Disclosed are devices, systems and methods related to agricultural planters. In some implementations, the row unit includes a soil engaging member, where the soil engaging member engages at least one sidewall of a trench and displaces soil from the sidewall to cover the seed. In further implementations, the row unit includes a sensing system for sensing sidewall compaction and/or soil moisture.

A seedling planter is configured to plant a plurality of seedlings in ground. The seedling planter includes a vehicle body, a seedling-storage unit, and a seedling-distribution unit. The seedlings are held together in the form of a seedling package that is stored within the seedling-storage unit. The seedling-distribution unit is configured to separate each seedling from the seedling package and plant each seedling in the ground as the vehicle body travels across the ground. A method includes forming the seedling package.

A seedling planter is configured to plant a plurality of seedlings in ground. The seedling planter includes a vehicle body, a seedling-storage unit, and a seedling-distribution unit. The seedlings are held together in the form of a seedling package that is stored within the seedling-storage unit. The seedling-distribution unit is configured to separate each seedling from the seedling package and plant each seedling in the ground as the vehicle body travels across the ground. A method includes forming the seedling package.

An agricultural implement includes at least one row unit having a plurality of support members, each of which is pivotably coupled to an attachment frame or another of the support members to permit vertical pivoting vertical movement of the support members, and a plurality of soil-engaging tools, each of which is coupled to at least one of the support members. A plurality of hydraulic cylinders are coupled to the support members for urging the support members downwardly toward the soil. A plurality of controllable pressure control valves are coupled to the hydraulic cylinders for controlling the pressure of hydraulic fluid supplied to the cylinders. A plurality of sensors produce electrical signals corresponding to predetermined conditions, and a controller is coupled to the sensor and the controllable pressure control valves. The controller receives the electrical signals from the sensors and produces control signals for controlling the pressure control valves.

A seed depth device for an agricultural planter includes an electric motor. The seed depth device also includes an actuator driven by the electric motor and arranged to move to a home position. The seed depth device further includes a first stop proximate to the actuator when in the home position. The seed depth device yet further includes at least one controller including a computing processor and a computer readable storage medium configured to control the electric motor. The seed depth device also includes a seed depth auto-learn system at least in-part stored and executed by the at least one controller, the seed depth auto-learn system configured to learn the home position based at least in-part on the actuator stalling upon the first stop, wherein the seed depth auto-learn system is configured to move the actuator a prescribed distance away from the first stop to establish the home position.

An agricultural implement includes a toolbar that extends transverse to a tongue when in a field use configuration. The toolbar can be lifted and/or rotated relative to the tongue to transition between a field use and a transport use. A lifting assembly includes one or more actuators and linkage systems to lift the toolbar attached thereto in an arced manner in moving from a field use configuration to a transport configuration. A rotating mechanism can also include one or more actuators to rotate the toolbar about a pivot member. An anti-rotation link includes a member is connected to the toolbar and can be positioned at least partially within a groove to mitigate rotation of the toolbar, such as during the lifting of the toolbar.

A seed planter meter that orients plant seed and a delivery mechanism which can transport the seed to the soil while maintaining the seed's orientation during transport to the soil and encapsulation in the soil.

A seed planter meter that orients plant seed and a delivery mechanism which can transport the seed to the soil while maintaining the seed's orientation during transport to the soil and encapsulation in the soil.

The present invention relates generally to a device that allows a tire to adequately clean a soil cutting disc, maintains the critical seed planting depth, or prevents (1) punctures, (2) soil compaction, (3) premature wear, (4) tire readjustment, (5) operational problems, (6) rough surfaces that fill with mud and debris, and (7) tire removal to clean the gauge wheel or remove buildup. The present invention also provides a device with a gauge wheel for controlling the depth of a furrow created by a soil cutting disk that has one or more of these features. More specifically, the present invention comprises a gauge wheel assembly for farming with a centrally positioned hub, a plurality of spokes extending from the hub to at least one ground contacting finger that extend to an inner circular ring around the circumference.

A particle delivery system of an agricultural row unit includes a particle belt housing having a particle engagement aperture configured to receive a particle and a particle exit aperture configured to expel the particle toward a trench in soil. The particle delivery system includes a particle belt having a particle engagement section configured to receive the particle via the particle engagement aperture and a particle exit section configured to expel the particle via the particle exit aperture. The particle exit section is positioned adjacent to the particle exit aperture, the particle belt extends generally parallel to the trench at the particle exit section, the particle engagement section is positioned adjacent to the particle engagement aperture, and the particle belt at the particle engagement section extends at an angle between zero degrees and ninety degrees relative to the particle belt at the particle exit section.