Abstract
Fine powders are the cornerstone of new energy storage solutions to assist concentrated solar power plants. Though, their ability to behave like fluid can be seriously affected at high temperatures. This work investigates the use of nanosilica in fine limestone (calcium carbonate, CaCO3) powders to mitigate the promotion of cohesion forces at high temperatures. Experiments were conducted over limestone powder samples with particle sizes around 45μm. The analysis was performed monitoring the tensile yield strength as the samples were subjected to different temperatures and consolidation stresses while varying the nanosilica content up until 0.82wt%. Temperatures reached a maximum of 500°C(close to the Tamman temperature in limestone), whereas consolidation stresses were increased up to 2kPa. Results show that nanosilica coating is an efficient solution to inhibit the enhancement of powder cohesiveness at high temperatures and consolidations. A solution that offers better control to smooth the granular flow regimes in production environments.
Highlights
Limestone powders, nearly 100% calcium carbonate (CaCO3), are used to operate new thermochemical energy storage technology [1]
The main goal of this project is to prove the feasibility of thermochemical energy storage solutions to assist CSP plants via fine limestone powders
Where E stands for the Ergun’s empirical constant (E ≈ 180), η refers to the gas dynamic viscosity, ψp is the particle’s sphericity, h is the bed height, and φ is the particle volume fraction
Summary
Nearly 100% calcium carbonate (CaCO3), are used to operate new thermochemical energy storage technology [1]. A solution devised to assist concentrated-solar-power (CSP) plants channeling the solar energy from the receiver to the storage unit [2,3,4]. It is in these two extremes of the storage circuit where granular-based solutions surpass the performance of their molten salt counterparts [5]. Granular flows may exhibit jamming and other issues that eventually may lead to intermittent flow regimes This is especially relevant in fine powders, which would be the best candidates in gas–solid reactive flows that require large contact areas, if not for such issues
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