A system and method for a rider with an improved rider-controlled recreation vehicle. A recreational vehicle with a platform medium, for example a wide fabric strap rider platform (versus a hard surface like metal, wood or the like) supported only at the ends. Advantages may include that it provides shock absorption, more road feel, different performance characteristics, and more comfort than a traditional hard platform. The platform may also be adjusted for more or less tension for different riding surfaces and conditions and the strapping can easily be replaced with natural wear or to personalize the look with custom graphic designs.

A vehicle, comprising: a forward frame portion; a rear frame portion; and a motion control system comprising a first motion control device that movably interconnects the forward frame portion and the rear frame portion and a second motion control device that movably interconnects the forward frame portion and the rear frame portion, wherein the first motion control device connects to the rear frame portion at a first location, and the second motion control device connects to the rear frame portion at a second location that is a fixed distance from the first location, and the motion control system, by virtue of a geometric arrangement of the motion control system relative to the forward frame portion and the rear frame portion, adopts, in response to a forward acceleration of the rear frame portion resulting from a driving force imparted by a wheel supported by the rear frame portion, an operating state in which forces imparted onto the motion control system by a tensioning of a drivetrain element that transfers driving energy from a driving axle supported by the forward frame portion to a driven axle supported by the rear frame portion, the forward acceleration of the rear frame portion, and an acceleration of a user mass supported by the forward frame portion are in equilibrium.

Some embodiments include an energy source supply appliance. The appliance energy source supply system can comprise an appliance energy source supply subsystem, and the appliance energy source supply subsystem can comprise a pressure regulator, a first thermal control device, and a second thermal control device. The appliance energy source supply subsystem can be configured to receive a hydrogen fuel energy source and to make available the hydrogen fuel energy source to a receiver vehicle, and the receiver vehicle can comprise a drive system configured to use the hydrogen fuel energy source received by the receiver vehicle to motively power the receiver vehicle. Other embodiments of related systems, devices, and methods also are provided.

Some embodiments include an energy source supply appliance. The appliance energy source supply system can comprise an appliance energy source supply subsystem, and the appliance energy source supply subsystem can comprise a pressure regulator, a first thermal control device, and a second thermal control device. The appliance energy source supply subsystem can be configured to receive a hydrogen fuel energy source and to make available the hydrogen fuel energy source to a receiver vehicle, and the receiver vehicle can comprise a drive system configured to use the hydrogen fuel energy source received by the receiver vehicle to motively power the receiver vehicle. Other embodiments of related systems, devices, and methods also are provided.

The invention provides a cryogen engine, comprising a first rotor rotatable about a first axis and having at its periphery a recess bounded by a curved surface, and a second rotor counter-rotatable to said first rotor about a second axis, parallel to said first axis, and having a radial lobe bounded by a curved surface, the first and second rotors being coupled for intermeshing rotation, wherein the first and second rotors of each section intermesh in such a manner that on rotation thereof, a transient chamber of variable volume is defined, the transient chamber having a progressively increasing volume between the recess and lobe surfaces; a cryogen injector arranged to inject an amount of cryogenic fluid into the transient chamber once it has formed, such that expansion of the cryogen drives the engine. The invention also provides a method of operating an engine and a method of and system for liquefying air.

Some embodiments include an energy source supply appliance. The appliance energy source supply system can comprise an appliance energy source supply subsystem, and the appliance energy source supply subsystem can comprise a pressure regulator, a first thermal control device, and a second thermal control device. The appliance energy source supply subsystem can be configured to receive a hydrogen fuel energy source and to make available the hydrogen fuel energy source to a receiver vehicle, and the receiver vehicle can comprise a drive system configured to use the hydrogen fuel energy source received by the receiver vehicle to motively power the receiver vehicle. Other embodiments of related systems, devices, and methods also are provided.

Some embodiments include an energy source supply appliance. The appliance energy source supply system can comprise an appliance energy source supply subsystem, and the appliance energy source supply subsystem can comprise a pressure regulator, a first thermal control device, and a second thermal control device. The appliance energy source supply subsystem can be configured to receive a hydrogen fuel energy source and to make available the hydrogen fuel energy source to a receiver vehicle, and the receiver vehicle can comprise a drive system configured to use the hydrogen fuel energy source received by the receiver vehicle to motively power the receiver vehicle. Other embodiments of related systems, devices, and methods also are provided.

Some embodiments include an energy source supply appliance. The energy source supply appliance can comprise an appliance energy source supply system, which in turn can comprise a first appliance energy source supply subsystem and a second appliance energy source supply subsystem. The first appliance energy source supply subsystem can be configured to receive a first energy source. Meanwhile, the second appliance energy source supply subsystem can be configured to make available a second energy source to a first receiver vehicle, and the second energy source can be different from the first energy source. Further, the first receiver vehicle can comprise a first drive system, and the first drive system can be configured to use the second energy source received by the first receiver vehicle to motively power the first receiver vehicle. Other embodiments of related systems, devices, and methods also are provided.

Some embodiments include an energy source supply appliance. The energy source supply appliance can comprise an appliance energy source supply system, which in turn can comprise a first appliance energy source supply subsystem and a second appliance energy source supply subsystem. The first appliance energy source supply subsystem can be configured to receive a first energy source. Meanwhile, the second appliance energy source supply subsystem can be configured to make available a second energy source to a first receiver vehicle, and the second energy source can be different from the first energy source. Further, the first receiver vehicle can comprise a first drive system, and the first drive system can be configured to use the second energy source received by the first receiver vehicle to motively power the first receiver vehicle. Other embodiments of related systems, devices, and methods also are provided.

Disclosed is a method to make N-acetyl-p-aminophenol. The method includes steps for converting biomass-derived p-hydroxybenzoates to p-hydroxybenzamide, then to p-aminophenol; and then N-acetylating the p-aminophenol.