A driven linear axis includes a housing which has a linear rail guide on which a carriage is arranged such that it can be moved back and forth linearly with the aid of a transport device. The transport device comprises a belt which circulates in the housing and is guided over two gears, at least one gear being configured as a drive gear. Furthermore, a drive device is arranged within the drive gear and is in a torque-locking rotary connection with the drive gear.

The present invention disclose a tool-holder (10) comprising a first part (10a) and a second part (10b), wherein a wedge shaped locking mechanism is arranged partly on a first surface of the first part (10a) operable to be joined with further parts of the wedge shaped locking mechanism arranged on a second surface of the second part (10b).

An example robot includes inks comprising a first link and a second link, together with joints among the links. A joint between the first link and the second link is configured to enable relative movement between the first link and the second link. An end effector is connected in series with one of the joints. A hose assembly is connected to the end effector. The hose assembly includes a hose having a first end for making connection to a vacuum source and a second end for making connection to the end effector. An elasticity of the hose assembly is greater along the length of the hose assembly than along the cross-section of the hose assembly.

A device that dispenses spacer material is disclosed. The device may be implemented in connection with a robotic palletization/depalletization system. The device may include a mounting hardware configured to mount the device on or adjacent to an end effector of a robotic arm, a communication interface configured to receive a control signal, and an actuator configured to dispense a quantity of spacer material from a supply of spacer material in response to the control signal.

An example welding-type power supply includes: power conversion circuitry configured to convert input power to welding-type output power; auxiliary power output circuitry configured to output auxiliary power via an auxiliary power connection; communications circuitry configured to communicate via the auxiliary power connection; and processor(s) configured to: detect, via the communications circuitry, that a robot control system is coupled to the auxiliary power connection; and in response to detecting the robot control system, configuring the welding-type power supply based on receiving a communication from the robot control system via the communications circuitry.

Methods, systems, and apparatus, including computer programs encoded on computer storage media, for performing automated safety procedures for a robot. One of the methods includes receiving, by a robotic control system for a robot, a request to execute an automated safety procedure by a safety control subsystem for the robot. Each step of the automated safety procedure is iterated until an end of the automated safety procedure is reached, including if a step requires a new safety configuration, a respective safety configuration for the step is obtained and activated before performing one or more automatic actions for the step.

An apparatus, system and method for a substrate flipper capable of accommodating substrates of varying sizes. The apparatus, system and method may include a base housing providing at least a portion of a rotating feature; an arm enclosure rotatably associated with the rotating feature and providing at least one arm actuator, and at least one gripper actuator; two arms at two substantially distal points with respect to one another along the arm enclosure, each of the two arms being communicatively associated with the at least one arm actuator; and a gripper associated with each of the two arms distal from the arm enclosure, communicatively associated with the at least one gripper actuator and capable of gripping one of the substrates upon actuation of the gripper. The actuation of the at least one arm actuator effectuates a change in distance between central longitudinal axes of each of the two arms.

A method according to the present disclosure includes: (a) carrying out overexcitation of an electromagnetic brake; (b) controlling a fan cooling a control device in such a way that a power consumption of the fan becomes a first power consumption in an overexcitation period during which the overexcitation is carried out; and (c) controlling the fan in such a way that the power consumption of the fan becomes a second power consumption higher than the first power consumption, after the overexcitation period.

A power supplying module that can be reduced in size is provided. The power supplying module includes a module body, and a lead-in unit provided on one surface of the module body. The lead-in unit includes a plate unit that fixes at least one sealing tube to the one surface of the module body, and at least one circumference holding unit that holds a circumference of the corresponding sealing tube. The plate unit is provided with, in a longitudinal direction of the one surface of the module body, a plurality of cable insertion holes, and a plurality of positioning portions that position the plurality of circumference holding units to the corresponding cable insertion holes.

Disclosed herein are systems and methods directed to an industrial robot that can perform mobile manipulation (e.g., dexterous mobile manipulation). A robotic arm may be capable of precise control when reaching into tight spaces, may be robust to impacts and collisions, and/or may limit the mass of the robotic arm to reduce the load on the battery and increase runtime. A robotic arm may include differently configured proximal joints and/or distal joints. Proximal joints may be designed to promote modularity and may include separate functional units, such as modular actuators, encoder, bearings, and/or clutches. Distal joints may be designed to promote integration and may include offset actuators to enable a through-bore for the internal routing of vacuum, power, and signal connections.