An apparatus for distributing tie plates alongside rails of a railroad track including a singulating system for separating and singulating tie plates to be distributed along the rails of a railroad track, an orientation system positioned beneath the singulating system for orienting the tie plates with the correct side up, and a distribution system for distributing tie plates along the rails of a railroad track.

The present disclosure is directed to devices for manipulating meat pieces and methods therefore. In one form, a device comprises a chute, a conveyor, a backstop, and a paddle wheel. The chute is configured to hold pieces of a food product, and the conveyor is configured to receive pieces of the food product released from the chute. The first backstop is positioned above the conveyor and comprises a plate that is configured to align pieces of food product received at the conveyor into a single row. The paddle wheel is positioned above the conveyor downstream from the first backstop and is configured to manipulate the single row of pieces of food product traveling along the conveyor and cause only a single layer of pieces of food product to discharge from the conveyor.

A singulating conveyor having a herringbone pattern includes transporting rollers extending from the entry end to the exit end. The rollers are divided into four longitudinal zones, and each longitudinal zone is divided into a pair of side-by-side complementary outside and inside lateral zones. The rollers of each of the eight lateral zones are driven by a separate motor and V-Belt drive system that can be operated at differing speeds. The speed of the transporting rollers in the four longitudinal zones increases successively from the longitudinal zone adjacent the conveyor entry end towards the longitudinal zone having the discharge rollers, and the speed of the rollers of the outside lateral zones operate at higher speeds than the rollers of the adjacent inside lateral zones. Some of the rollers in the outside lateral zones preferably have higher coefficients of friction than the rollers of adjacent inside lateral zones.

Described is a component (1) for powering robots, automation systems and the like which comprises, on a frame (2), a series of belts (3, 4) for conveying objects (9) designed to be gripped by a robot. The conveyor belts (3, 4) constitute a closed path and have a first belt (3) and at least a second belt (4) positioned in such a way that the objects (9) pass from the first belt (3) to the second belt (4) cyclically and continuously.

A product flow regulator for temporary storage of products includes a frame, a conveying mechanism, and product carrier gondolas, which are conveyed with products from a product inlet area to a product outlet area and back empty. The frame includes a stationary guide track, along which the product carrier gondolas circulate self-controlled. The gondolas includes a drive mechanism and electrical control devices, which enable individual independent circulation.

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.

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.

Apparatus for handling bars including a support plane configured to support a plurality of bars having an oblong development, and handling devices configured to remove a bar from a removal zone of the support plane and to deliver it to a delivery zone. Movement devices are associated with the support plane which are configured to distribute the bars on the support plane and to move them toward the removal zone.

A conveyor system includes: a pick conveyor defining a picking area for a bulk flow of parcels; a place conveyor positioned downstream of the picking area; a first robot singulator and a second robot singulator, which work in parallel to transfer parcels within a picking area of the pick conveyor to the place conveyor; and a vision and control subsystem that communicates instructions to control operation of some or all of the foregoing components. The vision and control subsystem includes a target camera for acquiring one or more images of the picking area, which are processed within the system to determine the location of parcels positioned within the picking area. The vision and control subsystem can execute one or more routines or subroutines to reduce system downtime associated with image acquisition and processing, parcel transfer to the place conveyor, and/or parcel delivery to the picking area.

Examples of automated gemstone feeding are described. According to an example, a gemstone feeding machine includes a conveyor belt assembly to feed holders carrying gemstones. The conveyor belt assembly can include a plurality of conveyor belts in two sets positioned parallel to each other and the two sets can move in opposite directions. Each belt in one set can be positioned alternately with respect to each belt in the other set. The assembly can include a fixed guiding plate at a first end of the conveyor belts and a detachable guiding plate adjacent to the loading assembly at a second end of the conveyor belts. The fixed guiding plate and the detachable guiding plate each comprises a plurality of transition profiles in alignment with immediately adjacent conveyor belts.