A robot having a shaft extending in vertical directions at an end of an arm pivoting in horizontal directions around a pivot axis parallel to the vertical directions and performing work using an end effector attached to a lower end of the shaft, the shaft having a helical groove and a longitudinal groove to enable upward and downward motion in the vertical directions and pivot around an axis of the shaft, includes a ring-shaped packing having a convex portion to engage with the longitudinal groove, fitted on the shaft, and sandwiched and fixed by a stopper portion and a collar portion in an extension direction of the shaft.

Described herein is a multi-axial industrial robot, in particular of a SCARA type, where the base structure designed to enable installation of the robot on an external supporting structure, can be mounted according to two opposite orientations, where one orientation is upside down with respect to the other, while at the same time the operating head of the robot may instead maintain one and the same orientation.

A robot includes a first member, a second member that is provided to be turnable about a turning axis with respect to the first member, marks that are disposed around the turning axis on a surface of the second member, and a mark detection portion that is disposed in the first member and detects the marks.

A ceiling mounted robot includes a first member, a first arm portion that is rotatably provided on the first member via a first joint portion, a second arm portion that is rotatably provided on the first arm portion via a second joint portion, a wiring portion that is inserted into the first arm portion and the second arm portion, and a connector portion that is connected to the wiring portion.

Systems, apparatus, and methods of manufacturing an article using electroadhesion technology, either as a sole modality of handling such materials or in concert with vacuum for the pick up and release of materials, respectively.

A robot includes a base, a first arm coupled to the base and rotating about a first rotation axis, and a second arm coupled to the first arm and rotating about a second rotation axis, wherein the first arm has a first portion coupled to the base, a second portion coupled to the second arm, and a third portion located between the first portion and the second portion and having an internal space, and a liquid exhaust hole communicating between the internal space and an outside of the first arm and exhausting a liquid entering the internal space to the outside of the first arm is provided in the third portion.

A flexible driver, a robot joint, a robot and an exoskeleton robot, the transmission mechanism including an active rotating member, a driven rotating member and a rope, which form a rope drive relationship; wherein, the rope is tightly wound around rotating surfaces of the active rotating member and the driven rotating member, and a rotational central axis of the active rotating member is perpendicular to a rotational central axis of the driven rotating member. An output end of the driving mechanism is connected to the active rotating member, to drive rotation of the active rotating member. The output mechanism includes a flexible driving part, and an output part which is used for connecting to an external actuator. The driven rotating member drives rotation of the output part through the flexible driving part. The flexible driver drives flexibly the actuator through a compact structure as well as reliable and high-efficient transmission.

A robot including a second arm supported by a first arm so as to be swingable around an axis line, the second arm has an arm main body supported by the first arm in a swingable manner, and a cover which is attached to the arm main body. The robot further includes an interface member attached to the cover, a cable support member one where end of which is fixed to the arm main body and the other end of which is exposed outside the second arm by passing through a hole or a cutout provided in the interface member, and a seal which seals a space between the cable support member and the interface member and which allows movement of the cable support member in a direction along the axis line with respect to the interface member.

According to the present embodiment, a control device of a conveyor system controls a moving device and a suction device to suction the transport target article so that an approximate center of an opening of at least one suction unit is located on a first imaginary line, and remaining suction unit is located on one end side in a longitudinal direction of the transport target article with respect to the first imaginary line, controls a turning-over section to be in a front-back reversing orientation, and performs control so that suction of the transport target article by the suction units is released after the suction device is in the front-back reversing orientation.

A component handling device for component handling in working or process machines, in particular injection moulding machines, comprises a basic linear axis running outside or inside the handling space of the handling device, a multi-axis arrangement, which is translationally displaceable on the basic linear axis, with a main rotational axis orthogonal to the basic linear axis, a secondary rotational axis directed parallel thereto and linked to the main rotational axis via a first robot arm, which guides a second robot arm pivotably over the handling space, and a vertical linear axis linked to the second robot arm eccentrically to the secondary rotational axis, and a gripping device linked to the vertical linear axis for a component to be handled.