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2,710 837 Aluminium 2,710 896 Iron 7,900 452 Steel 7,840 465 Gravelly earth 2,050 1,840 Magnetite 5,177 752 Water 988 4,182

      Latent heat storage systems including phase change-based systems have attracted more attention in fundamental research as well as in industrial applications. During latent thermal storage, the storage material is heated until it changes phase at constant temperature conditions. Latent heat energy storage allows efficient storage of thermal energy by minimizing the entropy generation in isothermal processes like evaporation or condensation. Latent heat storage systems employ the enthalpy change of a substance passing through a phase change. In CSP technology the development of absorbers directly generating steam have sparked interest in latent heat storage systems.

      Latent energy storage systems have high energy density resulting in easily structured, small and flexible designs. The material that is used for latent heat storage systems is called Phase change material (PCM). Latent heat can be absorbed (charging) as well as can be released (discharging) through phase change of the PCM. The amount of latent heat stored in the material (Q) can be calculated as follows:

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      Here m is the mass of the material and ∆h is the enthalpy of phase change.

      Raul et al. (2018) studied modelling and experimental study of latent heat TES with encapsulated Phase change materials for CSP applications. Soares et al. (2013) reviewed passive PCM latent heat TES systems. Agyenim et al. (2010) reviewed materials, heat transfer and phase change issues for latent heat TES systems. Rathod and Barnerjee (2013) carried out a comprehensive study on thermal stability of PCM used in latent heat TES systems. Further, Cárdenas and León (2013) studied design considerations and performance enhancement procedures for high-temperature latent heat TES systems.

Material Melting temperature (ºC) Melting enthalpy (MJ/m3)
Water-salt solutions –100–0 200–300
Water 0 330
Clathrates –50–0 200–300
Paraffins –20–100 150–250
Salt hydrates –20–80 200–600
Sugar alcohols 20–450 200–450
Nitrates 120–300 200–700
Hydroxides 150–400 500–700
Chlorides 350–750 550–800
Carbonates 400–800 600–1,000
Fluorides 700–900 > 1,000

       1.3.4.3 Thermochemical Energy Storage

      Although chemical reaction thermal storage has multiple advantages, the chemical reaction process is complex. It sometimes requires catalysers and has certain safety requirements, and there are other difficulties such as a huge one-time investment and low overall efficiency. Thus, it currently remains in the small-scale experimental stage with plenty of problems yet to be solved before any large-scale application.

      The theoretical option to store energy at higher densities compared to latent heat or sensible heat storage concepts and the advantage of storing the reactants at ambient temperature make thermochemical storage systems a promising solution for longer term energy storage. On the other hand, thermochemical storage systems show a higher complexity than concepts for sensible heat storage or latent heat storage. The long-term reversibility of the reactions is an important issue. Currently, these systems are at an earlier stage of development, and there have been no commercial applications so far.

      The use of TES provides round the electricity generation. However, as seen from the literature, most of the CSP plants use TES involving molten salts at high temperatures. Such materials are highly corrosive which can damage the components of CSP. It is impossible to prevent corrosion in molten salts altogether. The effect of corrosion may be reduced by using protective coating or corrosion resistant material. To use proper and effective coating, the material must have good adhesion properties with the structural material. The coating should be uniform and less porous (Liu et al., 2014). Another way to supress the effect of corrosion is by application of a cathodic potential (Schwandt and Fray, 2014). Failure due to corrosion is a major issue and such risk of failure of TES system must always be taken into account. Such cost is a function of the costs of HTF and of materials used (Liu et al., 2016).

      Integration of TES in CSP plants is important for improving environmental issues as well as alleviating the global energy crisis. This chapter provides a comprehensive discussion on the integration of Thermal Energy Storage systems (TES) in Concentrating Solar Power plants (CSP) plants worldwide. Different TES technologies and their implementation in commercial-level CSP plants are discussed. It was observed from the discussion that CSP technology is already developed for commercialization. A good number of well-established CSP plants are producing

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