Simulating gust-induced sloshing in the fuel tank of a liquid hydrogen powered aircraft
The Background
The sets technology development objectives and funds research in the UK aerospace industry. Its programme was a concerted effort across the sector to develop technology solutions to the problems of hydrogen powered aircraft. ÈÕ±¾avÎÞÂëDigital Engineering was commissioned to investigate the problems associated with the thermo- and fluid dynamics of the liquid hydrogen fuel whilst the aircraft is on ground and in flight.
The Challenge
Liquid hydrogen fuel must be kept at an extremely low temperature, so the normal design solution of using the wings as fuel tanks is not adequate for hydrogen-powered aircraft. Instead, hydrogen must be stored in dedicated pressure vessels located inside the fuselage. Because of this, as the tank empties the fluid is free to slosh in response to aircraft motions. This is a known problem in conventional aircraft too, where the motion of the liquid can impose forces on the structure and alter the centre of gravity of the aircraft, but for liquid hydrogen fuel there is another, more serious problem.
As with any cryogenic fuel, the liquid component is constantly boiling off in response to the thermodynamic equilibrium in the tank. This boil-off is a problem, as it gradually raises the tank pressure, and is a function of the amount of exposed free surface of liquid. Sloshing increases the free surface area and accelerates the boil-off, posing a potential hazard.
The Solution
We developed a Computational Fluid Dynamics (CFD) model of the fuel tank to simulate how the liquid hydrogen would respond to aircraft motions. CFD is a numerically-intensive mathematical tool used to solve the laws of conservation applicable to fluid flow problems. Recent developments in both numerical algorithms and computational power has allowed us to solve ever-more complex problems with CFD, including the modelling of heat transfer through the structure of the tank and the free surface between the liquid and gas inside the tank. The most challenging part was developing and validating against test a model for the equation of state that governs the boiling of the hydrogen.
We could then apply the aircraft motion data as a time-dependent series at the centre of gravity. The model responds by continuously predicting the motion of the liquid and gas, and the mass of gas that changes from liquid to gas state.
The Result
The modelling demonstrated that certain extreme manoeuvres left the liquid hydrogen in a dispersed state throughout the tank, considerably increasing the surface area and accelerating the boil-off rate. Despite this, our work has demonstrated that the pressurisation of the tank was more-likely to be affected by other factors and not by the boil-off rate. The findings of this study have contributed to the conclusions of the “” published by ATI at the end of the FlyZero project. ÈÕ±¾avÎÞÂëDigital Engineering are conducting research to assess means to dampen the liquid motion in the tank, while minimising the additional heat transfer caused by baffles.
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