A transport system for conveying goods in a conveying direction along a conveyor belt plane of a conveyor belt is provided. On a bearing, oriented along the conveyor belt plane, for bearing the goods and, on a guiding side of the conveyor belt, at least one guide surface, oriented along the conveyor belt plane, for guiding the conveyor belt. The conveyor belt includes a plurality of notches in the guide surface. The notches include a plurality of guide notches to engage at least one guide ridge for guiding the conveyor belt along the conveying direction, wherein a longitudinal axis of each of the guide notches is oriented along the conveying direction, and a number of drive notches for engaging at least one drive ridge for driving the conveyor belt along the conveying direction.

A conveyor system and drive element for same include a chain including a plurality of links that hinge with respect to each other and a plurality of moving elements such as balls that freely move in the links. A drive element drives the chain in a conveying direction and includes an elongated body with a surface that has a plurality of planar facets arranged around the longitudinal axis of the body. The facets extend along the body and engage respective links of the chain as the body is rotated to drive the chain. Relief elements are located in each facet and are configured for receiving the moving elements of the chain links engaging the facets so the links lie generally flat on the facets when the chain is driven. Other versions of the drive element are faceted for driving a chain with links but without relief elements.

A device for guiding a conveyor belt, having a guide unit with an outer and an inner hollow-cylindrical body, the inner hollow-cylindrical body having a first central axis and being arranged in the outer hollow-cylindrical body, which has a second central axis, and both hollow-cylindrical bodies each have a central axis, with at least one bearing for rotatably mounting the outer hollow-cylindrical body on the inner hollow-cylindrical body and with an articulation body designed for mounting the inner hollow-cylindrical body on a central axle, wherein the articulation body is further designed to allow a horizontal and/or vertical change in angle of the first and/or second central axis relative to a central axis of the central axle. In order to increase the service life of the conveyor belt, the device is equipped according to the invention with a measuring and evaluating system including a sensor unit arranged inside and/or outside the guide unit, wherein the measuring and evaluating system is designed to detect the change in angle. The invention is based on the consideration that from a control behavior of the device, the causes of a fault of the belt run can be identified, deduced or narrowed down. Furthermore, a system for monitoring and guiding a conveyor belt using a device according to the invention is described.

A belt driving device includes a plurality of rollers, an endless belt, a contact surface, and a non-contact surface. The rollers include a driving roller that is rotationally driven. The endless belt is stretched between the rollers such that a predetermined tension is applied to the endless belt, and the endless belt protrudes from opposite end portions of the rollers in an axis direction of each of the rollers. The contact surface is formed at a first end portion of at least one of the rollers and comes in contact with the endless belt. The first end portion is located on a meandering direction side of the endless belt. The non-contact surface is formed at each of second end portions of the rollers and doesn't come in contact with the endless belt. The second end portions are located on a side opposite to the meandering direction of the endless belt.

A belt driving device includes a plurality of rollers, an endless belt, a contact surface, and a non-contact surface. The rollers include a driving roller that is rotationally driven. The endless belt is stretched between the rollers such that a predetermined tension is applied to the endless belt, and the endless belt protrudes from opposite end portions of the rollers in an axis direction of each of the rollers. The contact surface is formed at a first end portion of at least one of the rollers and comes in contact with the endless belt. The first end portion is located on a meandering direction side of the endless belt. The non-contact surface is formed at each of second end portions of the rollers and doesn't come in contact with the endless belt. The second end portions are located on a side opposite to the meandering direction of the endless belt.

According to the present invention, a conveyor pulley for use in a belt conveyor is provided, comprising: a roller tube (1); wherein the roller tube (1) is formed by plastically deforming a central portion of a substantially cylindrical metal tube (2) radially outwardly so as to form a crowned portion (4) having an enlarged outer diameter (OD.sub.ENL) with respect to remaining portions (6) of the metal tube (2).

According to the present invention, a conveyor pulley for use in a belt conveyor is provided, comprising: a roller tube (1); wherein the roller tube (1) is formed by plastically deforming a central portion of a substantially cylindrical metal tube (2) radially outwardly so as to form a crowned portion (4) having an enlarged outer diameter (OD.sub.ENL) with respect to remaining portions (6) of the metal tube (2).

A tower lift includes a main frame extending in a vertical direction, a carriage module configured to be movable in the vertical direction along the main frame, a weight module disposed behind the carriage module and configured to be movable in the vertical direction along the main frame, a driving module disposed on the main frame and configured to move the carriage module and the weight module in the vertical direction using at least one timing belt, an auto tensioner disposed on a lower portion of the main frame and connected with the carriage module and the weight module by a balance belt, and an upper alignment unit for aligning a horizontal position of the at least one timing belt.

A belt driving device includes a plurality of rollers, an endless belt, a contact surface, and a non-contact surface. The rollers include a driving roller that is rotationally driven. The endless belt is stretched between the rollers such that a predetermined tension is applied to the endless belt, and the endless belt protrudes from opposite end portions of the rollers in an axis direction of each of the rollers. The contact surface is formed at a first end portion of at least one of the rollers and comes in contact with the endless belt. The first end portion is located on a meandering direction side of the endless belt. The non-contact surface is formed at each of second end portions of the rollers and doesn't come in contact with the endless belt. The second end portions are located on a side opposite to the meandering direction of the endless belt.

Provided is an elastic conveyor belt for a transport system for conveying goods in a conveying direction along a conveyor belt plane of the conveyor belt, the conveyor belt including, on a carrying side of the conveyor belt, a carrying surface which is oriented along the conveyor belt plane and is intended for carrying the goods, and, on a guide side of the conveyor belt, a guide surface which is oriented along the conveyor belt plane and is intended for guiding the conveyor belt, and, in the guide surface, at least one groove for the engagement of a guide element for guiding the conveyor belt along the conveying direction, a longitudinal axis of the groove being oriented along the conveying direction.