TITLE:
Proposal of a Deuterium-Deuterium Fusion/PWR Fission Hybrid Reactor
AUTHORS:
Patrick Lindecker
KEYWORDS:
Fusion Reactor, Fission Reactor, Hybrid Reactor, Nuclear Energy, Deuterium-Deuterium Reactor, Deuterium, Colliding Beams, Racetrack, Stellarator, Power Plant, PWR
JOURNAL NAME:
World Journal of Nuclear Science and Technology,
Vol.14 No.4,
October
31,
2024
ABSTRACT: This article proposes to associate a Deuterium-Deuterium (D-D) fusion reactor with a PWR (fission Pressurized Water Reactor) in a hybrid reactor. Even if the mechanical gain (Q factor) of the D-D fusion reactor is below the unity and consequently consumes more energy than it supplies, due to the high energy amplification factor of the PWR fission reactor, the global yield is widely superior to 1. As the energy supplied by the fusion reactor is relatively low and as the neutrons supplied are mainly issued from D-D fusions (at 2.45 MeV), the problems of heat flux and neutrons damage connected with materials, as with D-T fusion reactors are reduced. Of course, there is no need to produce Tritium with this D-D fusion reactor. This type of reactor is able to incinerate any mixture of natural Uranium, natural Thorium and depleted Uranium (waste issued from enrichment plants), with natural Thorium being the best choice. No enriched fuel is needed. So, this type of reactor could constitute a source of energy for several thousands of years because it is about 90 more efficient than a standard fission reactor, such as a PWR or a Candu one, by extracting almost completely the energy from the fertile materials U238 and Th232. For the fusion part, it is based on reasonable hypotheses done on present Stellarators projects. The working of this reactor is continuous, 24 hours a day. In this paper, it will be targeted a reactor able to provide a net electric power of about 1400 MWe, as a big fission power plant.