A computer numerical control (CNC) machining center is provided. The CNC machining center includes a spindle that receives a cutting tool. A work surface is operably arranged adjacent the spindle. A non-contact three-dimensional (3D) measurement device is operably coupled to the tool mount, the 3D measurement device including a projector and at least one device camera, the at least one camera being arranged to receive light from the light source that is reflected off of a surface. A plurality of targets is provided with at least one of the targets coupled to the 3D measurement device. At least two photogrammetry cameras are provided having a orientation and a field of view to acquire images of the targets. A controller is coupled for communication to the 3D measurement device and the at least two cameras, the controller determining the position of the 3D measurement device within the machining center during operation.

The invention relates to a method for fine-machining a bore of a plurality of workpieces and a machine tool unit. According to said method, the workpieces are subjected to fine-hole drilling and precision finishing, preferably roller-burnishing or smoothing, a post-processing measurement is carried out and, depending on said measurement, the fine-hole drilling tool is adjusted.

Disclosed is a machining system wherein provisions are made to be able to remove machining chips reliably without requiring human intervention. The machining system includes: an image processing unit which detects the position and amount of machining chips by comparing images captured of a workpiece and a machining tool before and after execution of a machining step; a condition judging unit which, based on the detected amount of machining chips, determines whether or not there is a need to execute a removal step; and a result judging unit which judges the result of the removal step by comparing the images captured of the workpiece W and the machining tool before and after the execution of the removal step.

Various embodiments of tools with associated optical measurement devices are described. An apparatus may include a tool to be applied to a workpiece, an optical measurement device in a feed path of the tool, and a controller. The optical measurement device may generate displacement measurements indicative of displacement of the workpiece as the workpiece traverses the feed path toward the tool. The controller may generate a measurement of the workpiece based on the plurality of displacement measurements.

A machining device is provided with a machine tool, a pallet to which a workpiece is secured, a pallet changer configured to move and change the pallet, and a workpiece attaching unit configured to attach and detach the workpiece to and from the pallet. Further, the machining device is provided with a visual sensor configured to capture an image of the pallet, and contaminants that may possibly cause jamming as the workpiece is supplied to the pallet are detected from the image captured by the visual sensor. A workpiece supply operation for the pallet is suspended if the contaminants are detected.

A machine tool of the present invention includes: a visual sensor that takes an image of unworked workpiece; an unworked workpiece shape information storing unit that stores unworked workpiece shape information obtained by the visual sensor; a worked workpiece shape information storing unit in which worked workpiece shape information is stored; a burr information calculating unit that recognizes a burr by comparing the unworked workpiece shape information with the worked workpiece shape information; a burr determining unit that determines the burr based on conditions including at least one of the location and the direction of the burr in the workpiece; a working method judging unit that decides whether or not to perform burring with a tool of the machine tool based on the determination result concerning the burr; and a working path generating unit that generates a working path for removing the burr judged to be a burr on which burring is to be performed with the tool.

A workpiece cutting method of cutting a workpiece having a front side on which a plurality of crossing division lines are formed to define a plurality of separate regions where a plurality of devices are each formed is disclosed. The workpiece cutting method includes a workpiece cutting step of cutting the workpiece held on a first chuck table along the division lines by using a cutting blade, a dummy wafer cutting step of cutting a dummy wafer held on a second chuck table by using the cutting blade, a dummy wafer imaging step of imaging a cut groove formed on the dummy wafer in the dummy wafer cutting step, by using an imaging unit to thereby obtain a detected image, and a determining step of determining the condition of the cutting blade from the condition of chippings formed on both sides of the cut groove in the detected image.

A measurement device includes: a sensor that acquires image information by imaging an object targeted for addition of materials or cutting; a measurement unit that acquires measurement data by measuring the shape of the object on the basis of the image information, the measurement data representing a shape of the object; a missing region detecting unit that detects a missing region of the object; a measurement data complementing unit that acquires re-measurement data by re-measuring the shape of the object on the basis of the image information which the sensor has acquired by re-imaging, and complements the measurement data with the re-measurement data; and a machining region specifying unit that specifies a machining region for the addition or the cutting, on the basis of the complemented measurement data and a model of a finished product obtained by the addition or the cutting.

A tool-support system for working on holes of a surface. The tool-support system includes two rails fixed to the surface and having imprints regularly distributed over their length, and a mobile tool-support including a mobile optical system capturing an image of the surface. For each rail, at least one wheel is adapted to be moved on the rail, and includes on its rolling strip counter-imprints complementary to the imprints. A mobile tool carries a working tip, and a control unit is configured to control the movement of the mobile tool-support, of the tool and of the optical system to analyze an image captured by the optical system and to detect the presence of a hole. A tool-support system of this kind can therefore move along the rails without slipping while detecting the holes to work on them.

A method of processing profiles in a profile processing assembly includes a working machine and a profile infeed assembly. The profile infeed assembly includes an infeed cross transport assembly, and an infeed conveyor assembly with an infeed conveyor and a measuring truck. The infeed conveyor has a first end remote from the working machine. The infeed cross transport assembly supplies individual profiles to the infeed conveyor assembly. The infeed conveyor assembly supplies individual profiles to the working machine by means of a measuring truck which engages a profile and moves the profile over the infeed conveyor to the working machine. The method includes determining the longitudinal position of a first end of a profile that is facing away from the working machine and moving the measuring truck to an optimal rest position which is closest to the first end of the profile to be fed onto the infeed conveyor.