Evaluating the Transient Energy Dissipation in a Centrifugal Impeller under Rotor-Stator Interaction

Tao, Ran; Zhao, Xiaoran; Wang, Zhengwei

doi:10.3390/e21030271

Cited by 18 publications

(7 citation statements)

References 32 publications

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“…Different models have different requirements for y + and do not have a fixed value. 20,26,27 The average values of y + of each flow passage component are listed in Table 2, and it is less than 60. Because the calculation results are generally satisfactory, the y + value can be considered as appropriate in this paper.…”

Section: Numerical Model and Entropy Production Validationmentioning

confidence: 99%

Energy loss analysis of the double-suction centrifugal pump under different flow rates based on entropy production theory

Guan

Jiang

Yang

et al. 2020

Proceedings of the Institution of Mechanical Engineers, Part C:

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The investigation of energy loss of pump is of great significance for energy conservation and structural optimization design. And traditional methods have great limitations in researching the distribution of energy losses. In this paper, the entropy production theory is utilized to analyze the energy loss of the double-suction centrifugal pump. The numerical simulation results verified by experiments indicate that the difference in total entropy production under different flow rates is mainly affected by the entropy production in the main flow region. Moreover, the entropy production of the volute has the greatest impact on the entropy production in the main flow region, and even the proportion of entropy production in the volute at 1.2 QD operating point reaches 96%. Besides, the Q-criterion is applied to study the morphology of the vortex core in the volute. In the volute inlet region, it is found that the stable double-vortex flow has a better flow field and less energy loss than the scattered wake vortex.

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Section: Numerical Model and Entropy Production Validationmentioning

confidence: 99%

Energy loss analysis of the double-suction centrifugal pump under different flow rates based on entropy production theory

Guan

Jiang

Yang

et al. 2020

Proceedings of the Institution of Mechanical Engineers, Part C:

View full text Add to dashboard Cite

show abstract

“…Thanks to the continuous improvement of entropy production theory by Herwig and Knock [ 17 , 18 , 19 ], the hydraulic losses in rotating machinery [ 20 , 21 ] can be quantitatively evaluated based on the entropy production, which can be calculated in the CFD post-processing. Many scholars have used entropy production theory to visually analyze the distribution of hydraulic losses in pumps.…”

Section: Introductionmentioning

confidence: 99%

Energy Characteristics of a Bidirectional Axial-Flow Pump with Two Impeller Airfoils Based on Entropy Production Analysis

Meng

2022

Entropy

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This research sought to determine the spatial distribution of hydraulic losses for a bidirectional axial-flow pump with arc- and S-shaped impellers. The unsteady Reynolds time-averaged Stokes (URANS) approach with the SST k-omega model was used to predict the internal flow field. The total entropy production (TEP) and total entropy production rate (TEPR) were used to evaluate the overall and local hydraulic losses. The results show that the distribution of TEP and TEPR was similar for both impeller cases. Under a forward condition, TEP mainly comes from the impeller and elbow pipe. The high TEPR inside the impeller can be found near the shroud, and it shifts from the leading edge to the trailing edge with an increase in the flow rate due to the decline in the attack angle. The high TEPR inside the elbow pipe can be seen near the inlet, and the area shrinks with an increase in the flow rate caused by a reduction in the velocity circulation. Under the reverse condition, TEP mainly comes from the impeller and the straight pipe. The TEPR of the region near the shroud is obviously higher than for other regions, and the area of high TEPR near the suction side shrinks with an increase in the flow rate. The high TEPR of the straight pipe can be found near the inlet, and declines in the flow direction. These results provide a theoretical reference for future work to optimize the design of the bidirectional axial-flow pump.

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“…22 With the development of computational fluid dynamics (CFD) technique, entropy production based on the second law of thermodynamics is used to evaluate the energy dissipation details. 23–26 In many optimization cases of turbomachinery, entropy production is also effectively used. Zeinalpour and Mazaheri 27 optimized turbine cascade by using the continuous adjoint formulation and entropy production analyses.…”

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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Evaluating the Transient Energy Dissipation in a Centrifugal Impeller under Rotor-Stator Interaction

Cited by 18 publications

References 32 publications

Energy loss analysis of the double-suction centrifugal pump under different flow rates based on entropy production theory

Energy loss analysis of the double-suction centrifugal pump under different flow rates based on entropy production theory

Energy Characteristics of a Bidirectional Axial-Flow Pump with Two Impeller Airfoils Based on Entropy Production Analysis

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

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