Disclosed is a substrate conveyance device, comprising: a carrying platform, configured to support a substrate; a conveying mechanism, disposed below the carrying platform and configured to convey the carrying platform; and oppositely disposed guiding mechanisms, disposed on both sides of the carrying platform in a conveying direction, respectively. First magnetic field generators are disposed on both sides of the carrying platform in the conveying direction, and the guiding mechanism includes second magnetic field generators adjacent to the first magnetic field generators and disposed oppositely to the first magnetic field generators, respectively, such that the first magnetic field generator and the second magnetic field generator which are adjacent to each other have the same polarity. The substrate conveyance device is suitable for conveying various display substrates, especially the substrate having a large size.

Provided are a flat-member-feeding device with which it is possible to reduce power consumption and quickly supply a flat member, and a method for manufacturing the flat-member-feeding device. A method for attaching a motor for rotating a downstream roll to a flat-member-feeding device, the motor being provided with a hollow and substantially cylindrical stator and a hollow and substantially cylindrical rotor that is disposed in the space within the stator, includes: a step for disposing a sleeve so as to occupy part of the space inside the rotor, and mounting the sleeve on the rotor such that one end of the rotor is supported by one end of the sleeve and the other end of the rotor is supported by the other end of the sleeve; and a step for mounting the sleeve on a downstream roll shaft to which the downstream roll is fixed, and attaching the motor to the flat-member-feeding device.

Provided are a flat-member-feeding device with which it is possible to reduce power consumption and quickly supply a flat member, and a method for manufacturing the flat-member-feeding device. A method for attaching a motor for rotating a downstream roll to a flat-member-feeding device, the motor being provided with a hollow and substantially cylindrical stator and a hollow and substantially cylindrical rotor that is disposed in the space within the stator, includes: a step for disposing a sleeve so as to occupy part of the space inside the rotor, and mounting the sleeve on the rotor such that one end of the rotor is supported by one end of the sleeve and the other end of the rotor is supported by the other end of the sleeve; and a step for mounting the sleeve on a downstream roll shaft to which the downstream roll is fixed, and attaching the motor to the flat-member-feeding device.

A method and system for stacking coils in which a coil stacker lifting head can be used to raise one or more coils from a conveyor assembly. The coil stacker lifting head can be automatically actuated using a actuating cylinder and a counter balance cylinder. The coil stacker lifting head can include an expanding mandrel to grab opposite edges of the coil and lift the coil. One or more of the coils can be lifted from a conveyor assembly by the coil stacker lifting head. After the one or more coils are lifted, a carriage assembly can transport the lifted one or more coils to a desired position. Once the one or more coils reach the desired position, the one or more coils are lowered to a surface. Upon reaching the surface, the mandrel automatically collapses to release the one or more coils and the mandrel is released from the coils.

An energy harvesting roller for a cargo handling system may comprise a shaft and a sleeve located on the shaft. A piezoelectric member may be coupled to the sleeve. A shell may be located radially outward of the piezoelectric member and configured to rotate relative to the sleeve. A radially inward surface of the shell may define at least one of a plurality of grooves or a plurality of protrusions.

A method and system for stacking coils in which a coil stacker lifting head can be used to raise one or more coils from a conveyor assembly. The coil stacker lifting head can be automatically actuated using a actuating cylinder and a counter balance cylinder. The coil stacker lifting head can include an expanding mandrel to grab opposite edges of the coil and lift the coil. One or more of the coils can be lifted from a conveyor assembly by the coil stacker lifting head. After the one or more coils are lifted, a carriage assembly can transport the lifted one or more coils to a desired position. Once the one or more coils reach the desired position, the one or more coils are lowered to a surface. Upon reaching the surface, the mandrel automatically collapses to release the one or more coils and the mandrel is released from the coils.

Manual and automated racking systems and associated methods for loading/unloading glass panels (e.g., insulating glass units (IGU), laminated glass units, glass composites, monolithic glass, and the like) onto/from a transportable rack, and a rack for use with the manual and automated racking systems.

Manual and automated racking systems and associated methods for loading/unloading glass panels (e.g., insulating glass units (IGU), laminated glass units, glass composites, monolithic glass, and the like) onto/from a transportable rack, and a rack for use with the manual and automated racking systems.

An object redirection mechanism for a conveying system is provided. The object redirection mechanism is configured to redirect an object moved by the conveying system from a first direction to a second direction. The object redirection mechanism includes an arm tunnel positioned proximate an end of a conveyor configured for moving an object in the first direction. The arm tunnel includes an object stop having an object stopping portion defining at least a first side of the arm tunnel at least substantially parallel with the second direction and configured to engage an object moving in the first direction. The object stopping portion defines at least one finger aperture to enable at least one of the rotationally-retractable fingers to, when aligned with the at least one finger aperture, rotate between a retracted configuration and an extended configuration. A corresponding object conveying system and method of assembling an object stop are provided.

The present invention relates to a system (1) for arranging items in containers comprising a plurality of processing stations (11) for filling removable containers, wherein each of the processing station (11) is able to house a single of the removable containers and comprises a movable tray (211), able to support a respective of the removable containers, moving means of the movable tray (211) with respect to the processing station (11) and a conveyor (111), provided with an entry portion (111′) and with an exit portion (111″) of the items, wherein the conveyor (111) is arranged at a distance from the movable tray (211) such that the exit portion (111″) remains above the opening of a respective of the removable containers, wherein the moving means are able to operate a shaking of the movable tray (211) at least along opposite directions of a predefined axis of shaking to arrange the items in the removable container in a homogeneous way.