The marine propulsion systems that exist at the moment rely on the product
creating an almost continuous flow in which the mechanical energy is given
to the liquid in a continuous fashion. Here we study an original seawater p
ropulsor in which the mechanical energy is provided to the liquid by the al
ternative displacement of a fluid contact surface. The produced flow is cha
nneled towards the back of the vehicle that has to be propelled by a system
of valves, in order to create an average positive thrust. These valves are
free, so their operation is linked with the flow resulting from the intera
ction between the surface and the fluid contained within the mechanism. The
mode of surface displacement clearly shows the discontinuous character of
the transmission of the mechanical energy from the engine to the fluid as w
ell as the unsteady flow produced. Therefore we have developed a model whic
h permits study of the technical and geometrical characteristics, the parti
cular flow sizes (pressure and velocity), and the performance of the propul
sion system (thrust and efficiency). Three basic parameters allow study of
the evolution of the performance of the device in correlation to its geomet
ry. Moreover, we show that it's possible to make the flow almost continuous
by increasing the internal fluid mass of the mechanism considerably.