The present application discloses an automated kitchen system comprising a first computer and a plurality of second computers which are connected so that the first computer may communicate with any of the second computers. The automated kitchen system also comprises: a plurality of ingredient containers each configured to contain or store food ingredients; caps configured to close on the ingredient containers; a storage apparatus comprising compartments each configured to store a plurality of ingredient containers and refrigeration mechanism configured to cool the food or food ingredients in the containers of the storage apparatus; transport boxes each configured to contain capped ingredient containers; a transportation apparatus configured to move the transport boxes wherein the transportation apparatus comprises motors and sensors; a cap opening apparatus configured to remove a cap from a capped container wherein the cap opening apparatus comprises motors and sensors; a first transfer apparatus configured to move a capped ingredient container from a transport box to the storage apparatus, and also configured to move a capped ingredient container to a location on the cap opening apparatus, wherein the first transfer apparatus comprises motors and sensors; a cyclic transport apparatus comprising a cycle of container holders each configured to hold an ingredient container; a transfer apparatus configured to move an ingredient container from the location of cap opening apparatus to a position on a container holder of the cyclic transport apparatus wherein the second transfer apparatus comprises motors and sensors; and a plurality of cooking systems. Each cooking system comprises a cooking container configured to hold food or food ingredients during a cooking process, a stirring motion mechanism configured to produce a motion in the cooking container as to stir, mix or distribute food or food ingredients held in the cooking container, wherein the stirring motion comprising motors, sensors, and a stove; a cyclic transport apparatus comprising a cycle of container holders each configured to hold an ingredient container; an unloading apparatus configured to unload food ingredients from an ingredient. The above mechanisms and apparatuses comprise electrical or electronic devices and sensors, which are configured to be connected to the second computers. The first computer is configured to store various sub-programs and other lists that are useful to control the electric or electronic devices in the mechanisms, apparatuses or systems in the kitchen system.

Systems and methods here may include a vehicle with automated subcomponents for harvesting delicate targets such as agriculture. In some examples, the vehicle includes a targeting subcomponent and a harvesting subcomponent. In some examples, the harvesting subcomponent includes vacuum features which gently attach to target agriculture to secure it. In some examples, the harvesting subcomponent includes padded spoons to grasp and remove the target agriculture from the foliage.

A gripper for industrial manipulators comprising a body, jaws constrained to the body and activable to hold and release a piece, an actuator of the jaws and a sensor configured to detect the presence of a piece between said jaws, is described. Advantageously, the sensor is not positioned between the jaws, in the space intended to accommodate the piece to be held, but is functionally interposed between the actuator and one of the jaws.

A method for detecting the presence of a piece between the jaws of an industrial manipulator gripper, the method providing a sensor to be used to detect the position of a jaw with respect to the actuator of the gripper.

An end effector assembly of a robotic surgical instrument includes a clevis, first and second jaw members supported by the clevis, and a cam bar configured to move the first and second jaw members between an open state and a closed state.

Disclosed is a gripper (1) for beverage cans (20). The gripper (1) comprises at least one gripping device (6) used to grip a particular beverage can (20) from underneath the top seam (5) in a form-fitting manner in the region of a top seam (5), which top seam (5) is formed by a particular beverage can (20). The gripper (1) comprises at least one centering device (30), by which at least one centering device (30) aligns the particular beverage can (20) into a defined alignment, where the at least one gripping device (6) is able to grip a particular beverage can (20) from underneath in a form-fitting manner in the region of its top seam (5).

A manipulator module (100) comprising: a first housing segment (102) configured to be connected to a manipulator; a second housing segment (104) rotatably coupled to a distal end of the first housing segment (102) such that the second housing segment (104) can rotate about a longitudinal axis relative to the first housing segment (102); a linear actuator (118), wherein a distal end of the linear actuator (118) is configured to be coupled to an end effector; a first electric motor (110) arranged to drive the linear actuator (118) to actuate the end effector; a second electric motor (112) arranged to rotatably drive the second housing segment (104) relative to the first housing segment (102); wherein the linear actuator (118) is arranged to extend from the first housing segment (102) and through the second housing segment (104).

An end effector apparatus for a surgical instrument is disclosed including a housing having a first jaw mounted on a revolute joint and providing a first electrical conduction path between the housing and the first jaw. A second jaw is mounted on a revolute joint within the housing and is insulated from the housing, the jaws each having a manipulating portion and a lever arm. A yoke is received within the housing and mechanically coupled to the lever arms and to a control link and is moveable in response to movements of the control link to cause opening and closing of the jaws, the yoke being electrically insulated from the housing and the first jaw. A second electrical conduction path is provided between the control link and the second jaw. The electrical conduction paths facilitate conduction of an electrocauterization current through tissue grasped between the jaws.

A bottle gripping assembly including a pair of bottle gripping arms each having a grip member for gripping a bottle therebetween. The bottle gripping assembly also includes a base supporting the bottle gripping arms, with the base having a top surface and a recess into the top surface, a wear pad located in the recess of the base, with the wear pad and the base under the upper surface of the recess having a pair of aligned fastener holes, a pair of fasteners, with each one of the fasteners extending through one of the bottle gripping arms and into one of the fastener holes to connect the bottle gripping arms to the wear pad and the base, and a pair of wear bushings, with each of the wear bushings having a tubular portion that extends into one of the bottle gripping arms and surrounds a portion of the fasteners.

A modular gripper has a body with a trident section and cylindrical section. A powering assembly is positioned in the cylindrical section. A pair of oppositing jaws is pivotally secured between a center wall and a pair of side wall, respectively, of the trident section. The piston rod moves a cam assembly on the center wall. The cam assembly passes through a body having a trident section and cylindrical section. The trident section comprises a trident structure that includes, at one end, a pair of side walls along with a center wall. The cylindrical section includes a fluid driven powering assembly. A pair of opposing jaw member are pivotally secured to the trident portion about separate pivot pins. A cam assembly is operatively connected to a piston rod of the fluid driven powering assembly. The cam assembly extends laterally outward with respect to a cylinder bore axis to receive a cam bush that engages with a through slot on each of the pair of opposing jaw members. The jaws rotate with respect to one another in response to fluid power in the cylindrical section. A pair of side plate members, each slide plate member has an elongated blind slot that receives an end of the cam assembly, the ends travel in the blind slot. Cam slots in the pair of opposing jaws, via a cam bushing.

Systems and methods capable of selecting and positively grasping objects of interest within a cluttered environment are described. Some aspects of the present disclosure provide for real-time control of a robot that uses various sensors and reacts to sensor input in real time to adjust the robots path. In some embodiments, a robotic item picker includes an end effector having a shaft extending along a longitudinal axis between a proximal end and a distal end, a carriage configured to rotate about and translate along an intermediate portion of the shaft between a proximal position and a distal position, a suction device coupled to the distal end of the shaft, and a plurality of fingers spaced radially about the carriage. The robot may be a t-bot including a longitudinal member rotatable about a lengthwise axis of the longitudinal member, a carriage translatable along the lengthwise axis, and a radial member slidably mounted to the carriage. The end effector may be rotatably coupled at a distal end of the radial member.