A grain spreading device for evenly distribute grain as it is poured into a storage bin. The grain spreading device generally includes a flow-control ring (e.g., an evenflow ring) adapted to be positioned below a grain bin opening, the flow-control ring comprising an upper opening and a bottom, and a cone movably suspended below the flow-control ring by a plurality of springs to create a variable opening between the cone and the bottom of the flow-control ring, the plurality of springs creating a restoring force, wherein the variable opening increases in size when a weight of grain on the cone moves the cone away from the bottom of the flow-control ring against the restoring force of the plurality of springs.

A system for automatically opening a lid to a grain bin with controller in communication with an actuator for receiving a signal containing a data packet to activate the actuator. An RFID is combined to an unloading device for transmitting the data packet to the controller when the RFID is positioned proximate to the controller. The controller compares the device id with a stored identification value and upon a match the controller activates the actuator to open the lid of the grain bin.

A system for automatically opening a lid to a grain bin with controller in communication with an actuator for receiving a signal containing a data packet to activate the actuator. An RFID is combined to an unloading device for transmitting the data packet to the controller when the RFID is positioned proximate to the controller. The controller compares the device id with a stored identification value and upon a match the controller activates the actuator to open the lid of the grain bin.

A grain storehouse includes a granary, a grain loading system, and a grain unloading system. The granary includes multiple storages arranged in a network format. The bottom of each storage is a tapered structure with a tapered surface downward, and the bottom of the tapered structure provides a switchable blanking exit. The grain loading system includes a lattice girder structure, a plurality of conveyors and multiple hoppers. The grain unloading system includes at least one conveyor that is located under the blanking exit. The present invention improves the automaticity and efficiency of grain loading and unloading of the grain storehouse, so that the grain can be transferred quickly.

A framework for modeling performance of bin systems in precision agriculture settings, and grain stored in containers, collects information on auxiliary devices, the grain, and the container using both wireless sensors built into devices and transient sensors that are embedded within and move with the grain. Machine learning-based models are developed and applied within this framework for performing management functions such as monitoring for failure or malfunction, and controlling and adjusting bin systems in response to sensed conditions. Information collected and processed within this framework is stored and tokenized in a secure ledger for tracking, transactions, verification, and authentication of crop value and carbon emission-related data.

A framework for modeling performance of bin systems in precision agriculture settings, and grain stored in containers, collects information on auxiliary devices, the grain, and the container using both wireless sensors built into devices and transient sensors that are embedded within and move with the grain. Machine learning-based models are developed and applied within this framework for performing management functions such as monitoring for failure or malfunction, and controlling and adjusting bin systems in response to sensed conditions. Information collected and processed within this framework is stored and tokenized in a secure ledger for tracking, transactions, verification, and authentication of crop value and carbon emission-related data.

A safety door latch system is presented for a grain bin having a door frame. An inner door is connected to the door frame that is configured to move between an open position and a closed position. An outer door is connected to the door frame and is configured to move between an open position and a closed position. A safety mechanism is connected to the door frame and is configured to move between an open position and a closed position. When the inner door frame is moved to a closed position, a portion of the inner door engages the safety mechanism thereby causing the safety mechanism to move to the closed position. When the safety mechanism is in the closed position, the outer door may be latched to the safety mechanism. When the safety mechanism is in the open position, the outer door cannot latch to the safety mechanism.

A method for assisting a compaction-appropriate distribution of harvested material in a flat silo includes providing a silo vehicle having a control unit, ascertaining a dry-substance density to be achieved via the control unit, determining a maximally producible compaction pressure via the control unit, ascertaining a maximally permissible layer thickness via the control unit for the implementation of a distribution-and-compaction process, determining a layer thickness currently being applied during the implementation of the distribution-and-compaction process in a location-specific manner via a GPS receiver, comparing the maximally permissible layer thickness and the layer thickness currently being applied in the location-specific manner via the control unit in order to ascertain a target layer thickness, and driving a regulating device of a distribution tool provided on the silo vehicle to assimilate the layer thickness currently being applied to the target layer thickness via the control unit in an automated manner.

A grain spreading device for evenly distribute grain as it is poured into a storage bin. The grain spreading device generally includes a flow-control ring (e.g., an evenflow ring) adapted to be positioned below a grain bin opening, the flow-control ring comprising an upper opening and a bottom, and a cone movably suspended below the flow-control ring by a plurality of springs to create a variable opening between the cone and the bottom of the flow-control ring, the plurality of springs creating a restoring force, wherein the variable opening increases in size when a weight of grain on the cone moves the cone away from the bottom of the flow-control ring against the restoring force of the plurality of springs.

The present disclosure describes methods and apparatus for remote sensing with data analytics. The methods and apparatus have many applications including monitoring the quality of grain during storage and/or transport. The present disclosure describes a way to collect temperature and other environmental data to describe and predict quality of stored grains, current and future, based on a myriad factors including fumigation, external temperature and humidity, in storage grain temperature and humidity.