A work vehicle includes an engine, a cooling device, a cooling fan unit, and a regulating member. The cooling device includes a radiator core. The cooling device is disposed facing the engine. The cooling fan unit includes a cooling fan and is disposed between the engine and the cooling device. The regulating member is disposed above the cooling fan unit and regulates the movement of the cooling fan unit in the horizontal direction.

A monitor controller configured to control a display content on a display unit is configured to keep displaying a bird's-eye-view image when an operation of an operation device is sensed in the state where the display unit displays the bird's-eye-view image, and to cause the display unit to display the bird's-eye-view image when the operation of the operation device is sensed in the state where the display unit does not display the bird's-eye-view image.

An apparatus (e.g., for a vehicle) includes a housing, an oscillation bearing, and a hollow rotor shaft. The housing has a first end and a second end, and includes a first end cap at the first end thereof and a second end cap at the second end thereof. The oscillation bearing is housed within the second end cap. The hollow rotor shaft extends through the housing from the first end to the second end, and has a first shaft end having an interior spline surface, and a second shaft end. The interior spline surface of the hollow rotor shaft is configured to receive a splined end of an internal rear drive shaft and a splined end of a front drive shaft.

The present disclosure relates to a safety system for a construction machine, and the safety system for a construction machine according to the exemplary embodiment of the present disclosure includes: a pilot pump which supplies a pilot working fluid; multiple spools which are operated by the pilot working fluid to control a supply of a main working fluid and each have a signal unit formed in one region thereof; a signal line which sequentially connects the pilot pump and the signal units of the multiple spools and discharges the pilot working fluid, which is supplied by the pilot pump, to a hydraulic tank; and a pressure sensor which measures pressure in the signal line.

A hydraulic excavator (1) includes a controller (40) for generating, when the tip of a work implement (1A) is approaching a target surface (60) due to the pilot pressure output from an operating device (45a, 45b, 46a), a control signal for a boom cylinder (5) such that the tip of the work implement moves along the target surface and controlling the work implement (1A) by outputting the generated control signal to the flow control valve (15a) of the boom cylinder (5). The controller calculates the positional information of a finished shape (97) formed by the work implement, based on the topographic information input from a topographic measurement device (96) that measures the topography near the work machine and corrects the control signal based on the positional information of the finished shape such that the finished shape gets closer to the target surface.

A resin-made fuel tank mounting structure for construction machine is provided that provides a tank capacity without significantly affecting the layouts of other components and easily achieves assembling quality required for the resin-made fuel tank. A resin-made fuel tank mounting structure for mounting resin-made fuel tank on a construction machine including stepwise maintenance steps having plurality of treads and connecting a body floor on body frame and maintenance floor arranged above the body floor, wherein stepwise portion constituting a part of a plurality of treads of maintenance steps is formed on resin-made fuel tank, and horizontal surface of first bracket for fixing resin-made fuel tank onto the body floor is used as the lowest tread on the body floor of the plurality of treads.

An electric power system includes an engine, a generator, a drivetrain including a driveshaft, and an energy storage system having a flywheel. In an implementation, a parallel-path continuously variable transmission is structured to transfer energy between the flywheel and the driveshaft, and in another implementation a parallel-path continuously variable transmission transfers energy between the engine and the generator. The transmission includes a variator and a differential geartrain. An electric motor is coupled to the flywheel and charges the flywheel such that stored flywheel energy is available for bringing up engine speed from a standby state and/or to accommodate generator load changes with limited generator speed changes.

Provided is a hybrid work machine in which a hybrid system and a downsized engine are used. The hybrid work machine performs rapid charging of a power storage device while preventing decreases in the output power of a hydraulic pump. A vehicle body controller performs engine revolution speed decreasing control in which, if the charge rate of a battery becomes equal to or less than a minimum charge rate, the target revolution speed of an engine is reduced. The vehicle body controller also performs torque reducing control in which the maximum absorption torque of a hydraulic pump is reduced. By performing these control operations, the vehicle body controller coercively generates surplus torque for the engine and operates a generator-motor as a generator.

A tractor includes an engine, a transmission coupled to the engine, a hydraulic pump driven by the engine, at least one of a tractor implement, attachment, or control moved by the hydraulic pump, a sensor, and a controller coupled to the transmission. The controller is configured to downshift the transmission based on a signal from the sensor.

A BEIM (Built Environment Information Model)-based control system (CS) for controlling an earthmoving machine (E) is disclosed. The control system includes at least one controller (CO) for controlling at least one movement of an earthmoving tool (3) attached to the earthmoving machine, at least one control unit (CU), and sensing means (11, 12) for providing the control unit with position data of the earthmoving tool and a carrier (1) of the earthmoving machine with respect to the BEIM. The control system also includes at least one displaying means for displaying at least one BEIM selectable by the at least one controller. An earthmoving machine and a method for controlling an earthmoving machine are also disclosed.