A flight for use in a mesh conveyor belt assembly that can have a first planar portion and a second planar portion extending non-coplanar to the first planar portion. The first planar portion can have a pair of tabs extending therefrom. Each tab can have a through-hole configured to receive a cross-rod of the mesh conveyor belt assembly therethrough.

A flight for use in a mesh conveyor belt assembly that can have a first planar portion and a second planar portion extending non-coplanar to the first planar portion. The first planar portion can have a pair of tabs extending therefrom. Each tab can have a through-hole configured to receive a cross-rod of the mesh conveyor belt assembly therethrough.

Disclosed is a method for manufacturing an endless belt, of the flat type made of metal material, designed to be wound around at least one indexed pulley provided with teeth. The endless belt includes, for the one part, locations which are each designed to receive a product to be conveyed and, for the other part, indexing perforations. The manufacturing method includes the following successive steps: a) a step of supplying a flat band made of the metal material, b) a step of closing the band by welding of the transverse edges thereof via a weld seam, and c) a step of perforating the weld seam, at the at least one longitudinal indexing line, in order to form at least one additional indexing perforation that is also designed to engage with the teeth of the at least one indexed pulley.

Disclosed is a method for manufacturing an endless belt, of the flat type made of metal material, designed to be wound around at least one indexed pulley provided with teeth. The endless belt includes, for the one part, locations which are each designed to receive a product to be conveyed and, for the other part, indexing perforations. The manufacturing method includes the following successive steps: a) a step of supplying a flat band made of the metal material, b) a step of closing the band by welding of the transverse edges thereof via a weld seam, and c) a step of perforating the weld seam, at the at least one longitudinal indexing line, in order to form at least one additional indexing perforation that is also designed to engage with the teeth of the at least one indexed pulley.

Embodiments of the disclosure provide an eyelink conveyor belt and sprocket assembly. The eyelink conveyor belt includes a plurality of eyelets, a plurality of reinforcing drive bars having a driving notch and extending adjacent to the plurality of eyelets, and a plurality of cross rods used to couple the reinforcing drive bars and eyelets together. The sprocket includes a generally disk-shaped drive member having a plurality of teeth formed along and extending outwardly from the outer perimeter of the drive member.

Embodiments of the disclosure provide an eyelink conveyor belt and sprocket assembly. The eyelink conveyor belt includes a plurality of eyelets, a plurality of reinforcing drive bars having a driving notch and extending adjacent to the plurality of eyelets, and a plurality of cross rods used to couple the reinforcing drive bars and eyelets together. The sprocket includes a generally disk-shaped drive member having a plurality of teeth formed along and extending outwardly from the outer perimeter of the drive member.

A modular eye link conveyor belt and method of assembling a modular eye link conveyor belt includes (a) welding a plurality of eyelets and bar links to a cross wire having a predetermined module width to form at least one first module row; (b) welding a plurality of eyelets and bar links to a cross wire having a predetermined module width to form at least one second module row; connecting the first module row and the second module row with a cross rod extending through the plurality of eyelets and thereby forming a first module; repeating steps (a) and (b) and forming a second module; and connecting the first module and the second module with a cross rod extending through the plurality of eyelets.

A modular eye link conveyor belt and method of assembling a modular eye link conveyor belt includes (a) welding a plurality of eyelets and bar links to a cross wire having a predetermined module width to form at least one first module row; (b) welding a plurality of eyelets and bar links to a cross wire having a predetermined module width to form at least one second module row; connecting the first module row and the second module row with a cross rod extending through the plurality of eyelets and thereby forming a first module; repeating steps (a) and (b) and forming a second module; and connecting the first module and the second module with a cross rod extending through the plurality of eyelets.

An elongated object guiding device includes an elongated protection guide portion, inner wheels, outer wheels, a first rail surface, a second rail surface, at least one divided portion, and a restriction guide. The outer wheels are located at positions different from those of the inner wheels in the longitudinal direction of the protection guide portion and located farther from the protection guide portion in the width direction than the inner wheels. The divided portion is configured by dividing the first rail surface and the second rail surface. The divided portion allows the inner wheels and the outer wheels to move along a curved portion. The restriction guide limits a range in which at least the inner wheels or the outer wheels moves away from the first rail surface and the second rail surface.

An elongated object guiding device includes an elongated protection guide portion, inner wheels, outer wheels, a first rail surface, a second rail surface, at least one divided portion, and a restriction guide. The outer wheels are located at positions different from those of the inner wheels in the longitudinal direction of the protection guide portion and located farther from the protection guide portion in the width direction than the inner wheels. The divided portion is configured by dividing the first rail surface and the second rail surface. The divided portion allows the inner wheels and the outer wheels to move along a curved portion. The restriction guide limits a range in which at least the inner wheels or the outer wheels moves away from the first rail surface and the second rail surface.