In accordance with an example embodiment, a method of operating a work vehicle with an ejector body may include receiving a position signal indicative of a position of the work vehicle, receiving a target profile indicative of a target topography for an area, receiving an ejection command at a controller and entering the controller into an ejection mode based on the ejection command, and controlling, with the controller, in the ejection mode, at least one of a speed of the work vehicle and a speed of an ejector included in the ejector body based on the position signal and the target profile, to spread a load of material from the ejector body onto a ground surface.

A method for calculating the change in mass over time of a storage area holding a load, while components of the load are being removed or added, and while the storage area is subjected to changing vertical acceleration, is disclosed. The method uses a computer to compare the measured weight of a load with a known mass to the measured weight of the variable load and calculated the mass of the variable load. Periodic measurements and calculations allow the change of the variable load over time to be determined. Controls influencing the addition and removal of load components maybe controlled in response to the calculated change in mass to maintain targeted rates of change.

An asphalt finisher is provided that includes a tractor; a hopper mounted on a front side of the tractor; a conveyor that conveys a paving material in the hopper to a rear side of the tractor; a screw that spreads the paving material, which is scattered on a road surface by the conveyor, in a vehicle width direction; a screed device that lays and levels the paving material, which is spread by the screw, at a rear side of the screw; an actuator that drives at least one selected from the group consisting of the tractor, the conveyor, the screw, and the screed device using electric power; a power storage unit; and a power supply unit that is connectable to an external device and can receive electric power supplied from the external device.

In accordance with an example embodiment, a method of operating a work vehicle with an ejector body may include receiving a position signal indicative of a position of the work vehicle, receiving a target profile indicative of a target topography for an area, receiving an ejection command at a controller and entering the controller into an ejection mode based on the ejection command, and controlling, with the controller, in the ejection mode, at least one of a speed of the work vehicle and a speed of an ejector included in the ejector body based on the position signal and the target profile, to spread a load of material from the ejector body onto a ground surface.

In accordance with an example embodiment, a method of operating a work vehicle with an ejector body may include receiving a position signal indicative of a position of the work vehicle, receiving a target profile indicative of a target topography for an area, receiving an ejection command at a controller and entering the controller into an ejection mode based on the ejection command, and controlling, with the controller, in the ejection mode, at least one of a speed of the work vehicle and a speed of an ejector included in the ejector body based on the position signal and the target profile, to spread a load of material from the ejector body onto a ground surface.

A system and method for the application of friction-modifying coatings to roadways, walkways, pathways and other areas subject to vehicular, human or animal traffic, the system and method comprising the controlled, simultaneous application of binder and filler to a surface of a substrate, using a mobile device which passes over the substrate as the binder and filler are being applied. The system includes a frame coupled to a vehicle. A spray bar is mounted on the frame and includes an array of spray nozzles coupled to a resin container. An air knife is mounted on the frame and coupled to an air compressor for generating an air curtain. An aggregate dispenser bar including at least one aggregate dispenser is coupled to an aggregate bin and mounted on the frame for dispensing aggregate.

A power unit is configured for use as part of a concrete screed and includes a frame and a powered drive. The frame includes a drive housing. The powered drive is operably supported by the drive housing and is configured to rotate a rotatable concrete forming drum. The powered drive includes an electric motor and a battery operably coupled to the electric motor and configured to power the electric motor. The powered drive includes a drive shaft drivingly connectable relative to the drum, with rotation of the drive shaft causing corresponding rotation of the drum.

A system and method for the application of friction-modifying coatings to roadways, walkways, pathways and other areas subject to vehicular, human or animal traffic, the system and method comprising the controlled, simultaneous application of binder and filler to a surface of a substrate, using a mobile device which passes over the substrate as the binder and filler are being applied. The system includes a frame coupled to a vehicle. A spray bar is mounted on the frame and includes an array of spray nozzles coupled to a resin container. An air knife is mounted on the frame and coupled to an air compressor for generating an air curtain. An aggregate dispenser bar including at least one aggregate dispenser is coupled to an aggregate bin and mounted on the frame for dispensing aggregate.

A system and method for the application of friction-modifying coatings to roadways, walkways, and other areas subject to vehicular, human or animal traffic, the system and method comprising the controlled, simultaneous application of binder and filler to a surface of a substrate, using a mobile device which passes over the substrate as the binder and filler are being applied. The system includes a mobile platform configured for being coupled to a vehicle. A binder applicator is mounted on the mobile platform and coupled to a resin container. A plurality of openings is linearly arranged into two rows extending along the length of the binder applicator. An air knife is mounted on the mobile platform and coupled to an air compressor for generating an air curtain. An aggregate dispenser bar including at least one aggregate dispenser is coupled to an aggregate bin and mounted on the mobile platform for dispensing aggregate.

A topping spreader machine for dispensing topping material onto a concrete surface includes a base unit and a topping spreading head assembly movably mounted at the base unit. The topping spreading head assembly includes (i) a bin that holds topping material, (ii) a distributing device that distributes the topping material along the length of the bin, (iii) a dispenser disposed along a lower portion of the bin for dispensing the topping material, and (iv) a sensor for sensing elevation of the topping spreading head assembly above the concrete surface. The topping spreading head assembly is positionable at a starting location and is movable over the concrete surface in a topping direction from the starting location to dispense the topping material onto the concrete surface, and a control system controls elevation actuators responsive to the sensor to maintain the height of the topping spreading head assembly above the concrete surface.