Method for transporting pellets of a glass fibre reinforced thermoplastic polymer composition from a loading position to an unloading position, said pellets comprising a core and a thermoplastic polymer sheath surrounding said core, wherein the core comprises glass fibres extending in a longitudinal direction of the pellets and an impregnating agent, the method comprising loading pellets onto a non-vibrating belt conveyor at said loading position, conveying the pellets by means of said non-vibrating belt convey—or to said unloading position and unloading the pellets from said non-vibrating belt conveyor at said unloading position. Further methods are claimed as regards a process for manufacturing pellets of a glass fibre reinforced thermoplastic polymer composition and a process for the manufacture at a moulding position of a moulded product from pellets of a glass fibre reinforced thermoplastic polymer composition.

A conveyor system includes a looped belt and a conveying portion cover. The belt has a conveying portion and a retreating portion movable through the conveyor system, each of the conveying portion and the retreating portion having an interior surface and an exterior surface, the exterior surface of the conveying portion configured to convey materials. The conveying portion of the belt is disposed within the conveying portion cover, the retreating portion of the belt disposed exteriorly of the conveying portion cover, and the conveying portion cover has a convex sliding surface and a tubular shape. The interior surface of the conveying portion of the belt is slidable along the sliding surface of the conveying portion cover.

A conveyor system includes a looped belt and a conveying portion cover. The belt has a conveying portion and a retreating portion movable through the conveyor system, each of the conveying portion and the retreating portion having an interior surface and an exterior surface, the exterior surface of the conveying portion configured to convey materials. The conveying portion of the belt is disposed within the conveying portion cover, the retreating portion of the belt disposed exteriorly of the conveying portion cover, and the conveying portion cover has a convex sliding surface and a tubular shape. The interior surface of the conveying portion of the belt is slidable along the sliding surface of the conveying portion cover.

A conveyor system, at least a portion of which may traverse a continuous slope sufficiently steep such that tensile forces associated with overcoming the effects of the slope are several times larger per unit length of run than tensile forces per unit length of run due to main frictional resistance of the conveyor system, may include a belt-on-belt drive. The belt-on-belt drive may include at least one internal belt configured to operably engage the carry belt of the conveyor system so as to frictionally drive the carry belt over at least a one-third length of the sloped run. At the portion of the external belt driven by the at least one internal belt, the rate of tension change in the external belt may be configured to be approximately zero or a modest rise. In some embodiments, the longitudinal stiffness of the at least one internal belt may be substantially greater than the external belt's longitudinal stiffness.

A conveyor system, at least a portion of which may traverse a continuous slope sufficiently steep such that tensile forces associated with overcoming the effects of the slope are several times larger per unit length of run than tensile forces per unit length of run due to main frictional resistance of the conveyor system, may include a belt-on-belt drive. The belt-on-belt drive may include at least one internal belt configured to operably engage the carry belt of the conveyor system so as to frictionally drive the carry belt over at least a one-third length of the sloped run. At the portion of the external belt driven by the at least one internal belt, the rate of tension change in the external belt may be configured to be approximately zero or a modest rise. In some embodiments, the longitudinal stiffness of the at least one internal belt may be substantially greater than the external belt's longitudinal stiffness.

The present invention provides a rail conveyor system of the type having a rail track (9) including a delivery run (1) extending between a loading end (5) and a discharge end (6) and a return run (12) extending from the discharge end (6) to the loading end (5), a plurality of carriages (8) spaced apart from one another and arranged to run on wheels (24) supported by the track (9), and a continuous carry belt (10) supported by the carriages (8); wherein, at least at the discharge end (6), the carriages (8) are turned around to return to the loading end (5) by being entrained around only one or more vertical turnover wheels (7) arranged such that the carriages (7) are delivered to the return run (12) beneath the delivery run (1).

The present invention provides a rail conveyor system of the type having a rail track (9) including a delivery run (1) extending between a loading end (5) and a discharge end (6) and a return run (12) extending from the discharge end (6) to the loading end (5), a plurality of carriages (8) spaced apart from one another and arranged to run on wheels (24) supported by the track (9), and a continuous carry belt (10) supported by the carriages (8); wherein, at least at the discharge end (6), the carriages (8) are turned around to return to the loading end (5) by being entrained around only one or more vertical turnover wheels (7) arranged such that the carriages (7) are delivered to the return run (12) beneath the delivery run (1).

A continuous mining machine trailing conveyor system providing a sandwich belt system that incorporates a set of hugging modalities to ensure that the sandwich belt system provides sufficient friction.

A continuous mining machine trailing conveyor system providing a sandwich belt system that incorporates a set of hugging modalities to ensure that the sandwich belt system provides sufficient friction.

A conveyor belt (13A) includes a main body rubber (14) which extends in a belt longitudinal direction L and a loop coil (15A) which is embedded in the main body rubber (14) and has an annular shape in a plan view when viewed in belt thickness direction, in which the loop coil (15A) includes a plurality of wire portions (151) which are disposed in a direction which annularly extends in the plan view and in which end portions are joined to each other via a joining portion (152), a pair of longitudinal portion (15a and 15a) which extend in the belt longitudinal direction (L), and a pair of width portions (15b and 15b) which extend in a belt width direction, and a plurality of joining portions (152) are disposed in the direction which annularly extends in the plan view, and the number of the joining portions disposed in the longitudinal portion (15a) of the loop coil (15A) is greater than the number of the joining portions disposed in the width portion (15b) of the loop coil (15A).