Abstract
The growing concern over nonrenewable fuel sources, coupled with the continued increase of global energy demand has incentivised research into numerous new and pre-existing renewable energy sources. Concentrated solar thermal (CST) takes advantage of the high heat capacity of molten salts to provide an alternative solar solution to photovoltaic cells that allows reduced downtime through heat storage for use during suboptimal conditions. This meta-study examines the effectiveness of various eutectic Molten Salt compositions and materials as thermo-physical augmenters, with a focus on improved thermal conductivity when composited with molten salts as a method of enhancing the efficiency of concentrated solar thermal storage technology. The study is based on literature retrieved from scientific databases to investigate information available about enhancing LHTES technology. Research into carbon composites such as Expanded Graphite (EG) exhibits promising results revealing thermal conductivity increases as high as 40% in eutectic salt materials, however inconsistencies in measurements and materials used reveal a need for a greater analysis. Although molten salt thermal storage systems are not optimal in their current state, indication was found that composite storage mediums could potentially solidify their spot as a viable renewable energy source.
Highlights
Continuous and focused research into enhancing the efficiency of renewable energy systems is paramount due to the negative effects of non-renewable energy production on the environment
Molten salt is known as an Latent Heat Thermal Energy Storage (LHTES) due to it being a Phase change material (PCM) meaning it has a high heat of fusion
Background information and details on the current state of commercial CSP technology was gathered from the National Renewable Energy Laboratory (NREL) and the Deutsche Zentrum für Luft- und Raumfahrt (DLR) institute of solar research [15, 16]
Summary
Continuous and focused research into enhancing the efficiency of renewable energy systems is paramount due to the negative effects of non-renewable energy production on the environment. A significant aspect of renewable energy systems which plays a pivotal role in the future of renewable energy is thermal heat storage [1]. This meta-study focuses on Latent Heat Thermal Energy Storage (LHTES) utilising molten salt as the fluid used to collect, store and exchange heat to the commonly used Rankine cycle in CSP technology [2, 3]. Molten salt is known as an LHTES due to it being a Phase change material (PCM) meaning it has a high heat of fusion. LHTES systems achieve notably higher storage densities in comparison to other known methods such as sensible heat storage [4]
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