Disclosed is a mobile robot capable of communicating with other electronic devices and an external server in a 5G communication environment by executing mounted artificial intelligence (AI) algorithms and/or machine learning algorithms. The mobile robot may include a wheel driver and a controller. By providing the mobile robot, an autonomous driving-based transportation service may be provided.

A joint structure for a robot includes a first link and a second link rotatably coupled to each other through a joint part and a linear-motion actuator coupling the first link to the second link at a part separated from the joint part. The linear-motion actuator has a casing, and a pair of first shaft parts integrally formed with an outer surface of the casing. The first link is supported by the first shaft part so as to be pivotable with respect to the linear-motion actuator. The first link relatively pivots to the second link by the linear-motion actuator reciprocating.

A dielectric elastomer system (DES) variable stiffness actuator (VSA) is provided. In an embodiment, the DES VSA includes a variable stiffness module (VSM). The VSM includes a DES that softens when energized and stiffens when unpowered, an outer frame, and an inner frame member. The stiffness of the DES is variable. The outer frame supports the DES and the inner frame member, which is disposed within the DES. The inner frame member is configured to be displaceable with respect to the outer frame. The DES VSA also includes an actuation motor mechanically coupled to the inner frame member that is configured to cause a force to be applied to the inner frame member and the actuation motor is configured to control an equilibrium position of the DES VSA.

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 rotary drive device has a fluid-actuated rotary drive with a drive housing and a drive unit which is rotative relative thereto. The drive unit includes a drive shaft and a pivot piston, non-rotatably arranged thereon, separating two drive chambers from one another. For controlling the fluid-actuated rotary drive, a control valve arrangement including at least one electrically actuatable control valve is provided, which is attached to the drive housing and in this way is combined with the rotary drive to form a drive assembly that can be handled as a single unit. Furthermore, a robot arm is proposed, which has the rotary drive device as an arm joint connecting two arm members.

A lifetime estimation device for a robot including a linear-motion mechanism including a guide member and at least one slider moving along the guide member includes: a load calculation unit that calculates, at predetermined time intervals, a load acting on each slider on a basis of a program for operating the robot and geometric parameters of the robot and a load mounted on the robot; a travel-distance calculation unit that calculates travel distances of the slider at the time intervals; a lifetime calculation unit that calculates a lifetime of the linear-motion mechanism on a basis of the loads calculated by the load calculation unit and the travel distances calculated by the travel-distance calculation unit; and a display unit that displays the calculated lifetime.

An apparatus for robot-supported grinding includes: a manipulator; a grinding machine; a linear actuator coupling the grinding machine to a tool center point (TCP) of the manipulator; an extraction system connected to an outlet in a housing of the grinding machine; and a hose connecting the extraction system to the outlet in the housing of the grinding machine. The hose is arranged around the housing of the grinding machine and the linear actuator in a roughly spiral-formed manner and is attached at one end to the manipulator.

A linear motion mechanism includes: a plurality of linear motion elements that are cascaded in a mutually movable manner; a shaft fixed to one of adjacent linear motion elements among the plurality of linear motion elements; and a slider movably engaged with the shaft and fixed to the other of adjacent linear motion elements.

A robotic arm end effector for a laser head coupled to a robotic arm is disclosed. The end effector has a coupler to couple the end effector to the robotic arm and a first actuator assembly coupled to the first coupler. The first actuator has a first drive coupled to the laser cutting head and configured to move the laser cutting head along a first path. The first drive is coupled to a first counter mass and being configured to move the first counter mass along a second path in a direction opposite the first direction. The end effector also has a second actuator assembly coupled to the coupler. The second actuator has a second drive coupled to the laser head which is configured to move the laser head along a third path in a third direction.

The disclosure discloses an electric-pneumatic hybrid-driving flexible manipulator with spring framework from plates of special-shaped thickness, including a screw shaft motor, an upper seat plate, guide coupling rods, linear bearings, a driving plate, a push plate, short push rods, connecting rods, a bottom seat plate, flexible fingers, a rotating finger holder, a long push rod, a small support, tension springs, single-head bellows muscles and a ridged push plate. The framework of the flexible fingers is a thickness special-shaped plate spring designed according to the principle of equal strength. In the disclosure, through the control of a motor, an angle between a finger knuckle and a grasped object can be adjusted to realize the adjustment of the position of a contact point. To adjust the position of the contact point of the grasped object, the acting point of the contact force and the direction of the acting force can be selected according to situations, so that the grasping is more accurate and reliable. At the same time, the angle between the finger knuckle and the grasped object can be adjusted to adapt to a larger change in size of the grasped object. In the disclosure, a pneumatic system is large in gain and the pneumatic bellows muscles are light, so that the response is quick and the buffering effect is good.