Effect of structural characteristics on the transport characteristics of solid particles in the thermal storage and release system of circulating fluidized bed--颗粒学报PARTICUOLOGY

Ji, Z., Song, G., Tang, Z., & Sun, L. (2024). Effect of structural characteristics on the transport characteristics of solid particles in the thermal storage and release system of circulating fluidized bed. Particuology, 89, 22-31. https://doi.org/10.1016/j.partic.2023.09.016

Effect of structural characteristics on the transport characteristics of solid particles in the thermal storage and release system of circulating fluidized bed

Zengcai Ji ^{a b}, Guoliang Song ^{a b c *}, Zihua Tang^{a b}, Liwei Sun ^{a b}

a Institute of Engineering Thermophysics, Chinese Academy of Sciences, Beijing, 100190, China
b University of Chinese Academy of Sciences, Beijing, 100049, China
c Dalian National Laboratory for Clean Energy, Dalian, 116023, China

10.1016/j.partic.2023.09.016

Volume 89, June 2024, Pages 22-31

Received 25 June 2023, Revised 22 September 2023, Accepted 25 September 2023, Available online 21 October 2023, Version of Record 5 December 2023.

E-mail: songgl@iet.cn

Highlights

• Solid particle transport regulation system is coupled to Circulating Fluidized Bed (CFB).

• Inverted m-shaped valve feed structure exhibits lower energy consumption.

• N-shaped valve discharge structure excels in control characteristics.

• Obtain optimum overflow height for inverted m-shaped valve and N-shaped valve.

Abstract

Coal-fired power generation stands as the most economically viable modulating power source in present-day China. It holds the potential to offer prospective solutions to the challenges posed by the rapid expansion of intermittent, unpredictable, and unstable renewable energy sources. Solid particle thermal storage technology emerges as an effective means to enhance the flexibility of coal-fired circulating fluidized bed power units. To attain an optimized structure for the solid particle thermal storage and release system in circulating fluidized bed units, experimental research was conducted on a 0.1 MWth circulating fluidized bed test platform. This study delved into the impact of ash storage bin geometries and the shapes of their feed-discharge valves on the control properties of solid particle transportation. The experimental outcomes reveal that employing inverted m-shaped valve and dual U-shaped valves for feed control, alongside U-shaped valves and N-shaped valves for discharge control, both enable efficient and rapid storage and release of solid particles within the circulating fluidized bed. Under similar air distribution conditions, the inverted m-shaped valve exhibits lower conveying energy consumption than the dual U-shaped valves, while the N-shaped valve excels in control characteristics over the U-shaped valve. Furthermore, the inverted m-shaped valve and the N-shaped valve demonstrate optimal overflow port heights, and the ash storage bin exhibits an optimum height-to-diameter ratio.

Graphical abstract

Keywords

Solid particle; Thermal storage; System structure; Transport regulation

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