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 seed level managing system includes a seed tank configured to contain seeds, a plurality of seed level sensors placed on a sidewall of the seed tank, a surface detecting sensor, and a controller. The controller includes one or more processors, one or more memory modules, and machine readable instructions stored in the one or more memory modules that, when executed by the one or more processors, cause the controller to receive first information from the plurality of seed level sensors; receive second information from the surface detecting sensor and determine a number of the seeds in the seed tank based on the first information and the second information.

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.

The aspects herein relate to the field of fall prevention systems, and more specifically to fall arrest systems for storage bins and more particularly to grain bins or silos. In one aspect, a fall prevention system for a ladder may have an anchor plate coupled to a roof. In another aspect, the fall prevention system for the ladder may have an anchor bar coupled to at least a portion of the ladder. A rope is coupled at one end to the anchor plate or bar and at the other end to at least one rung of the ladder using a fastener. A rope grab is slidably coupled to the rope between the anchor plate or bar and the fastener.

A series of pre-fabricated building components assembled into modular units and further assembled into circular storage structures of various heights.

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 method and a probe for monitoring fermentation prone agricultural natural products, such as stored hay, straw, fodder, silage grains, seeds, and kernels. The method includes inserting at least one probe in the product to be monitored. The probe can include at least one sensor for monitoring fermentation, a wireless communication unit for communicating measured data from the probe, sending wirelessly the measured data, receiving the measured data by a base station arranged at a distance from the product, determining the location of the probe by a location unit arranged in the base station, and creating a location data of the probe, and enabling visualization of the measured data and the location data.

A method and a probe for monitoring fermentation prone agricultural natural products, such as stored hay, straw, fodder, silage grains, seeds, and kernels. The method includes inserting at least one probe in the product to be monitored. The probe can include at least one sensor for monitoring fermentation, a wireless communication unit for communicating measured data from the probe, sending wirelessly the measured data, receiving the measured data by a base station arranged at a distance from the product, determining the location of the probe by a location unit arranged in the base station, and creating a location data of the probe, and enabling visualization of the measured data and the location data.

A forage compactor is provided having a frame that has cross bars supporting risers that in turn support a shaft. At least one asymmetric wheel is supported by the shaft. The wheels can be paired whereby journals are used to connect to the shaft between recesses of respective wheels. Each wheel has a first side and a second side, each with radiused portions that turn forage away from the wheel. The wheels have a band that is flush with the outer portion of the wheel sides to prevent lifting of the forage. A storage assembly is provided and is integrated into the framework. The storage assembly can be stored within the frame when the compactor is in use, and can be deployed to a locked position in order to store the compactor. A hitch framework is provided that can attach to multiple categories of three point hitches.

A procedure for collection and processing of weed seeds of the type which includes: a first step of collecting of a plant material; fourth step of threshing of the harvested material; a fifth step of separating of grains from material other than the grains; a sixth step of cleaning of the main material; a seventh step of transporting the main material to a discharge device; and an eighth step of storing the main material in an appropriate media. Also includes a second step of placing the material obtained by a thresher head assembly into at least one conveyor belt towards a trailer; a third step of transferring the plant material into a transport and hauling vehicle to a stationary processing plant; a ninth step of grinding the residues; a tenth step of introducing the MDG into densification device; and a tenth step of incorporating in a mixer the resulting grinding of the ninth step along with at least one supplement.