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Journal of Thermal Science

热科学学报

Journal of Thermal Science >

2024 , Vol. 33 >Issue 4: 1325 - 1339

DOI: https://doi.org/10.1007/s11630-024-1966-4

Aerothermodynamics

Comparative Analysis of Diagonal and Centrifugal Compressors with Synergy Theory in Compressed Air Energy Storage System

  • ZHANG Yuxin ,
  • ZUO Zhitao ,
  • ZHOU Xin ,
  • GUO Wenbin ,
  • CHEN Haisheng
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  • 1. Institute of Engineering Thermophysics, Chinese Academy of Sciences, Beijing 100190, China
    2. University of Chinese Academy of Sciences, Beijing 100049, China
    3. National Energy Large Scale Physical Energy Storage Technologies R&D Center of Bijie, Bijie 551700, China
    4. Nanjing Institute of Future Energy System, IET, CAS, Nanjing 211135, China

Online published: 2024-07-15

Supported by

This study is supported by the Major Science and Technology Projects of Inner Mongolia (Grant No. 2021ZD0030), the National Natural Science Foundation of China (Grant No. 52106278), the National Science Fund for Distinguished Young Scholars (Grant No. 51925604), and the Science and Technology Foundation of Guizhou Province (No. [2019]1422).

Copyright

Science Press, Institute of Engineering Thermophysics, CAS and Springer-Verlag GmbH Germany, part of Springer Nature 2024
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Abstract

Energy storage technology is an essential part of the efficient energy system. Compressed air energy storage (CAES) is considered to be one of the most promising large-scale physical energy storage technologies. It is favored because of its low-cost, long-life, environmentally friendly and low-carbon characteristics. The compressor is the core component of CAES, and the performance is critical to the overall system efficiency. That importance is not only reflected in the design point, but also in the continuous efficient operation under variable working conditions. The diagonal compressor is currently the focus of the developing large-scale CAES because of its stronger flow capacity compared with traditional centrifugal compressors. And the diagonal compressor has the higher single stage pressure ratio compared with axial compressors. In this paper, the full three dimensional numerical simulation technologies with synergy theory are used to compare and analyze the internal flow characteristics. The performance of the centrifugal and diagonal impellers that are optimized under the same requirements for large-scale CAES has been analyzed. The relationship between the internal flow characteristics and performance of the centrifugal and diagonal impellers with the change of mass flow rates and total inlet temperature is given qualitatively and quantitatively. Where the cosine value of the synergy angle is high, the local flow loss is large. The smaller proportion of the positive area is the pursuit of design. Through comparative analysis, it is concluded that the internal flow and performance changes of centrifugal and diagonal impellers are different. The results confirm the superiority and feasibility of the off-design performance of the diagonal compressor applied to the developing large-scale CAES.

Key words: compressed air energy storage; synergy theory; diagonal compressor; centrifugal compressor; comparative analysis

Cite this article

ZHANG Yuxin , ZUO Zhitao , ZHOU Xin , GUO Wenbin , CHEN Haisheng . Comparative Analysis of Diagonal and Centrifugal Compressors with Synergy Theory in Compressed Air Energy Storage System[J]. Journal of Thermal Science, 2024 , 33(4) : 1325 -1339 . DOI: 10.1007/s11630-024-1966-4

References

[1] Whiteman A., Rinke T., Esparrago J., Elsayed S., Renewable capacity statistics. IRENA-The International Renewable Energy Agency, 2016.
[2] Zhang Y., Xu Y., Guo H., et al., A hybrid energy storage system with optimized operating strategy for mitigating wind power fluctuations. Renewable Energy, 2018, 125: 121–132.
[3] Mann M., Babinec S., Putsche V., Energy storage grand challenge: Energy storage market report. National Renewable Energy Laboratory (NREL), Golden, CO, United States, 2020.
[4] Mahmoud M., Ramadan M., Olabi A.G., et al., A review of mechanical energy storage systems combined with wind and solar applications. Energy Conversion and Management, 2020, 210: 112670.
[5] Olabi A.G., Wilberforce T., Ramadan M., et al., Compressed air energy storage systems: components and operating parameters–A review. Journal of Energy Storage, 2021, 34: 102000.
[6] Chen H., Cong T.N., Yang W., et al., Progress in electrical energy storage system: A critical review. Progress in Natural Science, 2009, 19(3): 291–312.
[7] Hoffeins H., Mohmeyer K.U., Operating experience with the huntorf air-storage gas-turbine power-station. Brown Boveri Review, 1986, 73(6): 297–305.
[8] Lihach N., Breaking new ground with CAES. EPRI Journal, 1982, 7: 17–21.
[9] Casey M., Zwyssig C., Robinson C., The Cordier line for mixed flow compressors. Turbo Expo: Power for Land, Sea, and Air, 2010, 44021: 1859–1869.
[10] Moore J., Moore J.G., Calculations of three-dimensional, viscous flow and wake development in a centrifugal impeller. Journal of Engineering for Power, 1981, 103(2): 367–372.
[11] Dai Y., Engeda A., Cave M., et al., A flow field study of the interaction between a centrifugal compressor impeller and two different volutes. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 2010, 224(2): 345–356.
[12] Zhao H., Wang Z., Ye S., et al., Numerical investigations on tip leakage flow characteristics and vortex trajectory prediction model in centrifugal compressor. Proceedings of the Institution of Mechanical Engineers, Part A: Journal of Power and Energy, 2016, 230(8): 757–772.
[13] Eckardt D., Detailed flow investigations within a high-speed centrifugal compressor impeller. Journal of Fluid Engineering, 1976, 98(3): 390–399.
[14] Eisenlohr G., Benfer F.W., Aerodynamic design and investigation of a mixed flow compressor stage. In AGARD, 1994. 
[15] Chen X.Y., Meng X.W., Gui X.M., et al., The aerodynamic design and investigation of loading distribution of a mixed flow compressor. Procedia Engineering, 2015, 99: 484–490.
[16] Guo H., Xu Y., Zhang Y., et al., Off-design performance and an optimal operation strategy for the multistage compression process in adiabatic compressed air energy storage systems. Applied Thermal Engineering, 2019, 149: 262–274.
[17] Guo W., Zuo Z., Sun J., et al., Experimental investigation on off-design performance and adjustment strategies of the centrifugal compressor in compressed air energy storage system. Journal of Energy Storage, 2021, 38: 102515.
[18] Meng C., Zuo Z., Guo W., et al., Experimental and numerical investigation on off-design performance of a high-pressure centrifugal compressor in compressed air energy storage system. Journal of Energy Storage, 2022, 53: 105081.
[19] Iandoli C., Sciubba E., 3-D numerical calculation of the local entropy generation rates in a radial compressor stage. International Journal of Thermodynamics, 2005, 8(2): 83–94. 
[20] Ma L.D., Li Z.Y., Tao W.Q., Experimental verification of the field synergy principle. International Communications in Heat and Mass Transfer, 2007, 34(3): 269–276.
[21] Chen Q., Ren J., Meng J., Field synergy equation for turbulent heat transfer and its application. International Journal of Heat and Mass Transfer, 2007, 50(25–26): 5334–5339.
[22] Liu W., Liu P., Dong Z.M., et al., A study on the multi-field synergy principle of convective heat and mass transfer enhancement. International Journal of Heat and Mass Transfer, 2019, 134: 722–734.
[23] Tao W.Q., Guo Z.Y., Wang B.X., Field synergy principle for enhancing convective heat transfer––its extension and numerical verifications. International Journal of Heat and Mass Transfer, 2002, 45(18): 3849–3856.
[24] Shao Z., Li W., Li A., et al., Loss analysis of the shrouded radial-inflow turbine for compressed air energy storage. Proceedings of the Institution of Mechanical Engineers, Part A: Journal of Power and Energy, 2021, 235(3): 406–420.
[25] Zhou X., Zuo Z., Liang Q., et al., Synergy methodology for internal flow of turbomachinery. Journal of Thermal Science, 2020, 29(3): 730–742.
[26] Guo H., Xu Y., Zhu Y., et al., Thermal-mechanical coefficient analysis of adiabatic compressor and expander in compressed air energy storage systems. Energy, 2022, 244: 122993.
[27] Darwish M., Moukalled F., The finite volume method in computational fluid dynamics: an advanced introduction with OpenFOAM® and Matlab®. Springer, 2021.
[28] Liang Q., Zuo Z., Zhou X., et al., Design of a centrifugal compressor with low solidity vaned diffuser (LSVD) for large-scale compressed air energy storage (CAES). Journal of Thermal Science, 2020, 29(2): 423–434.
[29] Spalart P., Allmaras S., A one-equation turbulence model for aerodynamic flows. 30th Aerospace Sciences Meeting and Exhibit, 1992.
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