Experimental investigations on the design of a dual-media thermal energy storage with liquid metal

“…Further information on the experiments and the operational details are given in ref. [15]. The spheres in the storage did not show any changes visible to the naked eye before and after the experiments.…”

“…Based on the target application of the materials investigated as a filler in a packed-bed TES, the materials should have a high volumetric heat capacity, low thermal conductivity, high thermal fatigue, and thermal shock resistance, need to be compatible with LBE, and should be low cost, which is explained in more detail in the study by Müller-Trefzer et al [15] The most important criteria for the selection of filler materials are the thermophysical properties and material compatibility. As there are very few data [11,20,21] available regarding the operation of a packed-bed TES with liquid metals as the HTF, a well-defined packed bed was intended to be tested for validation purpose.…”

“…[14] Its technical operability on a lab scale was successfully demonstrated at the Karlsruhe Liquid Metal Laboratory (KALLA). [15] However, a major challenge when working with liquid metal is its corrosiveness, which increases with rising temperature. [16,17] Liquid metals can dissolve elements of solid structural material, form intermetallic compounds, or penetrate into the solid structure, leading to a change in the mechanical properties.…”

“…Furthermore, the temperature measuring technique in a packed-bed TES with LBE will be tested and important design parameters can be derived for larger-scale systems, which is discussed in more detail in ref. [15]. In parallel, material tests (both structural and filler material) for higher temperatures beyond 700 °C will be currently performed, but are not part of this study.…”

Screening of Filler Material for a Packed‐Bed Thermocline Energy Storage Test Facility with Lead–Bismuth Eutectic as the Heat Transfer Fluid

“…Further information on the experiments and the operational details are given in ref. [15]. The spheres in the storage did not show any changes visible to the naked eye before and after the experiments.…”

“…Based on the target application of the materials investigated as a filler in a packed-bed TES, the materials should have a high volumetric heat capacity, low thermal conductivity, high thermal fatigue, and thermal shock resistance, need to be compatible with LBE, and should be low cost, which is explained in more detail in the study by Müller-Trefzer et al [15] The most important criteria for the selection of filler materials are the thermophysical properties and material compatibility. As there are very few data [11,20,21] available regarding the operation of a packed-bed TES with liquid metals as the HTF, a well-defined packed bed was intended to be tested for validation purpose.…”

“…[14] Its technical operability on a lab scale was successfully demonstrated at the Karlsruhe Liquid Metal Laboratory (KALLA). [15] However, a major challenge when working with liquid metal is its corrosiveness, which increases with rising temperature. [16,17] Liquid metals can dissolve elements of solid structural material, form intermetallic compounds, or penetrate into the solid structure, leading to a change in the mechanical properties.…”

“…Furthermore, the temperature measuring technique in a packed-bed TES with LBE will be tested and important design parameters can be derived for larger-scale systems, which is discussed in more detail in ref. [15]. In parallel, material tests (both structural and filler material) for higher temperatures beyond 700 °C will be currently performed, but are not part of this study.…”

Screening of Filler Material for a Packed‐Bed Thermocline Energy Storage Test Facility with Lead–Bismuth Eutectic as the Heat Transfer Fluid

“…[32][33][34] Recently, a packed-bed storage system with eutectic lead-bismuth as the heat transfer fluid has been demonstrated on a lab-scale (1 kWh) at KIT. A packed bed of ceramic fillers (zirconium silicate) was used with temperatures of up to 380 C. 35 The results showed that such a system is feasible and performs more efficiently than a single-medium thermocline storage tank with lead-bismuth only. Currently, a 100-kWh packed-bed storage system is under construction and will be integrated and tested in a test rig at KALLA at KIT.…”

A perspective on high‐temperature heat storage using liquid metal as heat transfer fluid

High-Temperature Corrosion Behavior of Fe-18Ni-12Cr-2.9Al and Fe-18Ni-12Cr-2.3Al-Nb-C Austenitic Steels Depending on Dissolved Oxygen Concentration in Static Liquid Pb at 700 °C