Experimental Study on Compact External Heat Exchanger for a 4 MWth Circulating Fluidized Bed Combustor

Zhi Wei Li; Hong Zhou He; Huang Huang Zhuang

doi:10.4028/www.scientific.net/AMM.448-453.3259

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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 448-453Experimental Study on Compact External Heat...

Experimental Study on Compact External Heat Exchanger for a 4 MW_th Circulating Fluidized Bed Combustor

Abstract:

The characteristics of the external heat exchanger (EHE) for a 4 MWth circulation fluidized bed combustor were studied in the present paper. The length, width and height of EHE were 1.5 m, 0.8 m and 9 m, respectively. The circulating ash flow passing the heating surface bed could be controlled by adjusting the fluidizing air flow and the heating transferred from the circulating ash to the cooling water. The ash flow rate passing through the heat transfer bed was from 0.4 to 2.2 kg/s. The ash average temperature was from 500 to 750 °C. And the heat transfer rate between the ash and the cooling water was between 150 and 300 W/(m²·°C). The relationships among the circulating ash temperature, the heat transfer, heat transfer rate, the heat transfer coefficient and the circulating ash flow passing through the heating exchange cell were also presented and could be used for further commercial EHE design.

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Periodical:

Applied Mechanics and Materials (Volumes 448-453)

Pages:

3259-3269

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.448-453.3259

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Online since:

October 2013

Authors:

Zhi Wei Li, Hong Zhou He*, Huang Huang Zhuang

Keywords:

Circulating Ash, Circulating Fluidized Bed Combustor (CFBC), External Heat Exchanger, Heat Transfer Coefficient

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References

[1] W. Y. Chen and R. N. Xu: Energy Policy, Vol. 38 (2010), pp.2123-2130.

Google Scholar

[2] Information on http: /www. stats. gov. cn/tjsj/ndsj/2009/html/G0602e. htm.

Google Scholar

[3] C.F. You and X.C. Xu: Energy (2009), (Article in Press).

Google Scholar

[4] Information on http: /zls. mep. gov. cn/hjtj/nb/2008tjnb/201004/t20100421_188500. htm. [in Chinese].

Google Scholar

[5] B. Xiong, X. F. Lu, et al.: Powder Technology, Vol. 202, (2010), pp.55-61.

Google Scholar

[6] G. X. Yue, H. R. Yang, J. F. Lu, H. Zhang, Latest development of CFB boilers in China, " In 2009 international conference on fluidized bed combustion. Xi, an, China, USA: ASME; (2009).

DOI: 10.1007/978-3-642-02682-9_1

Google Scholar

[7] Q. H. Wang, Z. Y. Luo, et al.: Chemical Engineering and Processing, Vol. 42 (2003), pp.327-335. [in Chinese].

Google Scholar

[8] J. M. Beer: Progress in Energy and Combustion Science, Vol. 26 (2000), pp.301-327.

Google Scholar

[9] J. F. Li, J. J. H. Hao: Power Technology, Vol. 10 (2010), pp.70-74. [in Chinese].

Google Scholar

[10] N.S. Bernstein, S.L. Goidich, J. Phalen: ASME (1995), New York, pp.27-37.

Google Scholar

[11] K. Cleve: ASME (1999), Savannah, USA, p.6.

Google Scholar

[12] C. Voyles, C. Gagliardi, D. Wolfson: ASME (1995), New York. pp.703-71.

Google Scholar

[13] C. C. Werdermann, C. J. Werther: ASME (1993), pp.985-990.

Google Scholar