Ca(OH) 2 /CaO reversible reaction in a fluidized bed reactor for thermochemical heat storage

Pardo, Pierre; Anxionnaz‐Minvielle, Zoé; Rougé, Sylvie; Cognet, Patrick; Cabassud, Michel

doi:10.1016/j.solener.2014.06.010

Cited by 125 publications

(48 citation statements)

References 26 publications

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“…Various systems can be considered, other than metal oxides [3,7]. For example, hydroxides, and especially calcium hydroxide [8][9][10][11][12][13][14] shows promising results for TCES. The systems based on carbonates are also relevant for TCES application.…”

Section: Ab(s) + Heat (Csp)mentioning

confidence: 99%

Mixed Metal Oxide Systems Applied to Thermochemical Storage of Solar Energy: Benefits of Secondary Metal Addition in Co and Mn Oxides and Contribution of Thermodynamics

2018

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Thermochemical energy storage is promising for the long-term storage of solar energy via chemical bonds using reversible redox reactions. The development of thermally-stable and redox-active materials is needed, as single metal oxides (mainly Co and Mn oxides) show important shortcomings that may delay their large-scale implementation in solar power plants. Drawbacks associated with Co oxide concern chiefly cost and toxicity issues while Mn oxide suffers from slow oxidation kinetics and poor reversibility. Mixed metal oxide systems could alleviate the above-mentioned issues, thereby achieving improved materials characteristics. All binary oxide mixtures of the Mn-Co-Fe-Cu-O system are considered in this study, and their properties are evaluated by experimental measurements and/or thermodynamic calculations. The addition of Fe, Cu or Mn to cobalt oxide decreased both the oxygen storage capacity and energy storage density, thus adversely affecting the performance of Co3O4/CoO. Conversely, the addition of Fe, Co or Cu (with added amounts above 15, 40 and 30 mol%, respectively) improved the reversibility, re-oxidation rate and energy storage capacity of manganese oxide. Computational thermodynamics was applied to unravel the governing mechanisms and phase transitions responsible for the materials behavior, which represents a powerful tool for predicting the suitability of mixed oxide systems applied to thermochemical energy storage.

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Section: Ab(s) + Heat (Csp)mentioning

confidence: 99%

Mixed Metal Oxide Systems Applied to Thermochemical Storage of Solar Energy: Benefits of Secondary Metal Addition in Co and Mn Oxides and Contribution of Thermodynamics

2018

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“…Since the early 80s, many researchers have paid attention to this issue, so that literature abounds in papers reporting on feasibility studies of storage materials . However, it is in the field of latent heat storage materials, which are usually called phase change materials (PCMs), where we can find the majority of these studies.…”

Section: Introductionmentioning

confidence: 99%

“…Since the early 80s, many researchers have paid attention to this issue, so that literature abounds in papers reporting on feasibility studies of storage materials. [2][3][4][5][6][7][8][9][10][11][12][13][14][15][16][17] However, it is in the field of latent heat storage materials, which are usually called phase change materials (PCMs), where we can find the majority of these studies. This is due to the large number of PCMs that are suitable for applications in a very wide temperature range [18][19][20][21][22][23] (from 0°C to 800°C).…”

Section: Introductionmentioning

confidence: 99%

Development of a new methodology for validating thermal storage media: Application to phase change materials

Bayón

Rojas

2019

Int J Energy Res

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Summary Long‐term stability and long‐term performance of thermal storage media are a key issue that should be thoroughly analysed when developing storage systems. However, no testing protocol or guideline exists up to now for validating storage media, so that authors apply their own criteria, not only for designing testing procedures but also for predicting the material behaviour under long‐term operation. This paper aims to cover this gap by proposing a methodology for validating thermal storage media; in particular, phase change materials (PCMs). This methodology consists of different stages that include PCM characterization, preliminary assessment tests, and accelerated life testing. For designing the accelerated life tests, lifetime relationship models have to be obtained in order to predict PCM long‐term behaviour under service conditions from shorter tests performed under stress conditions. The approach followed in this methodology will be valid for materials to be used as sensible or thermochemical storage media, too.

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“…Accordingly, thermal energy storage (TES) is recognized as one of the key technologies for exploiting solar energy . To date, many methods, including sensible heat storage, latent heat storage, and reversible chemical reaction heat storage, have been studied for TES. Among these TES methods, latent heat thermal energy storage (LHTES) based on phase‐change materials (PCMs) is the most effective primary technique due to its characteristics of high heat storage density, approximately isothermal behavior, and wide range of phase‐change temperatures .…”

Section: Introductionmentioning

confidence: 99%

“…[2] Accordingly,t hermal energy storage (TES) is recognized as one of the key technologies for exploiting solar energy. [3] To date,m any methods,i ncluding sensible heat storage, [2] latent heat storage, [4] and reversible chemical reaction heat storage, [5] have been studied for TES.A mong these TES methods,l atent heat thermal energy storage (LHTES) based on phase-change materials (PCMs) is the most effectivep rimary technique due to its characteristics of high heat storage density,a pproximately isothermal behavior, and wide range of phase-change temperatures. [6,7] As am ediumo fe nergy storage,P CM can absorb or release abundant latent heat at the melting or freezing point when the surrounding temperature increases or decreases; [8] this means it can be used in aw ide rangeo fa pplications,i ncluding energy-saving buildings, [9,10] latent functionallyt hermal fluids, [11] smart textiles, [12] and solar energy storage.…”

Section: Introductionmentioning

confidence: 99%

Preparation and Characterization of Graphene Oxide‐Grafted Hexadecanol Composite Phase‐Change Material for Thermal Energy Storage

Wang

Zhang

2017

Energy Tech

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With the aim of improving the shape stability and recycling reliability of hexadecanol (HD), graphene oxide (GO)‐grafted hexadecanol (GO‐g‐HD) shape‐stabilized phase‐change material (SSPCM) with good thermochemical properties was prepared by oxidizing graphite powders to form GO, which was converted into the acyl chloride and finally condensed with HD. Various characterization techniques were employed to investigate the microstructure, thermal properties, thermal durability, and reliability of the composite. The results show that HD was embedded in the composite with a maximum mass fraction of 62.7 wt % through physical adsorption and covalent bonding. The grafted percentage and density of HD on ultrathin GO sheets are 36.5 wt % and 1.51 mmol g−1, respectively. The GO‐g‐HD SSPCM melts at 49.7 °C with a latent heat of 152.3 J g−1, and freezes at 45.4 °C with a phase‐change enthalpy of 129.9 J g−1. The thermal conductivity of GO‐g‐HD is measured as 0.519 W m−1 K−1, which is an improvement of 41.8 % compared with that of neat HD. Moreover, the as‐prepared composite also presents excellent chemical and thermal stability, excellent thermal durability, negligible variation in latent heats, and no changes in the phase‐change temperatures due to strong covalent bonds and interactions between the matrix and HD. Thus, GO‐g‐HD is a promising candidate for thermal energy storage in the future because of the very good latent heat, enhanced conductivity, and stability.

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Ca(OH) 2 /CaO reversible reaction in a fluidized bed reactor for thermochemical heat storage

Cited by 125 publications

References 26 publications

Mixed Metal Oxide Systems Applied to Thermochemical Storage of Solar Energy: Benefits of Secondary Metal Addition in Co and Mn Oxides and Contribution of Thermodynamics

Mixed Metal Oxide Systems Applied to Thermochemical Storage of Solar Energy: Benefits of Secondary Metal Addition in Co and Mn Oxides and Contribution of Thermodynamics

Development of a new methodology for validating thermal storage media: Application to phase change materials

Preparation and Characterization of Graphene Oxide‐Grafted Hexadecanol Composite Phase‐Change Material for Thermal Energy Storage

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