A bolt supply device includes a conveyor, a bolt absorbing portion, a bolt storage portion, and an allocation portion. The conveyor is an endless belt and is provided to circulate between a first height and a second height above the first height. The bolt absorbing portion protrudes on an outer surface of a ring formed by the conveyor and is configured to absorb a bolt. The bolt storage portion is provided in a region where the bolt absorbing portion ascends, the region located at the first height. The allocation portion is configured to swing to drop the bolt in either one of both width directions of the conveyor at the second height, the bolt absorbed by the bolt absorbing portion in the bolt storage portion.

A bolt supply device includes a slide plate inclined to a vertical direction; and a groove portion formed in the slide plate and having a width that allows passing of a screw portion of a bolt and prevents passing of a flange portion of the bolt. The groove portion includes a first groove configured such that an angle formed between a line extending in an up-down direction along the slide plate and the first groove is a first angle; and a second groove connected to a lower end of the first groove and configured such that an angle formed between the line extending in the up-down direction along the slide plate and the second groove is a second angle smaller than the first angle. The bolt take-out portion is set in the groove portion at a lower end or below the lower end of the second groove.

A separation device has a conveying channel configuration and a transport belt configuration. A conveying material can be conveyed via the conveying channel configuration on the transport belt configuration, the conveying channel configuration has differently inclined regions, and a speed cascade of the conveyed material stream can be achieved by the differently inclined regions. The separation of the conveyed material stream is improved in that the conveying channel configuration has at least one wedge groove.

The present invention relates to a transfer chute (100) for granular material, comprising a chute body defining a flow pathway (120) for granular material, a raised portion (110) having an inclined surface (111), and a splitter member (130) arranged proximal to the raised portion (110) for, in use, dividing a flow of granular material over the raised portion into first portion in first conduit (100) and a second portion in a second conduit (300). In some embodiments, a channel (150) is disposed between the first and second conduits (100; 300) to transpose a vertical arrangement of first and second portions of granular material within the chute (10). In this way, separation by particle size or density in the flow may be reversed.

Embodiments herein describe a decline station for moving items between two structures at different heights. In one embodiment, the decline station includes a receiving ramp which receives an item from the first, upper structure. The receiving ramp is aligned with a pivot ramp so that items can be transferred from the receiving ramp onto the pivot ramp. The pivot ramp includes at least two positions: a receiving position where the pivot ramp is coplanar with the receiving ramp and a discharge position where the pivot ramp is aligned with another, lower ramp in the statione.g., another pivot ramp or a discharge ramp. The item is transferred between ramps until it is eventually discharged onto a second, lower structure.

Embodiments herein describe a decline station for moving items between two structures at different heights. In one embodiment, the decline station includes a receiving ramp which receives an item from the first, upper structure. The receiving ramp is aligned with a pivot ramp so that items can be transferred from the receiving ramp onto the pivot ramp. The pivot ramp includes at least two positions: a receiving position where the pivot ramp is coplanar with the receiving ramp and a discharge position where the pivot ramp is aligned with another, lower ramp in the statione.g., another pivot ramp or a discharge ramp. The item is transferred between ramps until it is eventually discharged onto a second, lower structure.

A wear resistant funnel sheet element for a material guide chute includes first and second edges located at a tapered angle from each other. Interlinking fastening features are provided in order to mate the respective edges of at least one of the wear resistant funnel sheets to form a funnel element. The sheet element may be a molded flat piece of a rubber material, which serves as an interchangeable wear part on a material guide chute.

Described are systems, methods, and apparatus for managing the movement of inventory items within a materials handling facility using rollable containers and a gravity feed conveyance system. Inventory items are placed in the rollable containers and are routed to different locations within the materials handling facility along the gravity feed conveyance system, through use of gravitational forces that cause the rollable containers to roll. By using gravity to route inventory items within the materials handling facility, the energy and power requirements for the materials handling facility are reduced, which reduces overhead costs and which is better for the environment.

An apparatus for vertical transfer of whole nuts from a first elevation to a second, lower elevation includes a run extending between an entrance and an exit, and having a plurality of alternatingly arranged conveying panels between the entrance and the exit. Each conveying panel is inclined to horizontal and has a variable effective conveying width. The apparatus further includes arcuate turn-arounds disposed between respective conveying panels to facilitate transferring the nuts from one conveying panel to the next lower conveying panel. The variable effective conveying width is selected based on a predetermined mass flow rate of nuts such that whole nuts move along the run in a continuous stream without tumbling, and wherein each nut is in contact with adjacent nuts in its respective layer.

Device for merging at least two piece goods streams arranged at different heights, with an upper feed channel for receiving packages from an upper piece goods stream, and a lower feed channel for receiving packages from a lower piece goods stream, the feed channels extending between a first vertical plane and a parallel second vertical plane, whose distance from each other corresponds to a total channel width, the upper feed channel having a first conveying surface between a first side panel running in the first vertical plane, and a second side panel, the second side panel running in the second vertical plane at least on an upstream-side final section, and a second conveying surface, which downstream joins the first conveying surface adjacent to a third side panel running in the first vertical plane and has a width, which is less than half the total channel width, wherein the second conveying surface loosely ends on a side panel running parallel to the first vertical plane at a vertical distance above the lower feed channel, the lower feed channel having a third conveying surface, which is bordered by a fourth side panel running in the second vertical plane and by a fifth side panel, wherein a width of the third conveying surface at a downstream-side end of the lower feed channel corresponds to the total channel width less the width of the second conveying surface.