Effect of cavitation evolution on power characteristics of tidal current turbine

Gao, Yanjing; Liu, Hongwei; Guo, Guanzhu; Lin, Yaolin; Gu, YuanTong; Ni, Yiming

doi:10.1063/5.0131906

Cited by 11 publications

(2 citation statements)

References 45 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…For the outlet conditions, the outlets of the three outlet chambers are all set as pressure-free outlets, i.e., the total pressure at the outlet of the draft tube P out = 0 pa. For the fixed wall condition, this paper adopts the non-slip boundary; for the dynamic static interface, this paper adopts the dynamic static coupling surface. Other detailed parameter settings related to visual effects can be found in references [28][29][30]. H, η, and output P (kW) are key performance indicators for the HTTM-ULSS that can be used to compare the hydraulic performance of different HTTM-ULSS models and are calculated using Equations ( 16)-( 18) [21].…”

Section: Boundary Conditions and Performance Parameter Calculationmentioning

confidence: 99%

Influence Analysis of Runner Inlet Diameter of Hydraulic Turbine in Turbine Mode with Ultra-Low Specific Speed

Chen,

Zheng,

Zhang

et al. 2023

Energies

View full text Add to dashboard Cite

The hydraulic turbine in turbine mode (HTTM) with an ultra-low specific speed (HTTM-ULSS) has the advantages of a simplified structure, high efficiency, and good stability and has great application value in the industry. However, the influence of the runner inlet diameter (D1) on the performance of HTTM-ULSS has not yet been fully studied. Therefore, the three-dimensional models of Francis runners were established in the ultra-low specific speed range by examining D1 = 0.49 m, 0.5 m, and 0.51 m, and the two-stage hydraulic turbine models were constructed with flow passage components. Then, internal flow and energy characteristics were calculated using Fluent 16.0 software. Further, the influence of D1 on HTTM performance was studied by comparing numerical simulation results. The results show that the water head of the HTTM-ULSS can reach 540.87 m when D1 = 0.51 m, showing its powerful ability to recover the pressure energy in high-pressure water. Moreover, the head and efficiency are closely related to D1; when D1 increases, the circulation at the runner inlet increases, resulting in an enhancement in the ability to recover the water head and decreases in efficiency and in the operating range of the high-efficiency zone; with D1 increasing, the flow pattern inside the runner becomes better, but the high-pressure area of the blade increases. When selecting the D1, attention should not only be paid to the ability to recover the water head but also to the pressure of the runner blades and the internal water flow pattern.

show abstract

Section: Boundary Conditions and Performance Parameter Calculationmentioning

confidence: 99%

Influence Analysis of Runner Inlet Diameter of Hydraulic Turbine in Turbine Mode with Ultra-Low Specific Speed

Chen,

Zheng,

Zhang

et al. 2023

Energies

View full text Add to dashboard Cite

show abstract

“…Cavitation is a phase change process of water. When the local pressure is lower than the saturated vapor pressure, water will change from liquid phase to vapor phase [4]. Cavitation is widely found in various hydraulic machinery, such as pumps [5,6], inducers [7], propellers [8] and pump turbines [9].…”

Section: Introductionmentioning

confidence: 99%

Study of Hydrofoil Unstable Partial Cavitation Emphasizing Unstable Sheet Cavitation Phenomenon

Wang,

Tang

2024

J. Phys.: Conf. Ser.

View full text Add to dashboard Cite

Unstable partial cavitation phenomenon often occurs during the operation of axial flow pumps. In this paper, the hydrofoil of an axial flow pump is taken as the research object, and the cavitation morphology at the design angle of attack is obtained by high-speed photography. And the flow characteristics under the transformation cavitation number of sheet cloud cavitation are studied by SBES turbulence model. The hydrofoil has hydrodynamic phenomena such as unstable sheet cavitation and multistage cloud cavitation. The high pressure propagating upstream from the trailing edge may be the cause of secondary cloud shedding, and the closer to the hydrofoil wall surface, the greater the intensity of this pressure. The frequency of unstable sheet cavitation shedding is 166.6 Hz. The instable closure of cavitation and the hydrofoil wall may be the main cause of unstable sheet cavitation formation. The generated quasi-periodic re-entrant jet will have a greater impact on the flow in the rear of the hydrofoil. This study provides reference for the design and operation of axial flow pumps and prevention of cavitation damage.

show abstract

Investigation on the vortex formation mechanism of flat hydrofoil under stall condition considering cavitation and non-cavitation states

et al. 2023

View full text Add to dashboard Cite

Effect of cavitation evolution on power characteristics of tidal current turbine

Cited by 11 publications

References 45 publications

Influence Analysis of Runner Inlet Diameter of Hydraulic Turbine in Turbine Mode with Ultra-Low Specific Speed

Influence Analysis of Runner Inlet Diameter of Hydraulic Turbine in Turbine Mode with Ultra-Low Specific Speed

Study of Hydrofoil Unstable Partial Cavitation Emphasizing Unstable Sheet Cavitation Phenomenon

Investigation on the vortex formation mechanism of flat hydrofoil under stall condition considering cavitation and non-cavitation states

Contact Info

Product

Resources

About