Agricultural devices, row unit adjustment systems, and methods of adjusting a depth of a furrow are provided. In some aspects, an agricultural device is adapted to plant seeds and includes a frame, a furrow opener coupled to the frame and adapted to cut a furrow including a depth, a sensor adapted to sense a characteristic associated with planting seeds and generate a signal associated with the sensed characteristic, and a processing unit receiving the signal associated with the sensed characteristic. The depth of the furrow is adjustable based on the signal associated with the sensed characteristic. Such characteristic may be a characteristic of the soil, a force applied to the agricultural device, or a position of a portion of the agricultural device.

A fluid system includes a fluid control assembly in fluid communication with a fluid source in fluid communication with a fluid supply port and the fluid control assembly is in fluid communication with an actuator via an outlet port. A controller controls at least one supply valve and at least one exhaust valve. The at least one supply valve and exhaust valve are in a normally closed position until being actuated by the controller to an open position. The fluid control assembly includes a pressure sensor in communication with the outlet port. Whereby when pressure in the outlet port is less than a predetermined pressure, a controller opens the supply valve to communicate fluid to the actuator via the actuator line and when the pressure in the outlet port is greater than a predetermined pressure the controller opens the exhaust valve to vent the is outside a predetermined range.

An agricultural harvester includes a harvester body, a header which is adapted for harvesting a crop, a feeder house which is adapted to receive said harvested crop from the header, a header adapter which is arranged between the header and the feeder house, which header adapter is adapted to allow the header to pivot relative to the feeder house about a horizontal pivot axis substantially parallel to the longitudinal axis of the header. A first actuator has a first end that is pivotably connected to the feeder house and a second end that is pivotably connected to the header adapter. A second actuator has a first end and a second end, which first end is pivotably connected to the harvester body. A coupling device is pivotably connected to the second end of the second actuator, the feeder house and the header adapter.

A tool mounting assembly comprising a shank holder having an elongated passage and an elongated tool shank for an earth working or agricultural tool which is received within the passage and which includes a series of longitudinally spaced teeth. A rotatable adjuster is mounted on the shank holder and can cooperate with the teeth for moving the shank longitudinally of the passage to vary the operating depth of the tool. The shank can also cooperate with the adjuster to lock the adjuster against rotation which prevents longitudinal movement of the shank. A retaining member can be located in the passage for cooperation with the shank to hold the shank in this position. The adjuster may also be rotated to a position out of engagement with the shank teeth which allows for longitudinal sliding movement of the shank through the passage.

A vehicle having a linkage for attaching an implement including a control system for controlling a draft mode of operation in which the linkage is automatically raised and lowered depending on a draft force detected by the vehicle and a lifting cylinder, and when the vehicle travels at low speeds, or is driven in reverse or is stationary, the control system automatically sets the detected draft force to zero and the draft control mode of operation is maintained.

In one aspect, a system for controlling the supply of hydraulic fluid to an implement may include a pump, a control valve coupled to the pump and first and second fluid lines provided in flow communication with output ports of the control valve. The system may also include a pressure control valve configured to regulate a pressure of the hydraulic fluid being supplied to the control valve such that the hydraulic fluid is supplied to the control valve at a first pressure for raising at least one ground-engaging component of the implement and a second pressure for lowering the ground-engaging component(s). Moreover, the system may include a bypass line in fluid communication with the pressure control valve such that fluid diverted through the bypass line actuates the pressure control valve to adjust the fluid pressure of the hydraulic fluid supplied to the control valve between the first and second pressures.

An agricultural vehicle includes a chassis (16), a lift arm (18) movably coupled to the chassis (16), a lift actuator (21) coupled to the lift arm (18), a header (14) coupled to the lift arm (18), and a controller (120) operably coupled to the lift actuator (21). The controller (120) is configured to: receive a header type signal corresponding to a header type of the header; define a lift height limit of the header based at least partially on the received header type signal, the lift height limit being a first height limit when a first header type signal is received or a second height limit when a second header type signal is received; and output a lift signal to the lift actuator (21) to vertically displace the header (14). Header vertical displacement is limited to the first height limit if the first header type signal is received or the second height limit if the second header type signal is received.

A self propelled aerator and fertilizer apparatus 10. The apparatus 10 includes an elongated frame 12, having front wheels 20 and rear wheels 22 coupled to the frame. A steering wheel 30 which controls the front wheels 20 is provided so that the apparatus 10 can be moved in a predetermined direction. An aerator 34 is coupled underneath a lower intermediate portion of the frame 12 for aerating the soil upon rotation thereof when the aerator is moved up and down to selectively engage the soil. A fertilizer 90 is coupled to an upper end portion of the elongated frame 12 so that fertilizer can be dispensed into the soil after aeration is accomplished.

An apparatus and system for adjustably controlling the position and depth of row closer wheels in no-till planting applications, the apparatus comprising a frame, a piston movably secured at the top to the frame, upper and lower parallel arms disposed about 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 upper or lower parallel arms and at the other end to the bottom of the piston. A closing wheel assembly having a closing wheel frame and a set of closing wheels pivotally mounted to a lever on a single axle assembly allows the operator to change the angle at which the closing wheels intersect the ground surface during use. Accordingly, as the angle of the lever is manipulated, the angle of the closing wheel pivotally mounted to that lever changes in the vertical and/or horizontal dimensions.

In one aspect, a method for reducing material accumulation relative to a closing assembly of an agricultural implement may include receiving an input associated with an amount of material accumulation relative to the closing assembly. Additionally, the method may include controlling an operation of the implement based on the received input such that at least one of a first closing tool or a second closing tool of the closing assembly moves from a working position to a material removal position to reduce an amount of material accumulation relative to the closing assembly. The method may also include controlling an operation of an actuator of the implement to actuate the at least one of the first closing tool or the second closing tool from the material removal position back to the working position.