In a method for fine-processing of an axicon (L) having a concave or convex cone surface (KF) with a cone axis (KA) and a cone angle (), with use of geometrically indeterminate cutting edges in the form of grain in combination with a liquid at a processing region (BB) of a tool (W2), which is constructed for linear engagement (LE) with the cone surface and has a front end (EB) with respect to the cone axis, material removal is produced at the cone surface by a relative cutting speed which results from a rotational movement of the axicon about the cone axis and a relative oscillating linear movement (oscillation axis R) of the tool, in which the processing region is disposed in linear engagement with the cone surface and its front end moves back and forth in a direction radial with respect to the cone axis.

Systems, methods, and computer-readable media are provided for machining a feature on a work piece along a curving tool path including a spiral pattern with continuously varying radius. In particular, the feature is scribed by a tool while varying an angle of rotation of a cutting surface of the tool with respect to the work piece to maintain a substantially constant angle between the cutting surface and a corresponding relative translational movement between the cutting surface and the work piece along the spiral pattern. A dynamic feed rate of the tool also is varied continuously with respect to the work piece based on the continuously varying radius of the at least one spiral pattern to substantially maintain a target centripetal acceleration of the tool with respect to the work piece.

Methods for making ophthalmic lenses are generally discussed herein with particular discussions extended to plastic injection molded ophthalmic lens molds that are machined or lens buttons located on the injection molds that are machined. The machine process can include setting a lens axis of the ophthalmic lens and machining a ballast that is aligned to a major axis of a toric zone.

A method for machining an optical lens via a trimming machine, includes: a step of locking the optical lens, a step of acquiring shape characteristics of the optical faces of the optical lens, a step of generating an instruction for trimming the optical lens, and a step of trimming the optical lens along a desired contour. The method also includes the following steps: a step of generating an instruction for etching the optical lens depending on the acquired shape characteristics, and a step of etching the optical lens along a line located inside the desired contour, during which a pointed etching tool of the trimming machine is controlled according to the etching instruction in such a way that the point of same continually slides against the optical face in order to score same along the line.

The invention relates to a machine for processing plastic workpieces. A machine housing surrounds a working chamber located between a workpiece spindle for rotationally driving the workpieces about a workpiece axis of rotation and a fast tool servo for producing an oscillating feeding movement of a rotary tool in the direction of the workpieces. The workpiece spindle is provided with a carriage which can be driven and is guided on at least two guide surfaces of a guiding arrangement in order to produce a relative advancing movement between the workpiece and the rotary tool. The advancing movement runs transversely with respect to the feeding movement and defining therewith a processing plane in which during processing the rotary tool engages with the workpiece. The guiding arrangement is mounted on the machine housing such that the processing plane extends between the two guide surfaces.