Disclosed herein is a mountable dental device for shaping a tooth of a subject. The device includes: (i) an anchoring member configured to be removably affixed to a jaw of a subject by securing thereof to one or more teeth of the subject, and (ii) a computerized numerical control (CNC) machine fixedly mounted or mountable on the anchoring member. The CNC machine is configured to have installed thereon and maneuver a dental turbine. When the anchoring member is affixed to the jaw, the device is supported by the subject. The anchoring member is adjustable such as to allow the affixing thereof to jaws of different subjects. The CNC machine is configured to control operation of the dental turbine in at least one dental tooth-shaping procedure on at least one tooth of the subject.

A method of machining a surface of a component. The method comprises scanning the surface of the component to obtain scanned electronic 3D data representing the scanned surface of the component locating a surface defect of the scanned surface and identifying a defect region that surrounds and includes the surface defect, and providing electronic 3D data representing a patch having the desired shape of the defect region. The method also comprises transforming the patch to generate a tooling path for repairing the surface defect. The transformation comprising translating a plurality of nodes of the patch. The translation distance of each node based on the distance of that node from an origin node of the patch. The method further comprises machining the surface of the component according to the generated tooling path.

A scanning apparatus for predictive shimming includes a scanning platform. The scanning apparatus also include a first scanner, coupled to the scanning platform, and a second scanner, coupled to the scanning platform. The scanning platform is configured to move the first scanner and the second scanner together along an X-axis and a Z-axis. The scanning platform is also configured to move the first scanner and the second scanner independent of and relative to each other along a Y-axis and a Z-axis. A first field of view of the first scanner and a second field of view of the second scanner at least partially overlap when the first scanner and the second scanner move in opposite directions along the Y-axis.

A manufacturing control system for an additive, subtractive, or hybrid machining system implements a morphic manufacturing approach that integrates in situ inspection and related decision-making into the manufacturing process. After execution of a machining or deposition operation, the system performs a sensor scan to collect sensor measurement data for the resulting part while the part remains in the manufacturing work cell. The measurement data is compared with an as-designed digital model of the part to determine whether further machining or deposition is necessary to bring the finished part into tolerance with the model. If necessary, the system performs another additive and/or subtractive manufacturing operation on the part based on analysis of the measurement data to bring the part into tolerance. The measured inspection data can be stored in association with each manufactured part for auditing purposes or for creation of part-specific digital twins.

A method for fabricating a wildlife reproduction includes placing a reference device relative to a wildlife subject. The reference device pertains to scale and chromaticity coordinates to provide an accurate size and color reference for fabricating the wildlife reproduction of the wildlife subject. The wildlife subject is photographed in combination with the reference device at one or more predefined locations to produce two dimensional photographic image data. The two dimensional image data is converted to a three dimensional image file using photogrammetry. A value of the principal dimension of the wildlife subject is determined using the reference device. Dimensions of at least one other feature of the wildlife subject are calculated from the principal dimension to modify a three-dimensional image file of a selected wildlife subject to correspond to the wildlife subject. A three dimensional wildlife reproduction is fabricated from the modified three-dimensional image file of the selected wildlife subject.

A manufacturing control system for an additive, subtractive, or hybrid machining system implements in situ part inspection to collect as-built metrology data for a manufactured part while the part remains in the work envelop, and uses the resulting measured inspection data to generate an as-built digital twin that accurately models the finished part. After execution of a subtractive and/or additive tooling operation, the system performs a sensor scan to collect three-dimensional imaging measurement data for the resulting manufactured part while the part remains in the work cell. The measurement data is then integrated with as-designed part metadata for the idealized part to yield the as-built digital twin. Since metrology measurements are integrated into the manufacturing process, customized as-built digital twins can be generated for each manufactured part without requiring manual inspections to be performed on each part.

A manufacturing control system for an additive, subtractive, or hybrid machining system implements in situ part inspection to collect as-built metrology data for a manufactured part while the part remains in the work envelop, and uses the resulting measured inspection data to generate an as-built digital twin that accurately models the finished part. After execution of a subtractive and/or additive tooling operation, the system performs a sensor scan to collect three-dimensional imaging measurement data for the resulting manufactured part while the part remains in the work cell. The measurement data is then integrated with as-designed part metadata for the idealized part to yield the as-built digital twin. Since metrology measurements are integrated into the manufacturing process, customized as-built digital twins can be generated for each manufactured part without requiring manual inspections to be performed on each part.

A manufacturing control system for an additive, subtractive, or hybrid machining system implements a morphic manufacturing approach that integrates in situ inspection and related decision-making into the manufacturing process. After execution of a machining or deposition operation, the system performs a sensor scan to collect sensor measurement data for the resulting part while the part remains in the manufacturing work cell. The measurement data is compared with an as-designed digital model of the part to determine whether further machining or deposition is necessary to bring the finished part into tolerance with the model. If necessary, the system performs another additive and/or subtractive manufacturing operation on the part based on analysis of the measurement data to bring the part into tolerance. The measured inspection data can be stored in association with each manufactured part for auditing purposes or for creation of part-specific digital twins.

The invention relates to a device and a method for repairing components by means of additive manufacturing. The deviation of the surface of the component from a predetermined dimensions within a repair region is determined along a specified tool path. In a subsequent filling cycle, a selective application of a filler along the specified tool path is carried out.

The invention relates to a device and a method for repairing components by means of additive manufacturing. The deviation of the surface of the component from a predetermined dimensions within a repair region is determined along a specified tool path. In a subsequent filling cycle, a selective application of a filler along the specified tool path is carried out.