A conveyor used with a harvester such as a wind rower has a chute at its discharge end with a deflection surface which controls the throw trajectory and thus the throw range of crop being cut. The orientation angle of the deflection surface relatively to the conveyor may be varied as a function of the particular crop throw characteristics to change the throw range of the conveyor as needed to form merged windrows of a particular crop while avoiding windrow widths which are too wide for efficient harvesting.

A compact modular mobile aggregate processing system configured with no stand-alone inter-plant conveyors for decreasing the footprint of the system and an infinitely adjustable flow diverter(s) for increasing the control of and variation of output characteristics of the system; the system further including specialized folding conveyors.

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.

A machine for distributing insulation material from a package of compressed insulation material is provided. The machine includes a chute having an inlet end and outlet end. The inlet end is configured to receive the package of compressed insulation material. The chute further has a removable hose hub configured for wrapping with a distribution hose. The removable hose hub is further configured for engagement with opposing flange assemblies such that rotation of the hose hub results in rotation of the flange assemblies. A lower unit is configured to receive the compressed insulation material exiting the outlet end of the chute. The lower unit includes a plurality of shredders and a discharge mechanism. The discharge mechanism is configured to discharge conditioned insulation material into an airstream.

Biomass (e.g., plant biomass, animal biomass, and municipal waste biomass) is processed to produce useful intermediates and products, such as energy, fuels, foods or materials. For example, systems and methods are described that can be used to treat feedstock materials, such as cellulosic and/or lignocellulosic materials, while cooling equipment and the biomass to prevent overheating and possible distortion and/or degradation. The biomass is conveyed by a conveyor, which conveys the biomass under an electron beam from an electron beam accelerator. The conveyor can be cooled with cooling fluid. The conveyor can also vibrate to facilitate exposure to the electron beam. The conveyor can be configured as a trough that can be optionally cooled.

A flow-through discharge assembly having a rotatable tube section and an opening through which product is discharged and a positioning apparatus for rotating the tube section between operation and non-operational conditions. When the tube is positioned in an operational orientation, grain exits through the opening for discharge from the assembly. When the tube is returned to a non-operational condition, the tube opening is blocked and grain is prevented from exiting through the opening. The tube opening may be a single elongated opening or may include multiple tube openings through which product is discharged. A method of using a rotary discharge assembly to control grain flow within a grain handling system is also disclosed.

A valve for controlling the flow of a solid material from an opening includes a gate having a first face adjacent the opening, a second face opposite the first, and an orifice. A support is disposed adjacent the second face of the gate and is configured so that the gate can move relative to the support from a first position permitting the material to flow from the opening through the orifice and a second position preventing the material from flowing through the opening. The support is movable in a direction substantially orthogonal to the first direction so that the distance from the first face to the opening can be varied.

Some examples described herein include a flexible hopper for a conveyor system. The flexible hopper may include a hopper weldment attached to a frame of the conveyor, wherein the hopper weldment surrounds a charge end of the conveyor, a flexible frame configured to enable an opening of the flexible hopper to expand or contract, and/or a skirt attached to the flexible frame and configured to form an enclosure between the flexible frame and the hopper weldment.

Some examples described herein include a flexible hopper for a conveyor system. The flexible hopper may include a hopper weldment attached to a frame of the conveyor, wherein the hopper weldment surrounds a charge end of the conveyor, a flexible frame configured to enable an opening of the flexible hopper to expand or contract, and/or a skirt attached to the flexible frame and configured to form an enclosure between the flexible frame and the hopper weldment.

A fully adjustable aggregate hopper system, comprising: a hopper box, the hopper box formed from a pair of opposed side panels each having an attached back panel, with the back panels overlapping each other and having a width adjustment mechanism located at each end of the hopper box; and a plurality of legs attached to the hopper box, each leg having a height adjustment mechanism to independently adjust height for each leg.