KR20070022333A - Shaving apparatus - Google Patents

Abstract

The shaving device has at least one cutting unit 3 with an outer cutting member 4 and a movable inner cutting member 6. After cutting the hair, an energy-dissipating system 22 is provided between the mutually movable portions of the inner 6 or outer cutting member 4 to reduce the springing effect between the inner and outer cutting members. do. Such an energy-dissipating system may be, for example, component 22 having viscoelastic properties.

Description

Shaving device {SHAVING APPARATUS}

The present invention relates to a shaving device having a housing and at least one cutting unit comprising an outer cutting member and an inner cutting member that can be driven relative to the outer cutting member, the outer cutting member being defined by a cutting edge. A hair trap opening, the inner cutting member having a cutting component at an end having a cutting edge for cooperating with the cutting edge of the outer cutting member for the purpose of cutting hair, and the shaving device having an internal cutting member It further includes an elastic member for applying a force on the inner cutting member in the direction of the drive member and the outer cutting member for driving the.

The invention also relates to a cutting unit for use in the shaving device.

This shaving device is known from WO 03/0115387 (PHNL010541). As small a cutting gap as possible should be between the cooperating cutting edges of the inner and outer cutting members if the hair is cut satisfactorily. This has actually been realized so far in that the driving member for driving the inner cutting member is also made elastic in the direction of the outer cutting member. As a result, the inner cutting member bears the outer cutting member under some deflection stress, ie the cutting edge of the inner cutting member is pressed against the cutting edge of the outer cutting member with some force. The cutting gap is thus substantially zero. This is necessary because the inner cutting member decelerates while cutting the hair, and the resulting cutting force has a direction that tends to press a somewhat distant cooperative cutting edge, which can lead to too wide a cutting gap. The elastic force of the drive member acts to prevent the gap between the cutting edges from becoming too wide while cutting the hair. As a result, the contact pressure between the inner and outer cutting members will be small while cutting the hair, and the friction force will also be low. Nevertheless, the speed of the cutting force generated attempts to drop the inner cutting member away from the outer cutting member immediately after cutting the hair. The inner cutting member will subsequently push back towards the outer cutting edge by the axial spring pressure of the drive member. The inner cutting member then strikes against the inner side of the outer cutting member. The inner cutting member then springs back to the outer cutting member, resulting in another cutting gap, although smaller than the initial gap. The inner cutting member then comes back again. The inner cutting member thus springs up a few more times on the outer cutting member until the cutting edges are in contact with each other. This only takes about 0.5 seconds, but new hair is cut again during this period. In addition, the cutting components are firmly connected to most shaving devices and to each other, and also springing action is caused by other cutting components or at least some of the cutting components. The fact is that the cutting component acts as a vibration mass spring system that attenuates. It would be best if the cooperative cutting edges were immediately in contact with each other again after the hair was cut and left facing each other, i.e. without any bleeding action. The cutting system will then be optimally prepared for cutting the next hair. This will be achieved if the deflection stress is chosen to be much larger. However, in the period when no hair is cut, the deflection stress force causes a relatively high contact pressure between the cooperating cutting members and thus a relatively strong frictional force. The hair is actually cut in less than 10% of the total shaving time during normal shaving operation. The cutting edges lie opposite one another under the rest of the elastic force. This not only causes the cutting edges to wear, but also causes friction for most of the time consuming a lot of energy. This means a rechargeable shaving device in which the battery has to be charged more often. Rechargeable batteries also have a finite lifetime and are not satisfactorily charged after some time and must be replaced. The device is more energy-efficient with less friction between the cutting members.

It is an object of the present invention to improve the cutting process of the shaving device as described at the outset.

The invention is characterized in that for this purpose an energy-dissipating system is between the inner cutting member or the mutually moving mass portion of the outer cutting member.

The energy-dissipation system increases attenuation or damping of the movement of the inner cutting member after cutting the hair. In other words, the inner cutting members stop more quickly, ie the cooperating cutting edges are placed faster and permanently opposite each other after the hair is cut than without the energy-dissipating system. A further advantage is that the inner cutting member can be selected such that the deflection stress pressed against the outer cutting member is small, which results in less frictional losses. The friction torque is also lower. This has the consequence for a rechargeable shaving device which results in a longer shaving time of a fully charged battery, less heat generation and less wear on the cutting edge (long operating life).

A preferred embodiment of the shaving device according to the invention is a disc having an inner cutting member with a cutting component formed thereon, the disk being fixed on the carrier, the inner cutting member being located on the opposite side of the cutting component with respect to the carrier. While further comprising a backing plate, the energy dissipation system is characterized in that it is between the carrier and the back plate. The disk with the cutting component, the carrier and the coupling part may be considered one unit of the main component of the inner cutting member, while the back plate may be considered the other main component of the inner cutting member. Thus, the energy-dissipation system is connected to the assembly of the main component on one side and to the main component formed by the back plate on the other side.

Another preferred embodiment is characterized in that the inner cutting member has a disk on which the cutting component is formed and a back plate located on opposite sides of the cutting component for the disk, wherein the energy-dissipating system is between the disk and the back plate. Disks with cutting components and connections now form one main component, while the back plate forms the other main component.

If the cutting component is a flexible component, it is also possible to provide an energy-dissipating material to the cutting component itself.

The springing of the inner cutting member relative to the outer cutting member may also be reduced in embodiments in which the outer cutting member has a back plate and the energy-dissipating system is located between the outer cutting member and the back plate. The outer cutting member and the back plate then constitute mutually moving principal components with an energy-dissipating system.

The energy-dissipation system is preferably formed by the components of the visco-elastic material. Materials with viscoelastic properties are, for example, polyborosiloxanes and bitumen.

A preferred embodiment of the shaving device according to the invention is characterized in that the inner cutting member can be driven in rotation and the damping means are formed by an annular component.

Another possibility is that the energy-dissipation system comprises a friction damper with at least one elastic component connected in parallel.

The invention further relates to a cutting unit comprising an outer cutting member and an inner cutting member that can be driven relative to the outer cutting member, the outer cutting member having a hair trap opening defined by a cutting edge, the inner The cutting member has a cutting component at the end having a cutting edge for cooperating with the cutting edge of the outer cutting member for the purpose of cutting the hair, and the energy-dissipating system is the main movement of the internal cutting member or the external cutting member. It is characterized by being between parts.

The invention will now be described in more detail with reference to the embodiment of the rotary drive shaving device shown in the drawings.

1 is a perspective view of a shaving device with three cutting units.

2 is a sectional view of the cutting unit of FIG. 1 of the first embodiment;

3 is a sectional view of the cutting unit of FIG. 1 of the second embodiment;

4 is a sectional view of the cutting unit of FIG. 1 of a third embodiment;

5 shows a fourth embodiment of the present invention.

Corresponding elements are given the same reference numerals in the description of the embodiments below.

The shaving device of FIG. 1 has a housing 1 with a holder 2 that can be removed from the housing or pivoted relative to the housing. Three cutting units 3, also referred to as shaving heads, are in the holder.

2 shows one of the cutting units 3 formed by the outer cutting member 4 and the inner cutting member 6 cooperated therewith. The outer cutting member 4 has the shape of a circular cap with a rim of the hair trap opening 5. The hair trap opening is defined by a wall provided with cutting edges 7. The inner cutting member 6 comprises a disk 8 on which a number of cutting components 9 are formed. The disk 8 is fixed on the carrier 10. The ends of the cutting components 9 have respective cutting edges 11 to cooperate with the cutting edges 7 of the outer cutting member 4. The connecting portion 12 is fixed to the center of the carrier 10 and has a connecting opening 13 at the bottom of the carrier. The carrier 10 and the connecting portion 12 may be separate elements or alternatively may be manufactured in one piece. The inner cutting member 6 has a central bearing on the outer cutting member 4. For this purpose, the outer cutting member 4 has a central bearing shaft 14 in the form of a projection of a circular cap and the connecting portion 12 has a bearing opening 15 at the top where the bearing shaft 14 fits. The inner cutting member 6 is driven in rotation by the motor 16. The drive member 17 is connected to the motor shaft 18. The drive member 17 has the shape of a hollow connecting pin that can be connected to the connecting portion 12. For this purpose, the connecting pin has a connecting head 19 which projects into the connecting opening 13 of the connecting portion 12. The connecting pin is provided on the motor shaft 18 so as to be elastic in the axial direction. To achieve this, the spring 20 is tensioned between the connecting pin and the motor shaft and presses the inner cutting member 6 in the direction of the outer cutting member 4 with some deflection stress. The cutting edge 11 of the cutting component 9 of the inner cutting member 6 thus lies under pretension against the cutting edge 7 of the outer cutting member 4. The inner cutting member 6 further comprises an annular back plate 21 which is located on the opposite side of the cutting component 9 with respect to the carrier 10. Between the back plate 21 (in fact the main plate) carrier 10, there is an energy-dissipating system in the form of an annular component 22 of material with damping properties. The disk 8 with the cutting component 9, the carrier 10, and the connecting portion 12 can be regarded as an assembly of the main elements of the inner cutting member 4, while the back plate 21 is It can be regarded as another main element of the inner cutting member. The energy dissipation system (component 22) is thus connected to the assembly of the main elements 8, 9, 10, 12 on one side and to the main element formed by the back plate 21 on the other side.

In the example of FIG. 3, the energy-dissipation system 22 is located between the disk 8 with the cutting component 9 and the back plate 21. The disk 8 with the cutting component 9 and the connecting portion 12 now forms the main main element, while the back plate 21 forms the other main element.

In the example of FIG. 4, the outer cutting member has a back plate 21. An energy dissipation system 22 is provided between the lower rim 23 and the rear plate 21 of the cap-shaped outer cutting member 4. The outer cutting member and the back plate now form a mutually moving main element with an energy dissipation system.

The example of FIG. 5 is a detailed view of the cutting component 9 of the inner cutting member 6. When the cutting component is configured as a flexible component, it may provide an energy-dissipating material to the cutting component itself, and more specifically, may be provided at a position where the cutting component is bent while the hair is cut, as shown in the figure. have. This also achieves damping of the inner cutting member after the hair is cut

The damping material used may be a viscoelastic material, for example polyborosiloxane or bitumen.

The energy-dissipation system can alternatively be formed by friction dampers with at least one elastic component connected in parallel (not shown).

It will be apparent that the present invention is not limited to the rotary shaving device as described in the embodiment, and that the present invention can be equally used in a razor having an internal cutting member driven reciprocally.

The present invention is used in a shaving apparatus having at least one cutting unit comprising a housing and an inner cutting member that can be driven relative to the outer cutting member and the outer cutting member.

Claims (10)

A shaving device having a housing and at least one cutting unit 3 comprising an outer cutting member 4 and an inner cutting member 6 which can be driven relative to the outer cutting member, wherein the outer cutting member 4 A hair trap opening 5 defined by the cutting edge 7, the inner cutting member 6 having a cutting edge 7 of the outer cutting member 4 for the purpose of cutting hair. Having a cutting component 9 at the end having a cutting edge 11 for cooperating with the shaving device, the shaving device being in the direction of the drive member 17 and the outer cutting member 4 for driving the inner cutting member 6. In the shaving device further comprises an elastic means 20 for applying a force on the internal cutting member 6, The energy-dissipating system 22 is characterized in that it is between the mutually moving main portions of the inner cutting member 6 or the outer cutting member 4, Shaving device. 2. The inner cutting member (6) according to claim 1, wherein the inner cutting member (6) has a disk (8) on which the cutting component (7) is formed, the disk (8) being fixed on a carrier (10) (6) further comprises a back plate (21) located on the opposite side of the cutting component (9) with respect to the carrier (10), while the energy-dissipating system comprises the carrier (10) and the back plate ( 21) between, shaving device. 2. The inner cutting member (6) according to claim 1, wherein the inner cutting member (6) has a disk (8) on which the cutting component (9) is formed and a back plate (21) located on the opposite side of the cutting component (9) to the disk (8). Shaving device, characterized in that the energy dissipation system is between the disk (8) and the back plate (21). 2. The shaving device according to claim 1, wherein the cutting component (9) is a flexible component provided with the energy-dissipating material. 2. The shaving device according to claim 1, wherein the outer cutting member has a back plate 21 and the energy-dissipating system is located between the outer cutting member 4 and the back plate 21. . 6. The shaving device according to any one of claims 1 to 5, wherein the energy-dissipating system is formed by a component of a visco-elastic material. 7. The shaving device according to any one of the preceding claims, wherein the energy-dissipating system comprises a friction damper with an elastic component connected in parallel to the system. 7. Shaving apparatus according to claim 6, characterized in that the inner cutting member (6) can be driven in rotation and the component of the visco-elstic material is an annular component (22). As a cutting unit, the cutting unit comprises an outer cutting member 4 and an inner cutting member 6 which can be driven relative to the outer cutting member, the outer cutting member 4 being defined by a cutting edge 7. A hair trap opening (5), the inner cutting member (6) of the end having a cutting edge (11) for cooperating with the cutting edge (7) of the outer cutting member (4) for the purpose of cutting hair. In a cutting unit having a cutting component 9, The energy-dissipation system 22 is characterized in that it is between the mutually moving main portions of the inner cutting member 6 or the outer cutting member 4, Cutting unit. 10. The inner cutting member (6) according to claim 9, wherein the inner cutting member (6) has a disk (8) with a cutting component (7) formed on the carrier (10) and the inner cutting member (6). ) Further comprises a rear plate 21 positioned on the opposite side of the cutting component 9 with respect to the carrier 10, while the energy-dissipating system comprises the carrier 10 and the back plate 21. The cutting unit, characterized in that between.

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