A conveyor belt (36) is arranged in at least one spiral conveyor unit (32) or (34) is arranged in tiers forming at ascending spiral stack (38) and/or a descending spiral stack (40). A ceiling or top sheet (58) is positioned over the spiral stack. A circulation fan (60, 62) draws spent thermal processing medium laterally from the tiers of the spiral stack, up the exterior of the stack and across the top of the stack above the ceiling or top sheet and through a heat exchanger (64) located above the ceiling. The treated thermal processing medium is then routed across the remainder of the diameter of the spiral stack and then down the side of the spiral stack diametrically opposite to the circulating fan thereby to enter the spiral stack in a lateral direction diametrically toward the circulating fan. At least one opening (70, 100, 200) is formed in the ceiling between the heat exchanger and the diametrically distal end of the spiral stack from the circulating fan thereby to provide an alternative flow path for a portion of the thermal processing medium to enter the spiral stack from above, thereby resulting in more uniform treatment of the work product being carried by the conveyor of the spiral stack.

A conveyor comprises a helical conveying path having an upright central axis, a frame and an endless conveying member for transporting a product through the conveying path which conveying member is displaceable with respect to the frame. In a central portion of the conveying path, as seen in radial direction from the central axis, the conveying member is provided with an upwardly directed supporting surface for supporting a product. The width of the supporting surface in radial direction from the central axis is smaller than 10% of the distance between the central axis and the supporting surface. At opposite sides of the supporting surface the conveying path is free from obstacles at the height level of the supporting surface. The conveyor is provided with a helical guide for guiding the conveying member along the guide.

A conveyor comprises a helical conveying path having an upright central axis, a frame and an endless conveying member for transporting a product through the conveying path which conveying member is displaceable with respect to the frame. In a central portion of the conveying path, as seen in radial direction from the central axis, the conveying member is provided with an upwardly directed supporting surface for supporting a product. The width of the supporting surface in radial direction from the central axis is smaller than 10% of the distance between the central axis and the supporting surface. At opposite sides of the supporting surface the conveying path is free from obstacles at the height level of the supporting surface. The conveyor is provided with a helical guide for guiding the conveying member along the guide.

An accumulating conveyor comprises a conveyor belt successively follows a first helical track from a lower end thereof in upward direction to a location below an upper end thereof, a first bridge to a location at a second helical track below an upper end thereof, the second helical track in downward direction to a lower end thereof, a first set of auxiliary guides to the upper end of the second helical track, the second helical track in downward direction, a second bridge to the first helical track, the first helical track in upward direction to the upper end thereof, and the second set of auxiliary guides to the lower end of the first helical track. The bridges are synchronously movable along the first and second helical tracks for varying the effective lengths of the conveyor belt.

An accumulating conveyor comprises a conveyor belt successively follows a first helical track from a lower end thereof in upward direction to a location below an upper end thereof, a first bridge to a location at a second helical track below an upper end thereof, the second helical track in downward direction to a lower end thereof, a first set of auxiliary guides to the upper end of the second helical track, the second helical track in downward direction, a second bridge to the first helical track, the first helical track in upward direction to the upper end thereof, and the second set of auxiliary guides to the lower end of the first helical track. The bridges are synchronously movable along the first and second helical tracks for varying the effective lengths of the conveyor belt.

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.

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.

A centrifugal dewatering conveyor system for removing liquid from a conveyed product comprises a modular conveyor belt designed to follow a path that includes both straight portions and helical portions. The modular conveyor belt comprises a plurality of hingedly connected modules having side walls and capable of shifting laterally relative to each other and curling up about the hinge rods to form the helical portions. In the helical portions, a centrifugal force imparted on conveyed product forces water through openings in the conveyor belt.

A centrifugal dewatering conveyor system for removing liquid from a conveyed product comprises a modular conveyor belt designed to follow a path that includes both straight portions and helical portions. The modular conveyor belt comprises a plurality of hingedly connected modules having side walls and capable of shifting laterally relative to each other and curling up about the hinge rods to form the helical portions. In the helical portions, a centrifugal force imparted on conveyed product forces water through openings in the conveyor belt.

Embodiments disclosed herein generally relate to systems and methods for emptying and/or cleaning a tray within in an assembly line grow pod. In one embodiment, a sanitizer component for cleaning a tray coupled to a cart in an assembly line grow pod is disclosed. The sanitizer component is coupled to a track such that the cart and the tray are received in the sanitizer component via the track. The sanitizer component comprises a first actuator arm positioned underneath the track and extendable through an opening in the track and an aperture at a bottom end of the cart to contact the tray such that the tray rotates in a first direction. The sanitizer component further includes an actuator motor coupled to the first actuator arm for extending the first actuator arm and a controller. The controller is communicatively connected to the actuator motor in the sanitizer component.