Additional automation in the form of a profile singulator for singulating profiles is proposed which includes: a first conveying device for feeding the profiles in a disorderly state over a first conveying section, a conveyor roller for unraveling the large quantity of fed profiles into individual profiles, wherein the conveyor roller is situated downstream from the first conveying device in the direction of transport. The profiles can be limp, flexible, or semi-flexible; moreover, they can have or not have a carrier.

A logistics center automation system includes a singulator to which a cluster control for simultaneously moving articles unloaded from a plurality of unloading vehicles is applied, a transport robot configured to deliver the articles moved by the singulator to a loading vehicle corresponding to destination information, a mobile multi-recognizer configured to extract destination information of the transport robot, and a controller configured to control the singulator, the transport robot, and the mobile multi-recognizer.

Examples of automated gemstone feeding are described. According to an example, a gemstone feeding machine includes a conveyor belt assembly to feed holders carrying gemstones. The conveyor belt assembly can include a plurality of conveyor belts in two sets positioned parallel to each other and the two sets can move in opposite directions. Each belt in one set can be positioned alternately with respect to each belt in the other set. The assembly can include a fixed guiding plate at a first end of the conveyor belts and a detachable guiding plate adjacent to the loading assembly at a second end of the conveyor belts. The fixed guiding plate and the detachable guiding plate each comprises a plurality of transition profiles in alignment with immediately adjacent conveyor belts.

The invention relates to a method for packaging objects (2) which are included in a plurality of objects belonging to the fruit and vegetable group and the shape of which is such that the objects included in the plurality of objects can roll along a surface, characterised in that the objects (2) included in the plurality of objects are deposited onto a solid surface, referred to as the deposition surface (1), of a system (10) for packaging the objects, the deposition surface (1) being substantially horizontal, suitable for receiving the objects included in the plurality of objects and elastically deformable such that the deposition of each object on the deposition surface (1) creates, under the weight of the object concerned, a recess (3) in the deposition surface (1) which tends to wedge the object in the recess (3), then the objects included in the plurality of objects deposited onto the deposition surface (1) and held in a position

A radiation detector unit includes a read-out integrated circuit (ROIC) including a plurality of core circuit blocks located on a continuous uninterrupted substrate adjacent to one another along a first direction, and a plurality of radiation sensors bonded to a front side surface of the ROIC, where each radiation sensor of the plurality of radiation sensors is bonded to a respective core circuit block of the plurality of core circuit blocks of the ROIC. Additional embodiments include detector modules and detector arrays formed by assembling the detector units, and methods of operating and manufacturing the same.

The present disclosure concerns a method for sorting items transported along a conveyance direction on an item carrier of a sorting system, the item carrier comprising a charging zone, a first detection zone, an item orientation-changing zone, a second detection zone and a sorting zone, the method comprising sequentially: loading the items on the item carrier in the charging zone; capturing a first image of the items in the first detection zone; changing an orientation of the items in the item orientation-changing zone, located downstream of the first detection zone; capturing a second image of the items in the second detection zone, located downstream of the first detection zone; identifying nonstandard items amongst the items from information derived from the first and second images; and isolating the identified nonstandard items in the sorting zone. It also concerns a corresponding sorting system.

The present application discloses a system, a method, and a computer system for moving items deemed to be too heavy to be picked up by a robotic arm. The method includes (i) receiving image data associated with a workspace, wherein the workspace includes a source of items to be placed singly each in a respective corresponding location on a segmented conveyance structure adjacent to at least a portion of the source of items, (ii) receiving an indication that a first item in the source of items is too heavy to be picked up by a first robotic arm the one or more processors are configured to control, (iii) determining, based at least in part on the image data, a plan to use the first robotic arm to push the first item onto an associated corresponding location on the segmented conveyance structure as the associated corresponding location on the segmented conveyance structure moves past the source of items, and (iv) controlling the first robotic arm to implement the plan.

A device for distributing clip-type components for assembling parts includes a main magazine for bulk storage of the components, a tray for temporary storage of components extracted from the main magazine, configured to temporarily store the components to be transferred out of the device and mounted for reciprocating translation in a longitudinal direction to shake the temporarily stored components and facilitate their positioning inside the tray in a predetermined stable position corresponding to their shape. The device includes an optical detection system to detect, from among the components temporarily stored inside the temporary storage tray, the components having the predetermined stable position, and a transfer system to transfer the components having the predetermined stable position to a downstream processing area outside the device. The device further includes an electronic control unit connected to the optical detection system and the transfer system, the unit configured to control the transfer system.

A system for automatic organization, hanging and driving of slaughtered animals installed at the outlet of a slaughtered animals processing station such as a chiller. The system comprises a receiving and aligning means of slaughtered animals in longitudinal position, which is previously disposed to an accumulator device of slaughtered animals positioned longitudinally. The system further comprises a suspension and movement assembly of each slaughtered animal from the axial alignment assembly to a driving guide of each slaughtered animal to a hanging transfer device of each animal slaughtered in the hanging line.

A conveyor system includes: a pick conveyor defining a picking area for a bulk flow of parcels; a place conveyor positioned downstream of the picking area; a first robot singulator and a second robot singulator, which work in parallel to transfer parcels within a picking area of the pick conveyor to the place conveyor; and a vision and control subsystem that communicates instructions to control operation of some or all of the foregoing components. The vision and control subsystem includes a target camera for acquiring one or more images of the picking area, which are processed within the system to determine the location of parcels positioned within the picking area. The vision and control subsystem can execute one or more routines or subroutines to reduce system downtime associated with image acquisition and processing, parcel transfer to the place conveyor, and/or parcel delivery to the picking area.