Experiments were conducted with two, smooth hills, lying well within the boundary layer over a flat plate mounted in a wind tunnel. One hill was shallow, with peak height 1.5 mm and width 50 mm; the other, steep, 3 mm high and 30 mm wide. Since the hills occupied one-half of the tunnel span, streamwise vorticity formed near the hills’ edge. At a freestream speed of 3.5 m/s, streaks formed with inflectional wall-normal and spanwise velocity profiles but without effecting transition. Transition, observed at 7.5 m/s, took different routes with the two hills. With the steep hill, streamwise velocity signals exhibited the passage of a wave packet which intensified before breakdown to turbulence. With the shallow hill there was a broad range of frequencies present immediately downstream of the hill. These fluctuations grew continuously and transition occurred within a shorter distance. Since the size of the streamwise vorticity generated at the hill edge is of the order of the hill height, the shallow hill generates vorticity closer to the wall and supports an earlier transition, whereas the steep hill creates a thicker vortex and associated streaks which exhibit oscillations due to their own instability as an additional precursor stage before transition.
展开▼
机译:实验是在安装在风洞中的平板上方边界层内的两个光滑山丘上进行的。一座山很浅,峰高1.5毫米,宽50毫米。另一个陡峭,高3毫米,宽30毫米。由于丘陵占据了隧道跨度的一半,因此在丘陵边缘附近形成了沿流的涡流。在3.5 m / s的自由流速度下,条纹会形成弯曲的壁法线和翼展方向速度曲线,但不会影响过渡。在这两个山丘上,以7.5 m / s的速度观察到的过渡路线不同。在陡峭的山坡上,水流速度信号显示出一个波包通过,该波包在分解为湍流之前就增强了。对于浅山丘,在山丘的下游存在大量的频率。这些波动持续增长,并且在较短的距离内发生过渡。由于在山坡边缘产生的沿流方向的涡旋的大小约为山丘高度的水平,因此浅山坡在靠近壁的地方产生涡旋并支持较早的过渡,而陡峭山坡则形成较厚的涡旋和相关的条纹,并表现出振荡由于它们自身的不稳定性,因此在过渡之前是一个额外的前体阶段。
展开▼
