A working machine includes an undercarriage, a main frame, a swing bearing supporting the undercarriage from the main frame, a swing motor configured to pivot the main frame on the swing bearing about a pivot axis, a boom extending from the main frame along a working direction, and a pivot angle sensor configured to provide a pivot angle signal corresponding to a pivot position of the main frame relative to the undercarriage about the pivot axis. A controller is configured to receive the pivot angle signal and to drive the swing motor automatically.

A concrete forming system for reducing the time and labor required for the framing, pouring, and curing of concrete walls. The concrete forming system generally includes concrete forms including a first wall, a second wall opposing the first wall, and a pair of sidewalls. A cavity is formed between the walls; with an opening being fluidly connected to the cavity. A first vehicle is connected to the first wall and a second vehicle is connected to the second wall. Using the vehicles, the positioning and orientation of the walls may be adjusted. After the walls have been placed and oriented, the vehicles will hold the walls in place as concrete is poured into the cavity through the opening. The concrete is allowed to cure into a structure; after which the vehicles and walls may be moved to another location to repeat the process.

A snow groomer with touch screen controls for tensioning tracks, suspension, drive unit, accessories and other, comprising: a plurality of tracks; at least one accessory device selected in a group comprising a shovel or blade, a tiller assembly and a winch assembly; and a user interface comprising a display and a selector device for receiving commands from an operator, preferably the selector device is a device that detects a touch of an operator on the display; a control unit coupled to the user interface, in particular to the display, for sending images to be displayed to the display and receiving commands from the display which are related to the touches detected; wherein the control unit is configured to display on the display a main screen divided into a plurality of main screen portions, wherein the plurality of main screen portions are displayed together in the main screen and each in a different position in the main screen; wherein each main screen portion is configured to display an image that illustrates one or more pieces of data and/or information correlated to the tracked vehicle; the control unit is configured to detect one or more selections made by an operator, preferably on the display by means of a touch, corresponding to the type(s) of data or information that are required to be displayed in each portion of the display, and to display a main screen portion in each portion of the display, wherein each main screen portion is configured to illustrate a respective image relating to the data or information selected by the operator for said portion of the display.

A system for controlling a machine may include a first joystick comprising a first asymmetric grip portion with a first asymmetric faceplate. The first asymmetric faceplate may comprise a first subset of primary controls that include a first plurality of input elements configured to control an operation of an implement mounted to the machine, and a first subset of secondary controls that include a second plurality of input elements configured to control an operation of a display device of the machine. The system may further include a second joystick comprising a second asymmetric grip portion with a second asymmetric faceplate. The second asymmetric faceplate may comprise a second subset of the primary controls that include a third plurality of input elements configured to control an operation of the implement, and a second subset of the secondary controls that include a fourth plurality of input elements configured to control a sound.

The present invention discloses a multifunctional vehicle lifting, steering, moving and obstacle crossing device. The apparatus is composed of a rotating mechanism, a lifting mechanism, a running mechanism and a control mechanism, is mounted at a bottom of an automobile, can be conveniently folded at the bottom of the automobile when not used at ordinary times, and has characteristics of portability, flexibility, no space occupation and easy operation. The apparatus can realize functions of a vehicle, such as lifting, rotating, moving and the like, in a wired or wireless control manner, and effectively overcome defects that the vehicle cannot realize four-wheel off-ground, entire side movement and in-situ rotation or pass through a narrow road or stride across a wide ditch or cross a high and narrow obstacle, thereby completing relatively difficult tasks of the vehicle, such as parking, moving, turning-around and turning in a narrow space, crossing ditches etc.

A guard assembly is provided for use with a track assembly for a vehicle. The guard assembly includes a guard body having a rigid portion made of a first polymeric material and a flexible portion made of a second polymeric material different from the first polymeric material. The first polymeric material has a greater modulus of elasticity than the second polymeric material. A vehicle including a guard assembly, namely including a guard body is also contemplated.

A tracked vehicle is shown which includes an air cooling system having radiators for cooling an engine of the vehicle, and an auxiliary radiator for cooling an auxiliary system of the vehicle. The vehicle further includes an air cooling system for cooling an engine compartment of the vehicle having intake and exhaust ducts which are fan driven to move ambient air into and heated air out of the engine compartment.

A tracked vehicle is shown which includes an air cooling system having radiators for cooling an engine of the vehicle, and an auxiliary radiator for cooling an auxiliary system of the vehicle. The vehicle further includes an air cooling system for cooling an engine compartment of the vehicle having intake and exhaust ducts which are fan driven to move ambient air into and heated air out of the engine compartment.

A remote-controlled powder fire extinguishing system includes a robotic mobile unit including a powder storage unit, a powder fluidization system, and a powder distribution system, the mobile unit being configured to distribute a fluidized powder onto a location affected by a fire, a remote control center, operable outside of the location affected by the fire, including a controller programmed to remotely communicate with and control the mobile unit, the powder storage unit, the powder fluidization system, and the powder distribution system, and a device configured to provide wireless connection between the mobile unit and the remote control center.

A laser cladding mobile platform comprises a platform arranged with a laser, a powder feeder, a processing platform, an electric generator, a power distribution cabinet and a PLC control system. The laser cladding mobile platform also comprises a self-propelled mechanical arm which comprises a multivariant mechanical arm and a crawler trolley, the multivariant mechanical arm is mounted on the crawler trolley; the multivariant mechanical arm is equipped with a laser cladding head at its end, the laser inputs laser light into the laser cladding head through optical fibers, the powder feeder is connected to the laser cladding head through a powder feeding tube, the electric generator supplies power for all the devices via the power distribution cabinet, the PLC control system controls the operation of each device.