A robot includes a robot arm formed with an ingredient channel including an ingredient inlet and an ingredient outlet; an ingredient feeder having an ingredient port configured to discharge ingredients; and a carrier configured to move the robot arm to a connection position where the ingredient inlet is connected to the ingredient port, and move the robot arm to an area where the ingredient inlet is separated from the ingredient port.

A robot includes a robot arm formed with an ingredient channel including an ingredient inlet and an ingredient outlet; an ingredient feeder having an ingredient port configured to discharge ingredients; and a carrier configured to move the robot arm to a connection position where the ingredient inlet is connected to the ingredient port, and move the robot arm to an area where the ingredient inlet is separated from the ingredient port.

Embodiments of the technology disclosed herein is directed to a medical manipulator capable of detecting an instant when a tip of the medical manipulator is unexpectedly separated from a body tissue and thus avoid making contact with surrounding body tissues. The technology disclosed eliminates the needs for providing a force sensor located on the tip of the medical manipulator. The medical manipulator includes a movable unit at one end and an electric motor, a control unit, and an operation input unit at opposed end thereof. The movable unit includes a treating unit for treating the body tissue. The electric motor is configured to operate the movable unit. The electric motor includes a current sensor or a torque detecting unit for detecting the torque of the motor. The control unit includes a torque reducing unit for reducing the torque transmitted to the movable unit from the electric motor.

Embodiments of the technology disclosed herein is directed to a medical manipulator capable of detecting an instant when a tip of the medical manipulator is unexpectedly separated from a body tissue and thus avoid making contact with surrounding body tissues. The technology disclosed eliminates the needs for providing a force sensor located on the tip of the medical manipulator. The medical manipulator includes a movable unit at one end and an electric motor, a control unit, and an operation input unit at opposed end thereof. The movable unit includes a treating unit for treating the body tissue. The electric motor is configured to operate the movable unit. The electric motor includes a current sensor or a torque detecting unit for detecting the torque of the motor. The control unit includes a torque reducing unit for reducing the torque transmitted to the movable unit from the electric motor.

An assembly having an aircraft door and auxiliary equipment. The aircraft door and the auxiliary equipment are connected by a flexible deformable bellows having creases. The door comprises a passing through hole and a support joinable to the first end of the bellows. The auxiliary equipment comprises a support joinable to the second end of the bellows and a projecting part. The projecting part is configured to have elevation movement and/or azimuth movement, and the projecting part crosses the interior of the bellows and the hole of the door and protrudes out of the door. At both ends of the bellows a clamp joins and tightens each end of the bellows with the corresponding support. There is a fixed joint between the first end of the bellows and the door and a movable joint between the second end of the bellows and the auxiliary equipment.

An assembly having an aircraft door and auxiliary equipment. The aircraft door and the auxiliary equipment are connected by a flexible deformable bellows having creases. The door comprises a passing through hole and a support joinable to the first end of the bellows. The auxiliary equipment comprises a support joinable to the second end of the bellows and a projecting part. The projecting part is configured to have elevation movement and/or azimuth movement, and the projecting part crosses the interior of the bellows and the hole of the door and protrudes out of the door. At both ends of the bellows a clamp joins and tightens each end of the bellows with the corresponding support. There is a fixed joint between the first end of the bellows and the door and a movable joint between the second end of the bellows and the auxiliary equipment.

A sensing device is described for mounting on a movable component of a robotic device. The sensing device includes a plurality of illumination sources comprising at least one ultraviolet (UV) illumination source. The sensing device further includes at least two cameras arranged in a stereo pair. The sensing device additionally includes a camera with a UV filter, wherein the UV filter is configured to allow wavelengths corresponding to UV light and to block wavelengths corresponding to visible and near infrared light, wherein the UV filter allows transmission of light within an angular range such that the UV filter allows for the transmission of light at one end of the angular range to be equivalent to the transmission of light at an opposite end of the angular range.

A sensing device is described for mounting on a movable component of a robotic device. The sensing device includes a plurality of illumination sources comprising at least one ultraviolet (UV) illumination source. The sensing device further includes at least two cameras arranged in a stereo pair. The sensing device additionally includes a camera with a UV filter, wherein the UV filter is configured to allow wavelengths corresponding to UV light and to block wavelengths corresponding to visible and near infrared light, wherein the UV filter allows transmission of light within an angular range such that the UV filter allows for the transmission of light at one end of the angular range to be equivalent to the transmission of light at an opposite end of the angular range.

An apparatus to automatically place layers of a printed circuit board on a fixture includes a robotic device having a base that is secured to a surface, an upright column that extends upwardly from the base, and a movable arm rotatably coupled to the upright column. The movable arm is configured to rotate about a vertical axis defined by the upright column. The movable arm is further configured to rotate from a position in which the movable arm is disposed over a laminate sheet fixture and to pick up a laminate sheet to a position in which the movable arm is disposed over a board layup fixture to deposit the laminate sheet in the board layup fixture, and from a position in which the movable arm is disposed over a bond film fixture and to pick up a bond film to a position in which the movable arm is disposed over the board layup fixture to deposit the bond film in the board layup fixture.

An articulating robotic arm for minimally invasive surgery, comprising a proximal arm segment extending along a longitudinal axis of the robotic arm and a distal arm segment connected to the proximal arm segment, pivotable about a pivot axis orthogonal to the longitudinal axis. The distal arm segment comprises a pinion segment formed with pinion teeth arranged about the pivot axis in the form of a pinion. A rack element is arranged on the proximal arm segment such that the rack element is movable in the longitudinal direction of the rack element parallel to the longitudinal axis by means of a translation, and rack teeth formed on the rack element are engaged with the pinion teeth so that a movement of the rack element in the longitudinal direction via the rack teeth and the pinion teeth is converted into a rotational movement of the distal arm segment about the pivot axis, and so that the distal arm segment pivots relative to the proximal arm segment about the pivot axis.