A disk for use with a tillage machine includes a body portion rotatable about an axis of rotation. The body portion has a circumferential edge and a concavity with a first radius defined from a point on the axis of rotation. A hub portion is continuous with the body portion and presents an abutment face having a concavity with a second radius defined from a point on the axis of rotation. An aperture extends through the abutment face and is centered about the axis of rotation.

An apparatus and system for adjustably controlling the position and depth of row cleaner wheels in no-till planting applications, the apparatus comprising a frame, a piston movably secured at the top to the frame, first and second sets of parallel arms disposed on either side of the piston and movably secured at one end to the frame and at the other end to a hub stem, and a set of piston arms each movably secured at the top to one of the first or second set of parallel arms and at the other end to the bottom of the piston.

An apparatus and system for adjustably controlling the position and depth of row cleaner wheels in no-till planting applications, the apparatus comprising a frame, a piston movably secured at the top to the frame, first and second sets of parallel arms disposed on either side of the piston and movably secured at one end to the frame and at the other end to a hub stem, and a set of piston arms each movably secured at the top to one of the first or second set of parallel arms and at the other end to the bottom of the piston.

An agricultural tillage implement has a vertical tillage section and an aerating section behind the vertical tillage section, each extending substantially perpendicular to the pull direction of the implement. Individual vertical tillage elements, such as disc blades, can be indexed with individual rotary tine assemblies of the aerator section so that discrete holes formed by the aerator section are positioned between substantially continuous slits formed by the vertical tillage section. A ground deposit system is provided for depositing a component on the ground and may be configured for conducting and depositing a granular component, such as seeds, fertilizers, minerals or the like, or liquid components, such as liquid manure.

In one aspect, a method for controlling an orientation of ground engaging elements of a harrow of an agricultural implement may include controlling an operation of an actuator such that the actuator applies an actuator force against a support arm when the harrow is disposed at an operating position. The method may also include receiving an input indicative of an instruction to move the harrow from the operating position to a raised position. Furthermore, after receiving the input, the method may include controlling the operation of the actuator such that the actuator force applied against the support arm is adjusted in a manner that reduces the biasing force being applied on the ground engaging elements. Additionally, the method may include initiating movement of the harrow from the operating position to the raised position to raise the ground engaging elements above the ground after reducing the biasing force.

In one aspect, a method for controlling an orientation of ground engaging elements of a harrow of an agricultural implement may include controlling an operation of an actuator such that the actuator applies an actuator force against a support arm when the harrow is disposed at an operating position. The method may also include receiving an input indicative of an instruction to move the harrow from the operating position to a raised position. Furthermore, after receiving the input, the method may include controlling the operation of the actuator such that the actuator force applied against the support arm is adjusted in a manner that reduces the biasing force being applied on the ground engaging elements. Additionally, the method may include initiating movement of the harrow from the operating position to the raised position to raise the ground engaging elements above the ground after reducing the biasing force.

An agricultural implement includes a plurality of ground-engaging tools configured to modify a surface configuration of an agricultural field and a hydraulically-controlled subsystem configured to modify an operating angle of the plurality of ground-engaging tools. The agricultural implement also includes a sensor coupled to the hydraulically-controlled subsystem configured to generate sensor signals indicative of a current operating angle of the plurality of ground-engaging tools. The agricultural implement also includes an implement control system configured to receive the sensor signals from the sensor to determine the current operating angle of the plurality of ground-engaging tools, and, upon determining the current operating angle is to be changed to a new operating angle, generate control signals for the hydraulically-controlled subsystem to modify the operating angle of the plurality of ground-engaging tools from the current operating angle to the new operating angle.

A disc conditioner to work soil in a forward direction including a main support structure, a secondary support structure that protrudes from the main support structure in the forward direction, a main disc assembly affixed to the main support structure, and a secondary disc assembly that is affixed to the secondary support structure and protrudes from the main disc assembly in the forward direction. The secondary disc assembly generates an oscillating soil and residue flow along a central axis of the disc conditioner that levels the soil.

An agricultural tillage implement has a vertical tillage section and an aerating section behind the vertical tillage section, each extending substantially perpendicular to the pull direction of the implement. Individual vertical tillage elements, such as disc blades, can be indexed with individual rotary tine assemblies of the aerator section so that discrete holes formed by the aerator section are positioned between substantially continuous slits formed by the vertical tillage section. A ground deposit system deposits a component on the ground and may be configured for conducting and depositing a granular component, such as seeds, fertilizers, minerals or the like, or liquid components, such as liquid manure.

An agricultural tillage implement has a vertical tillage section and an aerating section behind the vertical tillage section, each extending substantially perpendicular to the pull direction of the implement. Individual vertical tillage elements, such as disc blades, can be indexed with individual rotary tine assemblies of the aerator section so that discrete holes formed by the aerator section are positioned between substantially continuous slits formed by the vertical tillage section. A ground deposit system deposits a component on the ground and may be configured for conducting and depositing a granular component, such as seeds, fertilizers, minerals or the like, or liquid components, such as liquid manure.