An apparatus for active contact force control is disclosed. The apparatus can have upper flange on which to mount a production tool. The apparatus can be mounted, via a lower flange, on a multi-axis machine to obtain spatial motion together with the corresponding production tool. The apparatus can comprise a housing inside which can be a linear actuator connected to guides. Mechanical connection between a ball screw and the upper flange can contain a force sensor and at least one spherical joint. The connection between the spherical joint and the upper flange can be formed using a mechanical dissipative element made of elastic dissipative elements and a disc plate positioned between the elastic dissipative elements.

A protective device for an effector of a manipulator includes a shell having a plurality of chambers, wherein the shell is flexurally slack and bounds a fillable and/or evacuable pressure space. The protective device further includes at least one first pulling means for pulling back the shell, and at least one actuator for applying a tensile force to the at least one first pulling means. A device for manipulating workpieces includes a robotic manipulator having an effector, and the protective device disposed proximate the effector.

A configuration that exerts floor reaction force directly to a force sensor in a foot of a legged mobile robot requires a sensor having a large withstand load. A foot (10f) includes an upper frame (44) that is connected to a movable leg and receives the load of a robot, a lower frame (48) that is deployed under the upper frame (44) and contacts with a walking surface, a high rigidity spring (50) attached the lower frame (48) and elastically supporting the upper frame (44) against the load, and a plurality of sensor mechanisms that detect floor reaction force at positions different from each other on the lower frame (48). Each of the sensor mechanisms includes a force sensor (62) attached to one of the upper frame (44) and the lower frame (48) and a sensor spring (52) that is an elastic body having rigidity lower than that of the high rigidity spring (50) and has a supporting point deployed on the other one of the upper frame (44) and the lower frame (48) so as to exert pressing force to the force sensor (62) according to a change of the distance between the upper frame (44) and the lower frame (48).

The present disclosure discloses a self-adaptive mechanical foot for the legged robot. The mechanical foot has a piston disposed inside a piston cylinder. The piston is connected to one end of each humeral plate, and the piston cylinder is connected to the other end of each humeral plate. The humeral plates perform opening and closing movement through the up-down movement of the piston in the piston cylinder. The humeral plates are connected to toes on the foot and drive the toes to open and close through the up-down movement. The mechanical foot provided by the present disclosure has higher standing stability and fast interaction response speed when interacting with the terrain. It can realize arbitrary and fast switching between a point-like foot and a planar foot, and meanwhile avoids collision between a support leg and a swing leg.

Disclosed is a fully automatic intelligent spraying robot. The robot includes a chassis, a driving device, a sliding device, a clamping device, a detection device and a control device; the driving device is fixedly connected to the chassis, and the driving device drives the chassis to move freely on the ground; the sliding device is fixed on the chassis; one end of the clamping device is used to fix a spray gun, and the other end of the clamping device is connected to the sliding device, and the clamping device can freely slide along the height direction of the sliding device; the detection device is fixed on the chassis, and the control device is also fixed on the chassis; and the control device is respectively in signal connection with the driving device, the sliding device, the clamping device and the detection device.

A robot includes a movable unit displaced in horizontal directions and having a recessed part opening upward in a vertical direction, a connector placed within the recessed part, and a drain part that communicates between a bottom portion of the recessed part and an outside of the movable unit and drains a liquid within the recessed part out of the recessed part.

A clamping jaw of a connecting terminal includes a rotary cylinder assembly configured for achieving different swing angles for clamping different types of connecting terminals. The rotary cylinder assembly includes a rotating shaft for providing a driving force through rotating cylinder and an initial state limit part. A first state limit part is configured to position the rotating cylinder in a first rotation angle and a second state limit part has a working and non-working position. When the second state limit part is in the working position, it is configured to position the rotating cylinder in a second rotation angle. When the second state limit part is in the non-working position, it is configured to position the rotating cylinder in the first rotation angle. The second rotation angle is smaller than the first rotation angle.

A rotary-type series elastic actuator (SEA) for use in robotic applications. The SEA including a motor, gear transmission assembly, spring assembly, and sensors. In one example, a robotic joint may include the SEA as well as two links coupled with each other at the joint assembly. The two links may be designated as input and output links. Each link may have a joint housing body which may be concentrically connected via a joint bearing so that they freely rotate against each other. The housing frame of the SEA may be fixed at the joint housing body of the input link while the output mount of the spring assembly of the SEA may be concentrically coupled with the joint housing body of the output link. The rotation of the motor rotor causes the rotation of the output link with respect to the input link plus spring deflection of the spring assembly. When an external force or torque are applied between the two links, a control action of a control loop may cause a rotation and motive force of the motor that lead to the deflection of the spring assembly to balance with the external force/torque and inertial force from body masses moving together with the links.

The present disclosure relates to protecting fragile members of robots from damage during fall events. In response to detecting a fall event, a fragile member of a robot can be actuated to a defensive configuration to avoid or reduce damage. An actuatable protective member can be actuated to protect a fragile member to avoid or reduce damage to the fragile member. Actuatable protective members can be dedicated protective members, or can be other members of the robot which serve different functionality outside of a fall event but act as a protective member during a fall event.

A conveyor apparatus that includes a support, a crossbar and a plurality of tools attached to the crossbar. The crossbar is suitable for being moved to convey a workpiece and is supported only by the support. The crossbar includes first and second segments that are located on opposite sides of the support. First and second tools are respectively attached to the first and second segments. The conveyor apparatus includes at least one passive vibration compensation block attached to at least one element of the conveyor apparatus selected from the crossbar, the first tool, and the second tool, to reduce vibrations generated during the movement of the crossbar.