A pharmacy order processing system includes a container disassembly workstation defining a container disassembly workspace and a bulk container area including a plurality of bulk containers configured to receive a plurality of pharmaceuticals. The container disassembly workstation includes a holding area, a cutter device, a container manipulation device, a pharmaceutical receptacle, and a container receptacle. The cutter device includes a cutter head and is configured to cut through at least one wall of at least one container to separate at least a first portion of the at least one container of the plurality of containers from a second portion of the at least one container when the at least one container is in a cutter position. The container manipulation includes a gripper device and is configured to move the at least one container between at least the holding position and the cutter position within the container disassembly workspace.

A robotic forming system and method for forming a tapered hole in a workpiece include a housing and a nose extending from the housing. The housing defines an internal chamber. A vacuum gate is in fluid communication with an internal cavity of the nose. A seal is within the nose. A first spindle includes a first operative head. The first spindle is retained within the internal chamber. The first spindle is configured to be moved between a first stowed position within the housing and a first operating position in which the first operative head extends into the nose. The first operative head is configured to form an initial hole within the workpiece. A second spindle includes a second operative head. The second spindle is retained within the internal chamber. The second spindle is configured to be moved between a second stowed position within the housing and a second operating position in which the second operative head extends into the nose. The second operative head is configured to modify the initial hole to form a tapered hole.

A robot system according to the present disclosure includes a robot installed in a work area, a manipulator configured to be gripped by an operator and manipulate the robot, a sensor disposed at a manipulation area and configured to wirelessly detect positional information and posture information on the manipulator, and a control device which calculates a locus of the manipulator based on the positional information and the posture information on the manipulator detected by the sensor, and operates the robot on real time.

Systems, and methods for harvesting a fruit.

An ultrasonic manipulator for processing three-dimensional composite preforms is provided, including at least one end effector, the end effector having an ultrasonic cutting device, an ultrasonic machining device, an ultrasonic inspecting device, and an ultrasonic bonding device. A method for creating three-dimensional preforms for use in molding composite parts is also provided, and includes the steps of grasping a preform/towpreg, inspecting the composite object using ultrasound, cutting a preform from the composite object using ultrasound, and at least some of the steps of shaping the preform using ultrasound, machining the preform using ultrasound, assembling a plurality of preforms, bonding the assembled preforms together to create a preform charge, and placing the preform charge in an injection mold.

This disclosure relates to apparatuses and methods for processing and grading food articles. For example, provided herein is a system for grading a portioned food article, in which the system includes: a first conveyor; a first receiving conveyor and a second receiving conveyor, defining a space therebetween; at least one spray-removal robot; and a third receiving conveyor. The spray-removal robot may include at least one valve with a nozzle, in which the valve ejects fluid through the nozzle to impact a food article being moved on the first conveyor toward the third receiving conveyor, such that at least one portion of the food article is moved by the impact through the space between the first receiving conveyor and the second receiving conveyor, and such that at least one portion of the food article is moved by the first receiving conveyor and the second receiving conveyor to the third receiving conveyor.

Pruning robot including means for removing processionary caterpillar nests, the robot being characterized in that it is carried by a drone provided with an onboard automaton, which is equipped with an electromechanical tool consisting of a gripper associated with a cutting device intended to cut the branches supporting the nests that are to be removed.

A system including an autonomous ground vehicle (“AGV”) designed as a common platform to which is affixed one or more articulated arms, which, when combined with attached implements and software for performing movement of the AGV and the arm(s), carries out tasks common to small farms and maintaining small parcels of land. The software enables a farm operator to set up, control, and monitor operations of the robotic system.

This disclosure concerns methods for processing and grading food articles including x-raying the food articles a first time and taking a 3D image of the food articles.

The invention relates to a robotic method for loading cases on a packaging line from cases contained in a closed parallelepiped container and wherein it is proceeded with the loading of the packaging line, after opening of the container (Ca) by: /d/ insertion of a first jaw (30) of the clamp between the first face (F1) of the container and the first case (Et1) of the row of cases and, insertion of a second jaw (31) of the clamp between the last case (Etd) of the row of cases and the second face (F2) of the container, and approach of the jaws until seizing up the row of cases, /e/ piloting of the robotic arm so as to extract the row of cases from the container grasped by the motor-driven clamp (3) and load the packaging line (Lg) with the row of cases.