Hydrated Salt/Graphite/Polyelectrolyte Organic-Inorganic Hybrids for Efficient Thermochemical Storage

Salviati, Sergio; Carosio, Federico; Saracco, Guido; Fina, Alberto

doi:10.3390/nano9030420

Cited by 25 publications

(4 citation statements)

References 32 publications

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“…It is generally classified as a sorption process or a chemical reaction that does not involve sorption. However, compared to liquid absorption and solid adsorption, chemical reactions are mono-variant and lead to transformation about the volume of the solid [129][130][131][132][133]. The main chemical reaction storage materials developed and studied can be grouped into carbonate decomposition material, redox material, inorganic hydroxide material, ammonia decomposition material, metal hydride material, and methane reforming material.…”

Section: Materials For Chemical Reaction Energy Storage Processmentioning

confidence: 99%

Recent Status and Prospects on Thermochemical Heat Storage Processes and Applications

Gbenou

Fopah-Lele

Wang

2021

Entropy

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Recent contributions to thermochemical heat storage (TCHS) technology have been reviewed and have revealed that there are four main branches whose mastery could significantly contribute to the field. These are the control of the processes to store or release heat, a perfect understanding and designing of the materials used for each storage process, the good sizing of the reactor, and the mastery of the whole system connected to design an efficient system. The above-mentioned fields constitute a very complex area of investigation, and most of the works focus on one of the branches to deepen their research. For this purpose, significant contributions have been and continue to be made. However, the technology is still not mature, and, up to now, no definitive, efficient, autonomous, practical, and commercial TCHS device is available. This paper highlights several issues that impede the maturity of the technology. These are the limited number of research works dedicated to the topic, the simulation results that are too illusory and impossible to implement in real prototypes, the incomplete analysis of the proposed works (simulation works without experimentation or experimentations without prior simulation study), and the endless problem of heat and mass transfer limitation. This paper provides insights and recommendations to better analyze and solve the problems that still challenge the technology.

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Section: Materials For Chemical Reaction Energy Storage Processmentioning

confidence: 99%

Recent Status and Prospects on Thermochemical Heat Storage Processes and Applications

Gbenou

Fopah-Lele

Wang

2021

Entropy

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“…Such a behaviour is ascribed to the limitations in mass transfer since composites with higher content of salt results in more compact and dense blocks, that represent increased obstacles to mass and heat transfer. In the work reported by Salviati et al [23], the composites made with the salt hydrate, expanded natural graphite and polydiallyldimethylammonium chloride show good heat and mass transfer properties, but the mechanical resistance of the material proved to be a critical issue: severe damage in the form of cracks to the composite tabs occurred already after the first hydration/dehydration cycle. In another study by D'Ans et al [39], a strong humidity dependence of thermal and mass transport properties of composites based on CaCl2 encapsulated in microporous silica gel was evidenced: considering the small dimensions of the pores of the matrix, for high humidity values (i.e.…”

Section: Feasibility Of the Composites For Thermal Energy Storage Application And Future Developmentsmentioning

confidence: 99%

“…The results showed that the natural graphite could improve the hydration-dehydration kinetics by reducing hysteresis and increase the thermal conductivity of the material. More recently, Salviati et al [23] proposed the addition of an organic compound, PDAC, polydiallyldimethylammonium chloride, to the strontium bromide/graphite composites. Experimental outcomes of the investigation show that PDAC has a beneficial effect on water sorption and mechanical resistance upon hydration/dehydration cycling.…”

Section: Introductionmentioning

confidence: 99%

Innovative composite sorbent for thermal energy storage based on a SrBr2·6H2O filled silicone composite foam

Calabrese

Brancato

Palomba

et al. 2019

Journal of Energy Storage

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This paper reports about the first experimental activity on a composite material for thermal energy storage, based on a SrBr2ꞏ6H2O filled silicone foam. The morphological and thermal features of the composite with different salt content (i.e. between 40 wt.% and 70 wt.%) were investigated. The dehydration behaviour was studied by thermo-gravimetric analysis. Furthermore, scanning electron and 3D optical microscopy were used to compare the cellular microstructure of the composite foams.The synthesized foams are characterized by a well-interconnected cellular structure with a threedimensional porous network. This, together with the high permeability to water vapour of the matrix favours water vapour diffusion and allows the reaction of all the salt embedded in the matrix. The main advantages of the composite material were analysed and compared to other composites in literature. Since the production process, especially for higher salt content, seemed not sufficiently effective, causing a reduced foaming ration and lower ability to incorporate the salt hydrate, possible improvements were proposed and discussed.

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“…graphite[59], MgSO 4 and CaCl 2 /ZMS[60] Salt hydrate composite with additive materials LiCl/AC and ENG TSA/Silica solution[61], SrBr 2 /ENG/PDAC[62], SrBr 2 /ENG/CNF[63] …”

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confidence: 99%

Review on Salt Hydrate Thermochemical Heat Transformer

2023

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The industrial sector utilizes approximately 40% of global energy consumption. A sizeable amount of waste energy is rejected at low temperatures due to difficulty recovering with existing technologies. Thermochemical heat transformers (THT) can play a role in recovering low-temperature industrial waste heat by storing it during high supply and discharging it on demand at a higher temperature. Thus, THT will enable waste heat reintegration into industrial processes, improving overall energy efficiency and lowering greenhouse gas emissions from the industrial sector. Salt hydrate is a promising thermochemical material (TCM) because it requires a low charging temperature which can be supplied by waste heat. Furthermore, its non-toxic nature allows the implementation of a simpler and less costly open system. Despite extensive research into salt hydrate materials for thermochemical energy storage (TCES) applications, a research gap is identified in their use in THT applications. This paper aims to provide a comprehensive literature review of the advancement of THT applications, particularly for systems employing salt hydrates material. A discussion on existing salt hydrate materials used in the THT prototype will be covered in this paper, including the challenges, opportunities, and suggested future research works related to salt hydrate THT application.

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Hydrated Salt/Graphite/Polyelectrolyte Organic-Inorganic Hybrids for Efficient Thermochemical Storage

Cited by 25 publications

References 32 publications

Recent Status and Prospects on Thermochemical Heat Storage Processes and Applications

Recent Status and Prospects on Thermochemical Heat Storage Processes and Applications

Innovative composite sorbent for thermal energy storage based on a SrBr2·6H2O filled silicone composite foam

Review on Salt Hydrate Thermochemical Heat Transformer

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