An outdoor grounds maintenance vehicle is self-propelled by a hydrostatic traction drive system that provides dynamic braking to the vehicle without the need for separate service brakes acting on the wheels of the vehicle. An engine kill device can be manually actuated by the operator to access the dynamic braking of the traction drive system by reducing the speed of the prime mover that powers the pump of the traction drive system. This provides an auxiliary braking system that can be used in an emergency or on demand by the operator in the event the accelerator pedal does not properly control the pump swashplates. The operator can control the rate at which the auxiliary brake system reduces the speed of the prime mover to zero.

An outdoor grounds maintenance vehicle is self-propelled by a hydrostatic traction drive system that provides dynamic braking to the vehicle without the need for separate service brakes acting on the wheels of the vehicle. An engine kill device can be manually actuated by the operator to access the dynamic braking of the traction drive system by reducing the speed of the prime mover that powers the pump of the traction drive system. This provides an auxiliary braking system that can be used in an emergency or on demand by the operator in the event the accelerator pedal does not properly control the pump swashplates. The operator can control the rate at which the auxiliary brake system reduces the speed of the prime mover to zero.

An externally adjustable pressure modulating valve is disclosed. In one example, the valve has a valve body extending along a valve axis and defining a plunger cavity extending axially into a first end of the valve body. A valve spool is retained in the valve body and is movable along the valve axis. An input plunger is slidable axially in the plunger cavity between a resting position and an actuated position. An external adjustment mechanism is configured to adjust the modulation spring force when the input plunger is fully actuated. In one example, the adjustment mechanism includes a threaded sleeve in the plunger cavity, where rotating the threaded sleeve changes the mechanical stop of the input plunger.

An externally adjustable pressure modulating valve is disclosed. In one example, the valve has a valve body extending along a valve axis and defining a plunger cavity extending axially into a first end of the valve body. A valve spool is retained in the valve body and is movable along the valve axis. An input plunger is slidable axially in the plunger cavity between a resting position and an actuated position. An external adjustment mechanism is configured to adjust the modulation spring force when the input plunger is fully actuated. In one example, the adjustment mechanism includes a threaded sleeve in the plunger cavity, where rotating the threaded sleeve changes the mechanical stop of the input plunger.

A coolant diverter system and method of controlling coolant flow are provided. The coolant diverter system includes a coolant diverter body having a coolant inlet opening, a driveline retarder outlet opening and a bypass outlet opening. The coolant diverter system also includes a valve positioned in the coolant diverter body. The valve is configured in a first valve orientation to fluidly couple the coolant inlet opening to the driveline retarder outlet opening in isolation from the bypass outlet opening. The valve is configured in a second valve orientation to fluidly couple the coolant inlet opening to the driveline retarder outlet opening and the bypass outlet opening. The coolant diverter system also includes a valve controller configured to place the valve in the first valve orientation in response to activation of a driveline retarder coupled to the driveline retarder outlet opening for braking.

A paving collision avoidance system includes a paving machine, a compactor, and a controller. The compactor has a hydrostatic braking capability. The controller is configured to stop the compactor when it enters a predetermined boundary determined by the momentum of the compactor and the relative positions of the paving machine and the compactor.

At least some embodiments of the present disclosure are directed to distributed pump architectures used in control systems for multifunctional machines. In some cases, a control system for a multifunctional machine includes three or more control circuits. At least two of the control circuits each has a hydraulic fluid pump and each of the pumps is controlled by a different control circuit. At least two of the hydraulic fluid pump have different flow rates.

A vehicle braking system includes a first hydraulic brake assembly associated with a first wheel, a second hydraulic brake assembly associated with a second wheel, a third brake assembly associated with a third wheel, a fourth brake assembly associated with a fourth wheel, a brake control module operably coupled to the first and second hydraulic brake assemblies to control primary operation of the first and second hydraulic brake assemblies and operably coupled to the third and fourth brake assemblies to provide brake torque application for parking brake functionality, and a backup brake actuator operably coupled to a first locking valve disposed in hydraulic lines supplying at least one among the first and second hydraulic brake assemblies and the third and fourth brake assemblies. Responsive to an indication of loss or degradation of the parking brake functionality, the brake control module triggers the backup brake actuator to lock hydraulic pressure in the hydraulic lines supplying the at least one among the first and second hydraulic brake assemblies and the third and fourth brake assemblies for backup parking brake functionality.

A braking unit for a fuel cell electric vehicle or a battery electric vehicle having a propulsion drive shaft or a differential wheel is provided. A hydraulic motor or a rotary gear pump is connected with the propulsion drive shaft or the differential wheel. The hydraulic motor or the rotary gear pump is fluidly connected with a heat exchanger. A restriction valve is configured to control a flow of a fluid in and out of the hydraulic motor or the rotary gear pump. A hydraulic compressor motor is arranged between the hydraulic motor or the rotary gear pump and the restriction valve, the hydraulic compressor motor is operatively connected with an air compressor.

A hydraulic/mechanical braking system for a vehicle comprises a cam (128) keyed onto a transmission shaft or a trailing wheel and at least two hydraulic cylinder assemblies (126, 129) including a cam follower (127). A hydraulic circuit (C) connects the hydraulic cylinder assemblies together. A master brake valve (113) controls the flow of fluid in the circuit. Actuation of the master brake valve (113) obstructs the flow of fluid and hence the reciprocation of the hydraulic cylinder assemblies, forcing the cam following against the cam to resist rotation. The cam (128) is formed with two opposing flat faces (142, 143) in order to provide an anti-lock braking system (ABS).