3. Results and discussionwave-ampli

3. Results and discussion

wave-amplitude, as well as the ratio of endwall rib-pitch to side- wall wave-pitch at the same values, the variations of channel width-to-height (AR = W/H) ratio are achieved by varying the height of the wavy sidewall. As a result, the respective rib-height (e) to channel-height (H) ratios for present two-pass channels of AR = 0.5, 1 and 2 are e/H = 0.05, 0.1 and 0.2. As e/H increases, the overall endwall heat transfer levels and the later examined pressure drop coefficients (f) are accordingly increased with the emerg- ing heat transfer characteristics attributed to the flow phenomena tripped by angled ribs, Fig. 2. In this regard, the high Nu stripe along the top face of each skewed rib shown by Fig. 2(c) is clearly visible over the ribbed endwall for present two-pass channel of AR = 2, e/H = 0.2. As compared by Fig. 2(c)–(b)–(a), such high Nu stripes along the rib-tops over the ribbed endwalls are systematically faded as AR and/or e/H decreases. Other heat transfer signatures induced by the angled ribs include the general rib-wise Nu decays from the obtuse edge to the acute edge of inlet/outlet leg and the high Nu regions initiated at the obtuse corner behind the angle ribs, Fig. 2. Adding the flow complexities tripped by the wavy sidewalls for present two-pass test channels, the high Nu zones behind the angled ribs over the inlet-leg/outlet-leg endwall are extended from those developed in a typical ribbed two-pass channel with flat sidewalls [21]. Moreover, acting by the complex vortical flow interactions between the Dean-type vortices, the rib induced swirls and the vortices tripped by the skewed sidewall waves in present sharp bends of three test channels, the considerable heat transfer elevations prevail over the most of turning regions as shown by the three endwall Nu imprints in Fig. 2. While the low Nu region attached along the inner edge downstream thetip of the central divider is typically induced by the separation‘‘air bubble’’ attached on the central divider in the outlet leg of a two-pass channel with a sharp bend and flat sidewalls, there is no clear sign of such low Nu imprint to feature the re-circulating air bubble attached downstream the tip of the central divider for present two-pass channels with wavy sidewalls, Fig. 2. However, due to the limitation for unifying the Nu scales for the three endwall Nu imprints collected in Fig. 2, the rib-wise Nu variations along the last/first rib of the inlet/outlet leg over the endwall of the turning region for each of present two-pass test channels are