A number of different studies were reviewed to investigate the functionality of splitter plates for the
purpose of drag reduction and vortex elimination behind a circular cylinder. The studies were carried
out numerically or experimentally in different combinations of Reynolds range, 2D or 3D dimensions,
with intention of drag reduction, vortex suppression or both. Results were compared to discover the
generalities of a splitter plate’s applications and its performance in drag reduction and vortex control.
The reduction of 12% up to 38.6% in drag coefficient suggests that all reviewed studies verified the
effectiveness of upstream plate in drag reduction. Varied upstream plate’s gap ratios (gap between the
plate and cylinder) were tested and the optimum position was obtained. For the finite cylinder case,
however, the studies discovered that the effectiveness of upstream plate decreased severely and thus, are
barely considered as a drag reductive tool for shorter cylinders. Although downstream plate influences
drag force, its prominent application is found to be vortex shedding elimination (up to 14.7%). The
length ratio and gap ratio of downstream plate were varied in these studies and it was found that the
length ratio was a more important factor compared with the gap ratio in the case of vortex suppression.