The invention concerns a coupling device (14) for articulated connection of two elements (12) of a device (10) for conveying and/or sorting piece goods, wherein the coupling device (10) connects together an end (24, 26) of each of the two elements (12) pivotably with respect to a rotational axis (20) in a plane to both sides (24, 26), and the two ends (24, 26) lie diametrically opposite each other in a neutral position.

It is provided that the coupling device (14) is configured such that, starting from a respective central axis (28) of the two ends (24, 26), the rotational axis (20) on a pivot movement in the direction of the one side (24) lies on this one side (24) of the central axes (28), and on a pivot movement in the direction of the other side (26) lies on this other side (26) of the respective central axis (28).

The invention furthermore concerns a corresponding device (10) for conveying and/or sorting piece goods.

A freezing spiral net chain structure includes a plurality of chain links successively arranged in a travelling direction of a rail. Transmission teeth are arranged at inner ends of the chain links. Engagement teeth are arranged at two sides of the chain links. The engagement teeth of the adjacent chain links are engaged with each other. Axial holes are disposed between the mutually engaged engagement teeth. Rotary shafts are inserted into the axial holes. A metal piece is connected between outer ends of every two adjacent rotary shafts. The metal piece may bear a load from an outer-end spiral net, and since a coefficient of expansion of metal is smaller than that of plastic, deformation between the adjacent rotary shafts as a result of cold shrinking is reduced. The metal piece is different from the rotary shafts of the plastic spiral conveying net chain in terms of pitch.

Curved magnetic guide for guiding the chain of a conveyor chain along a curvilinear transport direction including a pair of first guide profiles arranged spaced apart and extending in a continuous manner along a respective development direction concentric to the curvilinear transport direction, a support structure for supporting the first guide profiles having a plurality of box-shaped bodies, the box-shaped bodies being arranged in succession one after the other and spaced apart from one another along the curvilinear transport direction, where each of the box-shaped bodies houses at least one magnetic body and has an upper surface and a lower surface opposite one another, where the upper surface is provided with a pair of first constraining projections that are spaced apart and faced with distances between centers substantially equal to the distance between the development directions where the first constraining projections of the plurality of box-shaped bodies define two rows of first constraining projections that extend, spaced apart from one another, along a respective the development direction, where each of the first guide profiles is coupled with the first constraining projections aligned along one of the two rows, where the guide defines a forward guide for guiding the forward branch of the chain, the forward guide having a forward channel adapted for receiving the hinging portions of the links and which is laterally delimited by the first guide profiles of the at least one pair, where the first guide profiles each defines a sliding surface for the plate-shaped portion of the links to slide thereon, and where the magnetic bodies interact with the links to attract the links of the chain with the part of their plate-shaped portions against the sliding surfaces defined by the first guide profiles.

A conveyor belt having a plurality of spaced tractive rods including opposing inner and outer ends, and a support surface transversely disposed with respect to a direction of travel and interconnecting the plurality of spaced tractive rods, wherein at least one of the inner and outer ends of at least some of the plurality of spaced tractive rods includes a cone shaped end portion.

In one embodiment of the present disclosure, a drive chain system (22, 24) for a spiral conveyor belt (34) includes inner (52) and outer (62) drive chains driving the spiral conveyor belt, the inner and outer drive chains each including a plurality of links (70) defined by a plurality of first (72) and second (74) pitches connected by linking pins (84, 86) extending through holes (80, 82) in the pitches, wherein at least a portion of the linking pins of at least one of the inner and outer drive chains are hardened and/or dissimilar linking pins which are harder on an outer surface than other components in the inner and outer drive chains.

There is presented a conveyor belt module for a side flexing modular conveyor belt wherein a width ratio between a longitudinal surface width and a maximum width of eye parts placed centrally along a longitudinal is smaller than a width ratio for eye parts placed on both sides of the centrally placed eye parts. There is furthermore presented a modular conveyor belt, a conveyor belt system, a method for conveying one or more elements and use of modular conveyor belt for conveying one or more elements.

The present disclosure may be embodied as a belt module for a radius or spiral conveyor. The belt module includes first link ends extending in a direction of belt travel. Each first link end has a transverse opening. Second link ends extend in a direction opposite the first link ends and are configured to interdigitate with the first link ends of an adjacent belt module, and each second link end has a transverse opening defined therein. The transverse openings of the first and/or the second link ends are elongated. The belt modules further include a collapsible tab for contacting a frame member. The collapsible tab is located at a first transverse end of the belt module. In some embodiments, the collapsible tab is configured to engage a drive bar. The belt module may further include a guide tooth on a bottom side of the module for engaging a guide.

An active drive spiral conveyor belt system includes a drum configured to rotate about a drum axis, a plurality of modules, a plurality of cross-rods joining together the plurality of modules, and an infeed system. The drum can include a plurality of drive bars, each with a drive member extending therefrom, and spaced an arc length. At least some of the plurality of cross-rods or modules can include a drive end configured to engage with the drive members. The plurality of modules can be configured to be collapsible relative to each other and the plurality of cross-rods. The infeed system can be configured to collapse the spacing between adjacent drive ends prior to transiting into engagement with a cooperating drive member.

The present invention relates to conveyors, comprising at least one circulating conveyor strand (7, 8), wherein the conveyor strand has at least one clamping connection (1), wherein at least one sensor (2) is arranged in the clamping connection (1), a transmitter (3) for wirelessly transmitting data is arranged on the conveyor strand (7, 8), the sensor (2) is connected with the transmitter (3), and a receiver (4) for receiving the data transmitted by the transmitter (3) is provided.

Embodiments of the disclosure are directed to systems and methods for chain wear elongation measurement and drive compensation. In one embodiment, a chain system includes a chain including a plurality of links arranged in a continuous loop and having first measurement values for plurality of links and total chain length, wherein the chain is configured to rotate on a sprocket, and a chain elongation measurement system for counting the plurality of links of the chain and for determining total chain length to determine first chain elongation measurement values.