posted on 2020-01-23, 21:31authored byShohreh Mirzaei, Ali Ahmadpour, Akbar Shahsavand, Hamed Rashidi, Arash Arami-Niya
Adsorbed
natural gas (ANG) technology is a safe and low-cost approach
for natural gas storage. Improving the volumetric adsorption capacity
of adsorbents in the ANG tank can enhance the fuel density and make
this technology cost-effective compared to other available CH4 storage approaches. For this purpose, the present research
focuses on maximizing CH4 uptake on low-cost and available
anthracite-based carbon materials via experimental and analytical
investigations. The effect of preparation variables of the chemical
agent (KOH) impregnation ratio to the anthracite (2.6–4.3 g/g),
activation temperature (666–834 °C), and retention time
(39–140 min) on the specifications of the coal-based activated
carbons (ACs) and their CH4 adsorption capacity were examined
experimentally. The results were analyzed through empirical models,
including response surface methodology (RSM), our in-house developed
models, namely, regularization networks (RN) and adaptive neuro-fuzzy
interface systems. The statistical assessment revealed that all three
established models could effectively predict the methane adsorption
capacity of the carbon samples based on their preparation conditions.
The superior performance of our in-house RN is dedicated to its robust
theoretical backbone in the regularization theory. Finally, the carbon
sample prepared under the optimized preparation conditions, based
on the RSM and genetic algorithm, showed the highest CH4 uptake of 175 cm3(STP)/cm3. Based
on the authors’ knowledge, the volumetric CH4 capacity
of the optimized AC is one of the highest values reported in the literature
among different classes of the adsorbent.