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.

A process and tool for installing and removing various kinds of wear parts used with earth working equipment. The process and tool allows the operator to remove and install the wear parts at a safe distance so that the operator is physically remote from the potential risks of the removal and installation process. The tool may be manually operated via an operator or the tool may be a semi-automated or fully automated.

An automated cleaning system for cleaning an object, comprising a laser configured to be directed at the object, to remove contaminants from the object; detection system to identify details about the object; rotation apparatus to rotate the object in a cleaning position; and control apparatus to direct the laser at the object in the cleaning position, and operate the laser to clean the object.

An end-effector for installation of an emblem assembly is provided. The end-effector includes a support frame, a first splitter, and a second splitter. The first splitter and the second splitter are connected to the support frame. The pneumatically actuated grippers include: a first gripper connected to the first splitter and configured to grab at least a portion of the emblem assembly; and a second gripper connected to the second splitter and configured to peel off one or more layers of the emblem assembly. The roller is connected to the support frame and configured to wet out an adhesive layer of the emblem assembly.

A conveyance method includes: acquiring type identification information identifying a type of a conveyance target article; acquiring instrument identification information identifying the type of an instrument installed in each of a plurality of devices; specifying the type of the instrument associated with the type identified by the type identification information; selecting a target device in which the instrument of the specified type is installed among the plurality of devices; and outputting, to a conveyance robot, a conveyance instruction to convey the conveyance target article to the target device.

Systems and methods for a universal connection interface between a robot and a plurality of modular attachments are disclosed. The connection interface includes a data connection and a dynamic amplifier configured to adjust output of at least one electromechanically coupled mechanical output; and a processor configured to control gain of the dynamic amplifier.

An automated analyzer that receives samples prepared for analysis in an automated pre-analytical module and a method of operation of such automated analyzer. The automated analyzer includes a shuttle transfer station that receives a shuttle carrier from the automated pre-analytical system. The shuttle transfer station has a clamping assembly for the shuttle. The clamping assembly has jaws that advance engagement members into contact with a bottom portion of sample containers disposed in the shuttle. The clamping assembly secures the sample containers in the shuttle when sample is aspirated from the sample containers. The automated analyzer also has a multichannel puncture tool that is adapted to be carried by a robotic gripper mechanism. The multichannel puncture tool has multiple puncture members that each defines a channel Each channel is in communication with a different trough in the consumable. A pipette can pass through the channel in the puncture tool.

An autonomous robot for harvesting produce from a plant include a base, an arm coupled to the base, and an end-effector coupled to the arm. The end-effector includes one or more grippers, each having a first cutter, second cutter, and a compliant member between the first cutter and the second cutter. The first cutter is configured to cut a stem of the produce at a first location. The second cutter is configured to cut the stem of the produce at a second location. The compliant member is configured to plastically deform to hold the stem of the produce.

A lift device includes a base assembly, a turntable assembly, and a controller. The base assembly includes multiple base assembly batteries. The turntable assembly is rotatably coupled with the base assembly through a slip ring transmission. The turntable assembly includes multiple turntable assembly batteries. The controller is configured to operate the base assembly batteries to discharge electrical energy to the turntable batteries through the slip ring transmission. The slip ring transmission is configured to both (1) drive the turntable assembly to rotate relative to the base assembly and (2) to electrically and communicably couple electrical components of the base assembly with electrical components of the turntable assembly.

Systems, devices and methods for assembling a piece of furniture are described herein. The systems include a robot including a base, a robotic arm coupled to the base and a multi-functional robotic head coupled to the robotic arm. The multi-functional robotic head includes a camera configured to scan a barcode positioned on a part presented to the robot. The barcode provides instructions to the robot for attaching one or more hardware components to the part to assemble the piece of furniture. The multi-functional robotic head also includes a first applicator mechanism configured to apply an adhesive to the part; a first gripping mechanism configured to grip a first hardware component to be manoeuvred by the robotic arm to a first position to be attached to the part, and a first attachment mechanism configured to attach the first hardware component to the part at the first position.