WO2003070054A1 - Grinding device for machining the ends of bristle filaments of toothbrushes - Google Patents

Abstract

The invention relates to a grinding device (1) which is used to machine the ends (14) of bristle filaments (15) of toothbrushes. The grinding device (1) comprises a grinding surface (8,9) which is provided with grinding elements (4) and along which the ends (14) of the bristle filaments (15) slide during the grinding process. Several grinding tracks (6,7) with various grinding elements (4) are provided on the grinding surface (8, 9). A compact grinding device (1) enabling various grinding processes to be performed either successively or side by side by means of various grinding surfaces (8,9) is thus produced.

Description

Grinding device for processing the ends of bristle filaments of toothbrushes

The invention relates to a grinding device for processing the ends of bristle filaments of toothbrushes according to the preamble of patent claim 1.

From US 3,451, 173 A a grinding device for processing the ends of bristle filaments is already known, in which a grinding surface is formed on an outwardly curved disc on the outer surface, against which the ends of the bristle tufts are pressed. As the disc rotates, the tufts run across the disc. With the disc rotating and the tufts of bristles running continuously, their ends are pressed against the grinding surface. The tuft ends are rounded by the roughness of the grinding surface or otherwise machined. The various grinding processes are carried out in grinding units arranged one behind the other. Such an arrangement is complex and expensive because the tufts have to be transported to the next grinding process after the first rounding process by means of conveyors. Such a device also requires a lot of space.

From DE-198 48 221 A1 a grinding device for processing the ends of bristle filaments of toothbrushes of the type described in the introduction is also known, in which this consists of a drum, on the peripheral outer surface of which the grinding surface is formed. In this embodiment, two different grinding surfaces are present on the circumferential lateral surface, the first grinding surface forming a strip-shaped path running in the direction of rotation, which is interrupted by a second grinding surface which is in the form of projections or webs running transversely to the first grinding surface. The second grinding surface is used to roughen the bristle ends through the first grinding surface and their directly adjacent lateral surfaces, in order to thereby increase the cleaning-active surface. With this grinding wheel, the end faces and the lateral surfaces of the bristles are thus machined alternately in one grinding process, and this in one revolution as often as many projections and track sections are formed on the peripheral grinding surface of the wheel.

The object of the invention is to improve a grinding device according to the preamble of claim 1 such that several grinding processes can be carried out more quickly in a simple manner with simple means. With the grinder should can also be achieved that a rounding of complex bristle topographies can be more precisely adapted to a grinding process. Furthermore, the grinding device should be simple, time and space-saving and inexpensive than conventional grinding devices.

This object is achieved by the characterizing features of claim 1. By applying several sanding tracks on one sanding surface with different sanding elements, it is possible to get to the second sanding surface after the first sanding process on the first sanding surface by slightly displacing the bristle tufts relative to the sanding surface or the sanding disk opposite to the tuft or both already carry out the second grinding process. The grinding tracks are aligned so that they run in the direction of movement of the grinding wheel and / or the bristle tufts.

Thus, several grinding operations can be carried out in a particularly cost-effective manner on a single grinding device, for example by roughly sanding the bristle ends in the first operation, finely sanding in the second operation, finely sanding in the third operation and possibly polishing in the fourth operation. In this case, however, four grinding tracks would then have to be formed on the disc, which are scanned in succession after the previous grinding process has been carried out. However, it is also quite conceivable to skip some grinding tracks if, for example, the inner bristle tufts of a toothbrush do not require the high surface quality, as is the case at the bristle tuft ends on the edge.

Such a grinding device requires considerably less space, saves resources and shortens the grinding time per toothbrush, since the tufts of bristles to be processed do not have to be brought to different grinding wheels during different grinding processes. This reduces the cycle time of the grinding processes.

Due to the features of claim 2, the individual grinding surfaces are clearly separated from one another, which also leads to a clear separation of the grinding processes. However, there is also the advantage that if the ends of the bristle filaments run in one plane, when the transition from one grinding surface to the other grinding surface occurs, the pressure of the ends of the bristle filaments on the friction disks or friction belts in the second grinding process automatically corresponds to the formation of the gradation is withdrawn or reinforced because the distance between the teeth-cleaning ends of the bristle fi lamente to the second grinding surface has become larger or smaller than the distance to the first grinding surface. In this way, expensive press-on devices for the bristle filaments can be dispensed with, which reduces tooling, wear and other costs. In the case of a rotating disk, it is advantageous if the steps run radially to the center of the disk.

The same can be achieved by the features of claim 3, in which case at least one slideway is inclined or curved. Several grinding surfaces can also be inclined or curved without a step being formed. The inclination can also result in friction surfaces that run obliquely to the bristle filaments. If the bristles run perpendicular to the first grinding surface, the contact pressure is automatically reduced from the first to the second grinding surface when the second grinding surface is inclined to the bristle tufts. This can be an advantage during the subsequent polishing process.

Due to the features of claim 4, different grinding surfaces are created on the different grinding tracks by means of different grain sizes, different materials or different shapes. By using different friction elements, different grinding processes can be carried out side by side or one after the other.

The features of patent claim 5 preferably create a grinding wheel with two grinding tracks, with which two grinding processes can be carried out side by side or one after the other. However, three, four or even more grinding tracks can also be formed on the grinding wheel if a correspondingly large number of grinding processes are to be carried out and if the space on the grinding surface is large enough to accommodate the bristles or tufts. The diameter of the grinding wheel must then be adapted accordingly to the grinding tracks. This also has the advantage that the larger the diameter of the grinding wheel, the higher the outer circumference, the higher the friction speeds, and therefore the toothbrush filaments on the toothbrush side can be processed much more effectively with coarser wheel surfaces. In the interior of the grinding wheel, where the diameters are relatively small, finer grinding operations, such as polishing, can then be carried out due to the lower friction speeds. A round grinding wheel with circular and annular grinding tracks has proven to be a particularly inexpensive grinding wheel to manufacture. If, according to the features of patent claim 6, the grinding surface of the disk is formed by a truncated cone surface or a cone, different pressures can also be achieved due to the different heights of the grinding tracks compared to the teeth cleaning ends of the bristle filaments. The inclination of the wheel must be matched to the grinding surface, the grinding speed and the material of the bristle filaments.

In the grinding movements, the grinding device not only has to rotate about its own axis, it can also perform wobbling rotary movements, so that the contact pressure of the disc against the bristle ends changes constantly and the frictional forces act on the tuft ends from a radial to a tangential direction , This improves the rounding of the bristle ends. The rotation of the friction disc from left to right can also be changed continuously, which also improves rounding. A combination of all of these properties leads to optimal rounding technology.

According to the features of claim 7, the device consists of a belt on which a plurality of grinding tracks are formed side by side. This embodiment has the advantage that the friction speeds are the same on all grinding tracks, since the diameter remains constant. If the circumferential band runs inclined to the tuft axis, the contact pressures on the ends of the bristle filaments can also be changed here.

In the embodiment according to the features of claim 8, it is also conceivable that the rotational speed is changed when changing to a different grinding path in order to achieve optimal grinding processes at the bristle filament ends.

Two embodiments of the invention are shown in the drawing and are described in more detail below. Show it:

1 is a schematic plan view of a circular grinding surface of a grinding wheel with two grinding tracks according to the invention on a reduced scale, the grinding surfaces lying in one plane, 2 shows a section through the center of the grinding surface according to FIG. 1, although the cross section of the grinding surface is shown enlarged and the base body is only shown in sections,

3 shows a schematically illustrated plan view of a circular grinding surface of a second exemplary embodiment according to the invention, the individual grinding tracks not being arranged all around but on the grinding wheel in a cross-divided manner,

4 as in FIG. 2, but here the central section goes through the disc in FIG. 3,

5 shows a schematically represented plan view of a third exemplary embodiment of a circular grinding surface of a grinding wheel with two grinding tracks, the surface of the wheel being inclined towards the center,

6 as in FIG. 2, but here the central section goes through the disc in FIG. 5,

Fig. 7 as in FIG. 1, however, the radially inner grinding track is offset from the outer sliding track by a step and

8 as in FIG. 2, but here the central section through the disc in FIG. 7.

In the exemplary embodiments in FIGS. 1 to 8, the grinding device 1 consists of a grinding support 2, on the surface 3 of which is designed as a support surface, a grinding layer 5 provided with grinding elements 4 is formed. The thickness of the abrasive layer 5 is shown enlarged in the drawings, for the sake of better illustration. The grinding layer 5 here consists of two grinding tracks 6, 7, the grinding surfaces 8, 9 of which adjoin one another on the line 10. In FIGS. 1 and 2, the grinding surface 8 runs in a ring shape to the grinding surface 9, which is enclosed as a circle by the grinding surface 8. The transition from the grinding surface 9 to the grinding surface 8 is practically seamless at the line 10. Grinding surfaces 8, 9 lie here in a horizontal plane. In FIGS. 3 and 4, the grinding surface 8 runs according to a section of a crescent, although a semicircle is formed in the middle, so that the rest occupies the grinding surface 9 of a half circular ring on the round grinding layer 5. Here too, the grinding surfaces 8, 9 lie in a horizontal plane.

In FIGS. 5 and 6, the grinding surfaces 8, 9 are formed in plan view as in FIG. 1. 6, however, they slope towards the center 11, so that their lateral surfaces form a common conical surface.

7 and 8 essentially correspond to those according to FIGS. 1 and 2, but a step 12 is formed at the transition from the grinding surface 8 to the grinding surface 9, so that the grinding surface 9 is lower than the grinding surface 8. However, it is it is also conceivable for the step 12 to protrude upwards, so that the grinding surface 9 would then lie above the grinding surface 8. It is also conceivable that an inclined ramp is formed instead of step 12 so that the transition runs continuously. The step 12 can also be formed by a radius in order to make the transition appear constant.

A tufts of bristles 13 are shown in sketch form in FIG. 2 and here run perpendicular to the grinding surface 8. The tufts of bristles 13 consist of individual bristle filaments 15 running in the longitudinal direction of the tufts of bristles 13. As soon as the ends 14 of the tufts of bristles 13 have been sufficiently processed with the grinding surface 8 either the bristle tufts 13 are brought radially inward onto the second grinding surface 9 or the grinding support 2 is moved to the right until the ends 14 of the bristle tufts 13 come to rest on the radially inner surface 9 in order to be able to be processed there. For example, the rotational speed of the grinding device 1 can be increased or decreased in order to achieve the desired abrasion at the ends 14 of the bristle tufts 13.

The grinding device 1 according to FIGS. 3 and 4 has the effect that it has to be rotated oscillating about its axis 11 if the bristle tufts 13 are to remain on only one grinding surface 8 or 9.

According to FIGS. 5 and 6, the tufts of bristles 13 can be aligned here such that they run parallel to the center 11, ie the ends 14 of the tufts of bristles 13 are ground at an angle or rounded. The grinding device 1 according to FIGS. 7 and 8 enables a reduction in pressure when the ends 14 of the bristle tufts 13 transition from the outer grinding surface 8 to the inner grinding surface 9, so that they are pressed against the surface 9 with less force. This is particularly advantageous if the grinding surface 9 is to serve as a polishing surface.

Claims

Patent claims: 1. Grinding device (1) for processing the ends (14) of bristle filaments (15) of toothbrushes, which consists of a grinding surface (8, 9) formed on a grinding carrier (2) with grinding elements (4), on which the ends are during the grinding process (14) slide along the bristle filaments (15) and are thus mechanically processed, characterized in that several grinding tracks (6, 7) with different grinding elements (4) are formed on the grinding surface (3). 2. Grinding device according to claim 1, characterized in that the grinding tracks (6) are separated from one another by steps (12). 3. Grinding device according to claim 1, characterized in that the grinding surface (8, 9) of at least one grinding track (6 or 7 or 6, 7) is inclined or curved. . Grinding device according to claim 1, characterized in that the grinding elements (4) the individual grinding tracks (6, 7) have different properties in terms of their size, material and shape. 5. Grinding device according to claim 1, characterized in that it consists of a straight or curved disc, on the radially inner region of which a first circular grinding track (7) and on the radially outer region of which a second annular grinding track (6) is formed. . Grinding device according to claim 5, characterized in that the grinding surface (8, 9 or 8 or 9) forms the lateral surface of a cone or truncated cone, the central axis (11) of which runs through the pivot point of the grinding carrier (2). Grinding device according to claim 1, characterized in that it is formed by a rotating belt or a rotating roller and that the different grinding surfaces (8, 9) run next to one another. Grinding device according to one of claims 1 to 7, characterized in that the speed of the grinding surface (8, 9) is adapted to the grinding track (6, 7).