A method of controlling operation of a side-shaking mechanism in a combine is provided. The method includes enabling the side-shaking mechanism, and moving the side-shaking mechanism to a predetermined zero position. The method includes receiving incline data representing the inclination of the combine, and receiving sensed data representing at least one operating condition of a combine system. The method includes causing the side-shaking mechanism to increase the distance of movement of the at least one sieve in the side-to-side motion, or decrease the distance of movement of the at least one sieve in the side-to-side motion.

A combine harvester having a cleaning system with at least one cleaner assembly for cleaning the harvested and a drive assembly connected to the cleaning system to drive the cleaning system, thereby driving the at least one cleaner assembly to perform a reciprocating cleaner movement. The drive assembly comprises a variable speed drive assembly with a rotary drive comprising a rotatable output shaft for driving the cleaning system, a transmission to connect the rotatable output shaft to the at least one cleaner assembly, the transmission configured to convert an angular movement of the rotatable output shaft to the reciprocating cleaner movement, and a control unit to control an angular velocity of the rotatable output shaft based on an input signal.

A control method of an outdoor power equipment includes: determining corresponding initial current limiting values and maximum rotating speeds of a cutter motor and a walking motor of the outdoor power equipment according to a previous mowing data; monitoring an input current of each of the motors, and determining whether the input current of each motor is less than the current limiting value; when the input current of the walking motor is continuously equal to or greater than the current limiting value and an output value of a battery pack of the outdoor power equipment is less than a maximum discharging capacity, resetting the current limiting values and the maximum rotating speeds of the walking motor and the cutter motor according to a current slope of the outdoor power equipment and the maximum discharging capacity of the battery pack.

A control method of an outdoor power equipment includes: determining corresponding initial current limiting values and maximum rotating speeds of a cutter motor and a walking motor of the outdoor power equipment according to a previous mowing data; monitoring an input current of each of the motors, and determining whether the input current of each motor is less than the current limiting value; when the input current of the walking motor is continuously equal to or greater than the current limiting value and an output value of a battery pack of the outdoor power equipment is less than a maximum discharging capacity, resetting the current limiting values and the maximum rotating speeds of the walking motor and the cutter motor according to a current slope of the outdoor power equipment and the maximum discharging capacity of the battery pack.

A work vehicle has at least one caster wheel on an end of the work vehicle. In response to a caster locking signal sent via an electrical controller, a solenoid is electrically activated to reversibly move a locking pin in an axial direction, causing transitions between unlocking and locking states. In the unlocking state, the locking pin is pulled away from the engagement surface. In the locking state, the locking pin is pushed towards the pivoting support to engage the locking void when the pivoting support is oriented in a predetermined rotation angle.

A work vehicle has at least one caster wheel on an end of the work vehicle. In response to a caster locking signal sent via an electrical controller, a solenoid is electrically activated to reversibly move a locking pin in an axial direction, causing transitions between unlocking and locking states. In the unlocking state, the locking pin is pulled away from the engagement surface. In the locking state, the locking pin is pushed towards the pivoting support to engage the locking void when the pivoting support is oriented in a predetermined rotation angle.

A method for determining a mass flow composed of bulk material, in particular grain, which is conveyed by means of a continuous, circulating conveyor, having planar conveyor elements, from a lower bulk material receiving area to a higher bulk material delivery area, in which the bulk material delivered by the conveyor is deflected by a guide surface disposed in the bulk material delivery area toward a measuring device, wherein the mass flow is determined by the measurement of a resulting force (F_G) exerted on a sensor surface of the measuring device, wherein at least two parameters having an effect on the force measurement, in particular parameters independent of bulk material properties, are compensated for. A control and regulating device for executing the method for determining a mass flow composed of bulk material is also provided.

A lawncare apparatus includes a main body, multiple wheels supporting the main body, a cutting blade disposed in the main body, a motor driving the cutting blade, and an operating arm connected to the first end of the main body. The distance in the horizontal direction between the axial central line of the cylindrical gripping portion of the operating arm and the axes of the elongated handle of the main body along the length direction is less than 5 cm. Because of the structure mate relationship between the operating arm and the cylindrical gripping portion, the operator feels more comfortable during the transporting process, the volume of lawncare apparatus during transporting is reduced and the convenience of transporting is improved.

An agricultural harvester including a feeder. The feeder is pivotally mounted to an intermediate frame with respect to a first axis of motion. The intermediate frame is pivotally mounted to a header mounting frame with respect to a second axis of motion. Pivoting around the first axis of motion and the second axis of motion allows a fore-aft movement and a lateral tilt movement. At least one lateral tilt actuator is provided to actuate the header mounting frame in the lateral tilt movement. At least two fore-aft actuators are provided for extending between a first set of mounting positions at the feeder and a second set of mounting positions at the header mounting frame to actuate the header mounting frame in the fore-aft movement.

An agricultural harvester includes a plurality of controllable subsystems and a forward-looking crop sensor that detects a characteristic of the crop in front of the harvester. The forward-looking sensor generates a first sensor signal indicative of the detected characteristic. The harvester further includes a component sensor that detects a characteristic of a component of the agricultural harvesting machine and generates a second sensor signal indicative of the detected characteristic. Adaptation logic receives the first and second sensor signals and determines a sensor conversion factor intermittently during operation of the agricultural harvester. Recommendation logic receives the conversion factor and generates a recommendation to change operation of a controllable subsystem, based in part on the calculated conversion factor and a value received from the forward-looking crop sensor. A control system controls the controllable subsystem based on the generated recommendation.