A farm implement is provided. The farm implement includes a frame having a bed and a conveyor mounted to the frame. The farm implement further includes a latch mechanism for securing two or more bulk seed-boxes mounted on a plurality of bulk seed-box locations. The latch mechanism includes a handle to activate the latch mechanism and two or more latches located adjacent to one or more of the bulk seed-box locations, and is moveable between a latched position and an unlatched position. In the latched position, the two or more latches are configured to engage with the bulk seed-boxes to secure the bulk seed-boxes to the bed. In the unlatched position, the two or more latches are configured to disengage from the bulk seed-boxes to allow for the bulk seed-boxes to be unloaded from or loaded onto the bed.

An agitation control system of an agricultural system. The agitation control system includes an agitator that induces movement of particulate material through the agricultural system. An agitator motor couples to the agricultural system to move the agitator. A first motor couples to the agitation control system. The first motor includes a first sensor that detects a first temperature of the first motor and emits a first signal indicative of the first temperature. A controller couples to the agitator motor and to the first motor. The controller receives the first signal indicative of the first temperature from the first sensor and determines an ambient temperature from the first temperature. The controller controls the agitator motor in response to the ambient temperature.

An autonomous farming system (26) comprising one or more ground-based drones (10) and one or more unmanned aerial vehicles (12), whose routes through a field are optimized by an autonomous farming control system (30) that utilizes linearly constrained integer quadratic programming. The farming system (26) is particularly suited for farming steep terrain that is not accessible to conventional farming equipment.

A hydraulic system for an air cart includes a primary hydraulic assembly and a secondary hydraulic assembly. The hydraulic system also includes a first valve configured to block a flow of a hydraulic fluid flowing in a first direction from the primary hydraulic assembly and a second valve configured to block a flow of the hydraulic fluid flowing in a second direction from the secondary hydraulic assembly.

A vehicle for receiving and delivering granular material, such as agricultural seeds, includes a frame supporting a container defining an open top chamber having a bottom outlet. An elongated conveyor is supported by a system which includes a first support arm having one end pivotally connected to a side wall of the container for multiple directional movements and a second support arm pivotably connected to the opposite end of the first support arm. The opposite end of the second support arm supports an intermediate portion of the conveyor near its center of gravity and in suspended relation for tilting and rotating the conveyor. Power actuators are connected to rotate and pivot the first support arm to position the conveyor in many selected positions including the conveyor inlet under the outlet of the chamber, a storage position and a position between horizontal and substantially inclined for filling other containers.

A crop input transfer system for transferring a crop input to an implement tank supported on an implement dispensing the crop input, the crop input transfer system includes a mobile supply vehicle powered independent of the implement. The mobile supply vehicle has a boom and a supply tank holding a crop input supply. The crop transfer system includes a coupler with a first coupler portion that matingly couples with a second coupler portion. The first coupler portion is mounted to the boom and the second coupler portion is mounted to the implement. The crop input supply in the supply tank is communicated to implement tank via the matingly coupled first and second coupler portions.

A commodity cart includes at least one storage tank and a transfer arm having a product chute, a tube portion coupled to the product chute. The tube portion ends in a product outlet. A hydraulic system is coupled to the transfer arm and configured to move the transfer arm to a product loading position wherein the product chute is positioned at a location on the ground. A controller is configured to determine a desired fill vehicle position and generate an indication of the desired fill vehicle position.

An exemplary diverter valve generally includes a shell, a pipe, and a handle. The shell includes a body extending in a longitudinal direction, a shell inlet port, a shell outlet port, and a positioning slot formed in the body. The pipe is seated in the body for sliding movement in the longitudinal direction, and includes a first passage and a second passage. The handle is connected to the pipe through the positioning slot, and is operable to move the pipe relative to the shell between a first position in which the shell inlet port is connected with the shell outlet port via the first passage, and a second position in which the second passage is connected with the shell inlet port and the shell outlet port is disconnected from the second passage.

An information map is obtained by an agricultural system. The information map maps values of a characteristic at different geographic locations in a worksite. An in-situ sensor detects material consumption values as a mobile material application machine operates at the worksite. A predictive map generator generates a predictive map that maps predictive material consumption values at different geographic locations in the worksite based on a relationship between values of the characteristic in the information map and material consumption values detected by the in-situ sensor. The predictive map can be output and used in automated machine control.

An example container for collecting bulk material dispensed from a meter during a calibration operation may include a canister comprising an open end to receive bulk material, a coupler configured to releasably couple to a meter, and at least one weight sensor extending between the enclosure and the coupler. The weight sensor may be configured to detect weight of the bulk material deposited into the enclosure via the open end.