Device for polishing optical lenses

Abstract

The device for polishing optical lenses includes a lens holder; a device for positioning the lens holder; and a device for rotating the lens holder about an axis. There is also a polishing tool; a tool holder; a device for positioning the tool holder; and a device for rotating the tool holder about an axis. The device for polishing also includes a ball joint arranged between a shaft secured to the tool holder and the device for positioning the tool holder, or between a shaft secured to the lens holder and the device for positioning the lens holder, so as to enable a spherical movement of the polishing tool and of the lens. The invention also relates to a method for polishing using the device according to the invention.

Claims

1. A device for polishing optical lenses, said device comprising: a lens holder having a lens holder axis; means for positioning said lens holder; means for rotating said lens holder about said lens holder axis; a tool holder having a tool holder axis; a polishing tool attached to said tool holder; means for positioning said tool holder; means for rotating said tool holder about said tool holder axis; and a ball joint engaging at least one of a group consisting of said tool holder and said lens holder through a shaft, said tool holder having a range of spherical displacement relative to said lens holder, wherein said tool is fixed to said tool holder through an elastic means, and wherein said tool holder comprises an interior space having a volume, containing gas, adjacent to said elastic means, and wherein said volume of said interior space corresponds to a force applied on said elastic means.

2. The device according to claim 1, wherein said ball joint engages said tool holder, said shaft being connected to said means for positioning said tool holder.

3. The device according to claim 2, further comprising an additional ball joint engaging said lens holder by an additional shaft, said additional shaft being connected to said means for positioning said lens holder, said lens holder having a range of spherical displacement relative to said tool holder.

4. The device according to claim 1, wherein said means for positioning the tool holder comprises: a supporting shaft having an end and being rotatable about a supporting shaft axis; another ball joint on said end; an eccentric casing integral with said supporting shaft; and means for guiding a hinged axis between said shaft and said supporting shaft, said means for guiding said hinged axis being mounted on said eccentric casing.

5. The device according to claim 4, wherein said means for guiding reciprocates between a position close to said supporting shaft axis and a position away from said supporting shaft axis.

6. The device according to claim 1, wherein the tool holder is comprised of means for detecting pressure exerted by the tool, and a control loop between the means for detecting and the means for positioning said tool holder, so as to enable a control of said pressure.

7. The device according to claim 1, wherein said elastic means drives said tool in rotation.

8. The device according to claim 1, further comprising a tool support fixed to said tool holder through said elastic means, said tool being secured to said tool support through a deformable part.

9. The device according to claim 1, wherein said elastic means is comprised of an elastic membrane.

10. A device for polishing optical lenses, said device comprising: a lens holder having a lens holder axis; means for positioning said lens holder; means for rotating said lens holder about said lens holder axis; a tool holder having a tool holder axis; a polishing tool attached to said tool holder; means for positioning said tool holder; means for rotating said tool holder about said tool holder axis; a shaft integral with said tool holder; and a ball joint between said shaft and said means for positioning said tool holder, said polishing tool having a range of spherical displacement corresponding to said ball joint, wherein said means for positioning said tool holder comprises: a supporting shaft having an end and being rotatable about a supporting shaft axis; a supporting ball joint on said end; and an eccentric casing integral with said supporting shaft; and means for guiding a hinged axis between said shaft and said supporting shaft, said means for guiding said hinged axis being mounted on said eccentric casing.

11. The device for polishing optical lenses, according to claim 10, wherein said means for guiding said hinged axis reciprocates between a position close to said supporting shaft axis and a position away from said supporting shaft axis.

12. A device for polishing optical lenses, comprising: a lens holder; means for positioning said lens holder; means for rotating said lens holder about an axis; a polishing tool; a tool holder; means for positioning said tool holder; means for rotating said tool holder about an axis; a shaft integral with said lens holder; and a ball joint between said shaft and said means for positioning said lens holder, said polishing tool having a range of spherical displacement corresponding to said ball joint, wherein said means for positioning said lens holder comprises: a supporting shaft having an end and being rotatable about a supporting shaft axis; a supporting ball joint on said end; and an eccentric casing integral with said supporting shaft; and means for guiding a hinged axis between said shaft and said supporting shaft, said means for guiding said hinged axis being mounted on said eccentric casing.

13. The device for polishing optical lenses, according to claim 12, wherein said means for guiding said hinged axis reciprocates between a position close to said supporting shaft axis and a position away from said supporting shaft axis.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The understanding of this description will be facilitated when referring to the attached drawings.

(2) FIG. 1 represents a schematic perspective view of a device according to the state of the art.

(3) FIG. 2 represents a functional schematic view of a device according to the invention.

(4) FIG. 3 represents a cross-sectional view of a tool holder of the device of FIG. 1.

(5) FIG. 4 represents a graph illustration showing an example of a path of the tool on the lens.

(6) FIGS. 5 and 6 represent two graph illustrations showing an example of inclination of the tool holder around its ball joint, respectively of the corresponding displacement of the hinged shaft.

DETAILED DESCRIPTION OF THE DRAWINGS

(7) As can be seen in FIG. 1, a device 1 for polishing lenses, according to the state of the art, comprises a tool 2, a tool holder 3 movable in rotation about its axis A, and movable in translation along said axis A. The assembly is also movable in rotation about a substantially vertical axis V, which axis V passes close to the tool holder 3, so that the rotational movement about the axis V does not produce any significant displacement of the tool, but only its rotation. The device 1 comprises in addition a lens holder 4 capable of holding a lens 5, and secured to the end of a shaft 6 movable in rotation about its axis Z, and movable in translation along said axis Z. The lens holder assembly and its shaft are also mobile in translation along an axis X perpendicular to the axis Z in the horizontal plane, so that the lens holder can move towards the tool or away from same, but also move sidewise relative to the tool.

(8) As shown in FIGS. 2 to 4 of the attached drawing, the present invention relates to a device 1 for polishing lenses. The lens 5 is arranged on a lens holder 4 secured to the end of a shaft 6, movable in rotation about its axis Z. A motor 7 is mechanically connected to the shaft 6 and capable of causing it to rotate. A translation device 8 permits to impart a horizontal translation motion to the assembly of lens holder 4 and shaft 6, so that the lens 5 can be moved horizontally while it is caused to rotate about the axis Z. According to a further embodiment, one can move the tool holder assembly instead of moving the lens.

(9) A tool 2 is fixed on a tool holder 3. This tool holder includes a tool-support body 16, in which a space 23 is formed that can include a gas, for example air. An elastic membrane 17, for example a flat membrane, is fixed on the one hand to the tool-support body by means of a locking ring 18, on the other hand to the tool support 19. The latter is therefore movable relative to the tool-support body, so that the pressure exerted on the tool support by the polishing operation results into a reduction of volume inside the tool-support body, and therefore into an increase of the pressure. A pressure sensor 20 permits to measure this pressure change and to transmit the information to data-processing means such as an automate or a computer, which then controls a movement of the tool holder towards the lens, if the pressure has decreased, or a movement away from the lens when the pressure has increased.

(10) The elastic membrane 17 permits furthermore to transmit the rotational torque of the tool-support body 16 to the tool support 19.

(11) A connecting part 21 is inserted by pressure onto the tool support. This part is for example made of plastic material. A foam pad 22 is stuck on the connecting part 21, and the tool 2 is stuck to the pad 22. This tool 2 can adopt the shape of an abrasive polishing sheet. The pad is deformable, which permits an automatic orientation of the polishing sheet tangent to the lens. The elastic membrane enhances the flexibility of the tool.

(12) The tool holder is secured to a hinged shaft 9 movable in rotation about its axis, and secured to a supporting shaft 10, which is here an upper shaft 10, through a ball joint 11. The upper shaft 10 is driven in rotation about its axis by a motor 12, a belt 13, or a chain ensuring the mechanical connection between said motor 12 and the upper shaft 10. The ball joint 11 enables the hinged shaft 9 to adopt an inclination with respect to the vertical line, designated by a in the continuation of this description, while transmitting the rotational motion of the upper shaft 9 to the hinged shaft 9, so that the hinged shaft 9 is driven in rotation about its axis. The inclination a of the hinged shaft 9 is controlled by a device 14 for horizontally displacing a point of the hinged shaft 9. Any other device for controlling the inclination could also be suitable. Preferably, a casing 15 is movable in rotation about a substantially vertical axis, and drives the device 14 for horizontal displacement in a rotational path about the axis of the upper shaft 10. The hinged shaft 9 can thus rotate not only about its axis, but also about the vertical axis of the upper shaft 10, so that the tool holder, while rotating on itself, describes a path about the vertical line, which can be circular if the device 14 for horizontal displacement maintains the hinged shaft in a fixed position with respect to the vertical line, but which can also describe a circular sinusoid, if the device 14 describes a reciprocating motion during the rotation of the casing 15.

(13) The upper shaft 10 is herein referred to as “upper”, and it is indeed located above the hinged shaft 9 in the embodiment of FIG. 2. But it could also be located next to, or under the hinged shaft 9. For the purposes of the present patent application, it will nevertheless be referred to as “upper shaft”, although it can be located lower.

(14) FIGS. 4 to 6 show such a movement, the tool describing a circle on this path. FIG. 5 shows the variation of the angle α depending on the angle of rotation θ on an entire turn (360°) about the vertical axis. FIG. 6 shows the variation of the distance d of the device 14 relative to the axis of the upper shaft depending on the angle of rotation θ on an entire turn (360°) about the vertical axis. These two curves are of the sinusoidal type in that the curve passes periodically above and below the abscissa axis. FIG. 4 shows the path obtained on the lens, of the circular sinusoidal type, in that the path passes periodically outside and inside a circle. The tool holder rotates on itself while describing this path. One should observe a phase shift between the reciprocating movement of the device 14, and the rotation about the vertical axis, producing a difference of path after each turn. In the example shown, the tool is located at the same point of the lens after three turns. It should also be noted, in the example shown, that the lens is not circular, but oval. The path obtained is adapted to this oval shape. This can for example be obtained through a coordinated horizontal movement of the lens. It should be noted that the shape of the lens can be any shape, the oval shape being only one example among many possible shapes.

(15) According to another embodiment of the invention, the shaft 6 can be subdivided into a lower vertical supporting shaft and a hinged shaft, connected to the supporting shaft by a ball joint, in a way similar to the construction of the hinged shaft for the tool holder. Such an arrangement can facilitate the polishing of the convex lenses by reducing the vertical movements for adapting the tool holder, which must always be located accurately on the surface of the lens.

(16) According to yet another embodiment, only the shaft supporting the lens holder is made of a vertical shaft and a hinged shaft, and the shaft supporting the tool holder is without such a ball joint. Such an arrangement does not depart from the scope of the invention. The word “vertical” is used here for simplicity of the description, but an arrangement in which said shaft would be inclined or even horizontal does not depart from the scope of the present invention.

(17) Because of the ball joint or the two ball joints, several movements are combined and because of the combination of all these movements, there is an increase of the intersection of the polishing lines, which results into uniformity of the polishing and not into a deformation of the lens.

(18) In addition, off-centering the tool in a path about the axis of rotation of the upper shaft permits to prevent the accumulation of polishing dust, which is always driven to one side or the other. Thus, the tool is always into direct contact with the lens, and performs an optimized polishing. Indeed, the accumulation of dust between the tool and the lens would reduce the quality of polishing, and can cause scratches on the lens.

(19) The advantage of the present invention resides in particular in that it permits a polishing along paths ensuring a regular polishing over the entire surface of the lens to be polished. It allows in addition an adjustment at any time of the pressure of the tool on the lens, thereby guaranteeing a better quality of polishing, especially for soft materials such as “plastics”.