A bulk material conveyor include a housing having a first end with an inlet and a second end with a discharge and a conveyor at least partially positioned in the housing and extending from the inlet to the discharge. A support assembly has a base frame and an extension mechanism operably connected to the base frame for positioning the housing into an inclined position. A motor assembly is configured to drive the conveyor for advancing bulk material through the housing. A hopper is disposed at the intake end of the housing and includes a tapered wall section extending downwardly from a first end to a second end adjacent the inlet in the housing. A gate assembly is interposed between the hopper and the housing and includes a door positionable between a closed position and a fully opened position for metering the bulk material directed into the housing at the inlet.

A bucket and a corresponding bucket elevator, the bucket has a bucket wall surrounding a filling and discharge opening and having a rear wall and a front bucket wall, the front bucket wall having a front edge delimiting the filling and discharge opening, and the bucket being connectable to a conveyor device via the rear wall, wherein the ratio between the bucket depth, which corresponds to the horizontal distance between the rear wall and the front edge, and the bucket height, which corresponds to the vertical distance between a bucket low point and the front edge, is greater than 1, preferably greater than 1.3, more preferably greater than 1.5.

A raw material supply device and a device for processing electronic and electrical device part scraps, which can control dropping positions of a raw material containing substances having different shapes and specific gravities, and a method for processing electronic and electrical device part scraps using those devices. The raw material supply device includes a receiving port, a discharge port, a first guide surface, and a second guide surface on a surface opposing to the first guide surface. The processing device includes a first conveying unit, a raw material supply device, a second conveying unit, and a pyramid-shaped disperser. The processing method comprises a sorting step, wherein the sorting step comprises dropping the electronic and electrical device part scraps onto a plurality of dispersion surfaces of a pyramid-shaped disperser, and dispersing the electronic and electrical device part scraps in a plurality of directions on a conveying surface.

A sorting device for packages includes a fifth wheel mounted on a support structure and rotatable around a vertical axis; a conveyor belt mounted on the fifth wheel and able to rotate therewith about the vertical axis; and at least one sliding surface placed below the plane of the conveyor belt, to close the openings which, during the rotation of the fifth wheel and of the conveyor belt around the vertical axis, are created between the sorting device and the conveyor belts adjacent to it.

A deployable bulk material distribution apparatus for discharging from a designated height an amount of a flowable bulk material into a discharge location is provided. In one embodiment, the apparatus comprises an auger section; a bucket elevator section configured so as to be movable between: an upright position; and a reclined position wherein the bucket elevator section is substantially reclined for transport; and a joint assembly coupling the exit aperture of the auger section to the boot inlet of the bucket elevator section so as to allow the flowable bulk material to move from the exit aperture to the boot inlet when the bucket elevator section is in the upright position, the joint assembly being rotatably coupled to the boot inlet. The auger section and container operable to freely move along the bucket elevator section when it is moved between the upright and reclined positions.

An example bulk material dispensing apparatus includes: a frame; a hopper supported in the frame, the hopper configured to contain a bulk material for dispensing by the dispensing apparatus and having a hopper outlet; a feeding unit interconnected with the hopper outlet, the feeding unit configured to receive the bulk material from the hopper outlet and comprising: a feeding tube; and an auger disposed in the feeding tube, the auger configured to rotate to drive the bulk material received from the hopper outlet to be dispensed from a dispensing outlet; and a controller interconnected with the auger, the controller configured to: receive a dispensing request specifying a quantity of bulk material to dispense; and control the auger to rotate to dispense the quantity of bulk material.

The present disclosure relates to a method for vibration feeding of bulk material and a vibration feeder device provided for such purposes, comprising a material feed, a charging hopper including a hopper discharge, a feeder tray, a height adjustment means for adjusting a level height between the hopper discharge and the feeder tray, and a vibration driver for driving the feeder tray at an oscillation amplitude and an oscillation frequency, where a target material throughput and material specific parameters of the bulk material are input, initial parameters for the level height, oscillation amplitude and oscillation frequency are determined from these inputs, and subsequently the level height is adjusted by controlling the height adjustment means.

A conveyor system includes a looped belt and a conveying portion cover. The belt has a conveying portion and a retreating portion movable through the conveyor system, each of the conveying portion and the retreating portion having an interior surface and an exterior surface, the exterior surface of the conveying portion configured to convey materials. The conveying portion of the belt is disposed within the conveying portion cover, the retreating portion of the belt disposed exteriorly of the conveying portion cover, and the conveying portion cover has a convex sliding surface and a tubular shape. The interior surface of the conveying portion of the belt is slidable along the sliding surface of the conveying portion cover.

An unloader for a shipping container includes a supporter having a frame structure and a pallet base supported by the frame structure and configured to receive the pallet and support the shipping container in an elevated position. A gate moving mechanism is supported by the pallet base and configured to engage the moveable gate assembly when the full shipping container is positioned onto the pallet base. A material director has a first end located beneath the pallet base subjacent of the gate moving mechanism. The material director extends downwardly from the pallet base and terminates at a second end opposite the first end. Bulk material is dispensed from the shipping container into the first end and is discharged from the second end of the material director. Shipping containers may be positioned onto and removed from the pallet base without disassembly of the unloader.

A conveying system for pneumatically conveying plastic granulate comprises a feed location, at which the plastic granulate is fed into a conveying line by pressurized conveying gas, a target location, in conveying connection with the feed location, for moisture contained in the conveying gas, and a condensation tempering unit, which is arranged along a section or sections of the conveying line, for making the conveying line such temperature to at least partial condensation of moisture contained in the conveying gas to form a sliding film on an internal wall of the conveying line.