A conveyor structure includes a first conveyor structure layer, a core structure layer, and a second conveyor structure layer. The core structure layer is provided on the first conveyor belt structure and includes a rope layer, a plurality of first wefts, a plurality of second wefts and a cloth layer. The rope layer may be provided on the first conveyor structure layer and includes a plurality of warp ropes. The cloth layer may be disposed above the rope layer. The plurality of second wefts and the plurality of first wefts may be obliquely intertwined with each other and wrapped on the rope layer, or on the cloth layer, or on the rope layer and the cloth layer. The second conveyor belt structure layer may be provided on the core structure layer.

Device for conveying piece goods along a conveying path includes a sorting device for sorting piece goods, track profile members extending transversely to a track conveying direction and connected together to form an endless conveyor track with an upper and a lower run. The upper run has a conveyor surface for conveying the piece goods in the track conveying direction. Push shoes are successive along the conveying path and each is displaceable along at least one track profile member of the track profile members so as to constrainedly displace the piece goods laterally on the conveyor surface transversely to the track conveying direction of the endless conveyor track. A drive drives the endless conveyor track in the track conveying direction. Each push shoe includes a guide roller, which is arranged below the upper run and mounted to be rotatable about an axis of rotation extending transversely to the conveyor surface.

Device for conveying piece goods along a conveying path includes a sorting device for sorting piece goods, track profile members extending transversely to a track conveying direction and connected together to form an endless conveyor track with an upper and a lower run. The upper run has a conveyor surface for conveying the piece goods in the track conveying direction. Push shoes are successive along the conveying path and each is displaceable along at least one track profile member of the track profile members so as to constrainedly displace the piece goods laterally on the conveyor surface transversely to the track conveying direction of the endless conveyor track. A drive drives the endless conveyor track in the track conveying direction. Each push shoe includes a guide roller, which is arranged below the upper run and mounted to be rotatable about an axis of rotation extending transversely to the conveyor surface.

An inspection device is provided in which X-rays are radiated in a fan-like shape with respect to an extension direction of steel cords, are transmitted through a conveyor belt, and reach an X-ray line sensor. A control device makes an X-ray generator and the X-ray line sensor move in a fixed relative position at a certain speed within a certain movement range in a direction parallel with a plane and orthogonal to an extension direction of the steel cords. The control device generates two-dimensional image information on the basis of an X-ray transmission signal obtained each time the X-ray generator and the X-ray line sensor move a unit amount equal to a pixel pitch of the X-ray line sensor. The control device detects measurement information relating to the conveyor belt and the steel cords on the basis of the obtained two-dimensional image information.

The present technology provides a conveyor belt. An upper cover rubber and a lower cover rubber are respectively disposed above and below a core layer so as to sandwich the core layer, which core layer is composed of a plurality of steel cords extending side by side in parallel. The outer diameter of the steel cords is not less than 0.35 mm and not greater than 6.0 mm, and the side-by-side pitch P of the steel cords is greater than 0.35 mm and not greater than 7.0 mm. The steel cords are embedded extending in the longitudinal direction of the conveyor belt.

The present technology provides a conveyor belt. An upper cover rubber and a lower cover rubber are respectively disposed above and below a core layer so as to sandwich the core layer, which core layer is composed of a plurality of steel cords extending side by side in parallel. The outer diameter of the steel cords is not less than 0.35 mm and not greater than 6.0 mm, and the side-by-side pitch P of the steel cords is greater than 0.35 mm and not greater than 7.0 mm. The steel cords are embedded extending in the longitudinal direction of the conveyor belt.

A flat belt provides an endless traction suitable for conveyor belts, and has no fabric insert in the force transmission region. In some embodiment it has no fabric insert in the back of the belt. The flat belt is formed by a multistage method which includes forming a flat belt with a main body and endless tension member elements, by a rotary vulcanization process, and subsequently forming at least a part of the force transmission region on the flat belt. The flat belt may be used in agricultural machines which convey agricultural harvested material.

A flat belt provides an endless traction suitable for conveyor belts, and has no fabric insert in the force transmission region. In some embodiment it has no fabric insert in the back of the belt. The flat belt is formed by a multistage method which includes forming a flat belt with a main body and endless tension member elements, by a rotary vulcanization process, and subsequently forming at least a part of the force transmission region on the flat belt. The flat belt may be used in agricultural machines which convey agricultural harvested material.

Synchronous belt systems include two or more sprockets, a first endless belt, and a second endless belt. The belts are connected together with belts attachment hardware through belt ports, and a belts gap is defined between the first endless belt and the second endless belt. Each of the sprockets includes sprocket teeth and sprocket tooth spaces between adjacent teeth of the sprocket teeth, and each of the sprockets has a sprocket center ridge. The belts each include a plurality of belt split teeth, and each split tooth of the plurality of belt split teeth has a first belt ridge, a second belt ridge and a belt split tooth space disposed between the belt ridges. The belts gap engages the sprocket center ridge of each of the sprockets, and each of the belts attachment hardware is disposed within the adjacent belt split tooth spaces of the belts.

Heavy duty conveyor belts (1) having excellent resistance to high temperatures. These conveyor belts (1) can be repeatedly exposed to temperatures of greater than 200 C. or even 250 C. without compromising the strength or reliability of the belt while providing a greatly extended service life. The conveyor belts (1) may also be manufactured in a commercially viable and cost effective manner. The conveyor belts (1) generally include a reinforcement layer (3), a carry cover layer (2) disposed above the reinforcement layer (3), a pulley cover layer (4) disposed beneath the reinforcement layer (3), and the carry cover layer (2) is comprised of a fluoroelastomer. In some aspects, the conveyor belts (1) have a carry cover layer (2) which includes an outer surface layer (6) containing a fluoroelastomer and an inner layer (7) based upon an EPM elastomer or an EPDM elastomer.