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

Calabrese, Luigi; Brancato, Vincenza; Palomba, Valeria; Frazzica, Andrea; Cabeza, Luisa F.

doi:10.1016/j.est.2019.100954

Cited by 22 publications

(7 citation statements)

References 39 publications

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“…In previous studies on SAPOs and AlPOs [160][161][162][163], the water adsorption mechanism was revealed, especially for structural phase-dependent water diffusivity at various concentrations and Si/Al ratios, by means of molecular dynamics (MD), density functional theory (DFT) computations [162], nuclear magnetic resonance (NMR) [160], and X-ray diffraction (XRD) [160,163]. AlPOs and SAPOs can load larger amounts of water than silica gel, showing a superior ability to bind to water [164]. Both of them process a higher energy storage capacity of 200-240 Wh/kg at a moderate desorption temperature of 75 to 140 • C [165].…”

Section: Silica Gelmentioning

confidence: 99%

“…Microporous or macroporous silicon foams are well interconnected, creating a continuity network and effective vapor permeability to allow for vapor flow into or out of pores for both low and high salt contents during the adsorption and desorption phases [164]. Good elasticity and flexibility of this foam can improve the mechanical stability and cyclicity, especially for salt hydrate volume expansion during the adsorption process [164,183,184]. Adsorption capacity of various host matrices at specified conditions [60,110,124,134,150,151,170,181,182].…”

Section: Peer Review 21 Of 58mentioning

confidence: 99%

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Salt Hydrate Adsorption Material-Based Thermochemical Energy Storage for Space Heating Application: A Review

et al. 2023

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Recent years have seen increasing attention to TCES technology owing to its potentially high energy density and suitability for long-duration storage with negligible loss, and it benefits the deployment of future net-zero energy systems. This paper provides a review of salt hydrate adsorption material-based TCES for space heating applications at ~150 °C. The incorporation of salt hydrates into a porous matrix to form composite materials provides the best avenue to overcome some challenges such as mass transport limitation and lower thermal conductivity. Therefore, a systematic classification of the host matrix is given, and the most promising host matrix, MIL-101(Cr)(MOFs), which is especially suitable for loading hygroscopic salt, is screened from the perspective of hydrothermal stability, mechanical strength, and water uptake. Higher salt content clogs pores and, conversely, reduces adsorption performance; thus, a balance between salt content and adsorption/desorption performance should be sought. MgCl2/rGOA is obtained with the highest salt loading of 97.3 wt.%, and the optimal adsorption capacity and energy density of 1.6 g·g−1 and 2225.71 kJ·kg−1, respectively. In general, larger pores approximately 8–10 nm inside the matrix are more favorable for salt dispersion. However, for some salts (MgSO4-based composites), a host matrix with smaller pores (2–3 nm) is beneficial for faster reaction kinetics. Water molecule migration behavior, and the phase transition path on the surface or interior of the composite particles, should be identified in the future. Moreover, it is essential to construct a micromechanical experimental model of the interface.

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Section: Silica Gelmentioning

confidence: 99%

Section: Peer Review 21 Of 58mentioning

confidence: 99%

Salt Hydrate Adsorption Material-Based Thermochemical Energy Storage for Space Heating Application: A Review

et al. 2023

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“…(2009b), the authors also experienced that magnesium sulfate is unable to uptake water above 50 °C unless very high relative humidity is applied (~80% R.H). Magnesium sulfate has also been widely studied in composite salt in the matrix with numerous matrices to solve the agglomeration and stability issues (Whiting et al, 2014;Casey et al, 2014;Hongois et al, 2014;Posern et al, 2015;Xu et al, 2017;Sutton et al, 2018a;Xu et al, 2018;Wang et al, 2019a;Calabrese et al, 2019;Mahon et al, 2019;Miao et al, 2021).…”

Section: Magnesium Sulfatementioning

confidence: 99%

Water sorption-based thermochemical storage materials: A review from material candidates to manufacturing routes

Palacios¹,

Navarro²,

Barreneche³

et al. 2022

Front. Therm. Eng.

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A comprehensive and updated review is provided in this article, with a focus on water sorption-based thermochemical storage (WSTCS) materials, covering materials and their manufacturing routes. The state of the art of 22 most relevant salt hydrates is classified into seven groups (bromides, sulphates, carbonates, chlorides, nitrates, hydroxides, and sulphides) and studied as candidates. This is followed by a discussion on TCS material manufacturing, covering both conventional (shaping, pelletizing, etc.) and more advanced routes (e.g., extrusion, 3D printing, encapsulation, etc.). Finally, concluding remarks are presented, including limitations and future potentials for TCS research.

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“…Also, hydrothermally stable metal−organic frameworks (MOFs), 27 aerogels, 24 carbon based materials, 5 and porous glass 28 were tested as matrices and different salts like SrBr 2 , copper, potassium, and sodium salt hydrates were explored as impregnates 24,29,30 to improve the CSPM storage materials. Additionally, synthesized matrices such as polymers 31,32 and silicone foams 33,34 were tested. Thereby, it was found that CSPM has generally better sorption kinetics than pure salt.…”

Section: ■ Introductionmentioning

confidence: 99%

“…Also, hydrothermally stable metal–organic frameworks (MOFs), aerogels, carbon based materials, and porous glass were tested as matrices and different salts like SrBr 2 , copper, potassium, and sodium salt hydrates were explored as impregnates ,, to improve the CSPM storage materials. Additionally, synthesized matrices such as polymers , and silicone foams , were tested. Thereby, it was found that CSPM has generally better sorption kinetics than pure salt. ,, It was also determined that a higher salt content in the composite results in higher water uptake and energy densities. , However, a too-high salt content could block pores off, mainly in microporous materials …”

Section: Introductionmentioning

confidence: 99%

The Effect of Nanoconfinement on Deliquescence of CuCl₂ Is Stronger than on Hydration

Eberbach

Huinink

Shkatulov

et al. 2023

Crystal Growth & Design

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The hydration of salts has gained particular interest within the frame of thermochemical energy storage. Most salt hydrates expand when absorbing water and shrink when desorbing, which decreases the macroscopic stability of salt particles. In addition, the salt particle stability can be compromised by a transition to an aqueous salt solution, called deliquescence. The deliquescence often leads to a conglomeration of the salt particles, which can block the mass and heat flow through a reactor. One way of macroscopically stabilizing the salt concerning expansion, shrinkage, and conglomeration is the confinement inside a porous material. To study the effect of nanoconfinement, composites of CuCl 2 and mesoporous silica (pore size 2.5−11 nm) were prepared. Study of sorption equilibrium showed that the pore size had little or no effect on the onsets of (de)hydration phase transition of the CuCl 2 inside the silica gel pores. At the same time, isothermal measurements showed a significant lowering of the deliquescence onset in water vapor pressure. The lowering of the deliquescence onset leads to its overlap with hydration transition for the smallest pores (<3.8 nm). A theoretical consideration of the described effects is given in the framework of nucleation theory.

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

Cited by 22 publications

References 39 publications

Salt Hydrate Adsorption Material-Based Thermochemical Energy Storage for Space Heating Application: A Review

Salt Hydrate Adsorption Material-Based Thermochemical Energy Storage for Space Heating Application: A Review

Water sorption-based thermochemical storage materials: A review from material candidates to manufacturing routes

The Effect of Nanoconfinement on Deliquescence of CuCl₂ Is Stronger than on Hydration

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

Cited by 22 publications

References 39 publications

Salt Hydrate Adsorption Material-Based Thermochemical Energy Storage for Space Heating Application: A Review

Salt Hydrate Adsorption Material-Based Thermochemical Energy Storage for Space Heating Application: A Review

Water sorption-based thermochemical storage materials: A review from material candidates to manufacturing routes

The Effect of Nanoconfinement on Deliquescence of CuCl2 Is Stronger than on Hydration

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The Effect of Nanoconfinement on Deliquescence of CuCl₂ Is Stronger than on Hydration