This study investigates the flow field and suspension phenomena of a large thin plate being transported vertically. For analyzing the lifting forces caused by flow disturbances, pressure distributions along upper and lower surfaces of the thin plate must be acquired and for processing this moving boundary problem, both Generalized Minimal Residual method (GMRES) and Arbitrary Lagrangian-Eulerian method (ALE) are adopted. In advance, this study utilizes a top heated, reciprocating curved channel with rib installed to verify the adoptability of numerical methods mentioned, and by relationship between channel pressure distributions and increment of heated surface’s back region heat transfer rates, these numerical methods are suitable for calculating the flow field induced by large thin plate vertical transportation. The results show that by moving accelerations of supporting frames and the thin plate, a tendency of suspension can be predicted, and by displacements of moving distances, the suspension timing can be predicted exactly. Furthermore, as the transporting speed increases, more likely the thin plate will suspend. This study utilizes finite element method (FEM), also the Pressure Convection -Diffusion preconditioning method (PCD) is adopted to increase convergent efficiency of GMRES iteration, and by advantages of multi-core computer, parallelization of the program by coding OpenMP directives is utilized to lower calculating time.