The present invention relates to a grain refrigerator including a housing having a grain storage space formed thereon to discharge grains stored therein, a fixing rod located at the center of the inside lower portion of the housing, dew condensation prevention means fixed to the fixing rod, a support plate located on a top periphery of the dew condensation prevention means, an evaporator disposed on the support plate to generate cool air, and a cooling tube disposed on a top periphery of the support plate on the outside of the evaporator to cool the grains, wherein a first pipe and a second pipe connected to the lower portion of the evaporator pass through a through hole of the support plate and a first drain hole of the dew condensation prevention means and are thus exposed to the outside of the housing.

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.

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.

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 sensor system for a grain storage device is presented. The sensor system includes sensor cable segments configured to connected together in series to form a modular multi-segment sensor cable. In one or more arrangements, each sensor cable segment has a housing, a sensor circuit positioned in the housing, a support cable, and a data cable. The sensor circuit has an upper electrical connector and a lower electrical connector. The data cable is configured to communicatively connect the electrical connector of the segment with and the lower electrical connector of another segment. The support cable is configured to operably connect an upper end of the housing in one segment with a lower end of the housing of another segment in the sensors. The support cables and housings in the multi-segment sensor cable prevent strain on data cables and sensor circuits.

A sensor system for a grain storage device is presented. The sensor system includes sensor cable segments configured to connected together in series to form a modular multi-segment sensor cable. In one or more arrangements, each sensor cable segment has a housing, a sensor circuit positioned in the housing, a support cable, and a data cable. The sensor circuit has an upper electrical connector and a lower electrical connector. The data cable is configured to communicatively connect the electrical connector of the segment with and the lower electrical connector of another segment. The support cable is configured to operably connect an upper end of the housing in one segment with a lower end of the housing of another segment in the sensors. The support cables and housings in the multi-segment sensor cable prevent strain on data cables and sensor circuits.

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 and method for managing of a particulate bulk good that includes a set of wireless sensor nodes, wherein each wireless sensor node comprises a set of environmental sensors configured to collect condition data of the particulate bulk good proximal to the wireless sensor node; an analysis engine that is configured to generate a particulate state analysis from the condition data; and a task manager that is configured to act on the particulate state analysis.

A system and method for managing of a particulate bulk good that includes a set of wireless sensor nodes, wherein each wireless sensor node comprises a set of environmental sensors configured to collect condition data of the particulate bulk good proximal to the wireless sensor node; an analysis engine that is configured to generate a particulate state analysis from the condition data; and a task manager that is configured to act on the particulate state analysis.