Loss Mechanisms of Interplatform Steps in a 1.5-Stage Axial Flow Turbine

Kluxen, Robert; Behre, Stephan; Jeschke, Peter; Guendogdu, Yavuz

doi:10.1115/1.4034848

Cited by 12 publications

(5 citation statements)

References 26 publications

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“…Many studies have applied SLT based on computational fluid dynamics (CFD) to the flow of turbomachinery. For reversible pump turbines, especially under the high-efficiency conditions of frequent operation, SLT can be used to track, visualize and eliminate FED (Jia and Liu, 2014;Zeinalpour and Mazaheri, 2015;Kluxen, et al, 2016). Among them, entropy production rate is one of the effective methods for FED quantitative analysis.…”

Section: Introductionmentioning

confidence: 99%

Comparative evaluation of the pump mode and turbine mode performance of a large vaned-voluted centrifugal pump

Yang

et al. 2022

Front. Energy Res.

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Large vaned-voluted centrifugal pump is a general machine used for large-scale water diversion. As a vane-type hydraulic machinery, it also has the ability of reversible operation. With the introduction of policies to reduce carbon emissions, the proportion of unstable new energy use has increased. The existing large centrifugal pump unit can realize the function of reverse power transfer. For peak shaving and valley filling of power grid, it has high feasibility and economy. In this paper, a large vaned-voluted centrifugal pump is simulated numerically, it is external characteristics and flow state under positive and negative rotation are obtained, its performance is predicted by best efficiency point method, and it is found that pump reversal can run at the optimum efficiency point with higher flow rate and head. Error analysis is carried out for different formulas. The flow energy dissipation (FED) of different flow rates under positive and negative rotation is analyzed. It is found that the main energy loss locates on suction side of blade, inlet and outlet part of blade and tail part of guide blade head. By comparing the flow energy dissipation distribution under the same flow conditions with positive and reverse rotation, it is found that the high energy loss area of blade mainly exists in inlet and outlet part of blade in pump mode. The high energy loss area of the blades in turbine mode mainly exists in the inlet part of the blades. This study is of great significance to the operation of low-carbon power grid assisted by existing reservoirs and hydraulic machinery.

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Section: Introductionmentioning

confidence: 99%

Comparative evaluation of the pump mode and turbine mode performance of a large vaned-voluted centrifugal pump

Yang

et al. 2022

Front. Energy Res.

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“…The region of high energy loss and the mechanism of loss formation are studied. Kluxen et al 21 carried out numerical analysis on the internal energy loss of axial-flow turbine. It is found that different local velocity will change the entropy production.…”

Section: Introductionmentioning

confidence: 99%

Large eddy simulation of the flow energy dissipation in the blade channels of a stalled pump impeller

Zhu

Tao

Xiao

2022

Proceedings of the Institution of Mechanical Engineers, Part A:

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Pump impellers usually work with the rotating stall phenomenon. The performance will be strongly affected by the undesirable flow. Understanding the features of flow energy dissipation is very important. In this study, large eddy simulation is conducted for the turbulent flow field based on a typical 6-blade pump impeller with “alternating stall” phenomenon. The stalled channels and well-behaved channels alternatively and stably distribute. Compared with the experimental data, the numerical simulation is proved accurate. In the well-behaved channel, flow pattern is relatively smooth. In the stalled channel, flow is completely blocked by several stall cells. Vortex shedding is well predicted mainly in three regions including the leading-edge region of stalled channel, the outlet region of stalled channel, and the blade suction side region of well-behaved channel. Turbulence kinetic energy is high in these regions. High flow energy dissipation is found among shedding vortexes due to flow-flow interaction and in the near-wall region because of flow-wall interaction. In the core region of vortexes, flow energy dissipation is not that high. The flow-flow interaction and the flow-wall interaction are two main sources of flow energy dissipation. In the well-behaved impeller blade channel with smooth flow pattern, the flow energy dissipation is mainly caused by flow-wall interaction. On the contrary, in the stalled impeller blade channel with vortical flow pattern, the flow energy dissipation is mainly caused by flow–flow interaction. The large eddy simulation-based study will be very helpful in enhancing the performance of pump impellers especially with the rotating stall phenomenon.

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“…Kluxen et al. 28 studied the entropy production details in axial-flow turbine for loss reduction. Soltanmohamadi and Lakzian 29 conducted optimization design for turbine unit on the basis of entropy production visualization.…”

Section: Introductionmentioning

confidence: 99%

A machine-learning approach to predicting the energy conversion performance of centrifugal pump impeller influenced by blade profile

Tao

Zhu

et al. 2021

Proceedings of the Institution of Mechanical Engineers, Part C:

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Centrifugal pump is a kind of energy conversion machine for fluid delivering. It transfers the mechanical energy of impeller to the potential and kinetic energy of fluid. As a key factor in influencing the energy conversion performance of centrifugal pump, blade profile design is crucial. Traditional design concepts have ideal assumptions. To have a better design guidance, machine-learning based on neural network is used in this study. A typical centrifugal pump with simplified blade profile is numerically studied with experimental validation for a better discussion. Statistical results show that, for the high dimensional nonlinear relationship between blade angle and performance of centrifugal pump, neural network can adapt to this complex correlation better. The blade installation angle at leading-edge ( βLE′) and trailing-edge ( βTE′) and the wrap angle (Δ θ′) has significant correlation with the performance including pump head H, pump efficiency η, impeller head Himp, impeller efficiency ηimp and volute loss Δ Hvol. The influence level of blade angle follows the high-to-low order of Δ θ′, βLE′ and βTE′. Determination of blade profile can be done for improving the energy conversion efficiency. Optimal blade profiles have higher βLE′ and Δ θ′ with better flow-control ability. Compared with the blade parameters of the initial pump, the blade profile with the best centrifugal pump efficiency is the best βLE′ increased by 1.926°, Δ θ′ increased by 9.858°, Optimization of impeller efficiency βLE′ increased by 1.855°, Δ θ′ increased by 9.421°. Computational fluid dynamics indicate the elimination of vortex in impeller after optimal selection. Then, βTE′ and Δ θ′ are found influential in aggravating the circumferential flow component in this special circular-volute with generating higher loss. βTE′ has a positive correlation with impeller head which suits traditional theory. In general, the machine-learning using neural network is effective in determining blade profiles for enhancing the performance of centrifugal pump.

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Loss Mechanisms of Interplatform Steps in a 1.5-Stage Axial Flow Turbine

Cited by 12 publications

References 26 publications

Comparative evaluation of the pump mode and turbine mode performance of a large vaned-voluted centrifugal pump

Comparative evaluation of the pump mode and turbine mode performance of a large vaned-voluted centrifugal pump

Large eddy simulation of the flow energy dissipation in the blade channels of a stalled pump impeller

A machine-learning approach to predicting the energy conversion performance of centrifugal pump impeller influenced by blade profile

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