A multi-axis imaging system comprising an imaging gantry with an imaging axis extending through a bore of the imaging gantry, a support column that supports the imaging gantry on one side of the gantry in a cantilevered manner, and a base that supports the imaging gantry and the support column. The imaging system including a first drive mechanism that translates the gantry in a vertical direction relative to the support column and the base, a second drive mechanism that rotates the gantry with respect to the support column between a first orientation where the imaging axis of the imaging gantry extends in a vertical direction parallel to the support column and a second orientation where the imaging axis of the gantry extends in a horizontal direction parallel with the base, and a third drive mechanism that translates the support column and the gantry in a horizontal direction along the base.

An improved method for investigating a functional behavior of a component of a technical installation includes comparing a signal of the component to be investigated and representing the functional behavior of the component with a reference signal which describes an average functional behavior of identical components. During the comparison, a comparison variable describing the deviation of the signal from the reference signal is determined. In addition, a probability of the occurrence of the comparison variable is determined by using a predefinable distribution of a multiplicity of such comparative variables. A computer program and a computer readable storage medium are also provided.

Provided is a structure of a joint portion which suppresses deterioration or damage of a seal member arranged inside the joint portion. The joint portion rotates a first structure portion and a second structure portion relatively to each other. The structure of the joint portion comprises: an oil seal which is arranged in a gap portion; and a labyrinth member which is arranged on outer surfaces of the first structure portion and the second structure portion. The labyrinth member comprises a passage which communicates with the gap portion. The labyrinth member is formed so as to be attachable to the outer surface of the first structure portion and the outer surface of the second structure portion. Further, the labyrinth member is formed so as to be detachable from the first structure portion and the second structure portion.

A robotic cleaner may include a body having a top surface, a navigation sensor extending from the top surface of the body, a protective cover defining a sensor cavity, the navigation sensor being at least partially received within the sensor cavity, and a cover liquid diverter extending from an upper portion of the protective cover, the cover liquid diverter being flared in a direction of the body.

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.

An apparatus for an efficient label application comprising a conveyor belt; a barcode reader that is disposed above a conveyor belt and attached to a first cross beam; a 3D profiler that is disposed above said conveyor belt and attached to a second cross beam, and records size, shape, and orientation of a shipping package; a first plexiglass shield that comprises a light curtain; wherein said first plexiglass shield and light curtain protect a robotic arm's operating space on one side of said conveyor belt; a second plexiglass shield that protects said robotic arm's foot; a printer that is disposed next to said robotic arm; two upward facing fans that are disposed between said printer and said robotic arm, and, together, create an air cushion; a third plexiglass shield that protects said robotic arm, air cushion, and printer on second side of said conveyor belt; said first plexiglass shield, third plexiglass shied, and said conveyor belt define and protect a critical zone of said robotic arm's operating space; a printer control panel that is mounted on said third plexiglass shield; an operator control panel that allows said apparatus to be started, stopped, and calibrated, and is mounted on said third plexiglass shield.

A robot includes a housing, a body frame disposed inside the housing, a driving motor provided at lower portion of the body frame, a driving wheel rotated by the driving motor and protruding downward of the housing, a control rack mounted to the body frame and positioned above the driving motor, an opening defined in the housing and positioned at a rear side of the control rack, the control rack being insertable into the opening, and a back cover covering the opening.

A snag point cover for an industrial manufacturing robot, the snag point cover including: a body adapted to be disposed about a protrusion extending from an external surface of an industrial manufacturing robot, wherein the body is adapted to form an external transition surface between the protrusion and the external surface of the industrial manufacturing robot thereby preventing a dresspack from becoming snagged on the protrusion when the industrial manufacturing robot is articulated. The snag point cover body is adapted to surround and cover one or more protrusions. The snag point cover body may be elongated or arcuate in shape and defines an internal cavity that conforms to the one or more protrusions. This allows external structures such as wiring harnesses and conduits to slide over these protrusions without becoming snagged or pinched during complex motion.

A linear robot according to the present disclosure includes a main body unit including a main body base part seated on a ground surface, and main body sidewall parts protruding in an upward direction by a predetermined thickness from two opposite sides of the main body base part, the main body unit having an internal space defined by the main body base part and the main body sidewall parts; a transfer block unit partially accommodated in the internal space of the main body unit, configured to linearly move in one direction, and having an upper portion on which a transfer target object is seated, the transfer block unit being configured to transfer the transfer target object from a first position to a second position; and a pair of guide rail units disposed between the main body unit and the transfer block unit, coupled to the main body unit, and configured to guide the transfer block unit, in which the main body sidewall parts each have a guide rail unit accommodation groove recessed by a predetermined length in a direction perpendicular to the upward direction, and at least a part of a surface of the guide rail unit accommodation groove has an uneven machined surface.

An end effector of a robot arm that is configured to participate in an animal-related operation, where the end effector is comprised of an actuator and a housing that is provided with a first aperture at a first end portion, where the actuator participates in the animal related operation via the first aperture, and the housing is provided with a second aperture providing access to an interior of the housing, wherein a passage extends through the housing along at least part of the actuator, from the second aperture to the first aperture such that the housing may be flushed through for removing dirt.