In one aspect, a planter row unit is provided an includes a frame, a first opener disc configured to open a seed trench, and a second opener disc configured to open a second trench different than the seed trench. The second opener disc is rotatable relative to the frame and is vertically moveable relative to the frame. In one aspect, an opener assembly is provided and includes a bracket, an opener disc coupled to the bracket and rotatable relative to the bracket and vertically moveable relative to the bracket, and a biasing member coupled to and between the bracket and the opener disc. The biasing member biases the opener disc vertically downward. In one aspect, a planter row unit is provided and includes an applicator support member made of a resilient material to allow movement of the applicator support member and inhibit deformation of the applicator support member.

An agricultural implement system having: a row unit coupled to a tool bar of an agricultural implement; an opener system coupled to a chassis of the row unit and configured to engage soil to form a trench; a downforce system configured to apply a downforce to the row unit to adjust a contact force between the row unit and the soil; a soil condition sensor configured to detect a condition of the soil and/or an operational sensor configured to detect operation of the agricultural implement system; a closing system, configured to close the trench created by the opener system; and a controller coupled to the soil condition sensor and/or the operational sensor, wherein the controller is configured to control the downforce system and the closing system in response to feedback from the soil condition sensor and/or the operational sensor.

A seed-planting implement includes a fluid-driven actuator coupled between a row unit frame and a row cleaner arm such that the actuator is configured to adjust a force being applied to the arm. The actuator, in turn, includes a cylinder and a piston moveable relative to the cylinder, with the cylinder and the piston collectively defining a lift chamber and a down chamber within the actuator. A first valve or pressure regulator is configured to control the flow of fluid into the lift chamber such that the fluid within the lift chamber is maintained at a first non-zero pressure value during a seed-planting operation. A computing system is configured to determine a second pressure value to which the down chamber is to be pressurized and control the operation of a second valve such that the fluid within the down chamber is pressurized to the second value during the seed-planting operation.

A row unit for a seed-planting implement includes a frame, a gauge wheel arm pivotably coupled to the frame and a gauge wheel rotatably coupled to the gauge wheel arm. Additionally, the row unit includes a wobble bracket configured to engage the gauge wheel arm and a linkage arm coupled to the wobble bracket. Moreover, the row unit includes an actuator, a gearbox coupled to the actuator, and a threaded shaft coupled to the gearbox. In addition, the row unit includes an actuation assembly such that the actuation assembly transmits rotation of the threaded shaft into linear motion of the linkage arm. The actuation assembly includes a hook arm having a first end forming a hook that directly couples to the linkage arm and a second end pivotably coupled to the frame. Furthermore, the actuation assembly includes a collar threadingly coupled to the threaded shaft.

An agricultural implement broadly includes a ground-engaging tool, a time-of-flight sensor, and a controller. The time-of-flight sensor is configured to obtain information indicative of seed parameters, furrow parameters, and/or soil condition parameters. The controller is configured to process the information obtained by the time-of-flight sensor to generate the parameters, wherein the controller is further configured to automatically control operation of one or more components of the implement based on the parameters.

A row unit for a high-speed agricultural seeder includes a leading system including an opener and a dispenser, a trailing system including a leveler and a packer, a primary force generator generating a primary force, and a packer force adjustment system generating a packer adjustment force. The primary force includes opener and trailing force portions that are transferred to the opener and trailing system, respectively. The trailing force portion includes a leveler force portion that is transferred to the leveler and a packer force portion that is transferred to the packer. The packer adjustment force is adjustable independently of the leveler force portion, such that a combined packer force equal to a sum of the packer force portion and the packer adjustment force is adjustable independent of the leveler force portion.

A seeding device for depositing seeds in a soil material, comprising: (i) a frame detachably mounted to a support structure of a moveable gantry, (ii) a plurality of discs rotatably mounted about a shaft of the frame and configured to be vertically lowered into the soil at a predefined depth relative to the ground plane, and, (iii) a seed deposition system mounted to the frame configured to dispense seeds into a plurality of seeding tubes. Each seeding tube is aligned with, and disposed downstream from, a respective one of the plurality of discs such that as the frame traverses over the soil by displacement of flue moveable gantry, grooves are produced in the soil by the plurality of discs, and seeds are deposited into each groove by the seeding tubes of the seed deposition system.

An agricultural implement broadly includes a ground-engaging tool, a time-of-flight sensor, and a controller. The time-of-flight sensor is configured to obtain information indicative of seed parameters, furrow parameters, and/or soil condition parameters. The controller is configured to process the information obtained by the time-of-flight sensor to generate the parameters, wherein the controller is further configured to automatically control operation of one or more components of the implement based on the parameters.

Described herein are implements and applicators for placement of fluid applications with respect to agricultural plants of agricultural fields. In one embodiment, a fluid applicator for applying fluids to plants in rows in a field includes a frame, a coulter connected to the frame and disposed to open a trench between the rows of plants, and at least one application member connected to the frame or to the coulter and disposed to apply fluid to a rhizosphere of the plants.

Air seeders that have force actuators acting on the firming implement and/or the closing wheel to adjust the downforce. In one example, the seeding implement includes a support arm having first and second portions. A finning implement support arm is pivotally connected to the support arm second portion at a first pivot at a first end of the finning implement support arm. A firming implement force actuator is pivotally connected to the support arm second portion at a first end of the firming implement force actuator and connected to the firming implement support arm at the second end of the firming implement force actuator.