A modular spiral belt constructed of a series of hingedly interconnected belt modules arranged in a helical stack. The modular spiral belt includes outer side plates, inner side plates and intermediate attachment members. The intermediate attachment members provide support for the conveyor belt to prevent sagging in an intermediate region.

A spiral conveyor system with a positive drive system includes a rotating drum with at least one rib that is attached to drum. The rib includes a drive face for engaging a conveyor belt. The height of the rib above of the surface of the drum varies along a length of the drive element. The rib may be directly attached to the drum or may be a part of a drive element attached to the drum. The conveyor belt includes at least one belt surface configured to engage the at least one drive face, such as a protruding tab with a flat surface.

A commercial-scale sous-vide system (10) includes a conveyor (20) for carrying food products (FP) vacuum sealed in plastic food-grade pouch or container (222) through a chamber (40) heated with saturated steam. The conveyor is in the form of first and second spiral stacks (26) and (28). A control system controls the steam supply and the movement of the conveyor.

An automated tensioning system is provided for a conveyor with an endless traction element that travels around an adjustably mounted pulley or sprocket. The tensioning system includes a spring housing with a lead screw/drive shaft assembly located therein that has a pushing face that extends out of one housing end. A spring compression plate is threadingly engaged with the lead screw. A plate indicator is located on the spring compression plate. A tensioner spring is located between the tensioner spring support provided by a first housing end and the spring compression plate. A sensor is located on the spring housing that is configured to detect a position of the plate indicator. A driven wheel, rotationally engaged with the drive shaft and axially slideable thereon, is driven by a motor that is controlled by a controller configured to receive position data from the position sensor/drive shaft assembly and to actuate the motor to drive the driven wheel and rotate the lead screw and advance or retract the face so that a desired tension is maintained.

An automated tensioning system is provided for a conveyor. The tensioning system includes a spring housing with a lead screw/drive shaft assembly located therein that has a pushing face that extends out of one housing end. A spring compression plate is threadingly engaged with the lead screw. A plate indicator is located on the spring compression plate. A tensioner spring is located between the tensioner spring support provided by a first housing end and the spring compression plate. A sensor is located on the spring housing that is configured to detect a position of the plate indicator. A driven wheel, rotationally engaged with the drive shaft and axially slideable thereon, is driven by a motor to drive the driven wheel and rotate the lead screw and advance or retract the face so that a desired tension is maintained.

A commercial-scale sous-vide system (10) includes a conveyor (20) for carrying food products (FP) vacuum sealed in plastic food-grade pouch or container (222) through a chamber (40) heated with saturated steam. The conveyor is in the form of first and second spiral stacks (26) and (28). A control system controls the steam supply and the movement of the conveyor.

A spiral conveyor system may include a cage associated with a motor; a conveyor belt traveling helically about the cage; the cage including a plurality of drive elements formed of vertically oriented cage bars; a cage bar cap mounted on at least one of the cage bars; the cage bar cap including a vertically oriented rib extending radially from a surface of the cage bar cap; wherein the rib includes at least one drive face; wherein the conveyor belt includes at least one belt surface configured to engage the at least one drive face; wherein the cage includes a ring that extends between the terminus of the rib and the entrance end of the cage; wherein the surface of the cage bar cap from which the rib extends defines a first diameter; and wherein the ring has a ring diameter that is larger than the first diameter.

The present disclosure relates to a drive bar apparatus for use in a helical conveyor system. In one embodiment, the drive bar apparatus includes at least one tapered drive bar configured to be mounted to a central drum of the helical conveyor system. Each of the at least one tapered drive bars includes a tapered tip having a conical outer surface for urging protrusions extending from conveyor belting to be engaged by the central drum to a first side or a second side of the at least one tapered drive bar. Each of the at least one tapered drive bars further includes a bar portion extending from the tapered tip and having a varying height which increases from the tapered tip to enable the bar portion to progressively increase engagement with the protrusions as the conveyor belting moves up the central drum.

A transport device for conveying a flowable material, comprises a screw conveyor for collecting the fluid from a collecting zone and transporting the fluid to a destination zone. The screw conveyor comprises a spiral which is wound around a shaft extending along a longitudinal axis and an outer casing which at least partly houses the spiral. The spiral has a plurality of turns. The outer casing has an inner surface facing respective head surfaces of at least some turns. Between two consecutive turns and the outer casing there is a compartment. The outer casing is made at least partly from a deformable polymeric material in such a way that the outer casing deforms radially and reversibly towards the outside when a solid particle of the flowable material conveyed by the spiral is interposed between a head surface of one turn and the inner surface of the outer casing, to allow the solid particle to be transferred from one compartment to a further compartment adjacent to said compartment passing between the head surface of the turn and the inner surface of the outer casing.

Provided is a conveyor belt link, of the type used in endless conveyor belts assembled from a plurality of such modular conveyor belt links, where the modular conveyor belt link has a main body extending in the modular belt link's width direction, and where a plurality of eye parts extend forwards and rearwards from the main body, the eye parts being spaced in the width direction of the modular belt link, where forwards extending eye parts are offset relative to rearwards extending eye parts, such that when two modular conveyor belt links are pushed together the eye parts on one link will inter-fit between eye parts on the other modular belt link, wherein the modular belt link laterally is limited by two sides, and that the outermost eye parts on either side are provided with a cutout, such that the width of the modular conveyor belt link is smaller in the cutout than outside the cutout.