An exemplary embodiment of the present invention is directed to an apparatus for emptying material from a container on a vehicle. The apparatus has a container with a bottom surface and a sidewall. A membrane being mounted within the container proximate the sidewall and the bottom surface. The apparatus further includes an engine and ducts having a first end and a second end. The first end connected to the engine so as to receive gas from the engine and connected at the second end to the membrane so as to direct the gas into the membrane.

An exemplary embodiment of the present invention is directed to an apparatus for emptying material from a container on a vehicle. The apparatus has a container with a bottom surface and a sidewall. A membrane being mounted within the container proximate the sidewall and the bottom surface. The apparatus further includes an engine and ducts having a first end and a second end. The first end connected to the engine so as to receive gas from the engine and connected at the second end to the membrane so as to direct the gas into the membrane.

A dry-bulk tanker for the provision of binding agents for soil stabilization for a spreading device comprises a storage container (10) for binding agent. A mechanical conveying device (18) for conveying binding agents from the storage container (10) into an intermediate chamber (20) is connected to the storage container (10). A pneumatic conveying device (36) for conveying the binding agent to the spreading device is connected to the intermediate chamber (20). A pressure relief device (40, 41) is connected to the mechanical conveying device in order to avoid the entry of compressed air into the storage container (10). The invention furthermore relates to a conveying system for a dry-bulk tanker and to a work train for working soils with a self-propelled ground working machine and a dry-bulk tanker.

A dry-bulk tanker for the provision of binding agents for soil stabilization for a spreading device comprises a storage container (10) for binding agent. A mechanical conveying device (18) for conveying binding agents from the storage container (10) into an intermediate chamber (20) is connected to the storage container (10). A pneumatic conveying device (36) for conveying the binding agent to the spreading device is connected to the intermediate chamber (20). A pressure relief device (40, 41) is connected to the mechanical conveying device in order to avoid the entry of compressed air into the storage container (10). The invention furthermore relates to a conveying system for a dry-bulk tanker and to a work train for working soils with a self-propelled ground working machine and a dry-bulk tanker.

A material conveying system, comprising: a plurality of material sources for providing material to be transferred; a plurality of destination locations for receiving material from one or more of the plurality of material sources, wherein each destination location has a destination material inlet valve and a destination vacuum valve; a plurality of material conveying tubes; a plurality of vacuum pumps wherein each vacuum pump is operatively connected to one or more of the destination vacuum valves via one or more vacuum source tubes, and wherein each of the vacuum pumps is operatively connected to one or more of the material sources through the one or more vacuum source tubes and respective destination vacuum valves, the one or more destination locations and one or more of the plurality of material conveying tubes; a first sensor disposed on or near each destination vacuum valve; a second sensor disposed on or near each material inlet valve; a third sensor disposed on or near a vacuum outlet of each of the vacuum pumps; a programmable system controller connected, via wires or wirelessly, to each component of the material conveying system including the one or more material sources, the one or more destination locations, the vacuum pumps and to each of the first, second and third sensors; wherein the programmable controller is configured to determine which material sources and destination locations are operatively connected, directly and indirectly, to each of the plurality of vacuum pumps using one or more of the first, second and third sensors.

A material conveying system, comprising: a plurality of material sources for providing material to be transferred; a plurality of destination locations for receiving material from one or more of the plurality of material sources, wherein each destination location has a destination material inlet valve and a destination vacuum valve; a plurality of material conveying tubes; a plurality of vacuum pumps wherein each vacuum pump is operatively connected to one or more of the destination vacuum valves via one or more vacuum source tubes, and wherein each of the vacuum pumps is operatively connected to one or more of the material sources through the one or more vacuum source tubes and respective destination vacuum valves, the one or more destination locations and one or more of the plurality of material conveying tubes; a first sensor disposed on or near each destination vacuum valve; a second sensor disposed on or near each material inlet valve; a third sensor disposed on or near a vacuum outlet of each of the vacuum pumps; a programmable system controller connected, via wires or wirelessly, to each component of the material conveying system including the one or more material sources, the one or more destination locations, the vacuum pumps and to each of the first, second and third sensors; wherein the programmable controller is configured to determine which material sources and destination locations are operatively connected, directly and indirectly, to each of the plurality of vacuum pumps using one or more of the first, second and third sensors.

A distribution ramp system for a dry product applicator with a pneumatic conveyance system is provided which lifts product that drags along a bottom surface(s) of a delivery line's wall(s) back into a main central or primary airflow portion that carries the product downstream through the pneumatic conveyance system. The system may include a ramp that nests against a bottom wall of the delivery line with a narrow front and wide back so the ramp presents a gradual wedge facing toward the incoming upstream airflow entrained with particulate material of the product, urging particulate material dragging on the bottom wall to lift away from the bottom wall and toward reentry into the primary airflow portion.

The invention is a dispensing module for use in delivering measured doses of feed supplement to an animal. It comprises a storage container for holding the supplement and a metering module that is rotatably connected to the storage container for dispensing a measured (pre-determined) dose of the supplement. The dispensing module is adapted to be moved between an open configuration and a closed configuration. In the open configuration, the measured dose of the supplement is able to be dispensed out of the dispensing module. In the closed configuration, the measured dose of the supplement is prevented from being be dispensed out of the dispensing module. Compressed air can be used to send the dose to an outlet when the dispensing module is closed.

The invention is a dispensing module for use in delivering measured doses of feed supplement to an animal. It comprises a storage container for holding the supplement and a metering module that is rotatably connected to the storage container for dispensing a measured (pre-determined) dose of the supplement. The dispensing module is adapted to be moved between an open configuration and a closed configuration. In the open configuration, the measured dose of the supplement is able to be dispensed out of the dispensing module. In the closed configuration, the measured dose of the supplement is prevented from being be dispensed out of the dispensing module. Compressed air can be used to send the dose to an outlet when the dispensing module is closed.

The present invention provides a plenum configured to evenly separate and distribute airflow generated by a fan into distribution lines of an agricultural machine. The plenum can utilize angled vanes symmetrically or asymmetrically arranged to form plenum chambers to provide a balanced airflow which contributes to maximizing fan efficiency, including power consumption and performance (airflow and static pressure). Accordingly, the plenum can be configured to separate the airflow and minimize imbalance between the lines during sectional control. The plenum height can be maintained for increased manufacturability and to prevent additional expansion. The plenum length can be configured within allowable space constraints of the machine yet allow airflow to develop upon separation into the lines. Vanes throughout the span of the plenum initially divide the airflow from the fan and maintain separation until the outlets.