This invention is pioneering a Strategic Trans-orbital Carrier (herein called a carrier’) which merges the technologies attributes of a plurality commercial jet engines with a plurality reusable rocket engines to provide capabilities permitting a smooth computer-controlled transition from terrestrial air space to insertion into and thru low earth orbit (LEO) and into high geostationary earth orbit (GEO). A carrier would return back to terrestrial air space with carrying approximately 60 tons of any type of customers' defined cargo and passengers which would include intermodal container modules, complete DoD military strategic devices; heavy industrial outfitting apparatuses; building components for infrastructure complexes; personnel and robots; and space defensive materials to an in-situ space complex. With a fleet of carriers', a routine commercial services becomes available that are built to and guided by FAA flight regulations using specific airport with runways greater than 8,000 feet and that can handle a carriers weight.

A galley monument having an integrated display arrangement includes a display; a display holder, by which the display is movably attached to the galley monument, wherein the display holder is designed as a rotary-pivot joint; and a receiving region, into which the display can be pivoted into a stowed state by the display holder; wherein the display can be rotated by the display holder in a state of use in order to set an orientation for use.

A galley monument having an integrated display arrangement includes a display; a display holder, by which the display is movably attached to the galley monument, wherein the display holder is designed as a rotary-pivot joint; and a receiving region, into which the display can be pivoted into a stowed state by the display holder; wherein the display can be rotated by the display holder in a state of use in order to set an orientation for use.

A device including a first member for supporting a user; and a second member 14, attached to the first member, including a counterbalance portion. The first member and the second member are each moveable, and operable to slide with respect to each other in opposite directions, between a first position and a second position. The device can be operable such that between the first and second positions, the combined center of mass of the device 10 and its user remains substantially fixed. This serves to reduce the extent of forces and vibrations generated by use of the device on the object to which the device is located.

Disclosed is a modular, human-crewed interplanetary spacecraft that is assembled in cislunar space. It is primarily comprised of a hollowed-out asteroid; five expandable habitation modules, one of which is expanded inside the asteroid cavity; two docking and airlock nodes; two landing craft suitable for exploring celestial bodies; structural support members; truss structures; robotic arms; a propulsion module; and shielding curtains that are filled with pulverized asteroidal material and attached to the truss structure. This configuration provides substantial radiation and meteoroid shielding. Upon completion of their mission, the crew will use the robotic arms to disconnect and mate (1) the asteroid containing the control module, (2) the forward docking and airlock node, and (3) the propulsion module. This crew-return vehicle will return to cislunar space. The remaining expandable modules with trusses, robotic arms, and landing craft will remain in the destination orbit to serve as a space station for future missions.

Disclosed is a modular, human-crewed interplanetary spacecraft that is assembled in cislunar space. It is primarily comprised of a hollowed-out asteroid; five expandable habitation modules, one of which is expanded inside the asteroid cavity; two docking and airlock nodes; two landing craft suitable for exploring celestial bodies; structural support members; truss structures; robotic arms; a propulsion module; and shielding curtains that are filled with pulverized asteroidal material and attached to the truss structure. This configuration provides substantial radiation and meteoroid shielding. Upon completion of their mission, the crew will use the robotic arms to disconnect and mate (1) the asteroid containing the control module, (2) the forward docking and airlock node, and (3) the propulsion module. This crew-return vehicle will return to cislunar space. The remaining expandable modules with trusses, robotic arms, and landing craft will remain in the destination orbit to serve as a space station for future missions.

A space relevator adapted to transition an object between a stationary compartment and a rotating module rotating in a first direction, the relevator comprising: a relevator module comprising a plurality of substantially solid pie-shaped structures separated by a plurality of pie-shaped compartments all positioned around a central axis; a relevator central shaft extending along the central axis; the relevator module being adapted to receive a rotate signal and a stop signal, one or more of the pie-shaped compartments comprising an entry between the stationary compartment and the rotating module when the relevator module receives a stop signal and after the relevator module receives a rotate signal.

A space relevator adapted to transition an object between a stationary compartment and a rotating module rotating in a first direction, the relevator comprising: a relevator module comprising a plurality of substantially solid pie-shaped structures separated by a plurality of pie-shaped compartments all positioned around a central axis; a relevator central shaft extending along the central axis; the relevator module being adapted to receive a rotate signal and a stop signal, one or more of the pie-shaped compartments comprising an entry between the stationary compartment and the rotating module when the relevator module receives a stop signal and after the relevator module receives a rotate signal.

A hydrophilic coating for use with a heat exchanger includes an insolubilizer configured to provide structure or support for the hydrophilic coating. The hydrophilic coating further includes a wetting agent configured to provide wettability for the hydrophilic coating. The hydrophilic coating further includes an antibacterial agent configured to eliminate at least a portion of bacteria that contacts the hydrophilic coating. The hydrophilic coating further includes an antifungal agent configured to eliminate at least a portion of fungi that contacts the hydrophilic coating, the antifungal agent being different than the antibacterial agent and the insolubilizer.

A hydrophilic coating for use with a heat exchanger includes an insolubilizer configured to provide structure or support for the hydrophilic coating. The hydrophilic coating further includes a wetting agent configured to provide wettability for the hydrophilic coating. The hydrophilic coating further includes an antibacterial agent configured to eliminate at least a portion of bacteria that contacts the hydrophilic coating. The hydrophilic coating further includes an antifungal agent configured to eliminate at least a portion of fungi that contacts the hydrophilic coating, the antifungal agent being different than the antibacterial agent and the insolubilizer.