A method and device for sorting articles, including at least one station for automatically loading articles allowing transfer of the articles to one or several transport units, the station equipped with at least one device for transporting the articles and a system able to determine the position, the shape and the size of the articles, with a set of cross belt transport units, each unit provided with a supporting plate between two adjacent units. The device includes a system allowing detection of a possible change in position of an article on a transport device during the acceleration phase. Maintaining the article in position on its unit(s) is ensured during its movement on the sorter, by supporting plates permanently ensuring supporting surface continuity between two units over a width substantially equal to the supporting surface of the belts and by the presence of vertical profiles on the belts.

A method and device for sorting articles, including at least one station for automatically loading articles allowing transfer of the articles to one or several transport units, the station equipped with at least one device for transporting the articles and a system able to determine the position, the shape and the size of the articles, with a set of cross belt transport units, each unit provided with a supporting plate between two adjacent units. The device includes a system allowing detection of a possible change in position of an article on a transport device during the acceleration phase. Maintaining the article in position on its unit(s) is ensured during its movement on the sorter, by supporting plates permanently ensuring supporting surface continuity between two units over a width substantially equal to the supporting surface of the belts and by the presence of vertical profiles on the belts.

A mail processing system utilizes a conveyor to shingle or de-shingle mailpieces as they move through the processing system and utilizes belts to move the mailpieces. A first shingling conveyor moves a first mailpiece to overlap with a second mailpiece to create shingled mailpieces. A second shingling conveyor moves a first mailpiece away from a second mailpiece to de-shingle them to create singulated mailpieces. A camera takes images of the mailpieces in the conveyor and image analysis software is used to determine dimensional aspects of the mailpieces that are used to control the belt speeds to move mailpieces with respect to each other. A mail processing system may include a mail processing station that scans addresses, applies postage and/or weighs the mailpieces. Mail may be de-shingled prior to being weighed and then re-shingled for subsequent processing, or mail may be shingled prior to passing through a scale if weighing is not necessary.

A mail processing system utilizes a conveyor to shingle or de-shingle mailpieces as they move through the processing system and utilizes belts to move the mailpieces. A first shingling conveyor moves a first mailpiece to overlap with a second mailpiece to create shingled mailpieces. A second shingling conveyor moves a first mailpiece away from a second mailpiece to de-shingle them to create singulated mailpieces. A camera takes images of the mailpieces in the conveyor and image analysis software is used to determine dimensional aspects of the mailpieces that are used to control the belt speeds to move mailpieces with respect to each other. A mail processing system may include a mail processing station that scans addresses, applies postage and/or weighs the mailpieces. Mail may be de-shingled prior to being weighed and then re-shingled for subsequent processing, or mail may be shingled prior to passing through a scale if weighing is not necessary.

A system for removing unstable articles from an automated processing stream includes an automated processing stream with a plurality of processing units including a flow diverter and configured to carry a stream of articles, a vision system, and a control system interfacing with the automated processing stream and the vision system, wherein the vision system is configured to detect positions of an article and to transmit position data to the control system, and wherein the control system is configured, through operation of a processor, to determine an expected position of the article based on a first detected position, compare the expected position to a second detected position of the article, determine a deviation of the second detected position from the expected position, and control the flow diverter to divert the article based on the deviation.

A singulating system for parcels comprises: an inner wall; a first section comprised of a series of driven rollers, which are skewed relative to a longitudinal direction of travel, so that the parcels are conveyed not only in the longitudinal direction of travel, but also toward the inner wall; a second section for receiving the parcels from the first section, and then identifying and moving parcels in a side-by-side arrangement and/or parcels with an irregular shape; and a third section for receiving the parcels from the second section. In some embodiments, the singulating system also includes a visioning subsystem, including a camera for acquiring image data of the parcels as the parcels move toward or into the second section, and a computer to receive and analyze the image data from the camera to identify parcels in a side-by-side arrangement and/or parcels with an irregular shape.

A sorting conveyor and a method for sorting packages to selected destinations. A neural network executed by a multi-core classification processor uses captured images of package units conveyed on an infeed conveyor to classify each package unit. A control processor controls a sorting conveyor to direct each package unit to a destination depending on the package unit's classification.

Systems, methods, and computer-readable media are disclosed for automated sweepers for item sortation systems. In one embodiment, an example item sortation system may include an aisle, a number of chutes accessible from the aisle, a shuttle configured to transport first items from an induction portion of the item sortation system to a first chute of the plurality of chutes, and a robotic sweeping system disposed in the aisle. The robotic sweeping system may be configured to sweep second items on a floor of the aisle to a first end of the item sortation system. The robotic sweeping system may include a motor and a sweeping device.

Systems, methods, and computer-readable media are disclosed for automated sweepers for item sortation systems. In one embodiment, an example item sortation system may include an aisle, a number of chutes accessible from the aisle, a shuttle configured to transport first items from an induction portion of the item sortation system to a first chute of the plurality of chutes, and a robotic sweeping system disposed in the aisle. The robotic sweeping system may be configured to sweep second items on a floor of the aisle to a first end of the item sortation system. The robotic sweeping system may include a motor and a sweeping device.

A mail processing system utilizes a conveyor to shingle or de-shingle mailpieces as they move through the processing system and utilizes belts to move the mailpieces. A first shingling conveyor moves a first mailpiece to overlap with a second mailpiece to create shingled mailpieces. A second shingling conveyor moves a first mailpiece away from a second mailpiece to de-shingle them to create singulated mailpieces. A camera takes images of the mailpieces in the conveyor and image analysis software is used to determine dimensional aspects of the mailpieces that are used to control the belt speeds to move mailpieces with respect to each other. A mail processing system may include a mail processing station that scans addresses, applies postage and/or weighs the mailpieces. Mail may be de-shingled prior to being weighed and then re-shingled for subsequent processing, or mail may be shingled prior to passing through a scale if weighing is not necessary.