A device for controlling a handling device comprising a carrier housing which can be arranged on the handling device with a tactile sensor body arranged on the outside of the carrier housing and a tool carrier movably mounted on the carrier housing, wherein the sensor body can be actuated by the tool carrier when load is acting on the tool carrier, wherein the sensor body is formed by a gas-filled chamber which is surrounded by a flexible shell, which can be deformed by collision with an obstacle, and further comprises a pressure sensor for measuring the gas pressure prevailing inside the chamber.

An apparatus including a plurality of robot arm links movably connected to one another, where a first one of the robot arm links includes a frame, where the frame has a first end movably connected onto a second one of the robot arm links; and at least one vibration damper arrangement on the frame of the first robot arm link, where the at least one vibration damper arrangement includes at least one viscoelastic element connected to the frame of the first robot arm link by a connection such that, as the frame of the first robot arm link experiences vibrations, the at least one viscoelastic element dampens the vibrations in the frame of the first robot arm link based upon viscoelasticity and the connection of the at least one viscoelastic element to the frame of the first robot arm link.

A drive assisting device for applying biasing forces that has the versatility to be compatible with a variety of installed states. A drive assisting device has a case from which an output shaft that is driven by an actuator protrudes; a connecting member for connecting the output shaft to that which is to be driven; an assist spring, disposed coiled around the output shaft, with one end thereof secured to the connecting member; and an adjusting member that is assembled together with the case while adjusting the biasing force of the assist spring, having the other end of the assist spring secured thereto.

A bionic robot is provided, which includes a body; a plurality of sets of wheeled leg devices arranged at intervals in a front-rear direction, each comprising two wheeled leg devices arranged symmetrically in a left-right direction, each comprising a leg assembly and a travel wheel, and a power output shaft connected to the travel wheel; and a suspension device disposed in the body and connected to at least two sets from the plurality of sets of wheeled leg devices. The at least two sets of wheeled leg devices are located at the foremost end and the backmost end respectively. The suspension device comprises a plurality of drive assemblies, each connected to a corresponding leg assembly, which each comprise: an electric cylinder being configured to drive a telescopic rod to extend or retract; a damper connected between the body and the leg assembly; and an elastic member fitted over the damper.

A support robot and control system having a support arm providing at least one degree of motion. The support robot includes a support arm supporting mechanism connected to the support arm and providing at least two degrees of motion. The support arm optionally includes a biomimetic actuator connectable to an end effector, a telescoping section operatively connected to the biomimetic actuator, and a tensile force transmitting member connected to an actuator. The actuator is capable of moving the biomimetic actuator towards and away from the actuator via the tensile force transmitting member. The support arm further includes an inflatable outer cover at least partially encasing the telescoping section and the tensile force transmitting member.

The present invention relates to an actuator module with a flexible unit, and more particularly, to an actuator module mounted on an articulated robot and having a flexible unit capable of detecting an abnormal load through sensor-based accurate load measurement to improve essential stability of the actuator module. The actuator module includes a drive unit for generating a rotational force, a deceleration unit connected to the drive unit to receive the rotational force therefrom for reducing a rotational speed transmitted thereto to increase the rotational force, a flexible unit connected to the deceleration unit to receive the rotational force therefrom and having a plurality of elastic members in a stacked form, the elastic members being variable by an external force, and an output unit connected to the flexible unit to receive the rotational force therefrom for outputting the transmitted rotational force to the outside, wherein the elastic members have the same elastic force or different elastic forces, and are selectively varied depending on the magnitude of the external force applied to the output unit.

A hand section 40 includes a hand base section 40a attached to a link section, a first finger section 40b provided to extend in a direction non-parallel with a direction toward a tip end portion from a base end portion of the hand base section 40a, from the tip end portion of the hand base section 40a, and a camera 40f provided at a side surface of the hand base section 40a, and capable of imaging a sideward of the hand base section 40a.

A horizontal articulated robot includes a base, a first arm supported by the base to be pivotable in a horizontal direction, a second arm supported by the first arm to be pivotable in the horizontal direction, a shaft supported by the second arm to be linearly movable along a longitudinal axis in a vertical direction, and a stopper mounted to the shaft and limiting movement of the shaft within a movable range. The stopper includes a fixing section fixed to an outer circumferential surface of the shaft and protruding therefrom, and a shock absorbing section fixed to one of the fixing section and the second arm. The shock absorbing section is disposed in a position sandwiched by the fixing section and the second arm in the vertical direction, and is elastically compressed in the vertical direction when the shaft tries to move beyond the movable range.

An apparatus for supplying chemical liquid may include a gantry, a chemical liquid supply member providing a chemical liquid onto a substrate, and a moving device supporting the chemical liquid supply member and moving along the gantry. The moving device may include a moving member, load supporting members and absorbing members. The moving member may support one side of the chemical liquid supply member and may run over the gantry. The moving member may cover an upper face, a first side and a second side of the gantry. The load supporting members may support a load applied to the moving member and the gantry while maintaining a substantially constant distance between the moving member and the gantry. The absorbing members may absorb an impulsive load or an impulsive force applied to the moving member and/or the gantry when the moving member deviates from a moving path provided by the gantry.

A surgical cart assembly may comprise a base portion; a plurality of wheels coupled to the base portion; a column extending vertically from the base portion; a manipulator arm coupled to an end portion of the column; a stabilization device coupled to the base portion, the stabilization device moveable between a retracted position and a deployed position; an actuation device to cause movement of the stabilization device between the retracted position and the deployed position; and a biasing element coupled to the stabilization device, the biasing element exerting a biasing force to bias the stabilization device toward the retracted position. The stabilization device may comprise a stabilization surface, the stabilization surface contacting the ground surface on which the surgical cart assembly is supported in the deployed position of the stabilization device, and the stabilization surface spaced from the ground surface in the retracted position of the stabilization device.