Novel dual-mixed refrigerant precooling process for high capacity hydrogen liquefaction plants with superior performance
Author | Sleiti, Ahmad K. |
Author | Al-Ammari, Wahib A. |
Author | Ghani, Saud |
Available date | 2023-05-16T09:07:32Z |
Publication Date | 2023 |
Publication Name | Journal of Energy Storage |
Resource | Scopus |
ISSN | 2352152X |
Abstract | Liquid hydrogen is a superior alternative for the current energy storage methods and energy carriers as it has higher energy density and cleanliness. However, hydrogen liquefaction is an energy-intensive process. In particular, the precooling process of hydrogen consumes a tremendous portion of about 30 % of the total compression power of the plant. Several previous studies introduced various pure-refrigerant and single mixed refrigerant (SMR) precooling processes, however, their specific energy consumption (SEC) still very high especially at large-scale capacities. Therefore, this study presents a novel, efficient, and large-scale dual-mixed refrigerant (DMR) process to precool the hydrogen from 25 °C to -192 °C at a pressure of 21 bar. New heavyweight-based mixed refrigerant MR1 and lightweight-based mixed refrigerant MR2 are developed for the DMR process using a new-proposed systematic approach. The proposed DMR process is capable of handling a wide range of hydrogen flow from 100 TPD to 1000 TPD with SEC of 0.862 kWh/kgH2Feed, which is 20.33 % lower than the most competitive SMR process available in the literature. Based on the sensitivity analysis, further optimization of the DMR operating parameters reduced the SEC to 0.833 kWh/kgH2Feed at an optimal capacity of 500 TPD. Furthermore, the COP of the new process is improved by 14.47 % and the total annualized cost is reduced by 12.24 %. Compared to five other technologies that use the pure-refrigerant and other SMR precooling processes, the DMR reduces the SEC by 39.0 % to 63.0 %. The novel precooling process presented herein has the potential to drive the development of large-scale hydrogen liquefaction processes. |
Sponsor | The work presented in this publication was made possible by NPRP-S grant # [ 11S-1231-170155 ] from the Qatar National Research Fund (a member of Qatar Foundation). The findings herein reflect the work, and are solely the responsibility, of the authors. |
Language | en |
Publisher | Elsevier |
Subject | Exergy efficiency Hydrogen precooling Large-scale hydrogen liquefaction LH2 Mixed refrigerant Thermoeconomic analysis |
Type | Article |
Volume Number | 66 |
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Mechanical & Industrial Engineering [1396 items ]