A meat processing apparatus has an automated analysis stage for analysing meat parts with penetrating radiation. Data is generated for sue in both feedforward and feedback information, and may be used for robotic control of trimming and boning operations. There is a radiation-shielded chamber within which there is a tomography scanner with a scanner controller, arranged to perform analysis of meat parts. A port is used for entry and exit of meat parts placed in carriers into and out of the chamber for analysis by the scanner, and a handling system performs automated movement of the carriers between the port and the scanner. The port has an interlock chamber, having an inner door and an outer door and a controller to ensure that while the scanner is operating only one door can open. The meat parts are inspected automatically by an inspection station and a controller of the inspection station feeds forward data which is used by the scanner controller to control scanner operation according to meat part physical attributes.

Various example systems and component systems for an automated food processing system are provided. In an example, a food processing apparatus comprises a basket retainer configured to support a basket of consumable items above a food processing device. The food processing apparatus may also include a reciprocating agitator configured to impart a repetitive contact to the basket, thereby inducing motion of the consumable items within the basket. In another example, guidance of a robot performing tasks such as moving a basket of consumable or food items may be enhanced using one or more mechanical guides configured to catch, engage, or otherwise contact a corresponding feature of a basket for the consumable/food items. In another example, one or more sensors may be provided to provide an indication that a robot gripper is within a proximity of a basket and/or handle thereof.

A system for lifting a deformable object includes a support structure, two pairs of opposing arms coupled to the support structure, and a fluid power driver operatively coupled in parallel to the pairs of opposing arms via a fluid power system. Each of the arms includes inclined surfaces configured to contact the deformable object. When the support structure is positioned above the deformable object on the surface, the fluid power driver is configured to increase pressure in the fluid power system until the pressure in the fluid power system reaches a predetermined level such that (i) each of the pairs of opposing arms independently closes a distance until the inclined surfaces are in contact with sides of the deformable object, and (ii) the pairs of opposing arms exert a compressive force on the deformable object that causes the deformable object to slide up one or more of the inclined surfaces.

An end effector adapted to be carried by a robot positioning apparatus for packing items of produce, the end effector adapted in use for holding an open topped elongate container (tube) in an inverted orientation, wherein the tube has a closed bottom end and an open top end; the end effector comprising: at least one actuatable movable element located on the end effector so as to be adjacent the open end of a tube held by the end effector; wherein the actuatable movable element is configured to be operable between: an extended position which at least partially extends over the open end of a tube held by the end effector to at least partially obstruct the open end of the tube; and a retracted position so that the open end of the container is substantially unobstructed to allow items of produce to be received in the tube.

A robotically-operated gripping device is provided and includes a frame assembly, a vacuum device, a clamping device, and a robotic arm. The vacuum device is connected to the frame assembly and configured to selectively attach to and position at least a portion of an object. The clamping device is connected to the frame assembly and provided for selectively clamping the object attached to the vacuum device. The robotic arm is connected to the frame assembly and provided for selectively positioning the vacuum device and the gripping device.

A cooking system comprises a robot; and a memory storing computer executable instructions which, when executed, cause the robot to execute a plurality of operations comprising: a first operation including picking up a cooking auxiliary tool in which a cooking target is set in a first section, conveying the cooking auxiliary tool to a second section, and causing the cooking target in the cooking auxiliary tool to undergo first cooking processing in the second section; and a second operation including conveying the cooking auxiliary tool storing the cooking target having undergone the first cooking processing in the second section to a third section. A duct is arranged in an upper space of the second section, the robot has a proximal end that is fixed to a vertical wall member, and the proximal end of the robot is attached to the wall member at a location away from the second section.

A robot for making coffee and a method for controlling the same are provided to couple or decouple a portafilter to or from an espresso machine without damage to the espresso machine or the portafilter due to a collision between the espresso machine and the portafilter. The robot includes a robot arm to move with a predetermined degree of freedom, a gripper provided in the robot arm to grip a portafilter, a torque sensor provided in the robot arm to detect repulsive force (Fr) when the portafilter makes contact with a group head of an espresso machine, and a controller configured to set a virtual spring having a predetermined elastic modulus (C) based on the repulsive force (Fr) detected by the torque sensor, and to control driving torque (T) of the robot arm depending on the restoring force (Fe) of the virtual spring.

An example system includes a nozzle having an inlet: an outlet mechanism disposed longitudinally adjacent to the nozzle; a conduit longitudinally adjacent to the outlet mechanism where the conduit includes a distal chamber, a middle chamber, and a proximal chamber, that; are longitudinally disposed along a length of the conduit; a partition block configured to move between (i) a first position at which the partition block: is disposed laterally adjacent to the middle chamber, such that the partition block is offset from a longitudinal axis of the conduit, and (ii) a second position at which the partition block resides in the middle chamber between the distal chamber and the proximal chamber; and a deceleration structure disposed at a proximal, end of the conduit and bounding the proximal chamber, where the deceleration structure is configured to decelerate fruit feat has traversed the conduit.

A suction transfer device suction-holds a bag-like article with a suction component and moves the suction component suction-holding the article to thereby transfer the article. The suction component has a negative pressure chamber, one or more suction openings, and a first surface. The negative pressure chamber forms a negative pressure space inside when a negative pressure generator is driven. The suction openings communicate with the negative pressure chamber. The first surface is disposed around the suction openings and opposes an article subjected to suction. An area of the first surface is from 0.5 times to 2 times an area of a sucked surface, which opposes the first surface, of the article subjected to suction.

According to the present embodiment, a serving module includes: a tray; a main body formed therein with a tray space configured to accommodate the tray and having a tray entrance; a tray moving device configured to move at least a part of the tray out of the tray entrance or move an entire of the tray into the tray space; a door configured to open and close the tray entrance; and a door driving device connected to the door to open and close the door.