This invention relates to technology used for creating an enhanced artificial magnetosphere or electromagnetic shield for use in both manned and unmanned spacecraft. The invention includes an Interference Generating Pattern (IGP) which is tuned to the high-frequency radiation of X-rays and gamma rays and a conformal magnetic field. This technology will reduce the exposure of astronauts or other space travelers, as well as radiation-sensitive equipment, to the environmental hazards present therein. The net result will be reduced flux intensity in order to create a space radiation-free environment as to render space travel safe.

Apparatus, systems, and methods for protecting a vehicle from a radiation source (e.g., the sun) are provided. One apparatus includes a set of first wires and a set of second wires located proximate to the set of first wires. The set of first wires maintains a positive voltage and the set of second wires maintains a negative voltage. The set of first wire and the set of second wires are arranged to generate an electrostatic field (ESF) between the vehicle and the radiation source. A system includes a spacecraft and a field generator that generates an ESF between the spacecraft and a radiation source. A method includes tracking a location of a spacecraft relative to a radiation source and generating an ESF between the spacecraft and the radiation source.

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 spacecraft radiation shield system (2) is disclosed for improving the protection from ionising radiation from the external environment and providing an improved freedom of orientation to the spacecraft. The spacecraft radiation shield system includes: at least two magnets arranged in a magnetic multipole (6), a magnetometer (14), and an adjustable magnet (10). The magnetometer (14) is configured to measure the magnetic field experienced at the spacecraft, and the magnetic field orientation of the adjustable magnet (10) is controlled in response to the measured magnetic field thereby controlling the direction and magnitude of the overall dipole moment of the system

In some aspects, this disclosure relates to improved Z-grade materials, such as those used for shielding, systems incorporating such materials, and processes for making such Z-grade materials. In some examples, the Z-grade material includes a diffusion zone including mixed metallic alloy material with both a high atomic number material and a lower atomic number material. In certain examples, a process for making Z-grade material includes combining a high atomic number material and a low atomic number material, and bonding the high atomic number material and the low atomic number together using diffusion bonding. The processes may include vacuum pressing material at an elevated temperature, such as a temperature near a softening or melting point of the low atomic number material. In another aspect, systems such as a vault or an electronic enclosure are disclosed, where one or more surfaces of Z-grade material make up part or all of the vault/enclosure.

A system to create a magnetic field around the outside of a spacecraft to afford human occupants and electronic equipment with protection from cosmic and solar radiation. Using electromagnets to generate magnetic fields placed on the outer surface of the spacecraft, cosmic and solar radiation may be deflected from entering the main body of the spacecraft. In addition, the magnetic field lines are kept away from the human occupants and interior electronic equipment. Side electromagnets are placed on the side outer surface of the spacecraft and separate electromagnetics are positioned in a cross shaped configuration at the front and rear of the spacecraft in alignment with the side electromagnets. Magnetic field lines are channeled around the outside of the spacecraft or centered on the center of quadrupole magnets placed either at the front of rear of the spacecraft.

A supporting frame for aerospace applications comprises a plurality of rods, which are arranged along two bases substantially parallel and opposite each other, and along two sides, which are substantially parallel and opposite to each other and are coupled to each other via the two bases; the rods are coupled to each other in a mutually rotating manner by nodes so as to be able to configure the supporting frame between a deployed operating condition and a compacted operating condition; the nodes are spaced apart from one another in the deployed operating condition and are each hinged to at least two of the rods; in the compacted operating condition, each of the nodes is placed side by side with two adjacent nodes so as to form, together, two supporting members arranged at opposite longitudinal ends of the supporting frame and each being ring-shaped.

A system to create a magnetic field or fields around the outside of a spacecraft to provide protection from cosmic and solar radiation. Electromagnets are placed within one or more layers of the outer shell or surface of a spacecraft and are used to generate magnetic fields. Side electromagnets are placed within one or more of the side layers of the outer shell or surface of the spacecraft and separate configurations of electromagnets are positioned within one or more layers of the outer shell or surface of the spacecraft, in a cross shaped configuration, either Quadrupole electromagnet configuration or two right-angled electromagnet configuration, at the front and rear of the spacecraft in geometric alignment with the opposite poled side positioned electromagnets. Magnetic field lines are channeled around the outside of the spacecraft by use of the right-angled electromagnet configuration or centered on the center of the quadrupole electromagnet configuration.

A system to create a magnetic field around the outside of a spacecraft to afford human occupants and electronic equipment with protection from cosmic and solar radiation. Using electromagnets to generate magnetic fields placed on the outer surface of the spacecraft, cosmic and solar radiation may be deflected from entering the main body of the spacecraft. In addition, the magnetic field lines are kept away from the human occupants and interior electronic equipment. Side electromagnets are placed on the side outer surface of the spacecraft and separate electromagnetics are positioned in a cross shaped configuration at the front and rear of the spacecraft in alignment with the side electromagnets. Magnetic field lines are channeled around the outside of the spacecraft or centered on the center of quadrupole magnets placed either at the front of rear of the spacecraft.

In some aspects, this disclosure relates to improved Z-grade materials, such as those used for shielding, systems incorporating such materials, and processes for making such Z-grade materials. In some examples, the Z-grade material includes a diffusion zone including mixed metallic alloy material with both a high atomic number material and a lower atomic number material. In certain examples, a process for making Z-grade material includes combining a high atomic number material and a low atomic number material, and bonding the high atomic number material and the low atomic number together using diffusion bonding. The processes may include vacuum pressing material at an elevated temperature, such as a temperature near a softening or melting point of the low atomic number material. In another aspect, systems such as a vault or an electronic enclosure are disclosed, where one or more surfaces of Z-grade material make up part or all of the vault/enclosure.