A device (10, 100) for handling and/or machining a workpiece (1) having a non-metal surface, comprising: a workpiece identification device (20) which is designed to irradiate electromagnetic radiation inside the workpiece (1) and to receive electromagnetic radiation reflected from the inside of the workpiece (1); and a data processing unit (30) which is configured to determine information from the inside of the workpiece (1) on the basis of measured data of the reflected electromagnetic radiation. Also disclosed is a method with which it is possible to determine a characteristic material parameter, preferably a component-specific reflection value of the workpiece (1), on the basis of the received electromagnetic radiation.

A workpiece information recognition system includes a workpiece placing tool (20) capable of placing a workpiece, a reference block (31) detachably provided on workpiece placing tool (20), an information detector configured to detect information about reference block (31), and a control device configured to receive the information of reference block (31) from the information detector. The control device includes a storage configured to store data on a relationship between the information about reference block (31) and information about the workpiece and a controller configured to recognize the information about the workpiece placed on workpiece placing tool (20) by checking the information about reference block (31) detected by the information detector with the data stored in the storage. With this configuration, the workpiece information recognition system capable of easily cope with a change in a type of the workpiece is provided.

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 disclosure discloses an automatic wheel detecting device. The device can automatically detect marks of spoke back cavities and the inner side coaxiality and the outer side coaxiality of wheels, the wheels with marks being missed are identified in time, the values of the inner side coaxiality and the outer side coaxiality of the wheels on a production line are monitored in time, if the values are out of tolerance, an alarm is given out in time, and the device can be used for automatic production.

A measurement system includes a measuring instrument, a measurement control device, and a ranging device. The measuring instrument includes a base that is to be fixed to a tool shaft of a machining apparatus, a first rod and a second rod that are connected to the base, and a first measuring head and a second measuring head that are fixed to the respective rods and irradiate an object to be measured with measurement light. The measurement control device acquires a distance I between the first measuring head and an inner peripheral surface of the hole of the object to be measured, and a distance O between the second measuring head and an outer peripheral surface of the object from the ranging device, and calculates the thickness of the object on the basis of the distance I, the distance O, and a distance between the first and second measuring heads.

A machine tool control system according to the present invention includes: a three-dimensional coordinate computing unit which calculates three-dimensional coordinates of a workpiece based on a plurality of images of the workpiece, the images being taken by the imaging apparatus from a plurality of different directions, and which calculates, from the three-dimensional coordinates, three-dimensional coordinates of a specified machining start point on the workpiece; and a coordinate converting unit which converts three-dimensional coordinates that includes the machining start point on the workpiece calculated by the three-dimensional coordinate computing unit into coordinates in the machine coordinate system for the machine tool, and which sets the converted three-dimensional coordinates of the machining start point on the workpiece, as a workpiece origin, into the machining program for the machine tool.

An apparatus and method for supporting and severing an object of interest is described and which includes a frame for positioning an object of interest which is to be severed; a cutting device which is selectively mounted in spaced relation relative to the frame; a multiplicity of orientation units mounted on the frame and which are adjustable, as to length, to maintain the object of interest in a predetermined orientation while being severed; and a controller operably coupled to each of the cutting device, and orientation units, so as to effect an optimal severing of the object of interest while maintaining the object of interest in a given planar orientation on the frame.

The present invention demonstrates a halfway cutter changing method for large-area microstructure cutting based on in-situation film thickness measurement, including the following steps: step 110: preparatory work; step 120: workpiece preliminary machining; step 130: transparent film coating; step 140: film thickness detection; step 150: halfway cutter changing; and step 160: machining completion. The halfway cutter changing method for the large-area microstructure cutting based on the in-situation film thickness measurement provided by the present invention implements machining of a microstructure with large area, high quality and high uniformity.

A system is placed upon a target object and a machining tool. The system comprises a variety of sensors to detect adverse relative movement and position loss of the target object as it is affected by the machining tool. The system further comprises portable sensors in communication with a printed control board, configured to communicate position data to a remote computing device. The remote computing device may receive the position data, process it, and present output to a display. The system may detect position, kinematic, and mechanical issues present during the machining process by comparing the position data to thresholds, including position loss, and automatically adjust the operation of the machining tool in response.

The present invention relates to an automatic fault diagnosable integrated sheet body punching and grinding assembly, including a frame and a conveying slot seat, a processing frame is provided on the conveying slot seat, the processing frame is sequentially provided with a punching device and a grinding device; the frame is provided with a feeding motor and a feeding screw cooperating with each other, the feeding screw is sleeved with a movable feeding block, and the movable feeding block is fixedly connected with a movable feeding seat, the movable feeding seat is provided with a feeding lift cylinder, the feeding lift cylinder is provided with a feeding lift block; the feeding lift block is evenly disposed with feeding blocks that can pass through the feeding slot, and the distance between the processing portion of the punching device and the grinding device is the same as that between the adjacent two feeding blocks. In the present invention, the conveying slot seat cooperates with the fixed distance feeding part to realize the fixed distance feeding of the sheet bodies, the punching device and the grinding device are provided sequentially on the conveying slot seat, which enables continuous automatic punching and grinding of sheet bodies, thereby greatly improves the efficiency of punching and grinding of the sheet bodies.