A movable object holding system for holding a movable object including a body portion 11 and a protruding portion protruding from the body portion, comprising a hand part 40 holding a movable object, the hand part 40 comprising plural guide portions limiting movement of the movable object in a first axis direction and a second axis direction that are perpendicular to each other and a pair of positioning portions 43e limiting movement of the movable object in a third axis direction that is perpendicular to the first and second axis directions, wherein the hand part 40 holds the movable object with the protruding portion of the movable object disposed in a space surrounded by the plural guide portions and touching the pair of the positioning portions 43e and with a part of the body portion of the movable object exposed out of the hand part 40.

The invention relates to a consumable-material handling device for transporting and/or handling at least one consumable material (12a; 12b), in particular packaging material, comprising at least one at least partially autonomous handling unit (14a; 14b), which is at least provided for handling the consumable material (12a; 12b). According to the invention, the machine tool comprises at least one, in particular at least partially autonomous, mobility unit (16a; 16b), on which the handling unit (14a; 14b) is arranged and which is at least provided for enabling locomotion, in particular at least partially autonomous locomotion, of the handling unit (14a; 14b).

Various embodiments of a bio-inspired robot operable for detecting crack and corrosion defects in tubular structures are disclosed herein.

A gripping mechanism includes a pair of inclined surfaces and rolling elements. The pair of inclined surfaces face each other, are inclined in opposite directions with respect to a vertical direction, and approach each other on a lower side. Each of the rolling elements is rollable on the respective inclined surfaces in an obliquely upward and downward direction. An opening space is formed between lower ends of the inclined surfaces, the opening space having a direction Y (horizontal) width smaller than a direction Y width of the respective rolling elements arranged in the direction Y.

Embodiments of the invention are directed to an apparatus that includes a moveable gripper element that includes a flexible inner sleeve. A mechanical energy source mechanism is communicatively coupled to the moveable gripper element, and the flexible sleeve defines an opening. The mechanical energy source mechanism transfers to the moveable gripper element a gripping force configured to move the moveable outer sleeve, reduce a size of the adjustable opening, and bring the flexible inner sleeve into an initial level of thermal contact with a container positioned within the adjustable opening. The mechanical energy source mechanism is configured to, subsequent to establishing the initial level of thermal contact, make adjustments to the gripping force, wherein the adjustment to gripping force increase thermal contact points at an interface between the flexible inner sleeve and the container; and displace air from the interface between the flexible inner sleeve and the container.

Embodiments of the invention are directed to an apparatus that includes a moveable gripper element including a flexible inner sleeve. A mechanical energy source mechanism is communicatively coupled to the moveable gripper element, and a sensor network is communicatively coupled to the moveable gripper. A controller is communicatively coupled to the mechanical energy source mechanism and the sensor network. The flexible inner sleeve defines an adjustable opening. The controller controls the mechanical energy source mechanism to transfer to the moveable gripper element a gripping force configured to move the moveable outer sleeve, reduce a size of the adjustable opening, and bring the flexible inner sleeve into an initial level of thermal contact with a container positioned within the adjustable opening. The controller is configured to, subsequent to establishing the initial level of thermal contact, control the mechanical energy source mechanism to make adjustments to the gripping force.

An automated cooking system for adding time and labor efficiencies in food production environments such as restaurants. The automated cooking system includes at least a fryer, a dispensing freezer, a hot holding station, a plurality of baskets, and a gantry system. The gantry system includes a gantry control for a gantry, configured to engage and move each of the baskets. The basket and gantry include interface elements for enabling precise movements and rapid opening and closing of baskets at the system. Aspects of an automated cooking system and a corresponding method for discharging cooked food product help to avoid the problems associated with manually operating a cooking system. Specifically, the system described herein provides for apparatuses and methods to cook and dispense food product in a more efficient manner with regard to both time and labor considerations within food production environments.

The present disclosure relates to systems and methods for automated drill pipe handling operations, such as trip in, trip out, and stand building operations. A pipe handling system of the present disclosure may include a lifting system for handling a load of a pipe stand, a pipe handling robot configured for engaging with the pipe stand and manipulating a position of the pipe stand, and a feedback device configured to provide information about a condition of the pipe stand, the lifting system, or the pipe handling robot. In some embodiments, the pipe handling robot may be a first robot configured for engaging with and manipulating a first end of the pipe stand, and the system may include a second pipe handling robot configured for engaging with and manipulating a second end of the pipe stand.

An apparatus for provisioning, in particular automatically, a complete tool having a toolholder and a tool, in particular a drilling and/or milling tool. The apparatus has a spindle that can be driven in rotation by a driving device. The spindle has a holding device for holding a toolholder. A measuring device, in particular an optical measuring device, measures a complete tool, held on the spindle. A heating device in the region of the spindle heats a shrink-fit chuck of the toolholder held on the spindle. A cooling device, in particular a cooling device associated with the spindle, enables the spindle and/or the complete tool held on the spindle, to be cooled.

An end effector for gripping and spinning a pipe includes a head portion including a first connection interface for connecting the end effector to a robotic arm. In addition, the end effector includes a pair of jaws rotatably connected to the head portion between an open position and a gripping position. Further, the end effector includes a spinner for spinning a pipe held by the pair of jaws in the gripping position around a spinning axis generally corresponding to a longitudinal centre axis of the pipe. The first connection interface has a normal which is substantially parallel to the spinning axis. There is also disclosed a robot including an end effector as well a robot assembly and a drilling installation including such as robot.