A system for adjusting the spacing between ground engaging tools of an agricultural implement may include a plurality of ground engaging tools including a first end tool, a second end tool, and at least one intermediate tool positioned between the first and second end tools, with an adjustable ground engaging width being defined between the first and second end tools. The system may further include a biasing element positioned between each respective pair of adjacent engaging tools and configured to apply a biasing force against its respective pair of adjacent tools such that an inter-tool spacing between each respective pair of adjacent tools is maintained substantially uniform across the plurality of ground engaging tools as the ground engaging width is adjusted.

A system for adjusting the spacing between ground engaging tools of an agricultural implement may include a plurality of ground engaging tools including a first end tool, a second end tool, and at least one intermediate tool positioned between the first and second end tools, with an adjustable ground engaging width being defined between the first and second end tools. The system may further include a biasing element positioned between each respective pair of adjacent engaging tools and configured to apply a biasing force against its respective pair of adjacent tools such that an inter-tool spacing between each respective pair of adjacent tools is maintained substantially uniform across the plurality of ground engaging tools as the ground engaging width is adjusted.

Disclosed herein are various devices, systems, and methods for protecting open seed trenches form ingress of foreign material, such as plant residue. The preventing foreign material from entering the open seed trench during planting increases crop yield by minimizing delayed germination and late plant emergence. Various implementations of adjustable row cleaners may be used to prevent ingress of foreign material. Also, various shields may be disposed on the row units of a planter to prevent ingress of foreign material.

With the object of providing a battery mounting structure and working machine which can improve the degrees of freedom in layout of constituent components including a battery, without restrictions in the mounting direction of the battery, it is configured to include a placement member provided at an upper part of an electrical component, a battery which is provided detachably to the placement member and drives the electrical component, and a connection member which extends from the electrical component towards the battery and can electrically connect the electrical component and the battery.

A method for estimating and adjusting crop residue parameters may include controlling an operation of a tillage implement as the implement is being towed by a work vehicle across the field to perform a tillage operation and receiving a pre-tilled image of an imaged portion of the field located to one side of a first section of the field as the implement is being towed across the first section of the field. The method may also include receiving a post-tilled image of the imaged portion of the field as the implement is being towed across the field, analyzing the pre-tilled and post-tilled images of the imaged portion of the field to estimate a crop residue parameter for the field, and, when the estimated parameter differs from a target associated with such parameter, actively adjusting the operation of the tillage implement in a manner designed to adjust the crop residue parameter.

A method for estimating and adjusting crop residue parameters may include controlling an operation of a tillage implement as the implement is being towed by a work vehicle across the field to perform a tillage operation and receiving a pre-tilled image of an imaged portion of the field located to one side of a first section of the field as the implement is being towed across the first section of the field. The method may also include receiving a post-tilled image of the imaged portion of the field as the implement is being towed across the field, analyzing the pre-tilled and post-tilled images of the imaged portion of the field to estimate a crop residue parameter for the field, and, when the estimated parameter differs from a target associated with such parameter, actively adjusting the operation of the tillage implement in a manner designed to adjust the crop residue parameter.

A harvesting and sowing integrated compound operation machine, including a combine harvester, a stubble cleaning device, a topsoil loosening device, a fertilization device, a rotary tillage and ditching device, a sowing device, a detection device, a first driving device, a second driving device and a control device, wherein the stubble cleaning device is mounted below a header of the combine harvester; and the topsoil loosening device, the fertilization device, the rotary tillage and ditching device and the sowing device are mounted at a rear of a chassis of the combine harvester.

In one aspect, a system for monitoring soil flow around a ground-engaging tool of an agricultural implement. The system may include a ground-engaging tool configured to be moved through the soil as the agricultural implement travels across a field. Furthermore, the system may include a radar sensor configured to capture data indicative of a flow of the soil around the ground-engaging tool within a detection zone of the radar sensor. Additionally, the system may include a controller communicatively coupled to the radar sensor. The controller may, in turn, be configured to generate a representation of the flow of the soil around the ground-engaging tool within the detection zone based on data received from the radar sensor.

An orientation control system for an agricultural implement includes a first sensor configured to emit a first output signal toward a soil surface and to receive a first return signal indicative of a first height of a first portion of a frame. The orientation control system also includes a second sensor configured to emit a second output signal toward the soil surface and to receive a second return signal indicative of a second height of a second portion of the frame. In addition, the orientation control system includes a first actuator, a second actuator, and a controller configured to control the first and second actuators such that a difference between the first height and a first target height is less than a first threshold value and a difference between the second height and a second target height is less than a second threshold value.

A closing wheel assembly for a seed row planter unit resides behind the gauge wheel assembly and furrow disks of the planter unit. The closing wheel assembly includes a coupler with a pair of closing wheels mounted thereon. A single pin removably extends through the coupler and through the gauge wheel assembly to detachably mount the closing wheel assembly to the gauge wheel assembly. Different closing wheel assemblies can be quickly mounted on the row unit, depending upon the type of seed being planted. The closing wheels are laterally adjustable via a rotatable threaded bushing so as to be centered behind the furrow disks.