In one aspect, a shank assembly for an agricultural implement may include a shank and a biasing element configured to exert a biasing force on the shank. The shank assembly may also include a reversible mounting plate defining a mounting aperture offset from a centerline of the reversible mounting plate such that a position of a second mounting location of the biasing element relative to a first mounting location of the biasing element differs depending on whether the reversible mounting plate is provided in a first orientation relative to the biasing element or a second orientation relative to the biasing element. The biasing element may exert a first biasing force on the shank when the reversible member is oriented in the first orientation and a second, different biasing force on the shank when the reversible member is oriented in the second orientation.

A disk blade has an outer perimeter, a first side wall, a second side wall, and a central hub. A plurality of fingers extend laterally at an angle from said first side wall. The fingers preferably comprise metal round bars curved to form part of an elliptical geometry inserted at a perpendicular angle to a vertical angle of said disk blade. The bars are arranged at locations equidistant around said disk blade and are disposed at a depth x from said outer perimeter of said disk blade. Preferably, the depth x is at least one (1) inch.

A disk blade has an outer perimeter, a first side wall, a second side wall, and a central hub. A plurality of fingers extend laterally at an angle from said first side wall. The fingers preferably comprise metal round bars curved to form part of an elliptical geometry inserted at a perpendicular angle to a vertical angle of said disk blade. The bars are arranged at locations equidistant around said disk blade and are disposed at a depth x from said outer perimeter of said disk blade. Preferably, the depth x is at least one (1) inch.

A soil cultivation tool, in particular a plowshare, includes a base body on which cartridges are optionally arranged and at least first cutting elements that are attached to the base body or the cartridges in order to cut into the earth along a working direction. The first cutting elements are arranged in separate seats.

A protection element for an earth-working implement includes a flat plate having a wearing portion on a side of the flat plate facing a distal end of the earth-working implement. A lower portion of the flat plate forms an attachment portion provided with notches, projecting portions, or a combination thereof configured to engage with the earth-working implement. When the attachment portion is engaged with the earth-working implement, the protection element is configured to project above a plane coinciding with a top surface of at least a portion of the earth-working implement proximal to the protection element such that the portion of the earth-working implement proximal to the protection element is shielded from a flow of loose mass during use of the earth-working implement. The wearing portion is arranged at an upper portion of the flat plate. The attachment portion is arranged at a lower portion of the flat plate.

A protection element for an earth-working implement includes a flat plate having a wearing portion on a side of the flat plate facing a distal end of the earth-working implement. A lower portion of the flat plate forms an attachment portion provided with notches, projecting portions, or a combination thereof configured to engage with the earth-working implement. When the attachment portion is engaged with the earth-working implement, the protection element is configured to project above a plane coinciding with a top surface of at least a portion of the earth-working implement proximal to the protection element such that the portion of the earth-working implement proximal to the protection element is shielded from a flow of loose mass during use of the earth-working implement. The wearing portion is arranged at an upper portion of the flat plate. The attachment portion is arranged at a lower portion of the flat plate.

An agricultural harrow includes a harrow tine configured to be advanced through the soil in a forward direction. The harrow tine broadly includes an elongated tine element and a laser deposited metallic wear material. The tine element presents a lower end configured to penetrate the soil as the tine is advanced. The tine element also presents an exterior element surface. The wear material is on the exterior element surface adjacent the lower end of the tine element.

An agricultural harrow includes a harrow tine configured to be advanced through the soil in a forward direction. The harrow tine broadly includes an elongated tine element and a laser deposited metallic wear material. The tine element presents a lower end configured to penetrate the soil as the tine is advanced. The tine element also presents an exterior element surface. The wear material is on the exterior element surface adjacent the lower end of the tine element.

By providing a linear actuator in communication with a slide bar disposed in a channel, and by configuring multiple bars of a harrow to achieve an angle of rotation defined by the slide bar, the angle of rotation for smoothing tools of the harrow may be precisely controlled by the linear actuator. As a result, an infinite range of downward angles may be available for the smoothing tools for achieving various effects with the soil.

By providing a linear actuator in communication with a slide bar disposed in a channel, and by configuring multiple bars of a harrow to achieve an angle of rotation defined by the slide bar, the angle of rotation for smoothing tools of the harrow may be precisely controlled by the linear actuator. As a result, an infinite range of downward angles may be available for the smoothing tools for achieving various effects with the soil.