The invention relates to a robot with a base (3), a pivoting arm (4) which is articulated to the base (3) and which is pivotable about a rotational axis (13), wherein at the free end of the pivot arm (4) a pivotable mounting for a possible support arm (5) may be provided, and at least one drive unit (6, 7) for driving the pivot arm (4) and the possible support arm (5). According to the invention, a first drive unit (6) is coupled to a first four-bar linkage (8), a second four-bar linkage (9) is coupled to the first four-bar linkage (8) in such a way that the pivot arm (4) can be pivoted by the first drive unit (6).

An apparatus for a robotic limb includes one or more limb segments connected via one or more joints. The robotic limb may feature one or more dual-reduction quasi-quasi-direct-drive joint actuators that permit the robotic limb to move throughout a scene. The robotic limb may further include an end-effector connected to a free end of the robotic limb with one or more opposable fingers comprising a four bar linkage. The end-effector may include a main actuator that actuates the one or more fingers via the four-bar linkages to complete various tasks.

A parallel link robot includes a movable portion, a base, a plurality of drive sources, a plurality of links, and a tension member. The plurality of drive sources is attached to the base. The plurality of links is respectively connected to the plurality of drive sources. The tension member is connected between the movable portion and at least one of the plurality of links such that a bending tension is generated.

A robot arm according to the present invention includes: a shoulder joint assembly which is connected to an upper arm portion, and includes a drive unit for generating driving power; an elbow joint assembly which is provided between the upper arm portion and a forearm portion, and operates by being supplied with driving power from the drive unit; and a wrist joint assembly which is provided between the forearm portion and a hand portion, and operates by being supplied with driving power from the drive unit.

A robot system includes a work apparatus, a robot, and control circuitry. The work apparatus is configured to move a work module relatively to the work apparatus. The work module is configured to perform work. The work apparatus is connected the robot. The control circuitry is configured to control the robot to move so as to reduce a force generated by moving the work module by the work apparatus.

A printing apparatus includes: a head having a discharge surface in which a discharge port is opened, a pressure chamber which communicates with the discharge port, and an actuator which is configured to change a volume of the pressure chamber; a carriage configured to move the head in a scanning direction; a conveyor configured to move an object in a conveyance direction crossing the scanning direction; a posture changing mechanism configured to change a facing posture of the head with respect to the object; and a controller configured to control the actuator, the carriage, the conveyor and the posture changing mechanism, based on image data, to execute alternately and repeatedly a scanning operation and a conveying operation.

A parallel link robot includes: a base portion; a movable portion; link portions coupling the base and movable portions; and actuators attached to the base portion and driving the respective link portions. Each of the link portions includes drive links swung around axes by the respective actuators, and two each of the passive links parallel to each other and swingably arranged between the drive link and the each of the movable portions. The robot includes a drive unit disposed parallel to the two passive links of at least one of the link portions and between the passive links and drives a mechanical unit attached to the movable portion. The drive unit is attached to the drive link with a joint, swingably coupling the drive unit to the drive link around at least mutually intersecting axes, on a straight-line coupling swinging center points of the passive links and the drive link.

A transmission device is provided, including a first housing, a second housing connected to the first housing, a third housing axially connected to the second housing, an adapter disposed on the third housing, a first power shaft actuating the first housing and the second housing to rotate, a second power shaft actuating the third housing to rotate, and a third power shaft actuating the adapter to rotate. The second and third power shafts are a coaxial structure. The first power shaft is an independent rod. Therefore, a motor loaded with a smaller rotation inertia and being thus cheaper can be used to drive the first power shaft, and the transmission device can have a reduced cost.

A robotic leg assembly includes a main body having a first end and an opposite second end, a first servo arranged at the first end of the main body, a second servo connected to the main body and comprising an output shaft, a servo holder arranged at the second end of the main body, a third servo received in the servo holder, and a linkage bar mechanism. Each of a first initial angle of the first rotary member and a second initial angle of the second rotary member is in a predetermined range.

The present invention comprises: a fixed four-node link in which four links are joined together in a hinged fashion, comprising a fixed link of which the position is fixed, a connecting rod positioned on the opposite side of the first link, an input-side transmission link connecting the end on one side of the connecting rod and the first link, and an output-side transmission link positioned on the opposite side of the input-side transmission link; an input link part to which an actuator is attached, and which is joined in hinged fashion between the two ends of the input-side transmission link; and an output link part which is fixedly joined to the output-side transmission link and is rotated by means of the output-side transmission link, and the one-degree-of-freedom link device according to the present invention and the robot arm using the same can be used to allow easy attachment and detachment between link devices and achieve smooth action in a robot arm in accordance with what is desired.