A motor assembly comprising a mover assembly and a stator. The mover assembly comprising a plurality of mover assembly units, each unit comprising: a non-ferromagnetic core with a profile of an outer surface having at least two flat sections lying on intersecting planes; at least two ferromagnetic laminated structures arranged on the at least two flat sections of the non-ferromagnetic core, each ferromagnetic laminated structure includes a stack of ferromagnetic plates, each plate is covered with a non-conductive coating. Each ferromagnetic laminated structure is arranged on a corresponding flat section of the at least two flat sections of the non-ferromagnetic core such that side of each ferromagnetic plate is adjacent to the non-ferromagnetic core thereby making the ferromagnetic plates of the at least two ferromagnetic laminated structures lie on intersecting planes. The mover assembly unit further comprises windings of wire wrapped around the ferromagnetic laminated structures and the non-ferromagnetic core.

A motor assembly comprising a mover assembly and a stator. The mover assembly comprising a plurality of mover assembly units, each unit comprising: a non-ferromagnetic core with a profile of an outer surface having at least two flat sections lying on intersecting planes; at least two ferromagnetic laminated structures arranged on the at least two flat sections of the non-ferromagnetic core, each ferromagnetic laminated structure includes a stack of ferromagnetic plates, each plate is covered with a non-conductive coating. Each ferromagnetic laminated structure is arranged on a corresponding flat section of the at least two flat sections of the non-ferromagnetic core such that side of each ferromagnetic plate is adjacent to the non-ferromagnetic core thereby making the ferromagnetic plates of the at least two ferromagnetic laminated structures lie on intersecting planes. The mover assembly unit further comprises windings of wire wrapped around the ferromagnetic laminated structures and the non-ferromagnetic core.

Exemplary embodiments provide a sorting system using the principles of linear motors to move a magnetized mat in multiple directions. The sorting system uses a series of stator coils in particular patterns to direct the magnetized mat along predefined looping pathways such that the magnetized mat can move articles in a desired direction. Embodiments include the use of multiple magnetized mats to improve package sorting rates. The magnetized mat is comprised of a plurality of magnetized and non-magnetized tiles which are connected using flexible tabs that form a living hinge. The living hinge flexes and allows the mat to travel along the predefined looping pathways. The sorting system may be used as a node in a larger grid sorting system and may be connected to conveyors, chutes, or other means for moving articles.

Exemplary embodiments provide a sorting system using the principles of linear motors to move a magnetized mat in multiple directions. The sorting system uses a series of stator coils in particular patterns to direct the magnetized mat along predefined looping pathways such that the magnetized mat can move articles in a desired direction. Embodiments include the use of multiple magnetized mats to improve package sorting rates. The magnetized mat is comprised of a plurality of magnetized and non-magnetized tiles which are connected using flexible tabs that form a living hinge. The living hinge flexes and allows the mat to travel along the predefined looping pathways. The sorting system may be used as a node in a larger grid sorting system and may be connected to conveyors, chutes, or other means for moving articles.

A curved belt conveyor includes a conveyor belt with a hooking element associated with an outer periphery of the conveyor belt and multiple pairs of rollers guiding the hooking element. A plurality of supporting elements is placed at the outer periphery, each for supporting at least one pair of rollers. A holding space for the hooking element is defined among each pair of rollers and a corresponding supporting element. A main roller of one of the pairs of rollers is movable along a trajectory extending along a longitudinal development of a corresponding main roller shaft between a releasing position, wherein the rollers are spaced to define an intermediate space therebetween to allow the passage of the hooking element, and a retaining position, wherein the rollers are close to each other to prevent passage of the hooking element from the corresponding holding space through the corresponding intermediate space.

A curved belt conveyor includes a conveyor belt with a hooking element associated with an outer periphery of the conveyor belt and multiple pairs of rollers guiding the hooking element. A plurality of supporting elements is placed at the outer periphery, each for supporting at least one pair of rollers. A holding space for the hooking element is defined among each pair of rollers and a corresponding supporting element. A main roller of one of the pairs of rollers is movable along a trajectory extending along a longitudinal development of a corresponding main roller shaft between a releasing position, wherein the rollers are spaced to define an intermediate space therebetween to allow the passage of the hooking element, and a retaining position, wherein the rollers are close to each other to prevent passage of the hooking element from the corresponding holding space through the corresponding intermediate space.

First scanned images of the first container are received from a scanning device that show the contents of the interior of the first container before the first container is cut and opened. Second scanned images that are of the contents of the first container after the first container is cut and opened are also received. The images are analyzed and, based upon the analysis, selective modifications to the operating parameters of the container opening machine are determined and made.

First scanned images of the first container are received from a scanning device that show the contents of the interior of the first container before the first container is cut and opened. Second scanned images that are of the contents of the first container after the first container is cut and opened are also received. The images are analyzed and, based upon the analysis, selective modifications to the operating parameters of the container opening machine are determined and made.

A packaging transport device has a support unit (10) including a first support surface (12), which defines a first track section (11), and at least one second support surface (14), which defines a second track section (13) and is tilted relative to the first support surface (12) around a tilt axis (16) running in a transport direction (15), the packaging transport device further including a driving member (17) and drivers (18), which are connected with the driving member (17), and are supported movably around the tilt axis (16), wherein the driving member (17) is implemented by a belt.

A packaging transport device has a support unit (10) including a first support surface (12), which defines a first track section (11), and at least one second support surface (14), which defines a second track section (13) and is tilted relative to the first support surface (12) around a tilt axis (16) running in a transport direction (15), the packaging transport device further including a driving member (17) and drivers (18), which are connected with the driving member (17), and are supported movably around the tilt axis (16), wherein the driving member (17) is implemented by a belt.