An removably installable apparatus and system for managing weight transfer along a tractor drawn tool bar for use in row planting systems is provided. The planter weight transfer system comprises first and second bolt-on bracket assemblies, each bolt-on bracket assembly comprising a primary plate and a secondary plate secured to each other and to a row planter tool bar by a set of fasteners. Additionally, the bolt-on brackets are joined at the top by an actuator which applies a force on the brackets.

An removably installable apparatus and system for managing weight transfer along a tractor drawn tool bar for use in row planting systems is provided. The planter weight transfer system comprises first and second bolt-on bracket assemblies, each bolt-on bracket assembly comprising a primary plate and a secondary plate secured to each other and to a row planter tool bar by a set of fasteners. Additionally, the bolt-on brackets are joined at the top by an actuator which applies a force on the brackets.

An air seeder cart has a fill auger pivotally mounted to the frame of the air seeder cart and moveable to position the fill auger for filling seed hoppers. The swivel joint for the air seeder has a brake assembly biased by a spring to prevent movement in the absence of an input. A remotely positioned lever and cable assembly unlock the brake assembly for movement to a new position upon an operator input to the lever.

An air seeder cart has a fill auger pivotally mounted to the frame of the air seeder cart and moveable to position the fill auger for filling seed hoppers. The swivel joint for the air seeder has a brake assembly biased by a spring to prevent movement in the absence of an input. A remotely positioned lever and cable assembly unlock the brake assembly for movement to a new position upon an operator input to the lever.

In one aspect, a method for adjusting the down force applied to a row unit of an implement during the performance of a planting operation within a field may include receiving, by a computing device, soil composition data associated with a soil composition of soil within the field and determining a moisture content of the soil within the field. The method may also include calculating a soil plasticity factor associated with the soil within the field based on the soil composition data and the moisture content of the soil and adjusting a down force applied to at least one row unit of the implement based on the soil plasticity factor.

In one aspect, a method for adjusting the down force applied to a row unit of an implement during the performance of a planting operation within a field may include receiving, by a computing device, soil composition data associated with a soil composition of soil within the field and determining a moisture content of the soil within the field. The method may also include calculating a soil plasticity factor associated with the soil within the field based on the soil composition data and the moisture content of the soil and adjusting a down force applied to at least one row unit of the implement based on the soil plasticity factor.

In one aspect, a system for monitoring the frame levelness of an agricultural implement may include an implement frame and first and second seedbed detection assemblies coupled to the implement frame. Each of the seedbed detection assemblies may include a seedbed tool configured to ride along a seedbed floor as the implement frame is moved across a field in a forward travel direction. Each of the seedbed detection assemblies may also include a seedbed floor sensor configured to capture data indicative of a position of the corresponding seedbed tool relative to the implement frame. Furthermore, the system may include a controller configured to monitor positions of the seedbed detection assemblies relative to the implement frame based on data received from the seedbed floor sensors of the first and second seedbed detection assemblies, respectively.

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.

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.

A system for controlling the depth of at least one closing wheel in an agricultural row unit for planting seeds in a furrow. The row unit includes a firming device that passes the seeds into the soil at the bottom of the furrow, and at least one closing wheel that is pressed into a side of the furrow to close the furrow over the seeds. A control system senses the depth of the closing wheels in the furrow relative to the depth of the firming device, and adjusts the downward pressure on the closing wheel, based on changes in the sensed depth of the closing wheel, to compensate for changes in the hardness of the soil. The up and down movement of the firming device can be adjusted independently of the movement of the closing wheel. The firming device can include multiple holes through which pressurized air is forced to dislodge any dirt or mud that accumulates on the soil-engaging parts of the firming device, and can be made according to an additive manufacturing process that allows narrow channels to be formed internal to the firming device.