The invention relates to a hair cutting apparatus with a housing and at least one cutting unit which comprises a stationary cutting member and a driven cutting member performing a reciprocating movement with respect to the stationary cutting member, which driven cutting member is provided with cutting elements, each cutting element of the driven cutting member and the stationary cutting member being provided with mutually cooperating bearing surfaces having cutting edges and counter-cutting edges, respectively, for cutting hairs, said driven cutting member being provided with a coupling element, while said hair cutting apparatus further comprises a drive member for driving the driven cutting member via the coupling element.
Such a hair cutting apparatus is known, for example, from EP 0914234 or EP 0487537. If hairs are to be cut off satisfactorily, a so-termed cutting gap that is as small as possible must be present between the cooperating cutting edges of the driven and the stationary cutting member. This has been realized in practice until now in that the driven cutting member is made resilient towards the stationary cutting member. This causes the driven cutting member to bear on the stationary cutting member under a certain bias tension, i.e. the cutting edges of the driven cutting member are urged against the cutting edges of the stationary cutting member with a certain force. The cutting gap, therefore, is in fact zero. Said bias tension is necessary because the driven cutting member is decelerated during cutting of a hair, and the occurring cutting edges have a direction such that the cooperating cutting edges tend to be pressed apart somewhat, which could lead to too wide a cutting gap. The resilient force of the drive member prevents the gap between the cutting edges from becoming too great during cutting. As a result, the contact pressure between the driven and the stationary cutting member is small during cutting, and the friction is correspondingly small. The cooperating cutting edges in fact form the bearing surfaces of an axial bearing between the stationary and the driven cutting member. In those periods in which no hairs are cut, however, the bias tension causes a comparatively great contact pressure between the cooperating cutting members, and accordingly a comparatively strong friction. Less than 10% of the total cutting time is occupied by cutting of hairs during a normal cutting operation. The cutting edges bear on one another under spring pressure in the remaining time. This causes a friction during a major portion of the time which causes not only wear of the cutting edges, but which most of all requires a lot of energy. This means for rechargeable hair cutting apparatuses that their batteries have to be charged more often. Rechargeable batteries also have a finite life span, and after a certain time the batteries can no longer be sufficiently charged and will have to be replaced. A smaller friction between the cutting members makes the apparatus more energy-efficient.
It is an object of the invention to have the cutting process proceed satisfactorily in a hair cutting apparatus and to reduce the friction losses between the driven and the stationary cutting member still further.
The invention is for this purpose characterized in that means with visco-elastic properties are present between the coupling element and the driven cutting member.
The means with visco-elastic properties have resilient as well as damping properties, i.e. the means behave rigidly in the short term and slackly in the longer term. This means that compression or tension exerted on said means in a very short time span causes them to have a comparatively rigid behavior, whereas compression or tension provided over a longer time span causes the means to be comparatively slack. In fact, the means with visco-elastic properties are present in the dynamic path of a closed system formed by the stationary cutting member, the driven cutting member, the coupling element, and the housing in which the cutting unit is present. As was described above, no hairs are cut during the major portion of the cutting time. Now if means having visco-elastic properties are present between the coupling element and the driven cutting member, a small cutting gap will arise between cooperating bearing surfaces during a major portion of the cutting time, i.e. both in periods in which no hairs are cut and during cutting of hairs. The friction between the cooperating cutting edges is accordingly small. This may be explained as follows.
The cutting force occurring during cutting of a hair causes a pressure on the cutting edge of the driven cutting member, so that the driven cutting member tends to be pressed away from the stationary cutting member, which would lead to an undesirable cutting gap. The speed of the cutting process suddenly increases the pressure on the driven cutting member strongly. The damping properties of the visco-elastic material ensure that the sudden pressure rise is accommodated by the material, which behaves rigidly then. Nevertheless, a very small cutting gap arises between the cooperating cutting edges: the visco-elastic element is compressed slightly. After the hair has been cut through, the internal cutting member is pressed back towards the external cutting member under the influence of the resilient pressure of the visco-elastic element. In practice, however, another hair will often be cut through again before the cutting edges lie completely against one another. The cutting gap is so small that the cutting process is not adversely affected.
The invention will now be explained in more detail with reference to embodiments shown in the drawings, in which:
The hair clipper shown in
The example shown in
The shaving head 21 can be pivotably provided in the handle 22. This is indicated in
The means having visco-elastic properties may comprise one element with both resilient and damping properties. As is well known in the art, visco-elasticity is measured in terms of the material's dynamic modulus (also known as complex modulus). The dynamic modulus of a material is based on the material's storage and loss moduli. Materials having such visco-elastic properties are, for example, polyborosiloxanes and bitumen. It is alternatively possible for the means having visco-elastic properties to comprise a plurality of elements, which all have both resilient and damping properties, or among which certain elements have only resilient and other elements have only damping properties. The elements must be connected in parallel in the latter case.
Number | Date | Country | Kind |
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04102823 | Jun 2004 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/IB2005/051919 | 6/10/2005 | WO | 00 | 12/19/2006 |
Publishing Document | Publishing Date | Country | Kind |
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WO2006/000935 | 1/5/2006 | WO | A |
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20080016695 A1 | Jan 2008 | US |