A controller of a machine tool includes a plurality of feed axes that feed a tool, machines a workpiece while making the tool oscillate and includes: an oscillation command creation unit which creates an oscillation command based on a machining condition; and a control unit which machines, based on the oscillation command and a movement command, the workpiece while making the tool oscillate, and the oscillation command creation unit creates, when the machining condition indicates machining by an interpolation operation of one feed axis of the plurality of feed axes, the oscillation command so as to make the tool oscillate in a direction along a machining path and changes, when the machining condition indicates machining by a simultaneous interpolation operation of the plurality of feed axes, the oscillation command so as to change the direction of the oscillation with respect to the machining path.

Weaving equipment may include warp strand positioning equipment that positions warp strands and weft strand positioning equipment that inserts weft strands among the warp strands to form fabric. The fabric may include insulating strands and conductive strands. The conductive strands may be coupled to electrical components. The warp strand positioning equipment may position the warp strands to form a shed. Component insertion equipment may be used to insert electrical components into the shed. The weaving equipment may have a reed. The reed may be used to help position an electrical component in the fabric. The weaving equipment may have take-down equipment and individually controllable warp fiber positioning and tensioning devices.

Weaving equipment may include warp strand positioning equipment that positions warp strands and weft strand positioning equipment that inserts weft strands among the warp strands to form fabric. The fabric may include insulating strands and conductive strands. The conductive strands may be coupled to electrical components. The warp strand positioning equipment may position the warp strands to form a shed. Component insertion equipment may be used to insert electrical components into the shed. The weaving equipment may have a reed. The reed may be used to help position an electrical component in the fabric. The weaving equipment may have take-down equipment and individually controllable warp fiber positioning and tensioning devices.

A controller of a machine tool includes: a position command calculation unit which calculates a position command for relatively moving a workpiece and a tool; an oscillation operation execution determination unit which analyzes a machining program and which. determines whether or not an oscillation operation of relatively oscillating the workpiece and the tool is performed in a machining block; an oscillation operation intermittent execution determination unit which determines, when it is determined that the oscillation operation is performed, in the machining block, based on the state of the machine tool, whether the oscillation operation is enabled or disabled so as to determine whether or not the oscillation operation is intermittently performed; an oscillation command calculation unit which calculates, when it is determined that the oscillation operation is enabled, an oscillation command for relatively oscillating the workpiece and the tool; and an adder which adds the position command and the oscillation command together.

A method and a system for machining a work piece by a machining tool are provided. The method includes relatively moving the machining tool against the work piece to apply machining feeds therebetween. The contact points at the work piece are arranged on the area of the work piece to be machined, and the contact points at the machining tool form a curve on the machining tool surface. The system includes a manipulator, a machining tool and a controller being adapted for controlling the manipulator to operate the machining tool according to the method as above. With this solution, the system can generate wave paths of a machining tool, so as to extend the life of the tool and ensure the processing quality.

A numerical controller includes a position instruction generating unit configured to generate the position instruction; an oscillation instruction generating unit configured to generate the oscillation instruction; a position speed control unit configured to add the position instruction and the oscillation instruction to generate a synthesized instruction; and a current control unit configured to control movement of a tool or rotation of a spindle. The oscillation instruction generating unit includes a tracking error calculating unit configured to obtain and calculate an actual angle and an ideal angle of the spindle, and a frequency recalculating unit configured to recalculate the oscillation frequency or a rotational speed of the spindle based on the actual angle and the ideal angle. The current control unit controls the movement of the tool or the rotation of the spindle according to the recalculated oscillation frequency or rotational speed of the spindle.

A numerical control apparatus includes: a drive unit controlling a main shaft rotating a workpiece, a first drive shaft feeding a cutting tool relatively to the workpiece along a perpendicular direction to a lead direction of a thread, and a second drive shaft feeding the cutting tool relatively to the workpiece along the lead direction; and a vibration unit superimposing, on movement of the first drive shaft, vibration having a period having a predetermined ratio with a rotation period of the main shaft, and forms a thread on the workpiece by moving the cutting tool and the workpiece relative to each other and performing cut processes on the workpiece. The numerical control apparatus includes a thread-cutting vibration adjustment unit controlling the drive unit to shift phase of the vibration with respect to phase of the main shaft by a predetermined vibration phase shift amount every time in the cut processes.

A numerical controller of the present invention is provided with an oscillating motion data holding unit configured to hold oscillating motion data used for the control of an oscillating motion, an oscillating pulse calculation unit configured to calculate oscillating pulses used for the control of an oscillation axis, based on the oscillating motion data held in the oscillating motion data holding unit, and output the calculated oscillating pulses, a motor control unit configured to control a motor for driving the oscillation axis, based on the oscillating pulses, and an oscillating motion data calculation unit configured to determine a data item related to the oscillating motion to be adjusted, based on the state of a switch means on a control panel of a machine, and to adjust the value of the data item related to the oscillating motion, based on manual pulses input from a manual pulse generator.

A controller of a machine tool includes a plurality of feed axes that feed a tool, machines a workpiece while making the tool oscillate and includes: an oscillation command creation unit which creates an oscillation command based on a machining condition; and a control unit which machines, based on the oscillation command and a movement command, the workpiece while making the tool oscillate, and the oscillation command creation unit creates, when the machining condition indicates machining by an interpolation operation of one feed axis of the plurality of feed axes, the oscillation command so as to make the tool oscillate in a direction along a machining path and changes, when the machining condition indicates machining by a simultaneous interpolation operation of the plurality of feed axes, the oscillation command so as to change the direction of the oscillation with respect to the machining path.

A controller performs high-accuracy oscillation control in which an axis driven by a motor is rocked in accordance with the rotation of a spindle motor for driving a main spindle. This controller determines a reference speed of rocking motion based on a reference speed set in advance, a reference main spindle rotational speed of the spindle motor, and an actual main spindle rotational speed, and calculates a rocking motion speed for each control period based on the determined reference speed of the rocking motion. The calculated rocking motion speed for each control period is added to a command outputted by the controller for controlling the position of the motor for each control period.