Process Research and Analysis on Potential Development of a Novel Air Separation Process Cooled by LNG Cold Energy

Wen Dong Xu; Jiao Duan; Wen Jun Mao

doi:10.4028/www.scientific.net/AMR.805-806.609

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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 805-806Process Research and Analysis on Potential...

Process Research and Analysis on Potential Development of a Novel Air Separation Process Cooled by LNG Cold Energy

Abstract:

In order to address the problems of the current air separation process such as the complex process, large equipment, cumbersome operation and high operating costs, a novel air separation process cooled by LNG cold energy was proposed in this paper, which is based on high-efficiency heat exchanger network and chemical packing separation technology. Utilization of high-efficiency heat exchanger network widened the operating temperature range of LNG cold energy from-140°C~ -70°C to-160°C~10°C and air separation pressure was also reduced from 0.5MPa to about 0.35MPa due to the chemical packing separation technology, thereby greatly improved the energy efficiency. An air separation process was designed with gasification scale of LNG at 3000m³/h, which could produce air separation product of 4.7t/h. Energy conservation reached 3228.9kWh, which meant the annual benefit was up to 23.248 million Yuan. With characteristics of miniature, skid-mounted and open-stop feature, the process can realize the full utilization of LNG cold energy in LNG satellite station in remote areas.

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Periodical:

Advanced Materials Research (Volumes 805-806)

Pages:

609-615

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.805-806.609

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Online since:

September 2013

Authors:

Wen Dong Xu*, Jiao Duan, Wen Jun Mao

Keywords:

Air Separation, Cold Energy, Heat Exchanger, High-Efficient, LNG

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* - Corresponding Author

References

[1] Guobang Chen: New cryogenic technology (Shanghai Jiaotong University Press, China 2007), p.20.

Google Scholar

[2] Nakaiwa M, Akiya T, Owa M and Y. Tanaka: Energy Conversion and Management, Vol. 37 (1996) No. 3, p.295.

DOI: 10.1016/0196-8904(95)00787-3

Google Scholar

[3] Zhongxiu Zhang and Weiguo Zhou: Gas&Heat, (2007) No. 6, p.18. (In Chinese).

Google Scholar

[4] Wensheng Lin, Anzhong Gu and Xuesheng Lu: Cryogenic Technology, Vol. 43 (2003) No. 3, p.26. (In Chinese).

Google Scholar

[5] Kin H and Hong S: 23erd World Gas Conference: Review on Economical Efficiency of LNG Cold Energy Use in South Korea( Amsterdam, 2006). p.2402.

Google Scholar

[6] Tajina M: Journal of the Japan Institute of Energy, Vol. 80 (2001) No. 8, p.707.

Google Scholar

[7] Zeshao Chen, Wenlong Cheng and Peng Hu: Journal of Engineering Thermophysics, Vol. 25 (2004) No. 6, p.913.

Google Scholar

[8] Tao Jin and Jianjun Hu: Air Separation, (2005) No. 5, p.15. (In Chinese).

Google Scholar

[9] Tao Jin, Jianjun Hu, Guobang Chen and Ke Tang: Journal of Zhengjiang University: Engineering Science, Vol. 41 (2007) No. 5, p.836. (In Chinese).

Google Scholar

[10] Na Yan, Yanzhong Li and Hanfei Tuo: Journal of Xi'an Jiaotong University, Vol. 41 (2007) No. 1, p.122. (In Chinese).

Google Scholar

[11] Na Yan and Yanzhong Li: Cryogenics, Vol. 156 (2007) No. 2, p.40. (In Chinese).

Google Scholar

[12] Na Yan and Yanzhong Li: Chemical Engineering, Vol. 35 (2007) No. 9, p.58. (In Chinese).

Google Scholar