A conveying system is disclosed. The conveying system may have a first conveying apparatus that conveys a first article to a first location. The conveying system may also have a second conveying apparatus that conveys a second article to a second location. The conveying system may have a frame, a chute connected to the frame, and a third conveying apparatus. The chute may convey the first article received from the first conveying apparatus to a discharge location. The third conveying apparatus, disposed below the chute, may convey the second article received from the second conveying apparatus to the discharge location. The chute may be movable relative to the to the third conveying apparatus, such that the first or second article may be selectively conveyed to the discharge location via the chute or third conveying apparatus, depending on the position of the chute relative to the third conveying apparatus.

A product delivery conduit for an agricultural product hopper assembly includes an inlet segment and an outlet segment. The inlet segment is configured to receive agricultural product from an inlet conduit, the outlet segment is configured to output the agricultural product to a storage area within a hopper of the agricultural product hopper assembly, the outlet segment is configured to be oriented substantially vertically while the agricultural product hopper assembly is in a working position, the inlet segment and the outlet segment are configured to position an outlet of the product delivery conduit above the storage area while the agricultural product hopper assembly is in a non-working position, and the outlet segment is configured to be oriented downwardly while the agricultural product hopper assembly is in the non-working position to enable the agricultural product to flow into the storage area.

A spiral chute having a center column assembly with a first center column segment is disclosed. The center column segment has a plurality of pairs of opposed apertures. The spiral chute also includes a plurality of chute assembly sections, each including a chute support arm, a chute section coupled to the chute support arm, an outer wall support coupled to a distal end of the chute support arms, an outer wall segment coupled to the outer wall supports, and a support arm bolt having a distal end and a proximal end. The distal end of each support arm bolt passes through a corresponding one of the first plurality of opposing apertures and engages a proximal end of the chute support arm such that the proximal end of the chute support arm abuts the first center column segment. A method of constructing a spiral chute is also disclosed.

A modular chute system for providing safe convenient access to an inside cavity of the chute system from a variety of locations to enhance safer serviceability features a chute channel formed from a plurality of chute sections. Each chute section is formed from a plurality of rigid structural panels. An edge flange is disposed on each panel edge encompassing an entire panel outer periphery, and the edge flange of one panel is connected to the edge flange of another structural panel. Upon removal of a structural panel or set of adjacent structural panels, the chute channel is self-supporting and non-collapsing. Chute serviceability, such as replacement of interior liners or panels, can be accomplished by removing panels and replacing liners without entering the chute cavity.

A baling machine may be adapted for use in stacking packages to support binding operations such as strapping, banding or wrapping. A stack of filled packages is accumulated in a chute that is disposed above and in registration with a conveyor, with a baseplate disposed above the conveyor in registration with the chute. The stack of filled packages is released from the chute into a magazine disposed between and in registration with the chute and the baseplate, so that the stack of filled packages rests on the baseplate inside the magazine. The magazine then moves in a conveyor-forward direction to move the stack of filled packages off the baseplate onto a conveyor surface of the conveyor, and the stack of filled packages is released from the magazine to move forward along the conveyor toward a binding machine, such as a strapping machine, banding machine or wrapping machine.

A component supply device includes a storage section, a mounting section, and a component support section. The storage section stores multiple components. The storage section is mounted to the mounting section. The storage section is attachable and detachable in relation to the mounting section. The component support section supports, in a scattered state, multiple components which are discharged from an opening of the storage section which is in a state of being mounted to the mounting section.

A chute assembly for directing cement from a cement truck is disclosed. The chute comprises an elongate chute of generally u-shaped cross section fabricated from UHMWPe and comprising an upper end and a lower end, a plurality of reinforcing rods arranged along a length of and encased within the UHMWPe, one end of each of the rods adjacent the upper end and another end of each of the rods adjacent the lower end, a pair of u-shaped collars, an upper one of the collars adjacent the upper end and a lower one of the collars adjacent the lower end, and a fastener for securing each of the collars to their respective rod ends. A method of fabrication is also disclosed.

A magnetic fastener and wear liner combination for use with material processing equipment for processing aggregate material, where a reverse taper counter bore hole of the wear liner is made to couple and decouple from a magnetic fastener which has a urethane cap, with a urethane cap reverse taper side. The magnetic fasteners are re-useable on replacement liners as the liners need replacement. The attachment and detachment of the magnetic fasteners is made to be simple and secure.

A system for assembling and installing a modular spiral chute includes a base support assembly having a plurality of rear rollers and a slot, where the slot is orientated in the base support assembly to receive a vertically positioned stanchion of the modular spiral chute. The system also includes a removable roller clamp having a front roller and configured to be inserted into the slot to form an aperture in the base support assembly to encircle the stanchion so that when the roller clamp is inserted into the slot the stanchion is rotatably secured vertically within the base support assembly between the plurality of rear rollers and the front roller. In addition, the system includes a caster mounted plate positioned on top of the base support assembly and configured to increase stability of the stanchion when secured within the base support assembly.

A system for assembling and installing a modular spiral chute includes a base support assembly having a plurality of rear rollers and a slot, where the slot is orientated in the base support assembly to receive a vertically positioned stanchion of the modular spiral chute. The system also includes a removable roller clamp having a front roller and configured to be inserted into the slot to form an aperture in the base support assembly to encircle the stanchion so that when the roller clamp is inserted into the slot the stanchion is rotatably secured vertically within the base support assembly between the plurality of rear rollers and the front roller. In addition, the system includes a caster mounted plate positioned on top of the base support assembly and configured to increase stability of the stanchion when secured within the base support assembly.