Manufacturing and assembly of a shoe or a portion of a shoe is enhanced by automated placement and assembly of shoe parts. For example, a part-recognition system analyzes an image of a shoe part to identify the part and determine a location of the part. Once the part is identified and located, the part can be manipulated by an automated manufacturing tool.

A system for fabricating a dental restoration to restore a tooth at a restoration site in a dentition of a patient is disclosed. The dentition includes a restoration dental arch and an opposing dental arch. The restoration dental arch include the restoration site and the opposing dental arch is opposite the restoration dental arch. The system includes an impression apparatus, a motion capture apparatus, an interface apparatus, and a restoration design system. The impression apparatus is configured to capture an impression of the dentition of the patient. The motion capture apparatus is configured to capture a plurality of location data points that represent the locations of the opposing dental arch relative to the restoration dental arch. The interference model generation system is configured to generate an interference model for the restoration site. The restoration design system is for designing a restoration using the interference model.

A system for fabricating a dental restoration to restore a plurality of teeth in a dentition of a patient is described. The dentition includes a restoration dental arch and an opposing dental arch. The restoration dental arch includes a restoration site and the opposing dental arch is opposite the restoration dental arch. The system includes an impression apparatus, a motion capture apparatus, an interference model generation system, and a restoration design system. The impression apparatus is configured to capture an impression of the dentition of the patient. The motion capture apparatus is configured to capture a plurality of location data points that represent the locations of the opposing dental arch relative to the restoration dental arch. The interference model generation system is configured to generate an interference model for the restoration site. The restoration design system is for designing a restoration using the interference model.

A robot apparatus includes: a robotic arm provided with a robotic hand capable of changing its position and its orientation by using joints; a visual sensor which measures a position or an orientation of a gripped object gripped with the robotic hand at a measurement teaching point; and a control device. The control device controls the position or the orientation of the gripped object when the gripped object is attached to an attachment target object at a corrected teaching point corrected based on a measurement result by the visual sensor. In this case, the control device determines a measurement teaching point, where the measurement with the visual sensor takes place, such that a driving direction of each of the joints from the measurement teaching point to the corrected teaching point is set to a definite driving direction.

The present invention relates to a vision based inspection tool for setting of an initial origin of an automation machine tool, and more particularly, to a built-in type of vision based inspection tool for setting of an initial origin capable of improving setting precision of a current automation machine tool that depends on initial setting and increasing productivity depending on individual automatic setting by automatically sensing a machining origin in order to perform initial machining and re-machining of an existing workpiece using an automation machine tool and compensating for the machining origin to eliminate a time required for setting machining origins for various shapes in a jog mode.

A device for feeding items to a sorting machine, including: a conveyor plane (26) for feeding items or parcels along an advancement direction (A1); an optical detection device (18), to allow the acquisition, while the items are in motion on the conveyor plane (26) of the three-dimensional coordinates of a determined number of points on the surface of the items and to organize them into coordinate vectors; a manipulator (19) provided to pick the items from the conveyor plane (26) and to place the items picked in a desired position; a control system, provided to process, for each item in motion on the conveyor plane (26), the coordinate vectors in order to obtain a three-dimensional representation of the item, including the information based on which the control system handles the manipulator for picking and placing the items.

The invention also relates to a sorting machine and a method for feeding items to a sorting machine aimed at increasing production capacity and accuracy thereof.

The system for making or breaking the riser includes a robotic system. The robotic system includes one or more robotic arms configured to be disposed on a spider deck, and one or more riser-connection manipulation tools each having a camera and being configured to manipulate a riser connection, the camera being configured to capture an image of an object, wherein each robotic arm is configured to couple to one riser-connection manipulation tool. Further the system for making or breaking the riser includes a control system. The control system includes a robot controller in communication with the one or more robotic arms and configured to control the one or more robotic arms. The system for making or breaking the riser is configured to analyze the image to determine the location and orientation of the object and transmit the location and orientation of the object to the robot controller.

A control device includes a control section configured to control a robot on the basis of first information concerning positions and sequential numbers for drawing a linear object around a first object. The first information is received by a receiving section and displayed on a display section.

A manufacturing system for fabricating a three-dimensional article includes a housing, a sensor within the housing, a coater, a removable powder module (RPM) with a platen, a laser system, and a controller. A method of operating the manufacturing system includes installing the RPM into the housing, forming pillars onto the platen, positioning the top surfaces of the pillars a distance D below a build plane, installing a calibration plate onto the top surfaces of the pillars, and then calibrating the laser system using the sensor. The sensor can include one or more of an optical sensor and an acoustic sensor.

A system and method for monitoring an industrial vehicle are presented. The system includes a first imaging subsystem for acquiring a plurality of load-carrying-portion images. A cargo-detection subsystem is configured for analyzing each of the plurality of load-carrying-portion images to determine whether cargo is positioned on the load-carrying portion. A power-detection subsystem is configured for determining when the industrial vehicle is running. A motion-detection subsystem is configured for determining when the industrial vehicle is in motion. An analytics subsystem is configured for calculating the amount of time that the industrial vehicle is running, the amount of time that the industrial vehicle is running while cargo is positioned on the load-carrying portion, the amount of time the industrial vehicle is in motion, and the amount of time the industrial vehicle is in motion while cargo is positioned on the load-carrying portion.