Abstract: A method for checking a tool uses a device with a light emitter for beam emission for tool scanning and with a beam receiver for beam reception and for outputting a shadow signal; and an evaluation unit for processing the shadow signal; rotation of the tool; moving the tool until it reaches a starting position in which the blade dips into the beam and shades this such that a threshold of a range of the evaluation unit is reached or undershot; moving the tool, starting from the starting position, out of the beam and registering the shadow signal; ascertaining that the shadow signal for a cutting edge does not fall below the lower switching threshold or exceed the upper switching threshold such that a shadow signal lies above the lower and below the upper switching threshold; wherein the feed is determined in proportion to a measurement range.

Abstract: A processing unit for measuring and controlling a rotary-driven tool, wherein the processing unit is connectable to a light barrier arrangement, which comprises a light-transmitting unit and a light-receiving unit, wherein the processing unit is configured to receive from the light-receiving unit signals that are at least approximately proportional to shading generated by the rotary-driven tool and/or at least one cutting edge of the rotary-driven tool at a first measuring position. The processing unit is further configured to evaluate the signals received and to transmit control signals to the light barrier arrangement, wherein the evaluation of the signals received by the processing unit comprises the following steps: determination of an interference signal component and/or a useful signal component of the received signal; and provision of information about the useful signal component, the interference signal component and/or the received signal for forwarding to a numerical controller of a machine tool.

Abstract: A processing unit for measuring and controlling a rotary-driven tool, wherein the processing unit is connectable to a light barrier arrangement, which comprises a light-transmitting unit and a light-receiving unit, wherein the processing unit is configured to receive from the light-receiving unit signals that are at least approximately proportional to shading generated by the rotary-driven tool and/or at least one cutting edge of the rotary-driven tool at a first measuring position. The processing unit is further configured to evaluate the signals received and to transmit control signals to the light barrier arrangement, wherein the evaluation of the signals received by the processing unit comprises the following steps: determination of an interference signal component and/or a useful signal component of the received signal; and provision of information about the useful signal component, the interference signal component and/or the received signal for forwarding to a numerical controller of a machine tool.

Abstract: The invention relates to a method for measuring a tool received in a workpiece processing machine, the method having the following steps: providing a contact or noncontact tool sensing device for detecting positional data on the tool and for outputting signals representative of the positional data; providing an evaluation device for receiving and processing the signals and for outputting a tool geometry determined from the processed signals; detecting a sequence of a first number of positional data on the tool and outputting signals representative of said positional data to the evaluation device; processing the signals representative of the first number of positional data in order to obtain a first approximation of the tool geometry; comparing the first number of positional data to said first approximation of the tool geometry and excluding a subset of the first number of positional data depending on a predetermined criterion, in order to obtain a second number of positional data; processing the second number

Abstract: The testing of a cutting-edge geometry of a tool takes place during time intervals that comprise time instants at which it is to be expected that a region, to be tested, of the tool enters a measuring beam. At time instants at which the tool does not enter the measuring beam, no measurements are performed, which increases the reliability of the test and avoids spurious measurements. For this purpose, a measuring system is used that preferably comprises programmable units in order to use the invention flexibly for various machine tools and tools without changing the construction of the measuring system.

Abstract: The testing of a cutting-edge geometry of a tool takes place during time intervals that comprise time instants at which it is to be expected that a region, to be tested, of the tool enters a measuring beam. At time instants at which the tool does not enter the measuring beam, no measurements are performed, which increases the reliability of the test and avoids spurious measurements. For this purpose, a measuring system is used that preferably comprises programmable units in order to use the invention flexibly for various machine tools and tools without changing the construction of the measuring system.