A method for controlling a power tool includes ascertaining a workpiece characteristic of the workpiece to be processed from previously acquired measured values, determining the workpiece material from the workpiece characteristic of the workpiece to be processed, specifying initial values, which are suitable for processing the workpiece made of the determined workpiece material using the power tool, for machine parameters such as feed, speed, and torque, storing the initial values for putting the power tool into operation with machine parameters set to the initial values and/or putting the power tool into operation with machine parameters set to the initial values. A cooling constant is ascertained according to the Newtonian cooling law as the workpiece characteristic of the workpiece to be processed. To ascertain the cooling constant, the ambient temperature is measured, the workpiece is heated, and the actual temperature of the workpiece is measured, whereupon the cooling constant is computed.

The technology herein developed arises from the need to monitor and automate the entire deep hole drilling, drilling and milling processes, in cutting machines, in order to not only optimize the relevant task performance but also to increase the useful life of the cutting tools involved. An operating system and method are disclosed that allow controlling the entire deep hole drilling, drilling and milling processes, acting directly and automatically on the control of the cutting parameters, such as for example drilling feed and cooling adjustment, by means of collecting and real-time analyzing of data from sensors arranged in said cutting machine.

The technology herein developed arises from the need to monitor and automate the entire deep hole drilling, drilling and milling processes, in cutting machines, in order to not only optimize the relevant task performance but also to increase the useful life of the cutting tools involved. An operating system and method are disclosed that allow controlling the entire deep hole drilling, drilling and milling processes, acting directly and automatically on the control of the cutting parameters, such as for example drilling feed and cooling adjustment, by means of collecting and real-time analyzing of data from sensors arranged in said cutting machine.

A method for controlling a power tool includes ascertaining a workpiece characteristic of the workpiece to be processed from previously acquired measured values, determining the workpiece material from the workpiece characteristic of the workpiece to be processed, specifying initial values, which are suitable for processing the workpiece made of the determined workpiece material using the power tool, for machine parameters such as feed, speed, and torque, storing the initial values for putting the power tool into operation with machine parameters set to the initial values and/or putting the power tool into operation with machine parameters set to the initial values. A cooling constant is ascertained according to the Newtonian cooling law as the workpiece characteristic of the workpiece to be processed. To ascertain the cooling constant, the ambient temperature is measured, the workpiece is heated, and the actual temperature of the workpiece is measured, whereupon the cooling constant is computed.

The trajectory planning system for integrating a computer numerical control (CNC) machine, trajectory planning device, trajectory planning method, and computer program thereof are provided. The aforementioned trajectory planning device includes a determining module. The determining module configures the related processing speed or processing acceleration based on type of the processing segment so as to provide a processing setting. Furthermore, the aforementioned trajectory planning device determines the processing segment whether the linear or circular segment and plans the tangent or normal acceleration of related processing segment so as to optimize the processing setting and finish the high order processing trajectory planning.

A numerical controller includes a commanded movement-amount adjustment section, in addition to a position command section and a positional deviation counter but also. The commanded movement-amount adjustment section calculates an adjusted command movement amount based on a commanded movement amount output from the position command section, positional deviation acquired from the positional deviation counter, and an actual velocity of a control axis, and outputs the calculated adjusted command movement amount to the positional deviation counter. When a load acts on a servo motor so that positional deviation is accumulated and the load is abruptly removed, a situation in which the servo motor abruptly accelerates with its maximum torque in an attempt to eliminate the accumulated positional deviation is avoided.