The present invention relates to a transportation system for transporting products in a transportation direction. The transportation system comprises a conveyor unit for transporting the products in the transportation direction from a first end of the conveyor unit towards a second end of the conveyor unit, and a drive unit for driving the conveyor unit. The drive unit comprises a drive means and a first magnetic clutch component for transmitting torque to the conveyor unit. The conveyor unit comprises a second magnetic clutch component for receiving torque from the drive unit. The transportation system further comprises supporting means which includes first and second supporting elements with the first supporting elements arranged at the drive unit and the second support elements arranged at the conveyor unit, for supporting the conveyor unit such that at least the first magnetic clutch component and the second magnetic clutch component are aligned to each other, and for supporting torque transmitted from the drive unit to the conveyor unit. The present invention further relates to a drive unit as well as a conveyor unit, both adapted for use in a transportation system.

An idler wheel support for a conveyor belt comprises a gear rack adjustment mechanism or for use in adjusting the position of one end portion an idler wheel supporting frame. The gear rack is provided at said one end portion of the frame, such as on a foot, or on a base to which the foot is slidably coupled. A tool comprising a gear is selectively positioned for pivoting on the foot or base that does not have the gear rack with the gear engaged with the gear rack. When so engaged, pivoting the gear shifts said one end portion of the frame and adjusts the angle of the frame relative to the longitudinal conveyor frame axis and adjusts the longitudinal tracking of the conveyor belt. The gear can be mounted on a lever and positioned for pivotal engagement with the gear rack to enable adjustment of the belt tracking while the belt is moving.

The invention employs a folding arm conveyor that rotates horizontally. The folding arm conveyor is mainly composed of an undercarriage mounted on the ground of a stockyard, a tower body mounted on the undercarriage, a balance arm, a conveying arm, a tower top, and other main components, wherein the balance arm, the conveying arm, and the tower top are mounted on the tower body. The conveying arm is provided with two portal frames (I) and (II) and an unloading trolley. The tower body is provided with a gyration apparatus and a hopper. The balance arm is provided with a balance trolley. The folding arm conveyor can rotate horizontally, and the conveying arm can be folded and retraced by controlling the wind rope by the windlass, so that the folding arm conveyor can be prevented from colliding with other devices or buildings during the rotation.

A method 10 of refurbishing a bucket wheel reclaimer (BWR) 41 having structural frame 68, a chute 66 supported by the structural frame 68, a yard conveyor 42 for receiving material from the chute 66 and an impact table 64 supported by the structural frame 68 below a portion of an upper run 44 of the yard conveyor 42. The method includes a step 12 of decoupling a current impact table 64 from the BWR structural frame 68. The impact table 64 is lowered at step 26 from the structural frame 68. Thereafter at step 14 the current impact table is moved laterally away from and to one side of the yard conveyor. At steps 16 and 18 a fresh impact table is moved laterally to a location beneath the upper run 44 of the yard conveyor and coupled to the BWR 41.

A method 10 of refurbishing a bucket wheel reclaimer (BWR) 41 having structural frame 68, a chute 66 supported by the structural frame 68, a yard conveyor 42 for receiving material from the chute 66 and an impact table 64 supported by the structural frame 68 below a portion of an upper run 44 of the yard conveyor 42. The method includes a step 12 of decoupling a current impact table 64 from the BWR structural frame 68. The impact table 64 is lowered at step 26 from the structural frame 68. Thereafter at step 14 the current impact table is moved laterally away from and to one side of the yard conveyor. At steps 16 and 18 a fresh impact table is moved laterally to a location beneath the upper run 44 of the yard conveyor and coupled to the BWR 41.

Described is an apparatus for conveying a product, such as articles of the tissue sector in the form of rolls or packages. The apparatus includes a unit for supporting corresponding unit for conveying the product, in particular following a respective path between a respective upstream end and a respective downstream end; More specifically, the conveying unit have one or a plurality of conveyor belts, especially of the type with links articulated to each other, preferably through corresponding articulation pins; the apparatus has a plurality of separate modules, each of which is designed to define a respective conveying section or stretch or longitudinal extension of the apparatus, the respective modules can be associated with each other and include a plurality of component units of the conveying section or stretch which are in a pre-assembled condition with each other.

Described is an apparatus for conveying a product, such as articles of the tissue sector in the form of rolls or packages. The apparatus includes a unit for supporting corresponding unit for conveying the product, in particular following a respective path between a respective upstream end and a respective downstream end; More specifically, the conveying unit have one or a plurality of conveyor belts, especially of the type with links articulated to each other, preferably through corresponding articulation pins; the apparatus has a plurality of separate modules, each of which is designed to define a respective conveying section or stretch or longitudinal extension of the apparatus, the respective modules can be associated with each other and include a plurality of component units of the conveying section or stretch which are in a pre-assembled condition with each other.

A modular conveyor is assembled from a kit of standard components, said conveyor having a length, width and height, and wherein the conveyor comprises: (a) four end side plates each having an aperture suitable to accommodate a sprocket wheel axle; (b) two sprocket wheel axles wherein at least one axle is suitable to be connected to a drive means, wherein each axle may accommodate one or more sprocket wheels; (c) web elements attachable to one side of the side plates in order to keep pairs of side plates at a determined lateral distance, wherein said web elements further comprise means for supporting an endless conveyor belt; and (d) an endless conveyor belt arranged around the sprocket wheels.

A conveyor employs an infeed assembly and outfeed assembly, each comprising a nosebar assembly that may be mounted to a conveyor frame to transition a conveyor belt between a returnway and a carryway. The outfeed assembly further includes a drive sprocket and a limiter to ensure engagement of drive elements on the conveyor belt with the drive sprockets. A limiter plate ensures proper placement of the limiter relative to the drive sprocket. The infeed assembly and outfeed assembly components may be easily mounted to and removed from the conveyor frame to facilitate replacement, cleaning or maintenance.

A segmented articulating conveyor is provided that is articulable between a straight configuration and an articulated configuration. The segmented articulating conveyor has a plurality of conveyor segments forming a conveyor system. The conveyor segments are pivotally connected to one another to permit manual articulation of the conveyor system between straight and articulated configurations. A belt is operably engaged with the conveyor segments, the belt being configured to accommodate an arc of the conveyor system when in the articulated configuration. A motor is operatively engaged with the belt and configured to move the belt. An associated method is also provided.