DE1151307B - Swing armature drive for dry razors with a reciprocating working movement of a shear knife - Google Patents

Description

Oscillating armature drive for dry shavers with reciprocating Working motion of a shear knife The invention relates to an improvement on an electric oscillating armature drive for dry shavers with reciprocating Working movement of a shear knife. The oscillating armature drives known for dry shavers usually form an oscillating system of two masses and a working spring; the both masses are an electromagnet and an armature assigned to it. at the use of a swing armature drive for a dry shaver with back and forth The armature with the shear blade is the following working movement of a shear knife usually combine to form a single vibratory mass. The swinging movement such an anchor is used for work performance, which is why this anchor hereinafter referred to as the working anchor. 1111 In terms of structure, The known oscillating armature drives distinguish between the following two types, for example: In one type, the one or both poles of the electromagnet upstream vibrates Armature in the direction of the magnetic pole axis, i.e. more perpendicular to the magnetic pole face Direction back and forth, with the other type it oscillates transversely to the magnetic pole axis, that is exactly or approximately parallel to the magnetic pole face. The latter type of training has the advantage that the armature never touches the magnetic core during its oscillating movement can toast. In a known oscillating armature drive of the latter type is the Magnetic core U-shaped, and the z. B. rod-shaped or also U-shaped trained armature is each with one of its two pole ends one pole of the magnet assigned and held in such a way that they can vibrate transversely to the pole axes of the two magnetic poles, that its poles are in its rest position laterally from the pole faces of the Both magnetic poles are located and in operation by the attraction of the magnet periodically drawn in the center in front of the pole faces of the magnet. Of a The present invention is based on oscillating armature drive of this type.

The oscillating movements of the working armature of any oscillating armature drive also cause the electromagnet to vibrate when driving a Dry shaver is also transmitted to the device housing as vibrations. this is undesirable for both the device and its user. As a remedy against this it is known to add one more to the electromagnet of the oscillating armature drive assign the second anchor, so that it is parallel to the working anchor, but in opposite directions swings. This second anchor is at least partially - with favorable dimensioning also largely - a mass balance against the effect of the working anchor mass achieved, which is why it is referred to below as a compensating anchor. If so desired the oscillating movement of the compensating anchor as well as that of the working anchor can be added be used for work performance.

The use of such compensation anchors is also important in dry razors known. For example, dry shavers with a vibrating armature drive are known, whose magnetic core is rod-shaped and wherein each pole end of the magnetic core an oscillating armature is placed in front of each. With some of these devices (German Patents 492 391 and 479 652, Fig. 2) is only one of the two anchors with a back and movable shear blades connected, so that the second anchor only the serves to balance the masses. In another such device (German patent 932172) is each of the two anchors with a shear knife of two parallel to each other Shaving heads connected. A vibrating armature drive for a dry shaver is also known (German patent 479 652, Fig. 1), in which only one pole end of a rod-shaped Magnetic core is a working anchor upstream. This working anchor is on one one-armed pivot lever attached whose free end protruding beyond the armature is connected to the shaving screen of the shaver. For mass balancing there is also a Auxiliary mass attached to one arm of a two-armed swivel lever, whose other arm is coupled to the pivot lever of the working anchor.

All of these known devices belong to the former of the two at the outset mentioned training types of oscillating armature drives in which the working armature oscillates in the direction of the magnetic pole axis and thus if the oscillation amplitude is unintentionally too large can hit the magnetic pole face. If you wanted the familiar with these devices Type of attachment of compensating anchors to the second of the two types of training mentioned transferred by oscillating armature drives, - in which the working armature is parallel to the Magnetic pole face vibrates and of which, as mentioned, the present invention out, they would probably be consistent even with skilful structural modifications rather complicated and only weak devices in terms of force. Object of the invention For such a transmission, it is necessary to have a transmission that is as simple as possible and also good in terms of force Find solution.

This solution is in the case of an electromagnet and armature Oscillating armature drive of a type in which the armature with one of its two Pole ends each assigned to a pole of the U-shaped magnet and such is held that can oscillate transversely to the pole axes of the two magnetic poles its poles in its rest position to the side of the pole surfaces of the two magnetic poles and periodically centered during operation due to the attraction of the magnet be drawn in front of the pole face of the magnet, for dry shavers with a reciprocating working movement of a shear blade according to the invention thereby achieved that in the known assignment of a mass balancing serving, Compensating anchor oscillating in the opposite direction and parallel to the working anchor at the same time The compensating armature electromagnet is divided into two half-armature and these are symmetrical in mass are arranged on both sides of the working anchor.

Particularly advantageous for the practical implementation of the invention Exemplary embodiments are described on the basis of the drawing. Each other in the figures corresponding individual parts are each provided with the same reference numerals.

A first embodiment is shown in FIGS. A Oscillating armature drive consists of the electromagnet 1, the working armature 2 and one U-shaped leaf spring 3 holding the armature so that it can vibrate. is the working anchor 2 in its rest position shown on the right side from the pole faces of the magnet 1. Additionally are the magnetic poles of the magnet 1 upstream of two compensating anchors 4, each of which has one; also U-shaped leaf spring 5 can be kept vibrating. The anchors 4 are also located in their illustrated Rest position to the side of the pole faces of the magnet 1, but to the left side. The working anchor 2 is provided with a driving pin 6, which for engagement in a not shown A shaving knife of a dry shaver is used. The compensation anchor 4 can either serve exclusively for mass balancing or, if desired, by means of the dashed line drawn driving pin 7 also drive a shear blade. For example can the driving pins 6 and 7, the two lower blades of two parallel next to each other arranged shaving heads, e.g. B. a sieve shear head and a comb shear head, drive.

If the electromagnet 1 is energized, the armature 2 and 4 together with their springs 3 and 5 move periodically from their rest position to the central position in front of the end faces of the magnet, namely the armature 2 with the spring 3 in the direction of arrow 30 and the armature 4 with the springs 5 in the direction of the arrow 50. The oscillating movement of the armature 2 on the one hand and the two armatures 4 on the other hand are therefore opposite to one another. As a result, mass balancing occurs at least partially; the moving masses and the effective spring forces can, however, be coordinated in a known manner in such a way that, at least in practice, a complete mass balance is achieved.

In what way the shear part driven by the oscillating armature drive of the shaver is formed and coupled to the oscillating armature drive is for the operation of the oscillating armature drive in itself indifferent. For example for this it is shown in FIG. 5 how by means of the anchor 2 or the attached thereto Driving pin 6 a knife support plate 8 can be set in oscillating movements, which carries the two shear blades 9 and 10 and in the present case on bearing balls 11 is stored. The cutting blades 9 and 10 can, for example, be the lower blades a comb shear head and a sieve shear head.

Since the two balance anchors 4 in Fig. 1 to 5 like a single mass work, they could, if desired, also be structurally connected to one another, for example, in such a way that in FIG. 5 the two balancing masses 4 form a frame-shaped Forms are supplemented, which includes the anchor 2 on all sides, so also on the front side. This at the same time makes it possible to use the balancing mass in a simple manner Way to enlarge. The same is achieved when the two balancing masses by means of one or more webs with one another to form a bridge structure spanning the armature 2 be united.

In the device according to FIGS. 1 to 5, unless the movement of the balancing armature 4 serving for mass balancing is also used to move a shear knife, the following two total masses against each other: One total mass consists of that of the working armature 2 and that driven by this and with Mass with the center of gravity a, while the second total mass is formed by the compensating anchors 4 with the center of gravity b. The first total mass is referred to in the following as the working total mass and the second as the balancing total mass. If it is not negligibly small, the mass of the springs 3 and 5 should also be included in one or the other total mass. The centers of gravity a and b of the two total masses lie perpendicularly one above the other in the embodiments according to FIG. 6; Due to the difference in height between points a and b , torques occur in the aforementioned central plane which are detrimental to the shaving device, but in particular are disruptive to the hand of the device user. According to a further development of the invention, these torques can be avoided in that the centers of gravity of the two total masses are brought to at least approximately the same level with one another. In the embodiment according to FIGS. 6 and 7, this is achieved by the following special measures compared to the example according to FIG. secondly, the compensating armatures 4, which are hereby forced away from the pole faces of the magnet 1, are arranged in such a way that they oscillate along the side faces of the magnet poles 100; thirdly, however, the compensation anchors 4 are provided with upwardly directed extensions 40 which shift the center of gravity of the total compensation mass upwards. As a result of this shift in the center of gravity of the two total masses, the two centers of gravity can be brought so far closer together that the torque to be combated becomes considerably smaller or practically negligible.

In Fig. 7, the compensation armature 4 and their springs 5 are drawn laterally away from the magnet 1 for better clarity; one has to think of the springs 5 in the direction of the arrows 500 so far closer to the spring 3 that they assume the position shown in dashed lines, so that the secondary armatures 4 carried by the springs 5 and their extensions 40 then also have the values shown in FIG have shown relative position to the magnet 1.

FIG. 8 shows a further development of the example according to FIG. 6, in that the upwardly directed extensions 40 even protrude beyond the armature 2 and grip around, whereby the center of gravity of the balance total mass is pressed even higher can be.

In Fig. 9 it is shown as a modification to FIG. 8 that the compensating anchor 4 can protrude beyond the armature 2 and embrace without coming from the face of the magnet 1 to be displaced.

The center of each of the U-shaped leaf springs 3 and 5 can be a be stiff traverse, which at both ends by means of z. B. straight leaf springs is supported to vibrate. The anchors can, for example, instead of using leaf springs be kept oscillatable by means of tension or compression springs. At least approximately rectilinear guidance of the anchor can also in this case by the attachment method the spring means, but can also be special guideways, z. B. guide grooves, be provided for the anchor.

An embodiment in which a pivot lever for parallel guidance is also shown in FIG. 10. The working anchor 2 is at one end of an in the axis 12 rotatably mounted two-armed pivot lever 13 attached with its other end drivingly engages the lower cutter 14. So are they Compensating anchor 4 at one end each one in the axis 12 rotatably mounted two-armed Swivel lever 15 attached, which has an additional balancing mass at its other end 16 carries. A spring 17 holds the pivot lever 13 together with the armature 2, and one spring each 18 holds the pivot lever 15 together with the compensating anchors 4 in the rest position shown, Here, too, the rest positions of the working anchor 2 and the compensating anchor 4 according to opposite sides of the magnet 1 are offset.

A driving pin 6 or the like for power transmission from the armature (working armature and possibly compensating anchor) for the shear blades 9 and 10 to be driven is not required if the anchor is firmly assembled with the shear knife or even forms a structural part of the shear blade. Are several shear knives with one each driving armature present, each of these anchors can be in the aforementioned manner be connected to the associated cutter.

Claims (5)

PATENT CLAIMS: 1. Oscillating armature drive consisting of electromagnet and armature of a type in which the armature with one of its two pole ends each one Pole of the U-shaped magnet assigned and so transverse to the pole axes of the two magnetic poles is held so that its poles are at its Rest position to the side of the pole faces of the two magnetic poles and During operation due to the force of attraction of the magnet, periodically centered in front of the pole face The magnet is attracted to dry razors with reciprocating Working movement of a shear knife, characterized in that the per se known assignment of a mass balancing serving to the working anchor (2) in opposite directions and compensating armature oscillating in parallel to the same electromagnet (1) of the compensating armature is divided into two half-banks (4) and these are symmetrical in mass on both sides of the Working anchor (2) are arranged. 2. Drive according to claim 1, characterized in that the working armature (2) along the pole faces of the magnetic poles (100) and the half bankers (4) along the side faces of the magnetic poles (100) are arranged such that they can oscillate (Figs. 7 and 8). 3. Drive according to claim 2, characterized in that the Halbanker (4) have extensions (40) extending in the direction of the shaving head (Figures 7-10). 4. Drive according to claim 3, characterized in that the extensions (40) encompass the working anchor (2) on the upper side like a horn (Fig. 9 and 10). 5. Drive according to claim 2, characterized in that the half-bench (4) structurally with one another are united, e.g. B. by means of the working anchor (2) encompassing the face or top Bridges. Considered publications: German Patent Specifications No. 492 391, 479 652, 932172.