A sensor assembly includes a sensor in the form of a microwave radar device to dispense microwaves in an area where seed or other particulate material is to be sensed. This may be a seed tube of a row unit. The microwaves of the radar provide an accurate determination if a seed or other particulate material has passed through the field of vision of the sensor to provide an accurate sensing of a seed event. This information can be used to determine the rate of planting, skips, doubles, as well as any other information related to the passing of a seed or other particulate material.

Embodiments of the present disclosure relate to systems and implements for sensing, analyzing, and displaying different soil parameters. A soil sensing system includes a mechanical component of an agricultural implement and at least one sensor disposed on the mechanical component. The sensor generates an electromagnetic field through a region of soil as the agricultural implement traverses a field. The sensor comprises at least one radar transmitter and at least one radar receiver and the sensor measures different soil parameters including a soil dielectric constant.

The present invention relates to a seed drill having a frame, to which the at least one seeding coulter and a fertiliser coulter arranged upstream of the seeding coulter in a working direction are connected, wherein the seeding coulter and the fertiliser coulter are each assigned a depth control means.

The present invention provides a closing wheel frame assembly comprising a closing wheel frame, a closing wheel assembly, and a lever arm adjustment assembly. A retaining pin secures a lever arm in a desired position to set an angle or orientation of the closing wheel assembly relative to the frame, seed furrow (trench or trough), or soil surface. Operation of the lever arm changes the angle or orientation of the closing wheel assembly relative to the frame, seed furrow (trench or trough), or soil surface.

A seeder assembly for placing a commodity in underlying soil that has a frame member having at least one ground engaging mechanism configured to contact an underlying surface, a rockshaft pivotally coupled to the frame member and pivotal between a lowered position and a raised position, a plurality of disk opener assemblies coupled to the rockshaft, the disk opener assemblies each having a single disk opener configured to cut into the underlying soil to provide an opening for the commodity, a plurality of row cleaner assemblies pivotally coupled to the frame member and each having a row cleaner configured to move residue on the underlying surface, and a plurality of linkages each coupling the rockshaft to a corresponding one of the plurality of row cleaner assemblies. When the rockshaft is in the raised position, the plurality of linkages maintain the corresponding plurality of row cleaner assemblies in a raised position.

An agricultural row unit adapted to be moved over soil by an agricultural planter to clear crop residue includes a residue clearing disk or brush. The row unit may include a motor to drive rotation of a crop residue disk or brush. The agriculture row unit may also include a controller configured to adjust the operating speed of the motor in response to factors internal and/or external to the agricultural row unit. The factors may include at least one of a speed of the agricultural planter along the row, a height of crop residue disk or brush the relative to a surface of the soil, a height of the crop residue disk or brush relative to a surface of the soil, amount of crop residue in the row, and a downforce pressure on the row unit.

In one aspect, a system for detecting plugging of an agricultural implement includes include a frame member and a ground-engaging tool rotatably coupled to the frame member. The ground-engaging tool is configured to engage soil within a field as an agricultural implement is moved across the field. The system also includes a tool scraper positioned relative to the ground-engaging tool such that the tool scraper is configured to remove field materials from the tool as the tool engages the soil. Moreover, the system includes a sensor configured to detect a parameter indicative of a load on the tool scraper and a controller communicatively coupled to the sensor. The controller is configured to monitor the load on the tool scraper based on data received from the sensor and determine when the tool is experiencing a plugged condition based at least in part on the monitored load.

A sensor assembly includes a sensor in the form of a microwave radar device to dispense microwaves in an area where seed or other particulate material is to be sensed. This may be a seed tube of a row unit. The microwaves of the radar provide an accurate determination if a seed or other particulate material has passed through the field of vision of the sensor to provide an accurate sensing of a seed event. This information can be used to determine the rate of planting, skips, doubles, as well as any other information related to the passing of a seed or other particulate material.

An agricultural planting machine includes a frame, a row unit supported by the frame, the row unit comprising a disk opener configured to create a furrow for planting agricultural material in a first row and a row cleaner disposed in a path of the disk opener and configured to move residue from the path. A residue shield is configured to shield a second row from the residue.

A method for reducing material accumulation relative to ground-engaging tools of a tillage implement includes receiving measurement signals from at least one accumulation sensor mounted to the tillage implement during a tillage operation. The measurement signals include a three-dimensional (3D) representation of an environment containing material accumulation relative to a plurality ground-engaging tools. The method also includes estimating an amount of material accumulation relative to the plurality of ground-engaging tools based on the 3D representation. Further, the method includes comparing the amount of material accumulation to an accumulation threshold. The material accumulation threshold is indicative of a given degree of material accumulation relative to the plurality of ground-engaging tools. Thus, based on the comparison between the amount of material accumulation and the accumulation threshold, the method includes controlling an operation of at least one component of the tillage implement to execute a control action for reducing the amount of the material accumulation.