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<\/p>\nThe D’Onghia magnetic shielding crew hat, or CREW HaT, is a system that uses electromagnetic coils to deflect cosmic radiation from astronauts. The system consists of: <\/p>\n
A ring of electrical coils positioned on arms roughly 5 meters from the spacecraft’s main body
\nA Halbach Torus, a circular array of magnets that creates a stronger field on one side while reducing the field on the other side
\nSuperconducting tapes
\nWhen turned on, the system forms an extended magnetic field outside the spacecraft that deflects the cosmic radiation<\/p>\n
The CREW HaT concept<\/b>
\nThe Cosmic Radiation Extended Warding (CREW) magnetic shield concept is based on a cylindrical Halbach array arrangement, or Halbach Torus (HaT). In the embodiment described here, the system consists of eight electromagnet racetrack coils disposed around the habitat region with rotating magnetic polarities. Such a configuration produces a magnetic field extending in the space around the CREW HaT while suppressing it in the habitat region at the center. Each coil is equipped with several rare-earth barium copper oxide (ReBCO) high-temperature superconducting tape wrappings to achieve the needed currents and generate a magnetic field in the surrounding space. The coils are equipped with dedicated cryocoolers, thus avoiding single-point failures. Solar panels may be considered to power the cryogenic pumps independently. Each coils’ containment structure is designed to support hoop stresses from self-induced magnetic forces. In addition, the coil support structure to the main body is designed to be deployable and withstand inter-coil magnetic forces.<\/p>\n
The preliminary feasibility study, described in section III, shows that the optimized current is 4 million Amps, corresponding to a maximum magnetic field strength of about 10 T. This current can be achieved by wrapping the conductor N times so that a current Ic is effectively amplified to N\u00d7 I1. To achieve such high currents, it is possible to use the recently developed high-temperature superconductors such as ReBCO. These wires’ high current carrying capabilities significantly reduce the magnets’ weight, while the strength of the fields can be about three times higher than of more conventional superconductors.<\/p>\n
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Commonwealth Fusion Systems (CFS) and MIT developed a 20 tesla superconducting magnet. The magnet was demonstrated in 2021. It’s the most powerful fusion magnet in the world. The CFS SPARC device, a collaboration between CFS and the Massachusetts Institute of Technology, will have 18 similar magnets. SPARC is currently under construction at a site outside Boston, with initial operations planned for 2025.<\/p>\n
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