A strip conditioner for an agricultural row unit includes a conditioner frame configured to be supported relative to a row unit, and a rotary tool assembly coupled to the conditioner frame for rotation relative thereto, with the rotary tool assembly including a plurality of cultivator wheels. The strip conditioner further includes a rake assembly supported by the conditioner frame relative to the rotary tool assembly. The rake assembly includes a rod support member coupled to the conditioner frame, and a plurality of rake rods coupled to the rod support member. Each rake rod extends from the rod support member to a location between a respective pair of adjacent cultivator wheels of the plurality of cultivator tools. Additionally, each rake rod of the plurality of rake rods defines a circular cross-sectional shape.

An agricultural trench depth sensing system and method includes a light source (2002), a receiver (2003) and a sensor (2004). The light source directs light downwardly toward a trench previously opened in a soil surface. The receiver is disposed at an angle relative to the light source to receive reflected light. A sensor connected to the receiver senses a pattern of the reflected light. A monitoring system in communication with the sensor, generates a data frame containing triangulated line coordinates and intensity values of the reflected light indicative of a measured depth of the trench. The generated data frame may be associated with GPS coordinates for generating spatial maps and may be used to control operating parameters. The generated data frames may also identify relative soil moisture versus trench depth, or presence of dry topsoil or residue in the trench, or to identify seeds, seed spacing and seed depth.

A mobile agricultural machine includes a row unit having a furrow opener mounted to the row unit and configured to engage a surface of ground over which the mobile agricultural machine travels to open a furrow in the ground. A furrow closer is mounted to the row unit behind the furrow opener and configured to engage the surface of the ground to close the furrow. A furrow sensor system is mounted to the row unit and configured to sense characteristics relative to the furrow opened by the furrow opener and generate a sensor signal indicative of the characteristics. The mobile agricultural machine can further include a control system configured to determine a furrow quality metric corresponding to the furrow sensed by the furrow sensor system based on the sensor signal and generate an action signal to control an action of the mobile agricultural machine based on the furrow quality metric.

A system for controlling the operation of an agricultural implement includes a leveling disk gang assembly including a plurality of leveling disk blades configured to rotate relative to the surface of the field. Additionally, the system includes an imaging device configured to generate data indicative of the sizes of soil clods. Furthermore, the system includes an actuator configured to adjust a position of the leveling disk gang assembly. Moreover, the system includes a computing system communicatively coupled to the imaging device. The computing system is configured to determine the sizes of the soil clods based on the data generated by the imaging device and control the operation of the actuator to adjust the position of the leveling disk gang assembly based on the determined sizes of the soil clods.

Systems, methods and apparatus for imaging and characterizing a soil surface and a trench in the soil surface formed by an agricultural implement. The sensors are disposed on the agricultural implement in data communication with a processor to generate the soil surface and trench images which may be displayed to the operator. In one embodiment, the sensors include one or more time of flight cameras for determining a depth of the trench and other characteristics of the surrounding soil surface and the trench, including detection of seeds, soil or other debris in the trench and moisture lines within the trench. The system may control operating parameters of the implement based on the generated images.

An agricultural implement having a rolling basket is disclosed. A stationary blade is disposed inside an inner chamber of the rolling basket and attached at ends of the rolling basket near the bearings that are connected to the rolling basket. The rolling basket rotates around its major axis via the bearings, while the blade is held stationary. The stationary blade has sleeves at the ends, and each of the sleeves is connected to a post of a support arm and locked into the posts via a pin.

A mobile agricultural machine includes a row unit having a furrow opener mounted to the row unit and configured to engage a surface of ground over which the mobile agricultural machine travels to open a furrow in the ground. A furrow closer is mounted to the row unit behind the furrow opener and configured to engage the surface of the ground to close the furrow. A furrow sensor system is mounted to the row unit and configured to sense characteristics relative to the furrow opened by the furrow opener and generate a sensor signal indicative of the characteristics. The mobile agricultural machine can further include a control system configured to determine a furrow quality metric corresponding to the furrow sensed by the furrow sensor system based on the sensor signal and generate an action signal to control an action of the mobile agricultural machine based on the furrow quality metric.

Implement apparatus may be configured to displace ground material. For example, an implement may include an extension member coupled to a roller apparatus. The extension member may be coupled to a mounting apparatus configured to mount each of a crumbler, a hipper, a bermer, a bermer, crumbler combination apparatus, or a chopping apparatus.

A methods for soil clod detection within a field is provided herein and can include receiving, with a computing system, data indicative of terrain variations within a region of an agricultural field. The region of the field is comprised of one or more adjacently positioned segments. The method can also include generating, with the computing system, a mean reference line. The method can further include calculating, with the computing system, a segment height for each of the one or more adjacently positioned segments. The method can also include determining, with the computing system, a presence of an object based on a deviation of one of the one or more segment heights being greater than a threshold height from the reference line.

An implement has an implement frame and a wheel for supporting the implement frame on a ground surface for movement in a direction of travel. The implement also includes a first basket coupled to the implement frame by a first arm and configured to work a portion of the ground surface, and a second basket coupled to the implement frame by a second arm and positioned rearward of the first basket relative to the direction of travel. The second basket is configured to work the portion of the ground surface after the first basket. A hydraulic cylinder is operatively coupled to the first arm and/or the second arm and configured to lift and lower the respective basket with respect to the ground surface to and from a raised position for travel. The hydraulic cylinder is further configured to regulate a pressure of the respective basket against the portion of the ground surface.