A modular conveying assembly that includes a plurality of roller bodies, a driving member, a positive stop body, and a positive stop actuator. Each roller body includes a top surface, a driven axle mounted to the roller body for conveyance therewith, a roller fixed to the driven axle, and a driven surface fixed to the driven axle. The rollers define a support plane. The driving member selectively engages the driven surfaces to affect rotation of the driven axle. The positive stop body is coupled to the plurality of roller bodies and includes a positive stop that is movable relative to the positive stop body between a first position and a second position. The positive stop extends above the support plane in the second position. The positive stop actuator selectively engages the positive stop to move the positive stop between the first position and the second 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.

A packaging installation that includes a grouping machine configured to form batches of products and a horizontal form-fill-seal packaging machine arranged downstream the grouping machine and being configured to receive the formed batches of products and to package them in individual packages. The grouping machine includes a receiving area to receive the products and a grouping area where the products are grouped into batches, and, for transporting products to the grouping area. The grouping machine includes a first product path and a second product path, different from the first product path, extending from the product receiving area to the grouping area. According to one embodiment, the grouping machine is configured to cause the products arriving at the grouping area from the first product path and from the second product path to have different orientations.

A conveying system employs independently controlled flights. The flights are controlled separately from a conveying surface using a linear transport system. The linear transport system allow the position of the flights to be controlled based on a parameter, such as the length of a conveyed object. The flights are pivotally mounted to a mover of the linear transport system and can pivot relative to the conveying surface to allow the flights to fit in a space between an end of carryway and a receptacle.

A packaging installation that includes a grouping machine configured to form batches of products and a horizontal form-fill-seal packaging machine arranged downstream the grouping machine and being configured to receive the formed batches of products and to package them in individual packages. The grouping machine includes a receiving area to receive the products and a grouping area where the products are grouped into batches, and, for transporting products to the grouping area. The grouping machine includes a first product path and a second product path, different from the first product path, extending from the product receiving area to the grouping area. According to one embodiment, the grouping machine is configured to cause the products arriving at the grouping area from the first product path and from the second product path to have different orientations.

A conveying system employs independently controlled flights. The flights are controlled separately from a conveying surface using a linear transport system. The linear transport system allow the position of the flights to be controlled based on a parameter, such as the length of a conveyed object. The flights are pivotally mounted to a mover of the linear transport system and can pivot relative to the conveying surface to allow the flights to fit in a space between an end of carryway and a receptacle.

The present application discloses a method, system, and computer system for controlling a gating structure to mediate a flow of items an input source to a pick area. The system includes: (i) the gating structure, which is configured to use a plurality of gate elements to mediate a flow of items from the input source to the pick area, (ii) a sensor configured to provide a sensor output associated with the pick area, and (iii) a processor configured to provide a control input to the gating structure to adjust a configuration of one or more of the plurality of gating elements based at least in part on the sensor output. The sensor output comprises the sensor output comprises one or more of a flow rate, a number, and an orientation of objects in an area associated with picking of objects by one or more robots. The control input is determined based at least in part on one or more of the flow rate, the number, and the orientation of objects in the area associated with picking of objects by one or more robots.

A packaging installation that includes a grouping machine configured to form batches of products and a horizontal form-fill-seal packaging machine arranged downstream the grouping machine and being configured to receive the formed batches of products and to package them in individual packages. The grouping machine includes a receiving area to receive the products and a grouping area where the products are grouped into batches, and, for transporting products to the grouping area. The grouping machine includes a first product path and a second product path, different from the first product path, extending from the product receiving area to the grouping area. According to one embodiment, the grouping machine is configured to cause the products arriving at the grouping area from the first product path and from the second product path to have different orientations.

The invention relates to a system (1) for conveying articles (3), which system comprises an article conveyor (2) extending from an upstream end (4) to a downstream end (5), and a motor-driven shuttle trolley (6) having an article carrier deck (7) and designed to dock with said ends of the conveyor so as to transfer an article between the trolley and the conveyor. The conveyor is a gravity conveyor under which a ramp (12) extends, and the trolley is suitable for travelling under the conveyor and is provided with a lever (11) that is mounted to move vertically relative to the deck and that is designed to co-operate with the ramp while the trolley is moving under the conveyor so that, by following the ramp, the lever moves between a retracted position in which it is retracted under the conveyor and a deployed position in which it projects above the conveyor so as to drive an article along the conveyor. The method of matching digital images of the same article in a data processor unit comprises the steps of: transforming each digital image of an article into a local divergence topographic map of the luminance gradient vector field; detecting singularities or extrema of local divergence in the luminance gradient vector field, such singularities corresponding to points of interest in said digital image; and, for each detected point of interest, encoding the values for the singularity of the gradient field that are located on a plurality of concentric rings centered on the point of interest so as to derive a digital data vector (210); and transforming said vector into a digital hash key (220) by means of a family of hash functions of the cosine Locality-Sensitive Hashing (LSH) type.

The invention relates to a system (1) for conveying articles (3), which system comprises an article conveyor (2) extending from an upstream end (4) to a downstream end (5), and a motor-driven shuttle trolley (6) having an article carrier deck (7) and designed to dock with said ends of the conveyor so as to transfer an article between the trolley and the conveyor. The conveyor is a gravity conveyor under which a ramp (12) extends, and the trolley is suitable for travelling under the conveyor and is provided with a lever (11) that is mounted to move vertically relative to the deck and that is designed to co-operate with the ramp while the trolley is moving under the conveyor so that, by following the ramp, the lever moves between a retracted position in which it is retracted under the conveyor and a deployed position in which it projects above the conveyor so as to drive an article along the conveyor. The method of matching digital images of the same article in a data processor unit comprises the steps of: transforming each digital image of an article into a local divergence topographic map of the luminance gradient vector field; detecting singularities or extrema of local divergence in the luminance gradient vector field, such singularities corresponding to points of interest in said digital image; and, for each detected point of interest, encoding the values for the singularity of the gradient field that are located on a plurality of concentric rings centered on the point of interest so as to derive a digital data vector (210); and transforming said vector into a digital hash key (220) by means of a family of hash functions of the cosine Locality-Sensitive Hashing (LSH) type.