In a method of operating a dimensioning system with a plurality of laser scanners, a processor controls the operations of the scanners and processes the scanner signals, and further with memory for storing data delivered by the processor, the data acquired by the dimensioning system in its regular mode of operation are used to construct a three-dimensional model of surface points of the object including spatial coordinates and image intensity for each surface point. The three-dimensional model is stored in the memory. Based on the three-dimensional model, two-dimensional images from any desired viewing angle that was exposed to the scanner rays can be produced on demand to document the appearance of the object at the time the scan was taken.

A method includes optically interacting a flow of bulk material or powder in a pneumatic conveyor with an integrated computational element (“ICE”) configured to modify an electromagnetic radiation according to a characteristic of the flow of bulk material or powder. The method includes detecting the modified electromagnetic radiation with a detector, producing an output signal corresponding to the characteristic of the flow, and receiving and processing the output signal with a signal processor to yield a value for the characteristic of the flow. Also, the method includes modifying at least one of a flow rate or an air pressure in the pneumatic conveyor in response to the value of the characteristic of the flow. The bulk material or powder includes a dry cement or a dry cement component.

An article induction system for preparing a stream of articles, such as mail parcels, for processing employs a series of conveyors operating under control of a controller for feeding articles to an operator at a cull belt at an optimal paced rate. The article induction system includes a destacking section, a separation and alignment section, a buffer section and a culling section manned by an operator. A controller controls the speed of each component based on measurements provided by sensors so as to feed articles to the operator at a desired paced rate.

An intervention device (1) for a conveyor line conveying products to be moved in an upright position, i.e. the largest dimension thereof being perpendicular to the normally horizontal conveying plane, such as bottles of liquid, the device including: a detection module (2) for detecting the position of the products in a detection area (3) on the conveyor line; a removal module (4) for gripping and removing products that are lying down from a removal area (5) on the conveying line; and a control module (6) receiving information from the detection module (2) and controlling the removal module (4) accordingly. A corresponding method is also described.

A method and apparatus are provided for sorting items to a plurality of sort destinations. The items are fed into the apparatus at an input station having a scanning station. The scanning station evaluates one or more characteristics of each item. The items are then loaded onto one of a plurality of independently controlled delivery vehicles. The delivery vehicles are individually driven to sort destinations. Once at the appropriate sort destination, the delivery vehicle ejects the item to the sort destination and returns to receive another item to be delivered. A re-induction conveyor may be provided for receiving select items from the vehicles and conveying the items back to the input station for re-processing. Additionally, a controller is provided to control the movement of the vehicles based on a characteristic each item being delivered by each vehicle. The system may also include vehicles having edge-detection assemblies for detecting items being loaded onto or discharged from the vehicles.

A box handling system is disclosed for use in an object processing system. The box handling system includes a box tray including a recessed area for receiving a box, and the recessed area includes a plurality of floor and edge portions for receiving the box that contains objects to be processed.

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 storage device (1′) for storing transport units (3′) includes a number of transport units (3′), a number of storage lines (12a′-12g′) which are configured to store transport units (3′), a feeding line (11′) which is connected by a respective first switch point (111′) to the storage lines (12a′-12g′), a measuring device (15′) which is arranged on the feeding line (11′) and which is configured to determine a respective extent of a transport unit (3′), and a controller (16′) which is connected to the measuring device (15′) and to the first switch pointes (111′) and which is configured to select a storage line (12a′-12g′) for storing the transport unit (3′) on the basis of the extent of the transport unit (3′) determined by the measuring device (15′).

A control system includes: a sway detection unit configured to detect a reference swaying amount that is a swaying amount of a mast at a detection height, which is set to be greater than or equal to a height of a lowermost part of a transfer apparatus when a lift is located at an upper limit of a lifting range; a lifting height acquiring unit configured to acquire lifting height information that indicates a lifting height, which is a height of the lift, at a plurality of points in time; and a transfer control unit configured to control the transfer apparatus. The transfer control unit converts the reference swaying amount detected by the sway detection unit into a lifting height swaying amount that is a swaying amount of the mast at the lifting height indicated by the lifting height information.

Systems, methods, and computer-readable media are disclosed for scanning and dimensioning items in motion. In one embodiment, an example system may include a first camera oriented along a vertical axis towards a gap between a first surface and a second surface, a first light emitting array positioned to emit light towards the gap, and a first light receiving array aligned with the light emitting array and configured to detect the light. The first light emitting array and the first light receiving array may be offset from the vertical axis, and the system may be configured to determine a first dimension of an item passing over the gap using the first light emitting array and the first light receiving array.