Circulation Budget Analysis of the Leading-Edge Vortex in a Wells Turbine Under Steady Inflow Conditions

Geng, Kaihe; Yang, Ce; He, Xinyu; Hu, Chenxing; Zhang, Hanzhi; Shi, Xiuyong

doi:10.1115/gt2022-81890

Cited by 1 publication

(2 citation statements)

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“…In fact, this problem was discussed in detail in our previous work. 34 At the same time, the situation that there is no obvious separation near the leading edge meets the application requirements of the LEFS technique.…”

Section: Results Analysis and Discussionmentioning

confidence: 97%

“…This configuration of the computation domain can ensure the full development of the inlet and outlet flows. 34 Hexahedral structured mesh generated by IGG v8.9 software 35 was employed to discretize the computation domain. As depicted in Figure 4(b), the grids near the endwall and blade wall were refined to meet the requirement that y + is close to 1 for the two-equation turbulent closure model.…”

Section: Numerical Configuration and Validationmentioning

confidence: 99%

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Leading-edge flow prediction in Wells turbine under the influence of tip leakage flows

Geng,

Yang,

et al. 2023

Proceedings of the Institution of Mechanical Engineers, Part C:

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Monitoring of aerodynamic parameters of the blade helps to enhance the operating capabilities of the Wells turbine. In this study, a few discrete pressure points were used to estimate the pressure patterns by fitting the exact potential-flow solution for flow over a parabola. The sectional aerodynamics was assessed by the leading-edge flow sensing (LEFS) algorithm. A characteristic parameter was employed to deduce leading-edge flow status. Moreover, the influence of rotor speeds and tip gaps on the vortex boundary was discussed in terms of the Lagrangian frame. For the rotor speed larger than 1000 rpm at the incipient stall point, there is no boundary layer separation at the suction side of the blade tip leading edge. At the same rotor speed, a large tip gap reduces the axial shear of the suction flows and the axial stretching of the tip leakage vortex, which helps to enhance the interaction time and strength of the leakage vortex and the suction flows. For the Wells turbine with attached flows, the LEFS algorithm can accurately evaluate the pressure distribution and suction parameters near the leading edge. The LEFS-derived dimensionless parameter can act as an equivalent angle of attack under different tip gaps, providing the possibility for stall warning of Wells turbines.

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Section: Results Analysis and Discussionmentioning

confidence: 97%

Section: Numerical Configuration and Validationmentioning

confidence: 99%