DE20107880U1 - Electrically operated personal care device, for example a toothbrush - Google Patents

Description

Schröter & Haverkamp Patent Attorneys

European Patent and Trademark Attorneys

WIK Far East Ltd.

Unit B, 23 F Manulife Tower
169, Electric Road
North Point
HONG-KONG
China

Electrically operated personal care device, for example toothbrush

The invention relates to an electrically operated personal care device, for example a toothbrush with a care part set in motion via an electric motor-driven drive train, in which drive train a power converter is inserted, by means of which the rotary motion of the drive shaft of the electric motor is converted into an oscillating motion.

Such electrically operated personal care devices, which can be designed as a toothbrush or massage device, for example, have an electric motor housed in a handle. The handle usually also houses a power source in the form of batteries. A shaft protrudes from the handle of such an electric toothbrush, at the end of which a brush head with the brushes is mounted so that it can rotate in an oscillating manner. The bristle head is driven into the oscillating rotary movement via a drive train arranged between the electric motor and the bristle head, into which a power converter is connected, by which the rotary movement of the drive shaft of the electric motor is converted into an oscillating movement. Such an electric toothbrush is

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known for example from DE 196 27 752 A1. In the subject of this document, a four-bar linkage is driven by the electric motor as a force converter, through which the desired conversion of the rotating rotary motion of the drive shaft of the electric motor into an oscillating or alternating rotary motion is converted. On the output side, an output shaft is connected to the four-bar linkage, which rotates in an oscillating manner according to the design of the four-bar linkage. The output shaft in turn engages with the brush head in such a way that the oscillating movement of the output shaft sets the brush head in an oscillating rotary motion. Depending on the design of the four-bar linkage used as a force converter, the oscillation angle can be designed differently.

A certain amount of installation space is required to create such a four-bar linkage. For this reason, the four-bar linkage is integrated into the handle and largely determines the diameter of the handle. However, slim handles cannot be created with such a force converter. Another disadvantage of using such a four-bar linkage is that several meshing gears are required to create it and to drive or output it, which can sometimes have a negative effect on the operating noise.

In the subject matter of this document, the output shaft necessarily extends from the area of the handle to the brush head. This oscillating rotary movement causes oscillations that are also transmitted to the handle, resulting in vibrations in the handle.

Based on this discussed prior art, the invention is therefore based on the object of developing an electrically operated personal care device as mentioned above, such that the disadvantages of the previously known prior art are avoided or at least reduced.

This object is achieved according to the invention in that the force converter comprises at least two conversion elements which support each other with their surfaces facing each other, one of which is a ro-

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tatorically driven drive element and another represents an output element connected to an output shaft and held against rotation, wherein the output element is supported with an output surface inclined with respect to the axis of rotation of the drive element on a drive surface of the drive element that is also inclined with respect to its axis of rotation, so that starting from a position of the drive surface and output surface inclined in the same direction, a rotary movement of the drive element is converted into a linear movement of the output element directed away from the drive element up to an oppositely inclined position of the drive surface and output surface, and comprises a return device for returning the output element moved by the stroke of the thrust movement carried out into the position of the drive surface and output surface inclined in the same direction.

In the personal care device according to the invention, which can be designed as an electric toothbrush, for example, the care part, for example the brush head, is driven, in contrast to the previously known prior art, not with an oscillating, rotary driven shaft, but with an oscillating, linearly moving shaft. This is achieved by using a force converter, which is formed from at least two conversion elements that support one another. One of the two elements is a drive element and another conversion element is an output element. The drive element is driven in rotation. The output element is connected to an output shaft that is mounted in a rotationally secure manner. The mutual support of the two conversion elements takes place on a contact surface that is inclined to the axis of rotation of the drive element and is formed by an inclined drive surface of the drive element and an equally inclined output surface of the output element. The angle of inclination of the two surfaces - drive surface and output surface - is expediently provided to be the same. Starting from a position of the drive surface and the output surface inclined in the same direction to each other, a rotary movement of the drive element results in a linear thrust movement of the output element directed away from the drive element due to the rotation-proof mounting of the output element. The thrust movement in this direction by the drive element continues until the two support surfaces are inclined in opposite directions to each other. In order to achieve the previously

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In order to return the output element moved away from the drive element to the starting position, the force converter further comprises a return device with which the output element is returned to the above-mentioned starting position when the drive element performs a further rotary movement. A spring element can serve as the return device, for example, against whose spring force the output element is moved by the drive element. The movement carried out by the output element and the output shaft connected to it is linear and takes place in the direction of the longitudinal extension of the axis of rotation of the drive element. Consequently, in the claimed object, in contrast to the previously known prior art, an oscillating linear movement is not imparted to an oscillating rotating movement but rather an oscillating linear movement. This has a positive effect on the vibration behavior.

By designing the power converter in the manner described above, it is clear that it requires very little installation space and that, in particular, no gears are in mesh with one another. This power converter can therefore be implemented in the smallest of spaces, for example in the shaft of an electric toothbrush, so that the output shaft driving the bristle head can also be designed to be very short. In particular, slim handles can also be implemented with such a power converter.

The two conversion elements are expediently designed in the shape of a disk, with the drive element being inserted in a rotationally driven hollow shaft in a rotationally fixed manner. A rotation-proof mounting of the output element can be achieved, for example, by mounting the output shaft connected to the output element in a rotation-proof manner.

In a preferred embodiment, a second output element arranged homoaxially to the first output element is arranged as a return device on the side opposite the drive element with respect to the first output element. Support between the drive element and the second output element takes place in the same way as the support between the drive element and the first output element, but the inclined output surfaces of the two output elements are inclined in opposite directions to each other and the

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both drive surfaces of the drive element are inclined in the same direction. With this return device, the second output element is driven starting in the position of the transfer elements in relation to one another in which the drive element no longer exerts a further pushing movement on the first output element. In this position, the drive element then exerts a pushing movement on the second output element, which pushing movement then results in the output unit being returned to its starting position when the drive element is stationary. This process, which extends over 360°, repeats according to the rotational speed of the drive element.

When using two output elements, as described above, the two output elements are expediently connected to one another by the output shaft, which passes axially through the drive element.

The drive surface of a drive element or the output surface of an output element can also be curved, for example concave, so that a play-free interaction between the drive element and the output element is ensured.

The invention is described below using exemplary embodiments. They show:

Fig. 1: Schematic of a force converter for an electrically operated

benes personal care device for implementing a rotary

Rotary movement into an oscillating linear movement in a first operating position,

Fig. 2: The force converter of Figure 1 in a second operating position

tion

Fig. 3: Another power converter for an electric toothbrush

trained personal care device in a first operating position and

Fig. 4: The personal care device of Figure 3 with the force converter in

a second operating position.

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A power converter 1 comprises two converter elements, one of which is a drive element 2 and another an output element 3. The drive element 2 is inserted into a rotary driven hollow shaft 4 and is connected to it in a rotationally fixed manner. The drive element is disk-shaped and has a drive surface 5 inclined relative to its axis of rotation. An output surface 6, which is also inclined relative to the axis of rotation of the drive element 2, is supported on the drive surface 5 of the drive element 2. This output surface 6 is the output element 3. The angle of inclination of the drive surface 5 and the output surface 6

Ø relative to the axis of rotation of the drive element 2 is the same. The drive element 3 is connected to an output shaft 7 which is mounted in a manner not shown in more detail so as to prevent it from rotating. The side of the output element 3 facing away from the drive element 2 is supported on a spring element 8. During a rotary movement of the drive element 2, the output element 3 is moved away from the drive element 2 as a result of the support arrangement of the two surfaces 5, 6 against one another, as symbolized by the arrow. This pushing movement is continued until the drive element 2 has rotated by 180° and is then in the position shown in Figure 2. From the co-inclined inclination of the drive surface 5 and output surface 6, they are now arranged in opposite directions to one another after the thrust has been exerted. To return the output element 3 to the initial situation shown in Figure 1 while simultaneously continuing to rotate the drive element 2, the energy stored in the spring element 8 during the thrust movement acts, which now returns the output element 3 and the output shaft 7 connected to it to the initial situation shown in Figure 1 after the drive element 2 has performed a 360° rotary movement. In this way, the rotary movement of the drive element 2 is converted into a linear oscillating movement of the output shaft 7.

Not shown in Figures 1 and 2 is the connection of a care part to be moved to the output shaft 7.

Figure 3 shows a section of a toothbrush 9 designed as an electric personal care device. Shown is a part of the shaft 10 adjacent to a handle (not shown), at the free end of which a

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Brush head 11 is rotatably mounted. The axis of rotation of the brush head 11 is approximately perpendicular to the longitudinal extension of the shaft 10. A hollow shaft 12 driven by an electric motor and a force converter 13 for converting the rotary motion of the hollow shaft 12 into an oscillating linear motion are accommodated in the shaft 10. The force converter 13 is basically constructed like the force converter 1 shown in Figures 1 and 2. The drive element 14 of this force converter 13 is connected in a rotationally fixed manner to the rotary driven hollow shaft 12. However, the force converter 13 has two output elements 15, 16 between which the drive element 14 is arranged. The drive element 14 has two drive surfaces 17, 17' running parallel to one another, which each cooperate with an output surface 18 or 19 of an output element 15 or 16. When the drive element 14 rotates, it exerts a thrust on either the output element 15 or the output element 16, so that the output unit formed from the two output elements 15, 16 and an output shaft 20 is set in an oscillating linear movement. To guide the rotationally fixed output elements 15, 16, these are also arranged so as to extend into the hollow shaft 12. The two output elements 15, 16 are connected to one another by the output shaft 20. In the subject of the design of this force converter 13, the output element 16 serves as a return device after the output unit has been moved away in the direction of the brush head 11 by a pushing movement. By using two output elements 15, 16, spring elements as a return means can be dispensed with, so that in this design the drive element 14 alternately generates a push towards or away from the brush head 11. By appropriately linking the output shaft 20 to the brush head 11, the brush head is set in an oscillating, rotary motion.

For the rotationally secure mounting of the output unit, the output shaft 20 can, for example, have radial projections which engage in corresponding recesses in the shaft 10, so that the output shaft 20 and accordingly also the output elements 15, 16 are then secured against rotation during a rotary movement of the drive element 14.

From the description of the invention it is clear that the force converter described can be used to effectively convert force from a rotary motion into an oscillating linear motion without requiring a particularly large structure for this purpose. In particular, the use of such a force converter also reduces vibrations, particularly in the handle. The force converter also causes no noise or at least no perceptible noise in terms of the volume that occurs when the device is in operation, particularly when the moving elements involved - drive elements and output elements - are made of plastic.

·? &id; i : ::..., · : ; -9- List of reference symbols Force converter 1 Transfer element, drive element 2 Transfer element, output element 3 Hollow shaft 4 Drive area 5 Output surface 6 Output shaft 7 Spring element 8th toothbrush 9 shaft 10 Brush head 11 Hollow shaft 12 Force converter 13 Drive element 14 Output element 15 Output element 16 Drive area 17, 17' Output surface 18 Output surface 19 Output shaft 20

Claims (10)

1. Electrically operated personal care device ( 9 ), for example a toothbrush with a care part ( 11 ) set in motion by an electric motor-driven drive train, in which drive train a force converter ( 1 , 13 ) is connected, by means of which the rotary motion of the drive shaft of the electric motor is converted into an oscillating motion, characterized in that the force converter ( 1 , 13 ) comprises at least two conversion elements ( 2 , 3 ; 14 , 15 ) which support one another with their surfaces facing one another, one of which represents a rotationally driven drive element ( 2 ; 14 ) and another of which represents an output element ( 3 , 15 ) connected to an output shaft and held in a rotationally secure manner, wherein the output element ( 3 , 15 ) is provided with an output surface ( 6 , 18 ) is supported on a drive surface ( 5 , 17 ) of the drive element ( 2 , 14 ) which is also inclined with respect to its axis of rotation, so that starting from a position of the drive surface ( 5 , 17 ) and the driven surface ( 6 , 18 ) inclined in the same direction, a rotary movement of the drive element is converted into a linear movement of the driven element ( 3 , 15 ) directed away from the drive element ( 2 , 14 ) up to an oppositely inclined position of the drive surface ( 5 , 17 ) and the driven surface ( 6 , 18 ), and a return device ( 8 , 16 ) for returning the driven element ( 3 , 15 ) moved by the stroke of the thrust movement carried out into the position of the drive surface ( 5 , 17 ) and the driven surface ( 6 , 18 ). 2. Personal care device according to claim 1, characterized in that the drive element ( 2 , 14 ) and the output element ( 3 , 15 ) are disc-shaped. 3. Personal care device according to claim 1 or 2, characterized in that the angle of inclination of the drive surface ( 5 , 17 ) of the drive element ( 2 , 14 ) and the output surface ( 6 , 18 ) of the output element ( 3 , 15 ) are each equal when measured against the axis of rotation of the drive element ( 2 , 14 ). 4. Personal care device according to one of claims 1 to 3, characterized in that the drive element ( 2 , 14 ) is inserted in a rotationally fixed manner into a rotationally driven hollow shaft ( 4 , 12 ) of the drive train. 5. Personal care device according to one of claims 1 to 4, characterized in that a second output element ( 16) connected to the first output element (15 ) is provided as the return device, which is supported by an output surface ( 19 ) inclined relative to the axis of rotation of the drive element ( 14 ) on a second drive surface ( 17 ') of the drive element ( 14 ) inclined relative to its axis of rotation, so that starting from a position of the drive surface ( 17 ') and output surface ( 19 ) inclined in the same direction, a rotary movement of the drive element ( 14 ) is converted into a linear thrust movement of the output element ( 16 ) directed away from the drive element ( 14 ) up to a position of the drive surface ( 17 ') and output surface ( 19 ) inclined in opposite directions. 6. Personal care device according to claim 5, characterized in that the angle of inclination of the output surface ( 19 ) of the second output element ( 16 ) relative to the axis of rotation of the drive element ( 14 ) corresponds to the angle of inclination at which the output surface ( 18 ) of the other output element ( 15 ) is inclined relative to the axis of rotation of the drive element ( 14 ). 7. Personal care device according to claim 5 or 6, characterized in that the inclination of the output surfaces ( 18 , 19 ) of the two output elements ( 15 , 16 ) are arranged in opposite directions to one another. 8. Personal care device according to one of claims 5 to 7, characterized in that the two output elements ( 15 , 16 ) are connected to one another by an output shaft ( 20 ) which extends axially through the drive element ( 14 ). 9. Personal care device according to one of claims 1 to 8, characterized in that either the drive surface of a drive element or the output surface of an output element is curved, in particular concavely curved. 10. Personal care device according to one of claims 1 to 9, characterized in that it is an electric toothbrush ( 9 ) and the care part set in motion is a brush head ( 11 ) which can be set into an oscillating rotary movement by the output shaft ( 20 ) when the electric motor is operating.