A system for measuring temperature and dielectric properties of soil and other semi-solid materials on-the-go uses a long-wearing non-ferrous wear plate with two metal prongs supported by the wear plate to measure dielectric properties. The metal prongs each have a mounting end soldered to a printed circuit board containing a capacitance sensor circuit. The metal prongs have exposed ends arranged to contact the semi-solid material being measured. The sensor circuit has an oscillation frequency of 50 to 100 MHz to allow rapid dielectric measurements to be made as the sensor moves through the semi-solid material. In one embodiment, the system includes an implement for traversing a field, a shank with a leading edge for opening a furrow in soil, and a spring-loaded mounting system for biasing the wear plate downwardly relative to a shank to maintain a consistent pressure of the wear plate and metal prongs against the soil.

Described herein are implements, systems, and methods for applying stress to agricultural plants of agricultural fields. In one embodiment, an agricultural implement comprises a frame transverse to a direction of travel of the agricultural implement and a stress mechanism disposed on the frame in operation such that the stress mechanism applies a force to the row of plants as the agricultural implement moves through the field.

In one embodiment, a row unit, comprising an upright frame portion comprising front and rear-facing sides, the front facing side configured to be coupled to a tool bar; a fore and aft extending frame coupled on one end to the rear-facing side, the fore and aft extending frame operably coupled to one or more disc openers and plural gauge wheels; a pair of arms pivotably and independently coupled to the fore and aft extending frame; a pair of closing wheels, each operably coupled to one of the pair of arms; and a pair of down force components, each coupled between the upright frame and the one of the pair of arms.

A carrier adjustment assembly for coupling to a frame member of an implement includes a laterally adjustable carrier configured to be coupled to an opener and a first outlet providing at least one nutrient. The assembly further includes a plurality of lateral spacers positioned adjacent to the carrier to laterally adjust the carrier and provide a plurality of adjustment positions. The carrier adjustment assembly facilitates lateral adjustment of the carrier by removal of at least one captively held lateral spacer that sets the lateral adjustment of the carrier, a lateral adjustment of the first outlet, and an adjustment of a lateral separation between a seed row provided by a second outlet and a nutrient row provided by the first outlet.

A load sensing bracket for a disk opener assembly of an agricultural implement. The load sensing bracket includes a body having a cantilevered arm, the body is configured to engage with and secure to a portion of a depth setting arm of a disc opening assembly. The cantilevered arm has an upper end with an extending projection that is receivable in any one of plurality of notches of a fan shaped member thereby setting a position of the depth setting arm relative to the fan shaped member which sets a position of the gauge wheel relative to the disk. A sensor is disposed on the cantilevered arm generating a signal relating to strain in the cantilevered arm which corresponds to a down pressure on the gauge wheel.

Agricultural planting implements, as well as other ground-engaging implements, can utilize supplemental force assemblies to provide up and/or down force at the row or rows of the implements. The force can be used to overcome changing field conditions, obstructions, as well as changing particulate amounts and weights carried by the rows of the implements, and the implement itself. The up force can be set at system pressure, or can include control valves at each of the row units to control the amount of up force provided. The down force can be controlled by control valves at each of the row units, and can be used to overcome the up pressure or provide a designated amount of down force to the row.

A header assembly for an agricultural harvesting machine having a traction unit comprises a cutter, a main frame that supports the cutter, a float cylinder configured to be coupled between the main frame and the traction unit, an accumulator, and fluidic circuitry that fluidically couples the accumulator to the float cylinder. The fluidic circuitry is configured to provide a first flow of pressurized fluid under pressure to the float cylinder, so the float cylinder exerts a float force on the main frame, and, based on a control input that corresponds to a lifting operation of the header assembly, provide a restricted flow of fluid, that is restricted relative to the first flow, between the float cylinder and the accumulator.

A downforce monitoring system for an agricultural row unit includes a controller configured to receive a first input signal indicative of torque applied to a gauge wheel support arm. The controller is also configured to receive a second input signal indicative of an angle of the gauge wheel support arm relative to a frame of the agricultural row unit. In addition, the controller is configured to determine a determined downforce applied to a soil surface by a gauge wheel rotatably coupled to the gauge wheel support arm based on the torque and the angle. The controller is also configured to output a first output signal of the determined downforce, to output a second output signal to a downforce actuator to control a downforce applied to the soil surface by the gauge wheel based on the determined downforce and a target downforce, or a combination thereof.

A crop handling apparatus comprises a mobile chassis. The chassis is mounted on ground-engaging wheels. A tow-bar is provided at a front of the chassis for releasable attachment to a towing vehicle such as a tractor. A crop conditioning rotor is mounted on the chassis and has a plurality of outwardly projecting radial tines. Drive for the crop conditioning rotor can be by way of a drive transmission on the chassis which connects via a drive input with a PTO shaft on a tractor behind which the crop handling apparatus is drawn in use. A crop gathering conveyor is mounted on the chassis in front of the crop conditioning rotor. The crop gathering conveyor has a discharge end located in front of an inlet of the crop conditioning rotor to feed crop material to the inlet of the crop conditioning rotor in use.

A method for controlling a hydraulic top link of a three-point linkage on a piece of accessory equipment coupled to a tractor includes providing the top link coupled between a first location on the tractor and a second location on the accessory equipment. The method includes defining an extension position of the top link as a distance between the first location and the second location, where the extension position is adjustable within a predetermined adjustment range. The method further includes determining a force acting on the top link and adjusting the extension position of the top link by a control unit as a function of the force acting on the top link.