The invention relates to a filling system (1) for a container intended to store solid particles, the system (1) being arranged to cooperate with a supply device for feeding solid particles and comprising a device (5) for distributing the solid particles, which has at least one separator element (9) intended to receive and selectively distribute the solid particles toward a dispensing device (7), the separator element (9) comprising a receiving body (11) for receiving solid particles, one end of which has an axial opening (13) for continuously feeding the dispensing device (7), the dispensing device (7) comprising at least one scattering element (21) for homogeneously filling the container with solid particles, which is driven by a drive shaft passing through the axial opening (13). According to the invention, the receiving body (11) comprises a frustoconical part (11a) which has the axial opening (13) and flares away from the axial opening (13), the frustoconical part (11a) being extended by a tubular part (11b) comprising at least one radial opening (15) which is located upstream of the axial opening (13) and is arranged to direct the solid particles without encountering those exiting the axial opening (13) before arriving in the dispensing device (7) from a predetermined amount of solid particles stored in the frustoconical part (11a) of the receiving body (11) in order to guarantee a minimum flow of solid particles even in the event of variations in the flow rate of the supply device.

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.

The invention relates to a filling system (1) for a container for storing solid particles, comprising a distribution device (5) for solid particles for receiving and selectively distributing the solid particles towards a dispensing device (7), and comprising at least one divider element (11), the dispensing device (7) comprising at least one scattering element (13) for homogeneously filling the container with solid particles, the divider element (11) being rotatably mounted about an axis substantially parallel to the direction of flow of the stream of solid particles in order to allocate any defect in the flow of the solid particles in the distribution device (5).

The invention relates to a filling system (1) for a container for storing solid particles, comprising a distribution device (5) for solid particles for receiving and selectively distributing the solid particles towards a dispensing device (7), and comprising at least one divider element (11), the dispensing device (7) comprising at least one scattering element (13) for homogeneously filling the container with solid particles, the divider element (11) being rotatably mounted about an axis substantially parallel to the direction of flow of the stream of solid particles in order to allocate any defect in the flow of the solid particles in the distribution device (5).

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 grain spreader apparatus is powered in rotation by the flow of grain through the grain spreader apparatus. The gravity grain spreader includes a distribution hopper mounted at the top of a grain storage bin to receive a supply of grain to be distributed within the grain storage bin in a uniform manner. The distribution hopper delivers the grain into a pair of opposingly oriented chutes meeting at an apex underneath the distribution hopper. Each chute is provided with a terminal deflector at the end of the chute, and with intermediate deflectors built into the sides of the chutes to provide a more uniform dispersal of the grain into the grain storage bin. The angle of repose of the chutes is variable through an adjustment mechanism so that higher moisture grains can be fed through the grains spreader apparatus and effectively distributed.

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 grain bin has a top opening with a hopper for receiving grain that is directed downwardly to a spreader supported for rotation by a vertical shaft. The spreader has an elongated inclined chute having a V-shape cross-section. The chute has a center portion having an opening with a trap door pivoted or controlled from a mechanism operable from the top opening of the bin. A deflector is positioned under the trap door opening and rotates the chute in response to the flow of grain through the opening. The chute has an extension that also supports a pivotal deflector.

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.

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.