The invention relates to a process for painting a workpiece using a painting robot including a robot arm equipped with a paint spraying device, the process including, an operation S1 of modeling a realistic 3D model corresponding to the workpiece as deformed and positioned in a paint cell, the realistic 3D model including paint trajectory information suitable for the workpiece as deformed and positioned in the paint cell, and a paint spraying operation S2 during which the paint spraying device is moved along the paint trajectory opposite the workpiece.

A system and method for automatically manufacturing custom parts for use in a prefabricated construction site includes scanning a room under construction. The method also includes determining, based on the scan of the room, an image of an installation location in the room. The method also includes calculating, based on the image of the installation location, alteration dimensions for a prefab part. The alteration dimensions comprise alterations to the prefab part to match spatial dimensions of the installation location in the room. The method additionally includes transmitting, via a network, the alteration dimensions to a factory. The factory fabricates a custom prefab part according to the alteration dimensions.

A method of using additive manufacturing to form or print a component based on an original model of a component, where the geometry of the original model is compensated to form a compensated model. The compensated model can be used to form or print the component. The printed component as a final model can then be compared to the original model.

A method of using additive manufacturing to form or print a component based on an original model of a component, where the geometry of the original model is compensated to form a compensated model. The compensated model can be used to form or print the component. The printed component as a final model can then be compared to the original model.

A system and method for automatically manufacturing custom parts for use in a prefabricated construction site includes scanning a room under construction. The method also includes determining, based on the scan of the room, an image of an installation location in the room. The method also includes calculating, based on the image of the installation location, alteration dimensions for a prefab part. The alteration dimensions comprise alterations to the prefab part to match spatial dimensions of the installation location in the room. The method additionally includes transmitting, via a network, the alteration dimensions to a factory. The factory fabricates a custom prefab part according to the alteration dimensions.

A method of forming a component that includes identifying an acute angle in an original model that is a virtual model of the component. The acute angle is defined by a first surface and a second surface. The method includes compensating the original model at the acute angle to create a compensated acute angle in a compensated model. The method also includes forming, by additive manufacturing, the component based upon the compensated model, where the formed component is more alike the original model than the compensated model.

A system and method for automatically manufacturing custom parts for use in a prefabricated construction site includes scanning a room under construction. The method also includes determining, based on the scan of the room, an image of an installation location in the room. The method also includes calculating, based on the image of the installation location, alteration dimensions for a prefab part. The alteration dimensions comprise alterations to the prefab part to match spatial dimensions of the installation location in the room. The method additionally includes transmitting, via a network, the alteration dimensions to a factory. The factory fabricates a custom prefab part according to the alteration dimensions.

This disclosure relates to a computer-implemented system and related methods for the design, evaluation, and/or manufacture of protective patient footwear, such as shoes, braces, boots, casts, corrective footwear, and orthoses. The system includes suitable hardware, software, and related peripherals, which function to acquire data related to the patient's particular footwear needs, such as by image capture, including three-dimensional scanning. The system may also acquire data through other sources of input, such as through one or more sensors for detecting various physiologic parameters associated with the lower extremity, or through input of medical conditions, prior indicators, exam, analysis, lab results, or the like, such as through medical practitioner input or other input protocols. The various inputs may be suitably processed to generate output in the form of a design accommodation to design or modify the protective patient footwear, or in the form of one or more medical evaluations or recommendations.

Method comprising: designing a gear in a software-based computer-aided manner in order to obtain a function-oriented geometry, using a software-based computer-aided method for ascertaining a theoretically producible gear geometry corresponding to or an approximation of the function-oriented geometry), providing production data representing the theoretically producible geometry, machining a gear using the production data in a CNC-controlled processing machine, measuring the gear to obtain an actual data set of the gear, carrying out a comparison of the actual data set with the production data in order to ascertain at least one correction variable, using the correction variable in order to ascertain corrected production data from the production data or carry out a machining correction in the processing machine, and post-machining the gear using the machining correction or using the corrected production data in order to machine at least one additional gear in the processing machine.

Method comprising: designing a gear in a software-based computer-aided manner in order to obtain a function-oriented geometry, using a software-based computer-aided method for ascertaining a theoretically producible gear geometry corresponding to or an approximation of the function-oriented geometry, providing production data representing the theoretically producible geometry, machining a gear using the production data in a CNC-controlled processing machine, measuring the gear to obtain an actual data set of the gear, carrying out a comparison of the actual data set with the production data in order to ascertain at least one correction variable, using the correction variable in order to ascertain corrected production data from the production data or carry out a machining correction in the processing machine, and post-machining the gear using the machining correction or using the corrected production data in order to machine at least one additional gear in the processing machine.