Roles of thermal energy storage technology for carbon neutrality

Sun, Mingyang; Liu, Tianze; Wang, Xinlei; Liu, Tong; Li, Mulin; Chen, Guijun; Jiang, Dongyue

doi:10.1007/s43979-023-00052-w

Cited by 23 publications

(1 citation statement)

References 287 publications

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“…A reversible reaction of interest is the calcination/carbonation of limestone (CaCO 3 CaO + CO 2 ). This reaction, which is also the basis for Calcium Looping (CaL), has been widely investigated in recent decades for post-combustion and atmospheric CO 2 capture, and for its subsequent release in concentrated form for geological sequestration or chemical reuse [18][19][20][21][22][23][24][25][26][27][28][29]. Nowadays, CaL is also of particular interest for energy purposes, thanks to the high reaction enthalpy (∆H r • = 178 kJ/mol) and low cost of the raw material.…”

Section: Overviewmentioning

confidence: 99%

Influence of Fluidised Bed Inventory on the Performance of Limestone Sorbent in Calcium Looping for Thermochemical Energy Storage

Di Lauro,

Tregambi,

Montagnaro

et al. 2023

Energies

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This research work deals with the application of the calcium looping concept for thermochemical energy storage. Experiments were carried out in a lab-scale fluidised bed reactor, which was electrically heated. An Italian limestone (98.5% CaCO3, 420–590 μm) was present in the bed alone, or in combination with silica sand/silicon carbide (this last material was chosen as per its high absorption capacity in the solar spectrum). Calcium looping tests (20 calcination/carbonation cycles) were carried out under operating conditions resembling the “closed-loop” scheme (calcination at 950 °C, carbonation at 850 °C, fluidising atmosphere composed of pure CO2 in both cases). Carbonation degree, particle size distribution, and particle bulk density were measured as cycles progressed, together with the application of a model equation to relate carbonation degree to the number of cycles. Mutual relationships between the nature of the bed material and possible interactions, the degree of CaO carbonation, the generation of fragments, and changes in particle density and porosity are critically discussed. An investigation of the segregation behaviour of the bed material has been carried out through tests in a devoted fluidisation column, equipped with a needle-type capacitive probe (to measure solid concentration).

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Section: Overviewmentioning

confidence: 99%

Influence of Fluidised Bed Inventory on the Performance of Limestone Sorbent in Calcium Looping for Thermochemical Energy Storage

Di Lauro,

Tregambi,

Montagnaro

et al. 2023

Energies

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Recent Progress on Thermal Energy Storage for Coal-Fired Power Plant

Wang,

Zhang,

et al. 2024

J. Therm. Sci.

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Large-scale energy storage for carbon neutrality: thermal energy storage for electrical vehicles

Zhao,

Lin,

Zhang

et al. 2024

Carb Neutrality

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Thermal Energy Storage (TES) systems are pivotal in advancing net-zero energy transitions, particularly in the energy sector, which is a major contributor to climate change due to carbon emissions. In electrical vehicles (EVs), TES systems enhance battery performance and regulate cabin temperatures, thus improving energy efficiency and extending vehicle range. The enhanced efficiency reduces overall energy consumption in EVs. Consequently, this reduction in energy demand can lead to decreased infrastructure needs, minimising the scale and investment required in energy production and distribution systems. Furthermore, the integration of TES with existing infrastructure allows for the simultaneous charging of thermal and electrical energy, leveraging waste heat or renewable energy sources. This not only cuts costs by optimizing resource use but also bolsters sustainability by minimising reliance on non-renewable energy sources. The widespread adoption of TES in EVs could transform these vehicles into nodes within large-scale, distributed energy storage systems, thus supporting smart grid operations and enhancing energy security. Strategic investments and regulatory updates are essential to realise a sustainable, carbon-neutral transportation future, underpinned by robust, cost-efficient infrastructure.

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Roles of thermal energy storage technology for carbon neutrality

Cited by 23 publications

References 287 publications

Influence of Fluidised Bed Inventory on the Performance of Limestone Sorbent in Calcium Looping for Thermochemical Energy Storage

Influence of Fluidised Bed Inventory on the Performance of Limestone Sorbent in Calcium Looping for Thermochemical Energy Storage

Recent Progress on Thermal Energy Storage for Coal-Fired Power Plant

Large-scale energy storage for carbon neutrality: thermal energy storage for electrical vehicles

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