Thermal Energy Storage for Concentrating Solar Power Plants

Kuravi, Sarada; Goswami, Yogi; Stefanakos, Elias K.; Ram, Manoj; Jotshi, C.K.; Pendyala, Swetha; Trahan, Jamie; Sridharan, P.; Rahman, Muhammad M.; Krakow, Burton

doi:10.3727/194982412x13462021397570

Cited by 30 publications

(17 citation statements)

References 21 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In recent years, a number of thermal storage technologies for medium to high temperature CSP systems have been developed from the use of materials in which energy is stored as sensible heat [1][2][3]. Diverse materials with high heat capacity are employed in thermal energy storage (TES) systems such as water [4], molten salts [5][6][7], mineral oils [8] or ceramic materials [9]. Commercial plants of considerable size (>100 MWt) do already exist where heat is stored in molten salts and used overnight to generate electricity.…”

Section: Introductionmentioning

confidence: 99%

Thermochemical energy storage of concentrated solar power by integration of the calcium looping process and a CO2 power cycle

et al. 2016

View full text Add to dashboard Cite

Energy storage is the main challenge for a deep penetration of renewable energies into the grid to overcome their intrinsic variability. Thus, the commercial expansion of renewable energy, particularly wind and solar, at large scale depends crucially on the development of cheap, efficient and non-toxic energy storage systems enabling to supply more flexibility to the grid. The Ca-Looping (CaL) process, based upon the reversible carbonation/calcination of CaO, is one of the most promising technologies for thermochemical energy storage (TCES), which offers a high potential for the long-term storage of energy with relatively small storage volume. This manuscript explores the use of the CaL process to store Concentrated Solar Power (CSP). A CSP-CaL integration scheme is proposed mainly characterized by the use of a CO 2 closed loop for the CaL cycle and power production, which provides heat decoupled from the solar source and temperatures well above the ~550ºC limit that poses the use of molten salts currently used to store energy as sensible heat. The proposed CSP-CaL integration leads to high values of plant global efficiency (of around 45-46%) with a storage capacity that allows for long time gaps between load and discharge. Moreover, the use of environmentally benign, abundantly available and cheap raw materials such as natural limestone would mark a milestone on the road towards the industrial competitiveness of CSP.

show abstract

Section: Introductionmentioning

confidence: 99%

Thermochemical energy storage of concentrated solar power by integration of the calcium looping process and a CO2 power cycle

et al. 2016

View full text Add to dashboard Cite

show abstract

“…6,11,16 Higher temperature PCMs (>200 °C) continue to be a significant area of research due to their application in concentrated solar power plants. 4 High phase transition temperature materials could also be used with other heat sources capable of producing pressurized steam for a Rankine cycle. For common triple pressure power plants, such as natural gas combined cycle and coal, PCM transition temperatures of about 330 °C would be required for evaporation of the high-pressure steam.…”

Section: ■ Introductionmentioning

confidence: 99%

Metal Nanoparticle–Carbon Matrix Composites with Tunable Melting Temperature as Phase-Change Materials for Thermal Energy Storage

Tran

Zhao

Carlson

et al. 2018

ACS Appl. Nano Mater.

View full text Add to dashboard Cite

Phase-change materials with tunable melting temperature provide a new design for thermal energy storage applications. Here, we demonstrate a general one-pot synthesis of composites containing ligand-free metal nanoparticles (Bi or Pb) distributed in a mesoporous carbon matrix as form-stable phase change materials. The melting temperature of the encapsulated metal nanoparticles (NPs) can be tuned as a function of particle size, which depends on the metal loading in the composite material. Melting and resolidification temperatures are stable through multiple melt− freeze cycles. The carbon matrix encapsulating the metal NPs prevents aggregation of the NPs, accommodates volume change, and prevents leakage during phase change process. The melting temperature of the Bi NPs decreases by 33 °C compared to the melting point of bulk Bi with a Bi loading of 48 wt % in the composite materials, and that of Pb NPs decreases by 18 °C compared to bulk Pb with a Pb loading of 47 wt %. Using transmission electron microscopy, we also demonstrate that the porous channels of the carbon matrix serve as containers for the melted Pb NPs.

show abstract

“…The two main drawbacks associated with this concept are the necessary heavy thermal insulation, preventing heat losses during storage through radiation, as well as the large volumes of storage medium. Latent heat storage [ 12 , 13 , 14 ]: Heat is stored taking advantage of the energy demand/energy release, associated with a phase-transfer from solid to liquid, or vice-versa. Although the first commercial applications with latent heat storage are already available, the technological readiness is less than for sensible technologies.…”

Section: Introductionmentioning

confidence: 99%

CuSO4/[Cu(NH3)4]SO4-Composite Thermochemical Energy Storage Materials

et al. 2020

View full text Add to dashboard Cite

The thermochemical energy-storage material couple CuSO4/[Cu(NH3)4]SO4 combines full reversibility, application in a medium temperature interval (<350 °C), and fast liberation of stored heat. During reaction with ammonia, a large change in the sulfate solid-state structure occurs, resulting in a 2.6-fold expansion of the bulk material due to NH3 uptake. In order to limit this volume work, as well as enhance the thermal conductivity of the solid material, several composites of anhydrous CuSO4 with inorganic inert support materials were prepared and characterized with regard to their energy storage density, reversibility of the storage reaction, thermal conductivity, and particle morphology. The best thermochemical energy storage properties were obtained for a 10:1 CuSO4-sepiolite composite, combining an attractive energy storage density with slightly improved thermal conductivity and decreased bulk volume work compared to the pure salt.

show abstract

Thermal Energy Storage for Concentrating Solar Power Plants

Cited by 30 publications

References 21 publications

Thermochemical energy storage of concentrated solar power by integration of the calcium looping process and a CO2 power cycle

Thermochemical energy storage of concentrated solar power by integration of the calcium looping process and a CO2 power cycle

Metal Nanoparticle–Carbon Matrix Composites with Tunable Melting Temperature as Phase-Change Materials for Thermal Energy Storage

CuSO4/[Cu(NH3)4]SO4-Composite Thermochemical Energy Storage Materials

Contact Info

Product

Resources

About