Systems, methods, and apparatuses can accurately determine proper payload transfer from a working implement of a working machine. Such systems, methods, and apparatuses can identify occurrence of a payload discharge event for the working implement; determine whether a position of the working implement at a time of the identification of the occurrence of the payload discharge event is in a preset working area or a preset discharge area; omit the payload discharge event from registration for a tally of discharge material payload amount under a first case where the position of the working implement is determined to be in the working area; and register the payload discharge event for the tally under a second case where the position of the work implement is determined to be in the discharge area. The tally of the discharge material payload amount may be increased by a load amount associated with the load discharge event.

A distance calculation unit calculates a first distance that is a distance between a first bucket point being a point on a bucket and a target design surface representing a target shape of an excavation target. The distance calculation unit calculates a second distance that is a distance between the target design surface and a second bucket point. The second bucket point is on the bucket on a straight line passing through the first bucket point and is parallel to an edge of the bucket. A tilt control unit compares the first distance and the second distance to calculate a tilt control amount to rotate the bucket around a tilt axis.

In a state where a slewing stop operation is input, in a first state where a slewing command value is equal to or greater than an actual slewing speed, a drive unit stops outputting a torque command value, and a free-run state occurs. In the first state, a command value calculation unit decreases the slewing command value at a first inclination. Meanwhile, in the state where the slewing stop operation is input, in a second state where the slewing command value is less than the actual slewing speed, the command value calculation unit decreases the slewing command value at a second inclination that is gentler than the first inclination.

In a state where a slewing stop operation is input, in a first state where a slewing command value is equal to or greater than an actual slewing speed, a drive unit stops outputting a torque command value, and a free-run state occurs. In the first state, a command value calculation unit decreases the slewing command value at a first inclination. Meanwhile, in the state where the slewing stop operation is input, in a second state where the slewing command value is less than the actual slewing speed, the command value calculation unit decreases the slewing command value at a second inclination that is gentler than the first inclination.

The disclosure relates to a method for monitoring and/or performing a movement of an item of machinery wherein the item of machinery comprises a movement device with a tool for picking up material, which comprises at least two components, each of which is movable via at least one actuator, and a control system by means of which the actuators of the movement device can be actuated by way of open-loop and/or closed-loop control. The method according to the disclosure comprises (i) detecting status information of at least two components, (ii) calculating torques that are applied to components, (iii) detecting torques actually applied to components, (iv) comparing the calculated and detected torques and determining a force vector actually applied, and (v) executing an action depending on the calculated force vector. The disclosure also relates to an item of machinery and a computer program product for executing the method.

Both a control for limiting operation of a machine body and a control for raising engine speed are achieved when an obstacle is detected. To this end, a machine controller performs operation limiting control by conducting a control for reducing the speed of the engine when the machine body does not require engine speed increase control and an obstacle is sensed by obstacle sensors, and the machine controller performs supply flow rate reduction control for reducing the flow rates of the hydraulic fluid supplied to hydraulic actuators from a hydraulic pump when the machine body requires the engine speed increase control and an obstacle is sensed by the obstacle sensors.

A first control unit outputs, to a work machine including work equipment, a first control signal of moving the work equipment to a position above a loading point before a transport vehicle including a dump body reaches the loading point. A transmission unit transmits, to the transport vehicle, an accessing instruction to travel the transport vehicle such that the dump body is located at the loading point. A second control unit outputs a second control signal of controlling the work machine or the transport vehicle such that a deviation between a waiting position of the work equipment and a position of the dump body when the transport vehicle arrives at the loading point based on the accessing instruction becomes small. The waiting position is a position of the work equipment holding an excavation object and waiting based on the first control signal.

An excavator includes a lower traveling body; an upper turning body turnably mounted to the lower traveling body; an attachment that is attached to the upper turning body; and a power engine that is mounted to the upper turning body. The excavator is configured such that, before a low-load operation by the attachment is started, a rotation speed of the power engine is reduced.

A hydraulic excavator includes a traveling body, a slewing body, a working front having a boom, an arm, and a bucket, an operation amount detector, a posture detector, a load detector, a drive controller, and a drive unit. The drive controller calculates a target operation speed of the actuator based on the operation amount, the posture of the working front, and the target surface distance so that the bucket excavates along the construction target surface, and determines soil hardness of a place to be excavated based on a result detected by the load detector, corrects the target operation speed based on the soil hardness, and generates a motion command value. The drive controller determines a target jack-up speed when the hydraulic excavator jacks up based on the target surface distance, and corrects the target operation speed based on the determined target jack-up speed.

A system and method are provided for operating a work machine comprising a laser receiver and an implement for working a terrain. Responsive to movement of the laser receiver, a laser reference is received at a plurality of positions relative to a transmitting laser source, wherein the laser reference corresponds in slope and direction at a defined elevation offset with respect to a target surface profile of the terrain being worked. A plane of the laser reference is determined from data points corresponding to the plurality of positions at which the laser reference is received, and movement of at least the implement is controlled with respect to at least the determined plane of the laser reference and the defined elevation offset.