Provided is a working machine including a device to be maintained and a winch disposed thereover and enabling a maintenance operation. The working machine includes a base machine, at least one device to be maintained installed at the base machine, and a winch which is driven to wind an operation rope. The winch is attached to the base machine to be pivotable, about a winch support shaft, between a use position at which the winch is used while closing at least a part of a maintenance space over the device to be maintained and a maintenance position at which the winch opens the maintenance space upward to enable the maintenance operation to be performed.

A method for controlling a machine is provided. The method senses an orientation of a seat of an operator. The method selects a desired mode function with respect to at least one work tool, wherein the at least one work tool is equipped with the machine. Further, the orientation of the seat and the desired mode function is communicated to a processing module. Furthermore, a number of input modules are configured corresponding to predefined patterns to control functions of the at least one work tool and the machine. The predefined patterns define functions of the at least one work tool and the machine corresponding to the orientation of the seat, and the desired mode function.

An excavator (1) having a lifting device (2) for lifting a pallet comprising a chassis (3) having a boom (4) mounted thereon and a dipper arm (5) pivotally coupled to a distal end of said boom to which an implement, such as a bucket, may be attached, said lifting device comprising a mast (12) upon which is slideably mounted a carriage (20), a pair of spaced tines (21, 22) being provided on said carriage for supporting a pallet thereon, wherein said mast is mounted on said dipper arm of said excavator to be arranged in a vertical or substantially vertical operative orientation such that, in use, said carriage can be moved between lowered and raised positions on said mast when the mast is mounted on said boom, wherein at least one ground engaging load bearing member (28, 29) is provided at a lower end of said mast.

An implement system is adapted for use with a machine including an implement and a fork assembly. The fork assembly having one or more loading members includes a first upright portion, a second upright portion, and a crimped portion. Further, the crimped portion interconnects the first upright portion and the second upright portion. A mounting device is configured to support the implement and the fork assembly. Further, the mounting device includes a first side plate and a second side plate. A first transverse member is disposed between the first side plate and the second side plate. A second transverse member is disposed between the first side plate and the second side plate, such that the one or more loading members of the fork assembly are pivotally connected to the second transverse member.

A hydraulic system is adapted to provide at least one of a fluid flow at a variable fluid pressure or a fluid flow at a variable fluid displacement. A pressure sensor measures a fluid pressure. A controller is in communication with the engine and the pressure sensor. Wherein, the controller sends an engine speed signal to operate the engine in an open state and controls the fluid displacement or the fluid pressure of the hydraulic system to a first load condition. Further wherein, the controller detects an engine speed and a fluid pressure of the hydraulic system with the pressure sensor when the engine is in the open state and the hydraulic system is in the first load condition. Further wherein, the controller operably calculates a total engine torque as a function of the detected engine speed and fluid pressure when the hydraulic system is in the first load condition.

An actuator assembly having an end guide with a first end and a second end, the end guide defining an axis passing through the first and second end, a rod having an outer surface, the rod being movable along the axis through the end guide, a wiper disposed outwardly of the rod and within the end guide, a scraper disposed outwardly of the rod and within the end guide and spaced axially from the wiper towards the second end, a cavity defined between the wiper, the scraper, the outer surface of the rod, and the end guide, and an orifice defined in the end guide between the wiper and the scraper, the orifice defining a flow path for a lubricating fluid to flow into the cavity, wherein, the wiper and the scraper are disposed in contact with the outer surface of the rod for removing debris therefrom.

An engine idle control method of an off highway vehicle. The method including the steps of: detecting a static load on the engine; detecting a dynamic load on the engine; determining if the static load is below a predetermined static level; determining if the dynamic load is less than a predetermined range; and engaging an auto-idle feature dependent upon both of the determining steps being true.

The present disclosure provides a steering system of an engineering vehicle, and a backhoe loader. The steering system includes: a direction control device, including a steering wheel, a steering cylinder and steerable wheels, the steering cylinder being in transmission connection with the steering wheel and the steerable wheels; a displacement sensor configured to detect a piston displacement of the steering cylinder; a return motor in transmission connection with the steerable wheels to drive the steerable wheels to return to a normal position; and a controller in signal connection with the displacement sensor and the return motor, and configured to output a control signal according to the piston displacement detected by the displacement sensor to manipulate the return motor to drive the steerable wheels to return. The backhoe loader includes the steering system.

To provide a drift-prevention valve device, a blade device, and a working machine capable of operating an actuated unit and preventing the machine body from drifting with a simple configuration. The drift-prevention valve device is provided with a non-return valve 41 that allows the flow of hydraulic oil from a control valve 28 to a head chamber 34h of a blade cylinder 34 and blocks the flow of the hydraulic oil in the reverse direction; and a piston accommodation part 42 separately disposed from an accommodation part 70 of the non-return valve 41, configured to movably accommodate a power piston 43. The power piston 43 defines a first piston chamber 42p1 communicating with a rod chamber of 34r of the blade cylinder 34 and a second piston chamber 42p2 for drain positioned on a poppet 71 side of the non-return valve 41 and communicating with a tank 52. The power piston 43 is connected to the poppet 71 of the non-return valve 41, so that the power piston 43 can be operated by the difference between the urging force of the poppet 71 by a spring 72 of the non-return valve 41 and a rod chamber pressure of the blade cylinder 34.

A method for automatically controlling a display system for a work vehicle having a first implement supported at a first end of a chassis, a second implement supported at a second end of the chassis, and a chair that is selectively movable between a first position oriented toward the first end of the work vehicle and a second position oriented toward the second end of the work vehicle. The method may include receiving an input indicative of a position of the chair and an input indicative of an operating state of the work vehicle. Additionally, the method may include controlling a display device to display image data from an imaging device associated with a first portion of a worksite or a second portion of the worksite based at least in part on the position of the chair and the operating state of the work vehicle.