An attachment for a tractor includes a rotary reducing component including a plurality of cutters; a hydraulic system having an activated state, a semi-activated state, and a deactivated state; an inlet, an outlet, a hydraulic motor positioned between the inlet and outlet and being mechanically coupled to the rotary reducing component; a first sensor positioned at the inlet for sensing parameters of the activated, semi-activated, or deactivated states; a hydraulic brake positioned downstream of the hydraulic motor configured to restrict flow from the motor to provide hydraulic motor braking only in the deactivated state; and a controller in communication with the first sensor and the hydraulic brake, wherein the controller triggers the hydraulic brake only when the controller determines the first sensor senses a parameter of the hydraulic system being in the deactivated state.

A sugar beet defoliator and top saver having a frame, removable cover, conveyor extending laterally across the frame, steel flails disposed about a first rotating shaft situated between a front end of the frame and the conveyor, rubber flails disposed about a second rotating shaft situated within the frame rearward of the conveyor, ground wheels situated rearward of the frame, and scalper blades arranged transversely relative to the frame and situated rearwardly of the ground wheels. An interior shroud is situated between the steel flails and a front end of the frame, and a crank arm is configured to move a deflector plate from a first position to a second position. When the deflector plate is in the first position, it extends horizontally parallel with a top end of the shroud. When the deflector plate is in the second position, it is situated between the steel flails and the conveyor.

A sugar beet defoliator and top saver having a frame, removable cover, conveyor extending laterally across the frame, steel flails disposed about a first rotating shaft situated between a front end of the frame and the conveyor, rubber flails disposed about a second rotating shaft situated within the frame rearward of the conveyor, ground wheels situated rearward of the frame, and scalper blades arranged transversely relative to the frame and situated rearwardly of the ground wheels. An interior shroud is situated between the steel flails and a front end of the frame, and a crank arm is configured to move a deflector plate from a first position to a second position. When the deflector plate is in the first position, it extends horizontally parallel with a top end of the shroud. When the deflector plate is in the second position, it is situated between the steel flails and the conveyor.

The invention relates to an automatic walking garden trimmer, which includes a power locomotive and a trimming device, the power locomotive is rotatably connected with a turntable support which is driven by the power device to rotate horizontally; a lower supporting arm and a base cylinder for driving the lower supporting arm to swing are hinged to the turntable support; at least two overhanging arms and an extension cylinder for driving the overhanging arms to swing and adjusting an overhanging distance are hinged to an end of the lower supporting arm, and a sphere is connected to the connecting seat; two groups of trimming devices are arranged on side surfaces of the sphere, the trimming device includes a spiral device and a trimming ring, the spiral device includes a spiral bracket on which a sleeve is disposed on. A rotary blade of the trimming device can be replaced.

The invention relates to an automatic walking garden trimmer, which includes a power locomotive and a trimming device, the power locomotive is rotatably connected with a turntable support which is driven by the power device to rotate horizontally; a lower supporting arm and a base cylinder for driving the lower supporting arm to swing are hinged to the turntable support; at least two overhanging arms and an extension cylinder for driving the overhanging arms to swing and adjusting an overhanging distance are hinged to an end of the lower supporting arm, and a sphere is connected to the connecting seat; two groups of trimming devices are arranged on side surfaces of the sphere, the trimming device includes a spiral device and a trimming ring, the spiral device includes a spiral bracket on which a sleeve is disposed on. A rotary blade of the trimming device can be replaced.

A transaxle with a brake of the present invention includes the braking device comprising a plurality of brake discs, fixing plates, and a brake operating member, wherein the brake discs have an inner gear tooth portion that can be fitted to an outer gear tooth portion of an output gear of the motor shaft so as not to rotate relative to the outer gear tooth portion and is slidably fixed in the axial direction of the motor shaft, wherein the fixing plates are fixed to the transaxle casing so as not to rotate relative to each other and are slidably fixed in the axial direction of the motor shaft, and wherein the brake operating member provides a predetermined gap between the fixing plates and the brake discs when the brake discs are not pressed.

A transaxle with a brake of the present invention includes the braking device comprising a plurality of brake discs, fixing plates, and a brake operating member, wherein the brake discs have an inner gear tooth portion that can be fitted to an outer gear tooth portion of an output gear of the motor shaft so as not to rotate relative to the outer gear tooth portion and is slidably fixed in the axial direction of the motor shaft, wherein the fixing plates are fixed to the transaxle casing so as not to rotate relative to each other and are slidably fixed in the axial direction of the motor shaft, and wherein the brake operating member provides a predetermined gap between the fixing plates and the brake discs when the brake discs are not pressed.

A drive and control system for a lawn tractor includes a CAN-Bus network, a plurality of controllers, a pair of electric transaxles controlled by the plurality of controllers, and one or more steering and drive input devices coupled to respective sensor(s) for sensing user steering and drive inputs. The plurality of controllers communicate with one or more vehicle sensors via the CAN-Bus network. The plurality of controllers receive the user's steering and drive inputs and posts on the CAN-Bus network and generate drive signals to obtain the desired speed and direction of motion of the lawn tractor.

A drive and control system for a lawn tractor includes a CAN-Bus network, a plurality of controllers, a pair of electric transaxles controlled by the plurality of controllers, and one or more steering and drive input devices coupled to respective sensor(s) for sensing user steering and drive inputs. The plurality of controllers communicate with one or more vehicle sensors via the CAN-Bus network. The plurality of controllers receive the user's steering and drive inputs and posts on the CAN-Bus network and generate drive signals to obtain the desired speed and direction of motion of the lawn tractor.

A hydrostatic transaxle includes: a casing; a hydraulic continuously variable transmission; and an oil filter that includes a filter body for filtering the hydraulic oil and a filter holding member configured to guide clean oil filtered in the filter body to a suction oil reservoir, in which the filter holding member includes a filter installation portion for installing the filter body, and a suction oil reservoir provided at a position different from the filter installation portion, and the filter installation portion and the suction oil reservoir are configured to be separable from each other and be couplable to each other to freely flow.