Description

OSCILLATING MOTOR FOR A PERSONAL CARE APPLIANCE

Technical Field

This invention relates generally to motors tor a personal care appliance, such as a power skαn brush, and more specifically concerns an electromagnetic motor using flexure elements to produce an oscillating action of the workpiocc portion of the personal care appliance.

Background of the Invention

Personal care appliances typically use an internal motor to produce a particular workpiece movement/action, which in turn produces desired functional results. Examples of such appliances include power skin brushes, power toothbrushes and shavers, among others.

Many such devices have a motor arrangement which produces an oscillating (back and forth) action rather than a purely rotational movement. Such arrangements require not only the typical motor bearing structures for support of the motion, but also specific structural elements to constrain the movement of the motor drive shaft and the workpiece to a selected angle/movement. Such bearings or other elements typically add significant expense and manufacturing difficulties to the manufacture of the appliance as well as reliability/durability concerns to the use of the appliance.

Hence, it is desirable to have a motor Cor a personal care appliance which produces a desired oscillating action, and which is also rugged, quiet, and does not require oearmgs or constraining members for operation.

Summary of the Invention Accordingly, the invention is a motor for a personal care appliance, comprising: a stator assembly portion driven by a drive assembly which includes a source of alternating current; an armature portion responsive to the stator action to move through a path; a mounting member affixed to a housing portion of the personal care appliance; a flexure assembly connected between the

armature and the mounting member, such that the armature in operation moves in an arcuate path about a pivot point located between the mounting member and the armature; and a workpiece assembly mounted to and extending from the armature such that the workpiece oscillates through a desired angle.

Brief Description of the Drawings

Figure 1 is a partial perspective view of a personal care skin brush appliance incorporating the appliance motor of the present invention.

Figure 2 as a perspective view of the appliance motor of Figure 1.

Figure 3 is a top view of the motor of Figures 1 and 2. Figure 4 is a top view of the motor of Figures 1 and 2 with selected portions thereof removed.

Figure 5 is a top view of the motor ot Figures 1 and 2 showing only the magnets and backiron portions thereof.

Best Mode for Carrying Out the Invention

Figure 1 shows a personal care appliance in tne form of a power skin brush. The personal care appliance 10 includes a case or housing 12 through which an on/off switch 14 extends to contact a button on the case otr the like for control of the appliance. Positioned within case 12 is a motot; 16 and a drive assembly, which includes an electronic drive circuit 20 and rechargeable batteries 22 which provide a self-contained source of power for the appliance. The appliance LO in the embodiment shown also includes a charging coil 24 which operates with a conventional charger (not shown) to maintain batteries 22 in a charged condition.

The appliance further includes a workpiece mounting arm 28 which extends from an armature portion of the motor 16. Mounted on the free end of arm 28 is a specific workpiece 30, which in the embodiment shown is a skin brush. Such a skin brush is shown and described in more detail in co-pending application Serial No. 10/873,352, which is owned by the assignee of the present invention, the contents of which is hereby incorporated by reference. However, the workpiece 30 can take various forms,

including, for example, a toothbrush brushhead or a shaving head. In operation, the workpiece will oscillate back and forth through a desired angle due to the action of the motor 16. Typically, but not necessarily, the oscillation will be rotational. The movement may also include a translational component as well, as discussed below.

Figures 2 and 3 show the motor 16 in more detail. The motor includes a stator portion 36, which in the embodiment shown is an E-core with a center leg 37 upon which a stator coil 38 is mounted and two outer legs 10 and 42. An armature portion 46 of the motor 16 has a curved configuration with tip ends 49 and 50 which come closely adjacent the curved tip ends of outer legs 40 and 42 of the stator E-core. The armature portion 46 includes a backiron member 48 which is made from a ferromagnetic material. Two or more spaced magnets 51 and 52 are mounted on the backiron, with magnetization in the radial direction, arranged such that the north pole of one magnet 51 faces outward, while the south pole of the other magnet 52 faces outward, although i I should be understood that the orientation could be reversed as long as the magnet poles point in opposite directions. The motor 16 also includes a mounting element 54 which is secured to the case 12 of the appliance, thus becoming a mechanical reference for the oscillating system.

Connecting the armature 46 to the mounting element 54 are a pair of flexure elements, in this embodiment flexure elements 58 and 60, although additional flexure elements can be used. In one example, the flexure elements are made from spring steel material, and are approximately 0.025 inch thick. Each flexure element is approximately 0.50 inch high. Flexure elements 58 and 60 are oriented approximately perpendicular to each other. The point of overlap between the flexure elements 58 and 60 is the functional pivot point 66 about which armature 46 oscillates .

Extending from the armature 46 is the mounting arm 28. As can be seen most clearly in Figure 2, mounting arm 28 extends outwardly from the armature and then extends horizontally (parallel with the handle of the appliance) until it reaches a line extending through pivot point 66, where the mounting arm extends outwardly again approximately at a right angle to the

handle. Mounted on the free end of mounting arm 28 is workpiece 30, which, for example, is a skin brush, as indicated above. The configuration of the mounting arm is thus such that; the brush oscillaLes about an axis which extends through pivot point 66 ac a right angle to the handle. The location/orientation of the output shaft can be changed, for instance by moving the location of the tip away from axis 66, to produce a combined rotational/translational movement of the workpiece.

Referring to Figure 4, the E-core 36, backiron 48, magnets 52, 52 and flexure elements 58, 60 are shown alone for clarity. The geometry of the E-core in relation to the width of the face of magnets 51, 52 is important for maximum efficiency of the motor. Specifically, the width of the E-core center leg 37 should be from 0.50 to 0.60 (preferably 0.56) times the width of the face of the magnets. The width of the outer legs 40, 42 should be from 0.90 to 1.10 (preferably 1.02) times the width of the face of the magnets. The width of the distances 70, 72 between center leg 37 and outer legs 40, 42, respectively, should be from 1.95 to 2.20 (preferably 2.07) times the width of the face of the magnets. The length of center leg 37 should be from 1.95 to 2.1.5 (preferably 2.06) time the width of distances 70, 72.

Further, the distance between the centers of the faces of magnets 51, 52 should be from 2.40 to 2.60 (preferably 2.49) times the width of the face of the magnets. It is also advantageous to motor efficiency to set magnets 51,52 at an angle with respect to each other such that a line normal to the face of the magnets, passing through the midpoint of the magnet face also passes through the pivot axis of the armature. In the embodiment shown, the angle 74 between the midpoint line 76 and the line 78 normal to the magnet face (both passing through pivot: axis 66) is from 18° to 22° (preferably 20") . It should be noted Lhat this angle can vary depending on the radius at which the magnets rotate about the pivot axis. As the radius increases, the angle decreases .

In operation, an alternating current is generated by the electronic current assembly and applied to the stator coil 36, resulting in an arcuate movement of the armature about the pivot point 66, due to the attractive/repulsive action between

the three legs 37, 40, 42 of the stator E-coil and permanent magnets 51, 52 on the backiron 48. The particular arrangement of the stator E-coil and the armature results in a substantially rotational oscillation of a selected angle about the pivot axis 66. The instantaneous center of rotation moves in a very small (approximately 0.010 inches) complex curve offset about the shaft center point when it is at rest. The angular range of oscillation can be varied, depending upon the configuration of the armature and the stator and the characteristics of the alternating drive current. Preferably, the motion is within the range of +3° to +_lb° about the pivot axis.

The flexure elements, with their configuration and aspect ratio, connected between the armature and tho mounting member, constrain the movement of the armature to substantially rotational action about a line generally passing through the pivot axis, eliminating the need for bearings and ether elements to constrain the oscillating movement of the workpiece.

The arrangement shown and described above is for a device where the axis of rotation of the motor shaft, and hence the brush, is at a right angle to the longitudinal axis of tho handle portion of the device. In another arrangement, the magnets on the backiron portion of the armature π>ay be affixed to the side of the armature away from the workpiece, with a magnetization arrangement/orientation parallel to the axis of rotation and with the stator assembly arranged in line with the axis of rotation, rather than the radial magnetization, right angle axis of rotation arrangement discussed above. This axial arrangement is suitable for a device having a desired axis of rotation of the motor drive shaft substantially parallel to the longitudinal axis υi the handle portion of the device.

Hence, a new motor arrangement for a personal care appliance has been disclosed which produces an oscillation over a defined angle without the need for bearings or other special constraining elements. Although a preferred embodiment of the invention has been disclosed for purposes of illustration, it should be understood that various changes, modifications and substitutions may be incorporated in the embodiment without departing from the

spirit of the invention which is defined by lhe claims which follow.

What is claimed is: