A device for processing the soil comprises a frame which carries at least one processing tool and at least one resilient element which has a first end portion which is associated with the processing tool and a second end portion which is associated with the frame by means of connection devices. The connection devices comprise a first laminar element which is arranged in an upper position with respect to the second end portion of the resilient element and a second laminar element which is arranged in a lower position with respect to the second end portion. The connection devices further comprise a separator device which is arranged between the first laminar element and the second laminar element which is capable of forming a separation between the second end portion and the laminar elements which defines a cavity between the first laminar element and the second laminar element, inside which the resilient element can bend.

A system for monitoring tool float on an agricultural implement may include an implement frame, a rocker arm pivotably mounted to the implement frame, and a tool coupled to the rocker arm. The system may also include a biasing element coupled between the frame and the rocker arm, with the biasing element configured to permit the tool to move relative to the implement frame. Furthermore, the system may include a rotational position sensor configured to detect a parameter indicative of a rotational position of the rocker arm relative the implement frame, with the rotational position being indicative of an additional amount of available relative movement between the tool and the implement frame.

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.

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.

An automated steering system for an agricultural vehicle operating in a row crop field. The automated steering system includes a correction system having a controller and an alignment sensor. The alignment sensor is disposed between two adjacently spaced crop rows and generates output signals indicative of the alignment sensor's lateral position relative to the two adjacently spaced crop rows as the vehicle advances in the forward direction of travel. The controller receives the generated output signals from the alignment sensor and determines an offset distance of said alignment sensor from a centerline between the two adjacently spaced crop rows. The controller outputs a modified vehicle position signal corresponding to the latitude and longitude position received from said GPS receiver shifted by the offset distance. The vehicle's on board navigation controller causes the vehicles on-board steering control system to steer the vehicle based on the modified vehicle position signal.

An apparatus, which may be a tillage apparatus may have a flexible frame. The frame may be made from transverse and longitudinal open members. The frame may support ground engagers and may be supported on wheel assemblies. The ground engagers may be connected to a spring trip mechanism. The ground engagers may be mounted to open members of the frame with a clamping style mechanism. The clamp mechanism may include wedge devices. The frame may be lowered and raised relative to wheels of the wheel assemblies with a lift mechanism. One row of ground engagers may be raised or lowered relative to the frame independent of another row of ground engagers. An anti-skid or skew control system may be employed in association with the independent height adjustment of one row of ground engagers. A system may be provided to maintain and control the height of a tow hitch forming part of the apparatus.

The present invention provides a ground engaging device (10, 10.100, 10.110 and 10.120) which includes a frame assembly (12) having at least one first frame arm (14), and at least one second frame arm (16), in this case only one second frame arm (16). The at least one first frame arm (14) is located in a forward position relative to the at least one second frame arm (16) relative to the forward direction of operation of the device (10). There is also present at least one gauge wheel (18) being mounted to the at least one first frame arm (14) for rotation with respect thereto. The present invention also provides an improved parallelogram linkage, and a planter, fertiliser, cultivator or trasher with such improvements.

The invention relates to a system for hydraulic actuation of multiple consumer units comprising a hydraulic circuit (130) operated by means of a hydraulic motor (122) which actuates a consumer unit (111) wherein, downstream of the first consumer unit (111), the hydraulic circuit (130) has at least one secondary circuit (140, 150) having at least a second consumer unit (114, 118) and arranged before the second consumer unit (114) and a pump (113, 117) directly or indirectly actuated by the first consumer unit (111).

A system for wirelessly monitoring the operational status of ground-engaging tools includes an attachment structure, a ground-engaging tool pivotably coupled to the attachment structure at a pivot point, and a shear pin at least partially extending through both the attachment structure and ground-engaging tool. In addition, the system includes a conductive member extending within the shear pin to form an electrical circuit therein, and a wireless circuit monitor coupled to the conductive member such that the circuit monitor is configured to detect a circuit parameter associated with the electrical circuit. Moreover, the system includes an antenna configured to receive data transmitted wirelessly from the circuit monitor that is indicative of the circuit parameter, and a controller configured to monitor the data received by the antenna and identify a change in a working condition of the shear pin based on a detected variation in the data.

A system for wirelessly monitoring the operational status of ground-engaging tools includes an attachment structure, a ground-engaging tool pivotably coupled to the attachment structure at a pivot point, and a shear pin at least partially extending through both the attachment structure and ground-engaging tool. In addition, the system includes a conductive member extending within the shear pin to form an electrical circuit therein, and a wireless circuit monitor coupled to the conductive member such that the circuit monitor is configured to detect a circuit parameter associated with the electrical circuit. Moreover, the system includes an antenna configured to receive data transmitted wirelessly from the circuit monitor that is indicative of the circuit parameter, and a controller configured to monitor the data received by the antenna and identify a change in a working condition of the shear pin based on a detected variation in the data.