On the feasibility of novel reactor configurations for next-generation CH4 storage as an energy carrier using computational, experimental, and statistical approach

IF 4.9 2区工程技术 Q1 ENGINEERING, MECHANICAL

International Journal of Thermal Sciences Pub Date : 2024-10-23 DOI:10.1016/j.ijthermalsci.2024.109485

Anupam Chaudhary, Gautam, Satyabrata Sahoo

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Abstract

The present investigation compares the constant pressure charging and controlled flow discharging performance of five different reactor configurations for methane (CH₄) storage as an energy carrier in the adsorbed form. A 3-D transient model, coupling the porous bed and coolant domain, is considered in this study. The study shows how the storage and discharge performance can be improved step-by-step, starting with an adiabatic case and progressing to adding an external cooling jacket, single and multiple rows of cooling pipes with internal longitudinal, annular, and conical fins. The findings also demonstrate the remaining scope for achieving 100 % isothermal efficiency with Maxsorb III (7.8 % and 4 %) and indigenous activated carbon (AC) IndoCarb GC D612 (0.01 % and 4.8 %) for charging and discharging, respectively. A detailed experiment is done to measure the thermophysical properties of the indigenous activated carbon. The reactor with an external cooling jacket and double row of cooling pipes with internal longitudinal fins is identified as the best reactor geometry based on the charge and discharge performance. Using the Taguchi method, a statistical analysis is carried out on the best reactor geometry to check the sensitivity of different design and operating parameters such as gas flow rate, heating fluid temperature, coolant flow velocity, and the reactor aspect ratio. It is found that, for the maximum effective performance ratio (i.e., discharge concentration per unit pumping work), the contribution of coolant fluid velocity (87.2 %) is maximum.

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利用计算、实验和统计方法研究新型反应器配置作为下一代能量载体储存甲烷的可行性

本研究比较了五种不同反应器配置的恒压充气和控流放电性能，以吸附形式储存甲烷（CH4）作为能量载体。本研究考虑了一个三维瞬态模型，将多孔床和冷却剂域耦合在一起。从绝热情况开始，逐步增加外部冷却套、带有内部纵向、环形和锥形鳍片的单排和多排冷却管，研究显示了如何逐步提高存储和排放性能。研究结果还表明，利用 Maxsorb III（7.8% 和 4%）和本地活性炭（AC）IndoCarb GC D612（0.01% 和 4.8%）分别进行装料和卸料，仍可实现 100% 的等温效率。为测量本地活性炭的热物理性质进行了详细实验。根据装料和卸料性能，确定了带有外部冷却套和双排冷却管及内部纵向翅片的反应器为最佳几何形状。利用田口方法，对最佳反应器几何形状进行了统计分析，以检查不同设计和运行参数（如气体流速、加热流体温度、冷却剂流速和反应器长宽比）的敏感性。结果发现，对于最大有效性能比（即单位泵功的排放浓度），冷却液流速（87.2%）的贡献最大。

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来源期刊

International Journal of Thermal Sciences 工程技术-工程：机械

CiteScore

8.10

自引率

11.10%

发文量

531

审稿时长

55 days

期刊介绍： The International Journal of Thermal Sciences is a journal devoted to the publication of fundamental studies on the physics of transfer processes in general, with an emphasis on thermal aspects and also applied research on various processes, energy systems and the environment. Articles are published in English and French, and are subject to peer review. The fundamental subjects considered within the scope of the journal are: * Heat and relevant mass transfer at all scales (nano, micro and macro) and in all types of material (heterogeneous, composites, biological,...) and fluid flow * Forced, natural or mixed convection in reactive or non-reactive media * Single or multi–phase fluid flow with or without phase change * Near–and far–field radiative heat transfer * Combined modes of heat transfer in complex systems (for example, plasmas, biological, geological,...) * Multiscale modelling The applied research topics include: * Heat exchangers, heat pipes, cooling processes * Transport phenomena taking place in industrial processes (chemical, food and agricultural, metallurgical, space and aeronautical, automobile industries) * Nano–and micro–technology for energy, space, biosystems and devices * Heat transport analysis in advanced systems * Impact of energy–related processes on environment, and emerging energy systems The study of thermophysical properties of materials and fluids, thermal measurement techniques, inverse methods, and the developments of experimental methods are within the scope of the International Journal of Thermal Sciences which also covers the modelling, and numerical methods applied to thermal transfer.