The purpose of the present invention is to improve the machined-surface quality of a curved surface of a workpiece without reducing the machining speed when the curved surface is subjected to removal machining. Provided is a workpiece machining method in which a rotating table on which a workpiece is placed and a tool are relatively moved along two linear movement axes orthogonal to each other, the workpiece is rotated about each of a first turning axis and a second turning axis orthogonal to each other by the rotating table, and at least one curved surface of a protruding curved surface and a recessed curved surface is subjected to removal machining. The method includes: disposing the first turning axis so as to be parallel to a first linear movement axis of the two linear movement axes, the motor load during linear movement in the first linear movement axis being relatively small; disposing the second turning axis on a plane perpendicular to the first linear movement axis; and subjecting the curved surface to removal machining along the direction of curvature while moving the workpiece along the first linear movement axis and rotating the workpiece about the second turning axis.

The disclosure relates to a processing installation for aircraft structural components having a processing station comprising a clamping frame for receiving the structural component, wherein the clamping frame extends along a station longitudinal axis which extends in a longitudinal direction and a processing unit which has an upper tool unit having an upper tool and a lower tool unit, wherein the processing installation has a processing region which is formed by a laterally delimited, first spatial portion in which the clamping frame and the processing unit are arranged during processing, wherein the processing installation has a service region for carrying out service operations, wherein the first spatial portion is separated from the second spatial portion in a transverse direction, wherein a service platform is arranged in the service region and can be positioned in a service plane which is orthogonal to the vertical direction.

A C-axis unit for a machine tool, the C-axis unit comprising a bushing (134) adapted to be fixed to a unit support (121) of the machine tool; a head mounting platform (130) adapted to receive an operating head (40), the head mounting platform being supported by the bushing (134) and being rotatable relative to the bushing (134) around a vertical axis; a platform rotation motor (150) supported by the bushing (134) and configured to control the rotation of the head mounting platform (130); and a spindle motor (160) configured to control the rotation of a tool-carrying spindle (45) on the operating head (40) through a driving extension (163) arranged in a through-bore (133) obtained through the head mounting platform (130). The spindle motor (160) is fixed to and is rotationally integral with the head mounting platform (130).

A multi-axis mechanism device includes: a base module, a first moving module, a second moving module, a third moving module, a reaction module, a tilting module and a rotating module. The first moving module performs a first axial movement relative to the movable bearing platform to drive the reaction module to be displaced relative to the movable bearing platform. The second moving module performs a second axial movement relative to the first moving module to drive the reaction module to be displaced relative to the first moving module. The third moving module drives the movable bearing platform to perform a third axial movement relative to the module body to drive the reaction module to be displaced relative to the module body. The reaction module is driven by the tilting module to perform titling action and by the rotating module to perform rotating operation relative to the central axis.

A manufacturing system for machining comprises a machine tool and a handling cell. The machine tool is arranged for multi-axis machining and includes a tool holder and a workpiece holder, which are movable relative to each other in at least three axes. The handling cell comprises a first interface to the machine tool, which is laterally coupled to the working space, a second interface for transfer purposes, a handling unit, and at least one buffer storage, wherein the handling unit is arranged for an automated workpiece change. A manufacturing line for machining comprises at least one manufacturing system and a combined transfer and storage device.

A machine tool includes a Z-slider with a main spindle rotating about a spindle axis, a main body on which the Z-slide is arranged, a machining table with a machining plane, a clamping device for clamping a workpiece, and a first drive to rotate the clamping device about an rotational axis. A support member is arranged on a pivot-axis housing on which the machining table is arranged. A second drive pivots the support member and the machining table about a pivot axis. The support member has first and second legs. The machining table is arranged on the first leg such that the support member and the housing form a U-shaped unit and provide an interspace between the second leg and the housing, into which interspace a toric workpiece clamped on the clamping device can project and is rotatable about the axis of rotation by the first drive.

A precision tripod motion system is provided. The tripod motion system in one example includes a bottom plate including three spaced-apart bottom single-degree-of-freedom hinges, a top plate including three spaced-apart top three-degrees-of-freedom (TDOF) joints, wherein the top plate is configured to receive a workpiece. Each linear actuator of three linear actuators is coupled to an associated SDOF hinge of the bottom plate and coupled to an associated TDOF joint of the top plate. Each linear actuator is configured to change length over a linear actuation span and configured to return the top plate to a predetermined set position after the top plate is displaced by an external force Each linear actuator includes a ball coupled to the associated three TDOF joint and a positioning actuator configured to move the ball to the predetermined set position prior to the return of the top plate to the predetermined set position.

A pretensionable locking system, a method for producing a locking system and a medical-technical instrument including a locking system. The locking system (2) includes a locking body (10) with an inner thread (12), and an inner locking body (20) with an outer thread (22). In a pretensioned position, the inner thread lies against the outer thread in a first longitudinal axial direction (80) and is pretensioned against the outer thread. In a locked position, the outer locking body is fixed on the inner locking body by screwing the inner thread onto the outer thread. The outer locking body has a resilient retaining element (14) that projects radially inward, and the inner locking body has a rigid bulge (24) that projects radially outward. In the pretensioned position, the retaining element lies against the bulge in a second longitudinal axial direction (85) that is opposite the first longitudinal axial direction.

The present invention aims at eliminating a need for a protective cover such as a bellows cover and improving a collection rate of machining scraps, and includes machining tables that are fixed at least in X and Y directions on a horizontal plane and hold a workpiece, a machining mechanism that machines the workpiece with a rotary tool using a machining liquid, a moving mechanism that linearly moves the machining mechanism at least in each of the X and Y directions on the horizontal plane, and a machining scrap storage unit that is provided below the machining tables and stores machining scraps generated by machining by the machining mechanism.

The present invention aims at eliminating a need for a protective cover such as a bellows cover and improving a collection rate of machining scraps, and includes machining tables that are fixed at least in X and Y directions on a horizontal plane and hold a workpiece, a machining mechanism that machines the workpiece with a rotary tool using a machining liquid, a moving mechanism that linearly moves the machining mechanism at least in each of the X and Y directions on the horizontal plane, and a machining scrap storage unit that is provided below the machining tables and stores machining scraps generated by machining by the machining mechanism.