A handling device according to an embodiment has an arm, a holder, a storage, and a controller. The arm includes at least one joint. The holder is attached to the arm and is configured to hold an object. The storage stores a function map including at least one of information about holdable positions of the holder and information about possible postures of the holder. The detector is configured to detect information about the object. The controller is configured to generate holdable candidate points on the basis of the information detected by the detector, to search the function map for a position in an environment in which the object is present, the position being associated with the generated holdable candidate points, and to determine a holding posture of the holder on the basis of the searched position. The function map associates a manipulability with each position in the environment in which the object is present. The manipulability is a parameter calculated from at least one joint angle of the holder.

A handling device according to an embodiment has an arm, a holder, a storage, and a controller. The arm includes at least one joint. The holder is attached to the arm and is configured to hold an object. The storage stores a function map including at least one of information about holdable positions of the holder and information about possible postures of the holder. The detector is configured to detect information about the object. The controller is configured to generate holdable candidate points on the basis of the information detected by the detector, to search the function map for a position in an environment in which the object is present, the position being associated with the generated holdable candidate points, and to determine a holding posture of the holder on the basis of the searched position. The function map associates a manipulability with each position in the environment in which the object is present. The manipulability is a parameter calculated from at least one joint angle of the holder.

A control unit performs first loading control that is to be performed when a target article that has been determined by a determination unit as being an article that is in an appropriate orientation is to be loaded onto a first supporting member in the appropriate orientation, and second loading control that is to be performed when a target article that has been determined by the determination unit as being an article that is in an inappropriate orientation is to be loaded onto the first supporting member in the appropriate orientation. The first loading control is performed to control a loading operation unit to suck and support a first sucking-target surface of a target article that is supported by the second supporting member, from above, then move a sucking portion, and thereafter release the target article from the state of being sucked by the sucking portion, and the second loading control is performed to control the loading operation unit to perform an orientation changing operation, and thereafter release the target article from the state of being sucked by the sucking portion when the target article is located immediately above the first supporting member and the first sucking-target surface faces upward.

A control unit performs first loading control that is to be performed when a target article that has been determined by a determination unit as being an article that is in an appropriate orientation is to be loaded onto a first supporting member in the appropriate orientation, and second loading control that is to be performed when a target article that has been determined by the determination unit as being an article that is in an inappropriate orientation is to be loaded onto the first supporting member in the appropriate orientation. The first loading control is performed to control a loading operation unit to suck and support a first sucking-target surface of a target article that is supported by the second supporting member, from above, then move a sucking portion, and thereafter release the target article from the state of being sucked by the sucking portion, and the second loading control is performed to control the loading operation unit to perform an orientation changing operation, and thereafter release the target article from the state of being sucked by the sucking portion when the target article is located immediately above the first supporting member and the first sucking-target surface faces upward.

A system and method for manufacturing a secondary battery, in which air is suctioned in an opposite direction of a transfer direction inside a loading part to prevent a radical unit, which freely drops at an initial speed in the transfer direction, from colliding with the loading part, thereby reducing folding short defects that occur in a subsequent process.

The system for manufacturing the secondary battery includes a transfer part configured to transfer a radical unit, a loading part configured to allow the radical unit transferred by the transfer part to drop in a direction of gravity so as to load the radical unit, and an intake part configured to suction air inside an inner space of the loading part from a side surface of the loading part.

A system and method for manufacturing a secondary battery, in which air is suctioned in an opposite direction of a transfer direction inside a loading part to prevent a radical unit, which freely drops at an initial speed in the transfer direction, from colliding with the loading part, thereby reducing folding short defects that occur in a subsequent process.

The system for manufacturing the secondary battery includes a transfer part configured to transfer a radical unit, a loading part configured to allow the radical unit transferred by the transfer part to drop in a direction of gravity so as to load the radical unit, and an intake part configured to suction air inside an inner space of the loading part from a side surface of the loading part.

One or more specific embodiments disclosed herein may include an end-of-arm tool for moving payloads or pallet stacks from one location to another, comprising a mast system comprising a mast, a plurality of mast gussets, and a mast plate; a frame; a clamp system comprising a plurality of clamp plates and a plurality of ball screws; and a vacuum system comprising a vacuum plate and one or more vacuum cups. Further, one or more specific embodiments disclosed herein may include a method of moving materials using an end-of-arm tool comprising aligning the end-of-arm tool over a payload, wherein the end-of-arm tool comprises an undercarriage in a retracted position, a plurality of clamp plates in an extended position, and one or more vacuum cups; lowering the end-of-arm tool towards the payload; engaging the payload with the one or more vacuum cups; engaging the payload with the plurality of clamp plates; and raising the payload into the interior of the end-of-arm tool.

Systems and methods to manipulate stacks of silicon wafers and rings are described. In one aspect, a robotic actuator includes a robotic end effector that further a first surface having multiple attached wafer suction cups arranged to collectively grasp a silicon wafer. The robotic end effector also includes a second surface that further includes multiple attached ring suction cups arranged to collectively grasp a ring. The second surface also includes a bulk grabber positionable to grasp a collective stack of rings. The robotic actuator also includes an axial actuator configured to rotate the robotic end effector about a flip axis, such that either the first surface or the second surface faces vertically upwards.

A robotic system includes: a control unit configured to: receive an object set including one or more object entries, wherein: the object entries correspond to source objects of an object source, each of the object entries are described by one or more object entry properties; receive sensor information representing one or more detectable object properties for detectable source objects of the object source; calculate an object match probability between the detectable source objects and the object entries based on a property correlation between the detectable object properties of the detectable source objects and the object entry properties of the object entries; generate an object identity approximation for each of the detectable source objects based on a comparison between the object match probability for each of the detectable source objects corresponding to a particular instance of the object entries; select a target object from the detectable source objects; generate an object handling strategy, for implementation by an object handling unit, to transfer the target object from the object source based on the object entry properties of the object entries corresponding to the object identity approximation; update the object set to indicate that the target object corresponding to a specific instance of the object entries has been removed from the object source; and a storage unit 204, coupled to the control unit, configured to store the object set.

A method of making a pad of labels comprises: printing display information on a top surface of a substrate; affixing a first layer of lamination material to a bottom surface of the substrate; affixing a second layer of lamination material to the top surface of the substrate, the second layer of lamination material having a release coating applied to a top surface thereof; applying an adhesive strip to a bottom surface of the first layer of lamination material, the adhesive strip being covered by a liner material; cutting the substrate having first and second layers of lamination material affixed into at least one label; removing the liner material to expose the adhesive strip after cutting the substrate into at least one label; and arranging the labels into a pad of labels.