A labware transport apparatus includes a frame, defining a labware space, and a robotic multi-link arm operably connected to the frame via a drive section. The arm has a predetermined link configuration determining a minimum footprint of the arm and a corresponding maximum reach of an end effector of the robotic multi-link arm within a range of motion of the end effector. The range of motion, at least in part of the labware space, of the end effector is delimited by a blockage of a substantially vertical axis of motion, of the drive section of the robotic multi-link arm, extending through the range of motion, wherein the blockage is sized and shaped based on and so as to maximize the range of motion of the end effector of the robotic multi-link arm having the predetermined link configuration that is common determining the minimum foot print and the corresponding maximum reach.

A labware transport apparatus includes a frame, defining a labware space, and a robotic multi-link arm operably connected to the frame via a drive section. The arm has a predetermined link configuration determining a minimum footprint of the arm and a corresponding maximum reach of an end effector of the robotic multi-link arm within a range of motion of the end effector. The range of motion, at least in part of the labware space, of the end effector is delimited by a blockage of a substantially vertical axis of motion, of the drive section of the robotic multi-link arm, extending through the range of motion, wherein the blockage is sized and shaped based on and so as to maximize the range of motion of the end effector of the robotic multi-link arm having the predetermined link configuration that is common determining the minimum foot print and the corresponding maximum reach.

An extension tool includes a plurality of sequentially arranged links moveable relative to one another. The plurality of sequentially arranged links include a first link. The extension tool further includes a line assembly having a line, the line including a first portion extending through the plurality of sequentially arranged links to the first link and a transition portion extending from the first portion through the first link. The extension tool further includes an attachment feature coupled to or formed integrally with the line of the line assembly at the transition portion of the line to support the line in the event of a failure of the line.

An extension tool includes a plurality of sequentially arranged links moveable relative to one another. The plurality of sequentially arranged links include a first link. The extension tool further includes a line assembly having a line, the line including a first portion extending through the plurality of sequentially arranged links to the first link and a transition portion extending from the first portion through the first link. The extension tool further includes an attachment feature coupled to or formed integrally with the line of the line assembly at the transition portion of the line to support the line in the event of a failure of the line.

An adapter system for connecting the last element of a kinematic chain of a handling device to same, wherein the last element has a computer-storage module, as well as at least one actuator and/or at least one sensor. At least three sequentially positioned system modules are arranged between the penultimate and the last element. A first system module is a mechanical module, via which electrical and/or pneumatic connection lines are guided. In a second system module, the connection lines are connected with transition points of a negative adapter geometry of a mechatronic combi-interface. At least one further system module is arranged in a couplable manner between the second system module and the last element. A third system module has an electronics assembly which adapts the predefined system architecture to the device interface of the last element.

A box packing device includes a first arm, a first hand, and a controller. The first hand includes a hand base, a gripping mechanism at the hand base and including a gripper to grip an upper-end of a flap of a large box, and a holding mechanism at the hand base and including a holder to hold an inner box. The controller controls the operation of the first arm and the first hand so as to perform a developing operation in which the gripping part of the gripping mechanism moves in a horizontal plane so as to develop the large box while gripping the upper-end part of the flap part of the large box in a folded state, and an accommodating operation in which the holder of the holding mechanism accommodates the inner box into the developed large box while holding the inner box.

A mobile robotic device includes a mobile base and a mast fixed relative to the mobile base. The mast includes a carved-out portion. The mobile robotic device further includes a three-dimensional (3D) lidar sensor mounted in the carved-out portion of the mast and fixed relative to the mast such that a vertical field of view of the 3D lidar sensor is angled downward toward an are in front of the mobile robotic device.

A robot 100 includes a base 1 having side portions, an arm 3 rotatably coupled to the base 1, and a hand 8 coupled to the arm 3. A joint between the arm 3 and the base 1 is closest to a first side portion 11a in a plan view. The base 1 houses control components. A second side portion 11b is provided with a maintenance area 12 on which a maintenance component such as a first board 24 is disposed. The maintenance area 12 is used for maintenance of the maintenance component.

An object of the present invention is to simplify a joint, such as reducing the weight of the joint, in a robot arm mechanism capable of detecting contact of a person or an object. A robot arm mechanism (1) according to an embodiment of the present disclosure includes rotational joints (J1, J2). The rotational joint (J1) and the rotational joint (J2) are connected to each other by a link (30). The link (30) includes a plurality of link portions (31, 33, 35, 37). The link portions (31, 33) are coupled to each other via a torque sensor (61), the link portions (33, 35) are coupled to each other via a torque sensor (63), and the link portions (35, 37) are coupled to each other via a torque sensor (65).

An object of the present invention is to simplify a joint, such as reducing the weight of the joint, in a robot arm mechanism capable of detecting contact of a person or an object. A robot arm mechanism (1) according to an embodiment of the present disclosure includes rotational joints (J1, J2). The rotational joint (J1) and the rotational joint (J2) are connected to each other by a link (30). The link (30) includes a plurality of link portions (31, 33, 35, 37). The link portions (31, 33) are coupled to each other via a torque sensor (61), the link portions (33, 35) are coupled to each other via a torque sensor (63), and the link portions (35, 37) are coupled to each other via a torque sensor (65).