A banknote handling system includes an unlocking system. The unlocking system includes a camera, a first mechanical arm to which one or a plurality of keys are affixed, and a controller that determines a position of a keyhole based on an image from the camera, and controls the first arm to insert one of the one or the plurality of keys into the keyhole and turn the inserted key for unlocking. In many examples, the unlocking system is configured to unlock a banknote cashbox.

A folding box stack transferring apparatus in a packaging machine has a gripping apparatus which is arranged on an adjustable manipulator. The gripping apparatus has at least two gripping jaws which can be moved toward one another in a clamping direction and between which the folding box stack can be clamped. In addition, a suction apparatus is provided which can be adjusted by means of an adjusting apparatus in such a way that the suction apparatus can be brought selectively into or out of contact with the surface of the folding box stack. In the case of the transfer of a folding box stack, the suction apparatus is brought into contact with the surface of the folding box stack, and the suction apparatus is activated at least temporarily during the transfer of the folding box stack.

The invention relates to a transport device (38) for transporting a workpiece (23) between a clamping chuck (22) and a workpiece carrier (30). The transport device (38) comprises a gripper arrangement (39) with a pivot arm (40). One end of the pivot arm (40) is supported on the machine tool (20) and, in particular, a machine slide (25) via a first pivot drive (41) so as to be pivotable about a first pivot axis (S1). On the other end, the pivot arm (40) supports a second pivot drive (42) that defines a second pivot axis (S2). A workpiece gripper (43) is supported so as to be pivotable about this second pivot axis (S2). The two pivot axes are inclined by 45 relative to each other. A workpiece (23) held by the workpiece gripper (43) has a workpiece longitudinal axis (W) that extends in a first position (I) of the workpiece gripper (43) at a right angle with respect to the pivot axis (S1). In a second position (II) of the workpiece gripper (43), the workpiece longitudinal axis (W) is oriented parallel to the first pivot axis (S1). The workpiece longitudinal axis (W) of the workpiece (23) held by the workpiece gripper (43) is inclined by 45 relative to the second pivot axis (S2).

A piezoelectric actuator includes a plurality of piezoelectric elements that generate a driving force to be transmitted to a driven portion; and a power supply portion that supplies power to the plurality of piezoelectric elements. The plurality of piezoelectric elements are electrically connected to the power supply portion in parallel.

A hand includes a plurality of first gripping members which move relative to each other, a first drive unit configured to move the plurality of first gripping members in a first opening and closing direction to bring the plurality of first gripping members close to each other or separate them from each other, a plurality of second gripping members which move relative to each other independently from the plurality of first gripping members, a second drive unit configured to move the plurality of second gripping members in a second opening and closing direction to bring the plurality of second gripping members close to each other or separate them from each other, and a third drive unit configured to move the plurality of first gripping members relative to the plurality of second gripping members in a third direction intersecting the first and second opening and closing directions.

An omnidirectional multi-finger asynchronous gripper for a casting robot, includes a connecting seat, an arc-shaped support, a mounting seat, longitudinal clamping devices, transverse adjusting devices and transverse clamping devices. The omnidirectional multi-finger asynchronous gripper is mounted to a tail end of the casting robot through the connecting seat; each longitudinal clamping device can independently and longitudinally clamp a casting or a mold core, is adjustable in spacing through the transverse adjusting devices, can automatically adapt to castings or mold cores with different outlines and can realize effective fitting-type adaptive clamping of specially-shaped castings and mold cores; and the transverse clamping devices are used for transversely and independently clamping the casting or mold core and a clamping position or angle can be adjusted through a swinging angle adjuster.

A series-parallel movable heavy-load casting robot, includes a four-driving-wheel type moving platform, a rotating device, an upright assembly, a lifting drive device, a parallel working arm, an end actuator and a binocular vision system. The four-driving-wheel type moving platform is driven by adopting four omnidirectional wheels, the platform utilizes rear hydraulic supporting legs and adjustable hydraulic supporting legs to implement stationary point self-balancing supporting, and a robot body has five freedom degrees of motion in space; and the rotating device and the lifting drive device can respectively implement rotating and lifting adjustment, the four-degree-of-freedom parallel working arm can carry out attitude adjustment for the end actuator, different end actuators can be changed according to working requirements.

A robot hand includes a first portion, and a second portion detachable from the first portion, including a pair of holding pieces For holding a workpiece. The first portion includes a first movable member movable in one direction by a first stroke, an actuator which moves the first movable member. The second portion includes a second base which is detachably attached to the attaching and detaching mechanism, and a second movable member movable in one direction by a second stroke which is larger than the first stroke. At least one of the holding pieces is fixed to the second movable member. A first engaging portion is provided in the first movable member, second engaging portions are provided in the second movable member, and the second engaging portion can be engaged with the first engaging portion.

A robot hand includes three or more holding portions arranged at intervals from each other along a circumferential direction about a predetermined axis, and configured to hold a work piece, and a driving portion configured to move the three or more holding portions toward a closing direction for approaching the axis and toward an opening direction for moving away from the axis, wherein at least one of the holding portions is swingable, about the axis, at a position at which the at least one holding portion is in contact with the work piece.

A robot apparatus according to the present technology includes: a clamp mechanism; a transport mechanism; and a control unit. The clamp mechanism includes a first finger and a second finger. The first finger has a first support surface and a housing portion, the first support surface being capable of supporting a wire group while the wire group is aligned, the wire group including a plurality of wires, one end of the wire group being fixed, the other end of the wire group including a terminal unit connectable to a connection portion, the housing portion including a guide wall that is connected to the first support surface and regulates an amount of movement of the band member in a width direction thereof. The second finger has a second support surface and a facing portion, the second support surface facing the first support surface, the facing portion being connected to the second support surface and facing the housing portion. The transport mechanism is configured to be capable of moving the clamp mechanism. The control unit controls a grip force of the clamp mechanism for gripping the band member and a direction of movement of the clamp mechanism by the transport mechanism.