tufts of bristles of the new brush can be moved alternately along its longitudinal axis during its rotation around the axis longitudinal of the handle. During their rotation and their axial translation, the cylindrical elements are aligned transversely without being offset with respect to one another.

  
To be able to be moved parallel to the hip axis of the new brush, the rotary supports for housing the ends of the or each cylindrical element

  
 <EMI ID = 16.1>

  
to the housing, during the rotation of this element. For this purpose, each aforementioned support, respectively each aforementioned housing, may have a sinusoidal or helical groove in which is guided a projection integral with this housing, respectively with this support. For the same purpose, this cylindrical element can be biased at one end

  
by a preferably helical spring to constantly force, by its other end, the support corresponding to this other end, to bear on a cam surface disposed transversely around the longitudinal axis of the sleeve. In the latter case, the helical spring can be arranged between one end of this element and the bottom of its housing in the corresponding rotary support, while the cam surface is formed or presented by the removable bottom of the protective screen and cooperates with a reverse cam surface formed or presented by the rotary support corresponding to this other end.

  
Other details and features of the invention will become apparent from the description and from the drawings appended hereto, which schematically and by way of example only represent several embodiments of the invention.

  
Figure 1 is an elevational view partially in section of a first embodiment of a brush according to the invention. Figure 2 is a section of the brush taken along the line II-II of the first figure.

  
Figures 3 and 4 are sections similar to that of the second figure and illustrating the mode of operation of the brush.

  
Figure 5 is a partial axial section of a second embodiment of the new brush. Figure 6 is a cross section of the brush taken along the line VI-VI of the fifth figure. FIG. 7 is a partial half-section in perspective illustrating the bore of the housing of the second brush. Figure 8 is a partial axial section of a third embodiment of the new brush. Figure 9 is a section similar to that of <EMI ID = 17.1> of the new brush.

  
In these different figures, the same reference notations designate identical elements.

  
In the first embodiment, the brush essentially comprises a head 2 connected to a handle 3. The handle 3 essentially consists of a handle 4 and a tubular extension 5 connected to the head 2. In the handle 4 is mounted an electric motor, a device for reversing the direction of rotation of the motor and possibly a device for reducing the speed of the motor, the motor, the reverser and the reduction gear not being shown.

  
The shaft 6 of the electric motor extends in the tubular extension 5 of the handle 3.

  
The toothbrush head 2 includes essential-

  
 <EMI ID = 18.1>

  
to each other, as can be seen clearly in Figures 3 and

  
4. Each of the cylindrical elements 7 carries a row of tufts of bristles 8. At each of their ends, the cylindrical elements 7 carrying tufts of bristles 8 are engaged in eccentric blind holes made in the inner flat face 9 of two cylindrical supports.

  
 <EMI ID = 19.1>

  
shaft 6 of the electric motor, so that the assembly

  
 <EMI ID = 20.1>

  
carriers of tufts of bristles 8 and the support 11 are driven in rotation by the shaft 6 of the motor, when the latter is in operation.

  
The head 2 of the toothbrush comprises, in

  
 <EMI ID = 21.1>

  
the contact of the tufts of bristles 8, of the cylindrical elements 7 which carry them and of the supports 10 and 11 with the user's cheek.

  
 <EMI ID = 22.1>

  
12-yard curved foras protection and its internal surface
13 is located at a distance from the longitudinal axis of the supports 10 and 11, greater than the radius of these supports and

  
 <EMI ID = 23.1>

  
At each of its ends, the protective screen 12 has a part 14, 14 'directed towards the longitudinal axis of the supports 10 and 11. At the front part

  
 <EMI ID = 24.1>

  
the support 11 in place. It can thus be seen that the protective screen also serves to support the rotary assembly formed by the cylindrical elements 7 and their supports 10, 11.

  
It should be noted that the ends of the cylindrical elements 7 are not integral with the supports 10 and

  
11. In other words, these cylindrical elements 7 can undergo a certain angular rotation about their longitudinal axis, relative to said supports 10 and <1> 1.

  
The various parts constituting the rota-; tif, namely the cylindrical elements 7 and their supports
10, 11, are advantageously mounted so as to be able to

  
 <EMI ID = 25.1>

  
wear or breakage.

  
On the handle 3 of the toothbrush is

  
 <EMI ID = 26.1>

  
electric. In the middle position of said cursor, which is the position shown in FIG. 1, the switch is open and the electric motor is therefore stopped. When the cursor 16 is moved from its middle position to its lower position, in the direction of arrow A, the motor

  
 <EMI ID = 27.1>

  
 <EMI ID = 28.1>

  
cylindrical elements 7 rotate in the sinistrorsum direction
(indicated by arrow B in figure 3). On the other hand, when the slider 16 is brought from its middle position to its upper position, in the direction of arrow C (FIG. 1), the shaft 6 of the motor and the enseable formed by the supports 10,
11 and the cylindrical elements 7 carrying tufts of bristles 8 rotate in the dextrorsua direction (indicated by the arrow D in FIG. 4).

  
In Figure 3 is illustrated the position of the rows of tufts of bristles 8 carried by the cylindrical elements 7, when the latter rotate, together with the supports 10 and 11, in the opposite direction to that of the ai-

  
 <EMI ID = 29.1>

  
each of the rows of tufts of bristles S carried by one of the cylindrical elements 7 is in contact with the lateral surface of another cylindrical element 7, terminal shown in
17, so that the rows of tufts of bristles 8 and the cylindrical elements 7 which carry them are unable to turn clockwise.

  
 <EMI ID = 30.1>

  
reference score 18, which is a jaw tooth

  
 <EMI ID = 31.1>

  
occlusal end 20 of the tooth, which prevents any accumulation of foreign matter in the gingivodental groove 21. On the contrary, thanks to the pressure exerted

  
by the hairs on the gingival margin, the foreign salt shakers are expelled from this furrow.

  
When reversing the direction of rotation of the shaft 6 of the motor and of the assembly formed by the supports
10, 11 and the cylindrical elements 7 carrying a row

  
 <EMI ID = 32.1>

  
this assembly in the direction of clockwise, as shown in FIG. 4, the rows of tufts of bristles 8 carried by the elements 7 first undergo an angular pivoting of approximately 210 degrees, by the fact that these cylindrical elements 7 themselves turn around their longitudinal axis at an angle of about 210 degrees in the sine direction &#65533;

  
 <EMI ID = 33.1>

  
nities -are accommodated. So each row of tufts of

  
 <EMI ID = 34.1>

  
 <EMI ID = 35.1>

  
the sense of dextrorsum. In this position, illustrated in figure 4, the rows of tufts of bristles 8 and the elements 7 which carry them are in the impossibility of <EMI ID = 36.1>

  
the rotation of the assembly formed by the cylindrical elements

  
 <EMI ID = 37.1>

  
 <EMI ID = 38.1>

  
that designated by the reference numeral 23, which is a tooth of the lower jaw, provides brushing from the gum 24 towards the occlusal end 25 of the tooth, which prevents the tufts of bristles from pushing foreign material back into the tooth. inferior gingival sulcus
26.

  
Pod can be seen in figure 3, the direction of rotation indicated by arrow B is that which is appropriate for brushing the teeth of the upper left jaw on the buccal side: while in figure 4, the direction of rotation indicated by arrow D is the one suitable for brushing the teeth of the lower left jaw on the buccal side.

  
 <EMI ID = 39.1> the first in that the cylindrical elements 7

  
 <EMI ID = 40.1>

  
vement along their own longitudinal axis during their rotation around the general axis of the shaft 6 of the motor.

  
In this way, the bristles 8 no longer rotate in their plane perpendicular to the general axis of the shaft 6 but rather by alternately sweeping a zone of predetermined length.

  
To this end, in the second embodiment, the shaft 6 for controlling the cylindrical elements 7 is constructed.

  
 <EMI ID = 41.1>

  
to the electric motor has an axial recess 6c of polygonal cross section, for example square. The part

  
 <EMI ID = 42.1>

  
 <EMI ID = 43.1>

  
square example is slightly less than that of 1

  
 <EMI ID = 44.1>

  
 <EMI ID = 45.1>

  
any rotation of part 6a causes identical rotation of part 6b.

  
In addition, the support 10 integral with the part

  
6b of the shaft 6 of the electric motor bears a lateral projection 27 clearly visible in FIG. 5. On the other hand, the part 14 of the protective screen 12, which forms the housing of the support 10, has an internal groove 28 s'

  
 <EMI ID = 46.1>

  
longitudinal axis of shaft 6, relative to any plane perpendicular to this axis. In addition, the lateral projection 27 of the support 10 is constantly engaged in the groove 28 <EMI ID = 47.1>

  
 <EMI ID = 48.1>

  
 <EMI ID = 49.1>

  
without significant play in a groove 30 identical to the groove 23 and arranged in the bore of the part of the protective screen forming the housing of this support 11.

  
Furthermore, the ends of the cylindrical elements 7 are constantly engaged to the bottom of their

  
 <EMI ID = 50.1>

  
the first example. However, the length of the bore of the ocher, protection 12 in which the supports 10 and 11 are mounted is greater than that relating to the first case and this by a distance equal to the translational stroke of the part 6b of tree 6 or elements

  
 <EMI ID = 51.1>

  
In this way, the rotation in one direction or the other of the part 6a of the shaft 6 causes both

  
the identical rotation of part 6b and the axial translation of this part 6b because of the lateral projections

  
27 and 29 guided will continue in the fixed grooves 28

  
and 30. The sinultuous rotation and translation of the part 6b cause identical movements of the cylindrical elements 7 and consequently of the tufts of bristles 8.

  
A slight variant of the second embodiment consists of the rotation without translation of the support

  
 <EMI ID = 52.1>

  
 <EMI ID = 53.1> arranged in the support 11 for the corresponding ends of the cylindrical elements 7 is larger and takes account of the axial travel of these elements. Finally, return springs are arranged between the bottom of the aforementioned recesses of the support 11 and the corresponding ends of the cylindrical elements 7 to allow the latter to follow the axial translation of the part 6b of the shaft 6.

  
and that of the support 10. These return springs can obviously be arranged elsewhere while filling the

  
same function.

  
In the third embodiment, the tree

  
control 6 is still in one piece as in the first case. The support 10 is also similar and rotates without sliding around the axis of the shaft 6. However, the housings of the support 10 for the ends of the cylindrical elements 7 are all deeper than in the first example and their depth is a function of the axial stroke of

  
these elements 7. On the other hand, the support 11 rotates by sliding around the axis of the shaft 6. For this purpose, the support 11 is' driven by: transmission rods 31 which

  
are parallel to the axis of the shaft 6 and whose ends

  
 <EMI ID = 54.1>

  
ports 10 and 11 by being able to slide there. In addition, the bottom of the support 11 'has a cam surface 32 constantly cooperating with a reverse cam surface 33 carried by the removable bottom 34 of the protective screen.

  
In the last example, the cylindrical elements 7 are biased by at least one helical spring 35

  
 <EMI ID = 55.1>

  
one on top of the other. In this way, any rotation of the shaft 6 causes an identical rotation of the cylindrical elements 7 and forces the cam surfaces 32 and 33 to cooperate with one another. Thus, during their rotation, the cylindrical elements 7 are obliged to be displaced axially along the profile of the cam surfaces 32 and 33.

  
The cam surfaces 32 and 33 can moreover be located for example as indicated in FIG. 8 or in any other position along the shaft 6. In fact, the cam surfaces 32 and 33 can be arranged at n ' any place of the brush between a fixed part and a rotating part of this brush.

  
In the last illustrated embodiment

  
in Figure 9, the two rotary supports 10 and 11 are mechanically connected to each other by rigid connecting rods 36 so as to be able to rotate at the same time and at equal angular speeds, around the longitudinal axis of the shaft 6 The ends of the connecting rods 36 are engaged in corresponding blind holes of the supports.
10 and 11. The connecting rods 36 extend parallel

  
 <EMI ID = 56.1>

  
shaft 6. The connecting rods 36 are arranged regularly around the longitudinal axis in question, respectively

  
 <EMI ID = 57.1>

  
indeed Figure 9. In fact, the connecting rods 36 are coupling elements of the rotary supports

  
 <EMI ID = 58.1>

  
of abutment to the tufts of bristles 8 of the cylindrical element

  
7 which is located before it with regard to the direction of rotation of the shaft 6.

  
Obviously, the connecting rods 36 can be replaced by at least one mechanical element connecting the rotating supports 10 and 11 to ensure like them the identical simultaneous rotation of these supports 10 and 11. In addition. In particular, the element in question may be located axially between the cylindrical elements 7.

  
The connecting rods 36 or the equivalent mechanical element make it possible to avoid the twisting of the cylindrical elements 7 during their rotation and the distortion of their tufts of bristles 8.

  
It is obvious that the invention is not exclusively limited to the embodiments shown and that many modifications can be made in the form,

  
the arrangement and constitution of some of the elements involved in their realization, provided that these modifications are not in contradiction with the object of each of the following claims.

  
Thus, instead of being three in number, the cylindrical elements 7 may be two in number or more than three in number. In the context of the invention, it is also possible to provide a toothbrush, the head of which has only a single cylindrical element carrying one or more rows of tufts of bristles. In this case, it is necessary to provide the head of the brush with means making it possible to block the single cylindrical element in different angular positions, so as to adjust it adequately; the angle of attack of the teeth by the tufts of bristles, as a function of the direction of rotation of the assembly formed by the cylindrical element and its supports.

  
Instead of being tangent to each other, as shown in Figures 3 and 4, the cylindrical elements 7 bearing the tufts of bristles 8 may not be in contact with each other, however being understood that their longitudinal axes must be equidistant from the axis of the supports 10

  
and 11, these supports being able to be joined together, for example by an axis passing between the cylindrical elements 7.

  
Instead of carrying only one row of tufts of bristles, the cylindrical elements 7 can carry several parallel rows of such tufts or, in general, carry bristles on one or more parts of their lateral surface. i


    

Claims (1)

<EMI ID = 59.1> <EMI ID = 60.1> che, characterized in that the aforesaid head comprises at least one element substantially cylindrical which extends in the direction of the handle of the brush and carry at the corners a row of tufts of bristles perpendicular to its longitudinal axis, this cylindrical element having in care one of its ends housed in a hole made eccentrically in one end of a rotating cylindrical support which also extends in the direction handle of the brush and is connected to means for driving said support and the cylindrical element in <EMI ID = 61.1> <EMI ID = 62.1> 2.- .mechanical toothbrush according to claim 1, characterized in that it comprises three cylindrical elements each carrying at least one row of tufts of hairs. <EMI ID = 63.1> other of claims 1 and 2, characterized in that the cylindrical elements each carrying at least one row of tufts of hair are tangent to each other. <EMI ID = 64.1> <EMI ID = 65.1> comprises means for locking the cylindrical element or elements in two different angular positions. <EMI ID = 66.1> other of the preceding claims, characterized in that that the head of the brush comprises two cylindrical supports with flat or rounded bases, maintained at a determined distance from each other and each having holes in which are housed the ends of each of the cylindrical elements carrying at least one row of tufts of hairs. 6. A mechanical toothbrush according to claim 5, characterized in that the two cylindrical supports are mechanically connected to each other to rotate simultaneously and at equal angular speeds. 7.- mechanical toothbrush according to claim 5 or 6, characterized in that the rotational movement of the cylindrical elements relative to their support (s) is limited by the contact of a row of tufts of bristles carried by one of the cylindrical elements, with another cylindrical element. <EMI ID = 67.1> further of claims 1 to 7, characterized in that the head is provided with a protective screen preventing contact of the hairs with the soft tissues of the mouth, during the rotation of the cylindrical elements and their support (s) 9. A mechanical toothbrush according to claim 8, characterized in that the protective screen has a concave inner surface. 10. A mechanical toothbrush according to claim 8, characterized in that the protective screen supports at least one of the aforementioned cylindrical supports. <EMI ID = 68.1> <EMI ID = 69.1> concave interior of the protective screen and the axis of rotation of the aforementioned supports is such that the bristles carried by the cylindrical elements bend in contact with this interior surface. <EMI ID = 70.1> another of claims 1 to 11, characterized in that it further comprises a device for reversing the direction of rotation of the cylindrical elements and of their support (s). 13. A mechanical toothbrush according to claim 1, characterized in that the means for driving the cylindrical element or elements and their support (s) in rotation are constituted by an electric motor. 14. A mechanical toothbrush according to claim 11, characterized in that it comprises a switch allowing at will to rotate the motor in one direction or the other. <EMI ID = 71.1> another of claims 1 to 14, characterized in that the bristles exhibit differential rigidity from one of their ends to their other end. 16.- Secant toothbrush as claimed in claim 15, characterized in that the diameter of the bristles increases from one of their ends to their other end. 17. A mechanical toothbrush according to one of claims 1 to 16, characterized in that the or each cylindrical element carrying the tufts of bristles is movable alternately along its longitudinal axis during its rotation around the longitudinal axis of the handle. 18.- Mechanical toothbrush according to the claim <EMI ID = 72.1> of their axial translation, the cylindrical elements bearers of the tufts of bristles are aligned transversely without being offset with respect to one another. 19. A mechanical toothbrush according to one of claims 17 and 18, characterized in that the rotary supports for housing the ends of the or each cylindrical element carrying the tufts of bristles are guided helically. <EMI ID = 73.1> 20. A mechanical toothbrush according to claim 19, characterized in that each aforementioned support, respectively each aforesaid housing, has a sinusoidal or helical groove in which is guided a projection integral with this housing, respectively of this support. 21.- Mechanical toothbrush according to one of claims 17 and 19, characterized in that the or each cylindrical element carrying the tufts of bristles is biased at one end by a preferably helical spring constantly forcing by its other end, the support corresponding to this other end to rest on a cam surface disposed transversely around the longitudinal axis of the handle. <EMI ID = 74.1> tion 21, / characterized in that, for the or each cylindrical element carrying the tufts of bristles, the helical spring is arranged between one end of this element and the bottom of its housing in the corresponding rotary support, <EMI ID = 75.1> the removable bottom of the protective screen and cooperates with a reverse cam surface formed or presented by the rotary support corresponding to the other end of this element. 23.- Mechanical toothbrush substantially as described above, with reference to the accompanying drawings.