A vehicle includes a body defining a front, a rear, lateral sides extending between the front and the rear. The vehicle further includes a fluid delivery system supported by the body. The fluid delivery system includes an intake manifold disposed at the rear, the intake manifold being constructed and arranged to receive fluid from at least one external fluid source, an outlet disposed at the front, the outlet being constructed and arranged to distribute fluid from the at least one fluid source to an external target, and a fluid conduit coupled with the intake manifold and the outlet to convey the fluid from the intake manifold to the outlet through the body. The vehicle further includes track assemblies coupled with the body, the body being disposed between the track assemblies to enable the track assemblies to provide stability to the vehicle during high speed fluid discharge from the outlet.

A wheel-at-rest automatic brake system including a base, a cam, two reset brackets and an interlocking gear is installed in a wheel hub and connected to a wheel shaft of the wheel hub. The base is installed in the wheel hub and has multiple mounting holes and three first pivot holes; the cam is hinged to the first pivot hole and has a protrusion and two driving portions; the two reset brackets are pivoted to the remaining two first pivot holes; each driving portion has a limit notch; the interlocking gear is fixed to the wheel shaft and engaged to the protrusion; and the two driving portions are situated in the two limit notches to define a locked state. When moving, the interlocking gear drives the protrusion to deflect, and the two driving portions prop the two reset brackets up to define a released state.

A system includes a carriage configured to move along a rail. The system also includes a clamping brake configured to selectively allow and prevent movement of the carriage along the rail. The clamping brake includes multiple brake pads configured to be moved inward to lock onto the rail and to be moved outward to release the rail. The clamping brake also includes multiple springs configured to apply spring forces that cause the brake pads to move inward and lock onto the rail. The clamping brake further includes a camshaft coupled to or including multiple eccentrics. The eccentrics are configured to overcome the spring forces and cause the brake pads to move outward and release the rail.

An expansion tank includes a tank body mounted inside a housing forming a sump, and defining an internal expansion volume. A fluid inlet opening in the tank body is in communication with the sump and the expansion volume. A combination valve may be disposed on a lower end of the tank to control fluid flow between the sump and the expansion volume. The valve may be a combination duckbill valve and umbrella valve. Fluid enters the expansion volume through the umbrella valve when sump pressure exceeds expansion volume pressure by a first predetermined amount, and fluid exits the expansion volume through the duckbill valve to the sump when expansion volume pressure exceeds sump pressure by a second predetermined amount. The tank body may include a cover on which an inlet tube is formed.

A bicycle braking and parking device includes a casing, two brake pads, a locking pin, and an electromagnetic driver. The casing has an accommodation space and two pistons located at two opposite sides of the accommodation space. The accommodation space can accommodate part of a brake disk. The brake pads are located at the accommodation space and located between the pistons. The pistons can push the brake pads, and the brake pads can clamp the brake disk. The locking pin is movably disposed on the casing. The electromagnetic driver can force the locking pin to move between a released position and a locked position. when the locking pin is in the released position, the locking pin is separated from the brake disk. When the locking pin is in the locked position, the locking pin is inserted into the brake disk to limit a motion of the brake disk.

A wheel-at-rest automatic brake system including a base, a cam, two reset brackets and an interlocking gear is installed in a wheel hub and connected to a wheel shaft of the wheel hub. The base is installed in the wheel hub and has multiple mounting holes and three first pivot holes; the cam is hinged to the first pivot hole and has a protrusion and two driving portions; the two reset brackets are pivoted to the remaining two first pivot holes; each driving portion has a limit notch; the interlocking gear is fixed to the wheel shaft and engaged to the protrusion; and the two driving portions are situated in the two limit notches to define a locked state. When moving, the interlocking gear drives the protrusion to deflect, and the two driving portions prop the two reset brackets up to define a released state.

A spring brake actuator for applying a brake of a vehicle includes a housing containing a diaphragm that separates the housing into first and second chambers. A clutch actuator device is for selectively compressing a compression spring such that the spring brake actuator is operable in a plurality of states including a parking state, driving state, and a braking state.

An overridable failsafe brake apparatus for a vehicle is provided. The overridable failsafe brake apparatus includes (a) a lever accessible from outside the vehicle, the lever being operable at a first position and a second position; (b) a brake; and (c) a spring having a first end coupled to the lever and a second end coupled to the brake. (d) The lever disposed in the first position is configured to induce tension in the spring that enables the brake to be activated, and the lever disposed in the second position is configured to reduce tension in the spring to disable the brake from being engaged. A method of operating an overridable failsafe brake apparatus for a vehicle and a vehicle including an overridable failsafe brake apparatus are also provided.

Techniques control attachment of equipment to a vehicle deck. Such techniques involve positioning an equipment base that serves as a base of the equipment on the vehicle deck. Such techniques further involve extending a latching mechanism of the equipment base to provide a first latching width that captures the equipment base between a set of deck clamps and a deck jamb mounted to the vehicle deck to fasten the equipment to the vehicle deck. Such techniques further involve contracting the latching mechanism to provide the equipment base with a second latching width that enables the equipment base to escape from the set of deck clamps and the deck jamb mounted to the vehicle deck to unfasten the equipment from the vehicle deck.

A vehicle includes a floor plate defining a front and a back of the vehicle, wall sections to receive vehicle loading and transfer the vehicle loading to the floor plate, and a fluid delivery assembly supported by the floor plate. The fluid delivery assembly includes an intake manifold that resides at the back, an outlet that resides at the front, and a set of lateral conduits extending between the intake manifold and the outlet to laterally convey fluid entering the intake manifold from a fluid source to the outlet for delivery to a fluid target. Accordingly, the back may connect to the fluid source and the front may deliver the fluid thus keeping the vehicle sides and top available for other uses. Moreover, the low isolated placement of the fluid delivery assembly safeguards the fluid delivery assembly and provides a low center of gravity for vehicle stability.