A header including at least one support and transport wheel assembly having an axle and two wheels. The wheel assembly is coupled to the main body of the header by an actuating system that has two actuator mechanisms. When changing from the field mode to the transport mode, the first actuator mechanism brings the wheel assembly forward from a position behind the header, after the header has been lifted up from the ground. After completion of this first movement, a second actuator mechanism swivels the wheel assembly to a position that is transversal to the header, after which the header is lowered to the ground. The two-step approach enables the changeover between field mode and transport mode without pivoting or otherwise moving the header relative to the feeder. The wheel axle may be pivotably suspended from a frame element that executes the swiveling movement.

A header including at least one support and transport wheel assembly having an axle and two wheels. The wheel assembly is coupled to the main body of the header by an actuating system that has two actuator mechanisms. When changing from the field mode to the transport mode, the first actuator mechanism brings the wheel assembly forward from a position behind the header, after the header has been lifted up from the ground. After completion of this first movement, a second actuator mechanism swivels the wheel assembly to a position that is transversal to the header, after which the header is lowered to the ground. The two-step approach enables the changeover between field mode and transport mode without pivoting or otherwise moving the header relative to the feeder. The wheel axle may be pivotably suspended from a frame element that executes the swiveling movement.

An outdoor robotic tool (10) comprising a first part (20) and a second part (30), wherein the first part (20) supports the second part (30) through a suspension arrangement. The suspension arrangement comprises a first component (40), which comprises at least one magnetic member; and a second component (50), which comprises at least one magnetic member. The first component (40) is attached to the first part (20), wherein the second component (50) is attached to the second part (30), wherein at least one of the magnetic members of suspension arrangement is a permanent magnet (42, 52); and wherein a magnetic member of the first component (40) is positioned so as to magnetically interact with a magnetic member of the second component (50) when in use. A magnetic field sensing unit (60) may be present that comprises a control unit (61) and a magnetic field sensor. A method for detecting the alignment of the first part (20) relative to the second part (30), wherein the method comprises detecting the magnetic field using the magnetic field sensing unit (60), is also disclosed.

An outdoor robotic tool (10) comprising a first part (20) and a second part (30), wherein the first part (20) supports the second part (30) through a suspension arrangement. The suspension arrangement comprises a first component (40), which comprises at least one magnetic member; and a second component (50), which comprises at least one magnetic member. The first component (40) is attached to the first part (20), wherein the second component (50) is attached to the second part (30), wherein at least one of the magnetic members of suspension arrangement is a permanent magnet (42, 52); and wherein a magnetic member of the first component (40) is positioned so as to magnetically interact with a magnetic member of the second component (50) when in use. A magnetic field sensing unit (60) may be present that comprises a control unit (61) and a magnetic field sensor. A method for detecting the alignment of the first part (20) relative to the second part (30), wherein the method comprises detecting the magnetic field using the magnetic field sensing unit (60), is also disclosed.

A track system for traction of a vehicle that is connectable to an axle of the vehicle and includes a track and a track-engaging assembly for driving and guiding the track around the track-engaging assembly. The track-engaging assembly includes a drive wheel for driving the track, idler wheels for contacting a bottom run of the track, and a bogie carrying the idler wheels. The track system includes a transmission for transmitting power from the axle of the vehicle to the drive wheel such that a rotational speed of the drive wheel is different from a rotational speed of the axle of the vehicle. The track system includes a connector disposed between the transmission and the bogie such that the bogie is movable (e.g., pivotable) relative to the transmission. The connector may be disposed below an output shaft of the transmission.

A track system for traction of a vehicle that is connectable to an axle of the vehicle and includes a track and a track-engaging assembly for driving and guiding the track around the track-engaging assembly. The track-engaging assembly includes a drive wheel for driving the track, idler wheels for contacting a bottom run of the track, and a bogie carrying the idler wheels. The track system includes a transmission for transmitting power from the axle of the vehicle to the drive wheel such that a rotational speed of the drive wheel is different from a rotational speed of the axle of the vehicle. The track system includes a connector disposed between the transmission and the bogie such that the bogie is movable (e.g., pivotable) relative to the transmission. The connector may be disposed below an output shaft of the transmission.

A latching assembly (100′, 100″) for operably coupling a cutting deck (50) to an equipment frame (60) of a riding lawn care vehicle (10) may include a pivot arm (300, 400), and a latch member (310, 410). The pivot arm (300, 400) and the latch member (310, 410) may each be pivotally coupled to each other. The pivot arm (300, 400) and the latch member (310, 410) may also cooperate with each other to affix the cutting deck (50) to the equipment frame (60) in each of a service position and a working position.

An agricultural mowing device includes a shaft, a first cutting device, and a second cutting device. The shaft has an upper section, a middle section, and a lower section. The shaft is advanced in a field between two adjacent rows of planted matter. The first cutting device is mounted to the lower section of the shaft. The first cutting device extends laterally from the shaft to a distance covering only a distance between the two adjacent rows. The first cutting device cuts plant matter that grows between the two adjacent rows. The second cutting device is mounted to the middle section of the shaft. The second cutting device extends laterally from the shaft to a distance covering at least a portion of at least one of the two adjacent rows. The second cutting device cuts plant matter that grows in the at least one of the two adjacent rows.

An agricultural mowing device includes a shaft, a first cutting device, and a second cutting device. The shaft has an upper section, a middle section, and a lower section. The shaft is advanced in a field between two adjacent rows of planted matter. The first cutting device is mounted to the lower section of the shaft. The first cutting device extends laterally from the shaft to a distance covering only a distance between the two adjacent rows. The first cutting device cuts plant matter that grows between the two adjacent rows. The second cutting device is mounted to the middle section of the shaft. The second cutting device extends laterally from the shaft to a distance covering at least a portion of at least one of the two adjacent rows. The second cutting device cuts plant matter that grows in the at least one of the two adjacent rows.

A system and method for attaching implements to skid steer machines having different implement mounting configurations. The implements include or are separately provided with a securement frame defining a mini skid steer pocket engageable with a mini skid steer mount and a larger standard skid steer pocket engageable with a standard skid steer mount. The mini pocket is located between the implement and the standard pocket. A passage opening extends through the standard pocket where through the mini pocket is accessible. For attaching the implement to a mini skid steer, the mini skid steer mount is inserted through the passage opening and engages the mini skid steer pocket while the standard skid steer pocket remains unused. For attaching the implement to a standard skid steer, the standard skid steer mount is inserted directly into and engages the standard skid steer pocket while the mini skid steer pocket remains unused.