Study on high-temperature hydrogen dissociation for nuclear thermal propulsion reactor.

• Hydrogen dissociation in NTP reactors was analyzed by the numerical method. • Thermophysical properties of H-H 2 were established and validated from 200 to 3000 K. • Degree of dissociation was small and x H,out was just 0.456% in the NRX-A6 reactor. • Power density was one of the most significant factors for hydrogen dissociation. Nuclear thermal propulsion utilizes the nuclear reactor rather than the combustion chamber to yield thermal energy. Propellant hydrogen could dissociate in the high-temperature reactor, which has an important effect on thermal hydraulic performance of the reactor. In this study, a one-dimensional steady-state analysis code has been developed for studying the behavior of hydrogen flowing through the high-temperature coolant channel. Thermal dissociation and real gas thermophysical property models of hydrogen were proposed and considered in the calculation models. It was found that the model validation deviations of thermophysical properties were within ± 5% in the range of 200 ∼ 3000 K and 0.01 ∼ 10.0 MPa. Developed models were reliable and accurate with validation. Thermal-hydraulic behaviors of hydrogen in NRX-A6 reactor channel were analyzed. When dissociation occurred, the variation of properties was larger than those without dissociation, which enhanced heat transfer. The degree of dissociation was small and x H, out was just 0.456% under the design condition. The power density was the most significant influence factor, especially under the high power density. x H, out was 3.2 times than that of design condition as the power density grew 20%. This study can provide an approach to study hydrogen dissociation phenomena in nuclear thermal propulsion reactors. [ABSTRACT FROM AUTHOR]