A sediment capping system is adapted to create, and distribute, a homogenized mixture of capping material. Where distributing the capping material, the system is configured to militate against the capping material forming clumps of a size and weight that would disturb the sediment on a bottom of a body of water. This in turn militates against the sediment being disturbed, and a disturbing of pollutants and toxins into the water surrounding the sediment. The sediment capping system militates against the clumping of capping material through a vibrating spreader and baffle system, producing a sediment cap with a more consistent depth that will minimally disturb the sediment on the floor of the body of water where the sediment cap is being deposited.

A method and apparatus to facilitate the loading of a grain bin such that the level in the grain bin increases generally uniformly and the distribution of grain size in the grain bin is generally uniform as well. The method includes redirecting the flow of the grain from the conveyer as it flows into the grain bin. In one embodiment, the apparatus includes an adjustable leveling band for redirecting the grain uniformly to a plurality of radially extending chutes. In one embodiment, the angle of the chutes can also be easily adjusted.

The disclosure relates to a method for producing a wooden composite material board, in particular an MDF or HDF board, wherein a cake made of wood chips or wood fibres wetted with a binder is spread, which is subsequently pressed in a hot press to form a board of a desired thickness, wherein, before the pressing, a mixed powder made of colour pigments and a second binder is spread onto an upper side of the cake as a primer, wherein the cake is sprayed with water after the spreading of the mixed powder.

The invention relates to a machine for handling waste material, the machine comprising an upper conveyor member with a conveying portion of a first width, a downstream lower conveyor member with a receiving portion of equal or greater width and an apparatus for distributing material from the upper conveyor member to the downstream lower conveyor member, wherein the apparatus comprises oscillating means, a drive mechanism connected to the oscillating means; and a protruding element attached to the oscillating means for oscillatory movement thereof, wherein the protruding element is a reciprocating attachment adapted to oscillate in a direction transverse to the direction in which it extends, wherein the apparatus is mountable between the conveying portion of the upper conveyor member and the receiving portion of the downstream lower conveyor member such that the protruding element extends substantially in the direction of conveyance of the downstream conveyor member; and wherein in use the osciallating protruding element agitates material being transferred from the upper conveyor member to the downstream lower conveyor member.

A storage module is provided for an organic material handling system. The storage module has a levelling component for levelling out the organic material stored therein, and a removal component for discharging the organic material. A modular system and method is described for improving the receiving, processing, storing, and transloading of bulk materials such as organic waste. A system includes at least a receiving module to receive material, a storage module, a discharge module, and a control system. Systems can be adapted with additional modules, such as processing modules and transfer modules, depending on the site and materials to be handled. A control system interfaces with the modular components and local operators, and provides remote reporting and monitoring.

A grain management system includes a robot and a computer system located remotely from one another and configured to wirelessly communicate. The robot comprises an auger-based drive system, a memory, and a processor which controls movement of the robot, via the drive system, relative to grain in a bulk store. During a load-in the robot traverses a landing zone portion, where the grain lands during load-in, of a surface of a pile of the grain to disperse broken grain and foreign material away from the landing zone portion. The dispersal is effected in part by rotation of augers of the drive system. The robot additionally traverses a sloped portion of the pile of grain to incite sediment gravity flow by rotation of the augers. The sediment gravity flow reduces a slope of the sloped portion and further disperses the broken grain and foreign material away from the landing zone portion.

The invention relates to a machine for handling waste material, the machine comprising an upper conveyor member with a conveying portion of a first width, a downstream lower conveyor member with a receiving portion of equal or greater width and an apparatus for distributing material from the upper conveyor member to the downstream lower conveyor member, wherein the apparatus comprises oscillating means, a drive mechanism connected to the oscillating means; and a protruding element attached to the oscillating means for oscillatory movement thereof, wherein the protruding element is a reciprocating attachment adapted to oscillate in a direction transverse to the direction in which it extends, wherein the apparatus is mountable between the conveying portion of the upper conveyor member and the receiving portion of the downstream lower conveyor member such that the protruding element extends substantially in the direction of conveyance of the downstream conveyor member; and wherein in use the oscillating protruding element agitates material being transferred from the upper conveyor member to the downstream lower conveyor member.

An overhead material handling system is provided. The system comprises a leveler having a cover defining an interior, and a screw having a shaft and a screw portion positioned within the cover interior. The system further comprises a lift structure comprising a plurality of hydraulic stabilizing legs, the lift structure being connected to the leveler wherein the plurality of hydraulic legs extend and retract to raise and lower the lift structure, at least one sensor, and a safety mechanism comprising at least one extension off of an end of the leveler.

A method and a device for loading a material in layers, in which a first fraction of the material intended to form a first layer is fed to a belt conveyor located above a loading zone, tilting the conveyor about its longitudinal axis such that the entire first fraction is poured into a receiving zone in a receptacle to form a first layer, feeding a subsequent fraction of the material intended to form a subsequent layer to the conveyor, and then tilting the conveyor about its longitudinal axis such that the entire subsequent layer is poured onto the receiving zone to thereby form the subsequent layer.

A flume for supplying vegetable pieces in a supply of liquid, the flume extending between a flume inlet and a flume outlet, the flume comprising: a gulley section having an upstream inlet end at the flume inlet and a downstream outlet end, the gulley section having opposed sidewalls and a gulley floor therebetween, and a spreader section having opposed first and second lateral walls and a spreader floor therebetween, the spreader section having an upstream end connected to the downstream outlet end of the gulley section, the spreader section progressively increasing in width between the opposed first and second lateral walls in a downstream direction from the upstream end to a downstream end of the spreader section, wherein the opposed first and second lateral walls are each outwardly inclined away from a longitudinal axis of the spreader section by a respective angle α° for the first lateral wall and β° for the second lateral wall, in respective opposite directions, which extends from the upstream end of the spreader section to the downstream end of the spreader section, wherein the gulley section has a width of the gulley floor at the downstream outlet end of W1, the length of the spreader section between the upstream and downstream ends of the spreader section is N, and the dimensionless ratio N/W1 is within the range of from 2 to 15, and wherein the sum of α° and β° is from 10 to 25°.