The permeate flux (J) and volume throughput (Q) dependence on rotation (omega), diameter (D), Reynolds Number (Re) and shear rate (gamma) for a high shear rotary membrane system (HSR-MS) was investigated to determine if larger, slower rotated discs could lead to a smaller system weight and foot/cube-print which is needed for US Navy shipboard placement. The HSR-MS steady state flux (J(ss)) was highly dependent on omega and D ranging from 10 to 433 L/m(2) hr (LMH). For every 100 rpm increase in omega, J(ss) increased on average by 26 LMH. The outer membrane third provided >= 50% of the total flow, with the inner third providing about 15%. The J(ss)-gamma relationship was extended to larger membranes (312 and 374 mm) and predicted that J(ss) increased by about 15% for each increase in size. Q(ss) was much more sensitive to increases in diameter and corresponding surface area - Q increased by 45% for D=267 mm -> 312 mm and 65% increased for D=312 mm -> 374 mm (approximate to 1% increase in Q per mm increase in diameter). Collectively, the results show that larger discs, rotated at lower rotations, can produce similar or greater Q compared to smaller discs rotating faster (C) 2014 Published by Elsevier B.V.