A raw material feed hopper according to the present embodiment may include a hollow tube having a raw material accommodating space formed therein, a supporter supporting the hollow tube, a cone accommodated in the raw material accommodating space so as to be able to lift up and down, a rod connected to the cone, a connector connected to an upper portion of the rod, a lifting rod connected to the connector, and an elevator installed on the supporter for lifting up and down the lifting rod.

An inertable container (10) for transporting an additive manufacturing powder comprises an inertable volume (12) and a main opening (14) granting access to the inside of this inertable volume, the inertable volume (12) comprising an upper portion (16) and a lower portion (18), the main opening (14) being located in the lower portion (18) of the inertable volume, and the section (S12) of the inertable volume (12) increasing gradually over at least part of the height (H10) of the container (10) and from the lower portion (18) towards the upper portion (16) of the inertable volume. The main opening is equipped with a passive half-valve (20) allowing this main opening (14) to be closed in such a way as to be sealed in an airtight and humidity-proof manner. The container comprises at least two inerting tappings.

An inertable container (10) for transporting an additive manufacturing powder comprises an inertable volume (12) and a main opening (14) granting access to the inside of this inertable volume, the inertable volume (12) comprising an upper portion (16) and a lower portion (18), the main opening (14) being located in the lower portion (18) of the inertable volume, and the section (S12) of the inertable volume (12) increasing gradually over at least part of the height (H10) of the container (10) and from the lower portion (18) towards the upper portion (16) of the inertable volume. The main opening is equipped with a passive half-valve (20) allowing this main opening (14) to be closed in such a way as to be sealed in an airtight and humidity-proof manner. The container comprises at least two inerting tappings.

A method for controlling a material flow rate from a metering system, includes determining, via a controller, a change in weight of material in a storage tank. The method further includes determining, via the controller, a swept area of an agricultural implement associated with the change in weight based at least in part on a width of the agricultural implement and a change in position of the agricultural implement. Further, the agricultural implement is configured to receive the material from the storage tank. The method also includes determining, via the controller, a calibration of the metering system based at least in part on the change in weight and the swept area. In addition, the method includes controlling, via the controller, a rotation rate of a meter roller of the metering system based at least in part on the calibration to control the material flow rate.

A method for controlling a material flow rate from a metering system, includes determining, via a controller, a change in weight of material in a storage tank. The method further includes determining, via the controller, a swept area of an agricultural implement associated with the change in weight based at least in part on a width of the agricultural implement and a change in position of the agricultural implement. Further, the agricultural implement is configured to receive the material from the storage tank. The method also includes determining, via the controller, a calibration of the metering system based at least in part on the change in weight and the swept area. In addition, the method includes controlling, via the controller, a rotation rate of a meter roller of the metering system based at least in part on the calibration to control the material flow rate.

Granular material flows out through the discharge opening of a silo and through a sealed housing to a target location. A vent opening in a top portion of the silo has a vent cover operative to selectively open and close the vent opening. When the vent cover is closed, air movement into an upper portion of the silo is prevented. A gate is operative to control a flow of granular material through the discharge opening. A vacuum conduit has a lower input end thereof connected to an interior of the housing, and an upper output end thereof located in an upper portion of an interior of the silo. Material flowing out of the silo creates a vacuum drawing dust from the housing up the vacuum conduit into the silo.

Granular material flows out through the discharge opening of a silo and through a sealed housing to a target location. A vent opening in a top portion of the silo has a vent cover operative to selectively open and close the vent opening. When the vent cover is closed, air movement into an upper portion of the silo is prevented. A gate is operative to control a flow of granular material through the discharge opening. A vacuum conduit has a lower input end thereof connected to an interior of the housing, and an upper output end thereof located in an upper portion of an interior of the silo. Material flowing out of the silo creates a vacuum drawing dust from the housing up the vacuum conduit into the silo.

A tilt-less liner apparatus and system for unloading bulk cargo from a container liner using a first layer on the container liner floor having a friction reducing top layer and a friction enhancing bottom layer to secure first layer against movement. A second layer of flexible high strength material folded in over lapping multiple pre-folded sections from at least two to eight folded stacked layers are used to cover the friction reducing top first layer. The second layer is connected to a coiling means and motor for coiling up and removing the second layer from the container over the friction reducing top layer of the first layer and the bulk cargo comes out with the second layer into a hopper provided with means for bulk product distribution. Vibrators, depth measuring devices and speed controls are provided to control bulk cargo unloading and prevent blockage build up.

A tilt-less liner apparatus and system for unloading bulk cargo from a container liner using a first layer on the container liner floor having a friction reducing top layer and a friction enhancing bottom layer to secure first layer against movement. A second layer of flexible high strength material folded in over lapping multiple pre-folded sections from at least two to eight folded stacked layers are used to cover the friction reducing top first layer. The second layer is connected to a coiling means and motor for coiling up and removing the second layer from the container over the friction reducing top layer of the first layer and the bulk cargo comes out with the second layer into a hopper provided with means for bulk product distribution. Vibrators, depth measuring devices and speed controls are provided to control bulk cargo unloading and prevent blockage build up.

In accordance with presently disclosed embodiments, a collapsible and optionally stackable storage container for bulk material is provided. The disclosed storage container includes a collapsible frame defined by a rigid upper support structure, a rigid lower support structure and a support member coupled at one end to the upper support structure and coupled at another end to the lower support structure. An actuator is also provided which is coupled to the support member at one end. The disclosed storage container further includes a storage sack having an upper portion coupled to the upper support structure and a lower portion coupled to the lower support structure. The lower portion of the storage sack is generally taper-shaped and may be equipped with a discharge opening that enables release of the bulk material onto a conveyor, which may be employed when the collapsible storage container is integrated into a bulk storage system.