not shown by Fig. 2 but to be later

not shown by Fig. 2 but to be later revealed by the sectioned Nu
profiles in the rib-wise (S-wise) direction.
To exemplify the differential endwall heat transfer properties between the two-pass channels with wavy and flat sidewalls, the centerline Nu profiles between present test channels of AR = 0.5,
1, 2 and the two-pass ribbed square channel with flat sidewalls [21] are compared by Fig. 3. Unlike the present test channels with skewed ribs installed on two endwall corners of the sharp bend, there is no rib on the bend endwall for the two-pass ribbed square channel with flat sidewalls [21]. As compared by Fig. 3, the present centerline Nu profiles sectioned through the ribbed endwalls of the three test channels consistently decrease following the order of AR(e/H) = 2(0.2) ? 1(0.1) ? 0.5(0.05) and are all elevated from the Nu references detected from the two-pass ribbed square channel with flat sidewalls [21]. With the identical AR(e/H) of 1(0.1) for present square test channel and the comparative channel with flat sidewalls [21], the centerline endwall Nu over present inlet and outlet legs are raised from the comparative Nu references [21], Fig. 3. While the overall axial Nu increases are followed by all the two-pass channels with present wavy and flat [21] sidewalls along the inlet legs, the elevations and extensions of the mid-rib high Nu bumps between two successive ribs for present test channels from the comparative counterparts [21] are evident, Fig. 3. With the coswirls tripped by the skewed ribs and the sidewall waves on the two endwall corners of present two-pass test channels, the twinpeak endwall centerline Nu profiles are consistently developed over the bend region for all present test channels; regardless the