In one aspect, a method for shared access of a machine for operator training, the machine including a traction device and an implement, includes receiving an authorization from an access device to share access to the machine, and entering a shared control state based on at least the authorization received from the access device. The method also includes receiving commands from a remote operation device during the shared control state and operating at least one of the traction device or the implement of the machine based on at least the commands from the remote operation device while an operator is present in the machine.

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 work assistance server 10 according to the present invention includes a first assistance processing element 121 that generates a surroundings image including a region around a work machine 40 when a request to start work by the work machine 40 is made, and a second assistance processing element 122 that permits the work by the work machine 40 on condition that the surroundings image is displayed on an image output device 221 of a remote operation apparatus 20.

A work machine includes one or more processors; and a memory device storing a program, wherein when executed by the one or more processors, causes a computer of the work machine to perform a process including prompting an operator to perform a safety check around the work machine at intervals of a predetermined time when the operator has not performed the safety check around the work machine for more than the predetermined time.

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.

An automatic torque control system and methods for automatically controlling a torque of a vehicle are disclosed. The method includes detecting when the vehicle engages a load. The method further includes automatically decreasing the torque when the vehicle engages the load and prior to one or more wheels of the vehicle slipping.

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.

A container measuring system includes a distance image acquiring part and a calculation part. The distance image acquiring part is provided on a working machine for performing a work of loading into a container, and is capable of acquiring a distance image of the container. The calculation part processes the distance image of the container acquired by the distance image acquiring part. The calculation part calculates a three-dimensional position of a flat face part constituting the container on the basis of the distance image of the container. The calculation part calculates three-dimensional information including a three-dimensional position and a three-dimensional shape of the container on the basis of the three-dimensional position of the flat face part.

There is provided a construction machine capable of performing hanging work according to the intention of an operator. A hydraulic excavator 1 includes: an operating lever 420 for performing a turning operation; the cameras 61, 62, 63 for detecting any obstacle; and a controller 8 for controlling the operations of a vehicle body and a front working device 5. In the hydraulic excavator 1, in a case where the obstacle is detected by any of the cameras 61, 62, 63, the controller 8 performs an operation limiting process. The hydraulic excavator 1 further includes a hook 53A, a mode selector switch 64 for switching the operation to a hanging work mode. In a case where the obstacle is detected by any of the cameras 61, 62, 63, the controller 8 disables the operation limiting process and controls the operation of the vehicle body or the front working device 5 according to the manipulated variable of the operating lever 420.

A system includes a support, a sensor coupled to the support and arranged to output signals in a direction towards a haul road on which a machine traverses, an indicator coupled to the support, a first line coupled to the support, and a second line coupled to the support. Sensor data is received from the sensor, and based on the sensor data, a position of the machine on the haul road is determined. An alignment of the machine on the haul road is determined, where the alignment is associated with the machine maintaining contact with the first line and the second line. An indication is displayed for laterally aligning the machine on the haul road.