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.

A cultivator function is coupled with a scraper function in a single implement such that the cultivator portion and the scraper portion of the combination farming implement, when attached to a vehicle, can be mechanically and remotely changed out at any time. The cultivator portion and the scraper portion of the combination farming implement are positioned on opposite sides of a rotating framework, such that the combination farming implement can be mechanically and remotely rotated during use in the field, thus enabling the performance of both the cultivator function and the scraper function without a vehicle operator ever leaving the vehicle.

A cultivator function is coupled with a scraper function in a single implement such that the cultivator portion and the scraper portion of the combination farming implement, when attached to a vehicle, can be mechanically and remotely changed out at any time. The cultivator portion and the scraper portion of the combination farming implement are positioned on opposite sides of a rotating framework, such that the combination farming implement can be mechanically and remotely rotated during use in the field, thus enabling the performance of both the cultivator function and the scraper function without a vehicle operator ever leaving the vehicle.

A system for monitoring soil composition within a field may have a ground-engaging tool configured to engage soil within a field as an implement moves across the field. The system may further have a sensor configured to generate data indicative of a soil composition within the field, where the sensor is movable relative to the ground-engaging tool while the implement moves across the field such that the sensor generates data indicative of the soil composition at different depths within the field. Additionally, the system may have a controller communicatively coupled to the sensor, with the controller being configured to determine the soil composition at the different depths within the field based at least in part on the data received from the sensor.

A system for monitoring soil composition within a field may have a ground-engaging tool configured to engage soil within a field as an implement moves across the field. The system may further have a sensor configured to generate data indicative of a soil composition within the field, where the sensor is movable relative to the ground-engaging tool while the implement moves across the field such that the sensor generates data indicative of the soil composition at different depths within the field. Additionally, the system may have a controller communicatively coupled to the sensor, with the controller being configured to determine the soil composition at the different depths within the field based at least in part on the data received from the sensor.

A soil preparation apparatus having a first frame member configured to couple to a towing vehicle, wherein the first frame member comprises a blade member configured to engage soil. The apparatus can also include a second frame member pivotally secured to the first frame member, wherein the second frame member comprises an adjustable height protruding member configured to engage soil. The apparatus can also include a third frame member pivotally secured to the second frame member, wherein the third frame member comprises a plurality of bars configured to engage soil, and wherein the second frame member pivots relative to the first and third frame members.

A soil preparation apparatus having a first frame member configured to couple to a towing vehicle, wherein the first frame member comprises a blade member configured to engage soil. The apparatus can also include a second frame member pivotally secured to the first frame member, wherein the second frame member comprises an adjustable height protruding member configured to engage soil. The apparatus can also include a third frame member pivotally secured to the second frame member, wherein the third frame member comprises a plurality of bars configured to engage soil, and wherein the second frame member pivots relative to the first and third frame members.

A soil monitoring system for an agricultural tillage implement includes a sensor configured to be coupled to a frame of the agricultural tillage implement. The sensor is configured to be directed toward a region of a soil surface. In addition, the sensor is configured to emit an output signal toward the region of the soil surface and to receive a return signal indicative of a profile of the soil surface within the region. Furthermore, the soil monitoring system includes a controller configured to identify a rough soil profile in response to determining that at least one variation in the profile of the soil surface within the region is greater than a first threshold value, and/or in response to determining that a number of variations in the profile of the soil surface within the region is greater than a second threshold value.

A soil monitoring system for an agricultural tillage implement includes a sensor configured to be coupled to a frame of the agricultural tillage implement. The sensor is configured to be directed toward a region of a soil surface. In addition, the sensor is configured to emit an output signal toward the region of the soil surface and to receive a return signal indicative of a profile of the soil surface within the region. Furthermore, the soil monitoring system includes a controller configured to identify a rough soil profile in response to determining that at least one variation in the profile of the soil surface within the region is greater than a first threshold value, and/or in response to determining that a number of variations in the profile of the soil surface within the region is greater than a second threshold value.

A ground opener for an agricultural implement. The ground opener comprising an opening disc, and a support assembly securing the opening disc to the agricultural implement. The support assembly comprises an upper bar, a lower bar, a forward bar, and a rearward bar. At least a portion of each of the bars is orientated at an offset angle with respect to a direction of travel of the agricultural implement.