An end-effector may include a base, a plurality of underactuated fingers coupled to the base; and an adhesion gripper coupled to the base. An end-effector may include a base, an actuator, a first underactuated finger comprising a proximal link and a distal link, the proximal link including a distal end, a guide for a first tendon spaced a first distance away from the distal end of the proximal link and the distal link including a lever arm disposed on a proximal side to the distal pad and which extends in a volar direction from a first axis, and a node disposed on the lever arm sized and shaped to receive a first tendon. The end-effector may include a first revolute joint compliant in a first direction disposed between the base and the proximal link; and a second revolute joint compliant in the first direction disposed between the proximal link and the distal link.

An adhesive gripper for pick-and-place maneuvers comprises one or more legs, where each leg terminates in a foot rotatably connected to the respective leg. Each foot includes a SMP dry adhesive comprising a shape memory polymer, and a rigid backing layer attached to a back side of the SMP dry adhesive, such that a front side of the SMP dry adhesive is available for attachment and release of objects. The adhesive gripper further includes a handle portion connected to the one or more legs, a release mechanism comprising a release ring within the handle portion, and one or more releasing rods integrated with the one or more legs for release of an object onto a substrate.

Methods and systems for training a robotic manipulator. The system may include one or more sensor devices and a robotic manipulator for executing an item grasping strategy to grasp an item. The system may further evaluate the item grasping strategy to determine whether the strategy was successful.

A transport tool for transporting a laboratory article using a pipette of a pipetting system and having a plug-in sleeve at a top end, an article holder at a bottom end, and a connecting part which connects the plug-in sleeve to the article holder. The plug-in sleeve has a side sleeve wall and a bottom which surround an interior space of the plug-in sleeve having a cylindrical and conically tapering shape. The plug-in sleeve further has an upward-facing opening for receiving an end of a pipette of an automated pipetting system. The connecting part has a top surface which defines the bottom of the plug-in sleeve, is positioned between the interior space of the plug-in sleeve and the article holder. The article holder has a holding plate which is flat and faces downward away from the plug-in sleeve, and further has a flatly acting magnet on the holding plate.

The present disclosure discloses a fibrillar, directional adhesive assembly, a gripper, and a robot including a gripper. In one embodiment, the fibrillar, directional adhesive assembly includes a carriage, a layer of fibrillar, directional adhesive, and at least one load component. The carriage may have a first lateral side and a second lateral side adjacent to the first lateral side and the at least one load component may connect the layer of fibrillar, directional adhesive to the first lateral side and the second lateral side. The load component may be capable of loading shear force from the carriage to the layer of fibrillar, directional adhesive along a first direction and a second direction substantially perpendicular to the first direction.

A vertical surface cleaning device comprising a main body, a cleaning arm, a cleaning head, and leg mechanisms with grippers. The cleaning head applies a cleaning fluid on a surface to carry out a cleaning operation. A waste collector is provided to collect a waste material arising from the cleaning operation. The grippers may remain in a grip or in a release state. The segments of the leg mechanisms are articulatable to configure a first group of the leg mechanisms to stably hold the main body at a first place with the grippers remaining in the grip state. A second group of the leg mechanisms move in a desired direction with their grippers in release state while the first group stably holds the main body. The first group of the leg mechanisms then moves in the same direction while the second group holds the main body at a second place.

The present invention provides a method for constructing an access floor by using unmanned robot, the method comprising: a first step (S100) of constructing an installation frame (10) and a peripheral slab (60) formed on the periphery of the installation frame; a second step (S200) of positioning the unmanned robot on the peripheral slab (60); and a third step (S300) of coupling a floor (30) to the installation frame (10) by the unmanned robot while moving along the peripheral slab (60). According to the present invention, an automated robot can install a mat and floor in place of a worker performing dangerous floor installation work, so as to prevent the occurrence of workplace safety accidents. Furthermore, through the installation of a mat and floor by the robot, floor installation location selection and leveling work can be quickly performed, so as to reduce the construction costs and shorten the construction period.

A toy retrieval apparatus wherein the present invention is configured to facilitate retrieval of a fallen toy or similar object subsequent a child sitting in the rear seat of a vehicle dropping the toy and a passenger in the front seat can utilize the present invention to retrieve the toy. The toy retrieval apparatus includes a housing wherein the housing has a spring loaded winding member disposed in the interior volume thereof. The spring loaded winding member has a cord member secured thereto. The cord member has attached to the distal end an attachment member. The attachment member of the present invention is formed to releasably secure to a toy through either adherence to the outer cover of the attachment member or being secured with finger members of the attachment member. The attachment member includes a malleable metal structural insert member that provides bending of the finger members.

A system for assembling a plurality of components into an assembly is provided. The system includes an installation table, a first transfer robot, a second transfer robot, and an adhesive dispensing robot. The first transfer robot is configured to assemble some of the plurality of components into a first sub-assembly and transfer the first sub-assembly to the installation table. The second transfer robot is configured to assemble remaining ones of the plurality of components into a second sub-assembly, transfer the second sub-assembly to the installation table, and attach the second sub-assembly to the first sub-assembly. The adhesive dispensing robot is configured to apply an adhesive between the first sub-assembly and the second sub-assembly, after the second sub-assembly is attached to the first sub-assembly, to bond the second sub-assembly to the first sub-assembly.

A gripper for a picking device for small piece goods is provided. The gripper includes a delivery table extending in a first horizontal direction and a second horizontal direction orthogonal to the first horizontal direction, a gripping jaw guide assembly having two gripping jaws extending in the first horizontal direction over the delivery table, wherein at least one of the gripping jaws is movable in the second horizontal direction, and a drive unit which is coupled to the gripping jaw guide assembly and configured to move the gripping jaw guide assembly in the first horizontal direction. At least one of the gripping jaws is configured as a suction jaw and has a suction device having a suction surface for suctioning a small piece good, wherein a vacuum can be applied on the suction device using a suction line.