Industrial waste materials and by-products as thermal energy storage (TES) materials: A review

Gutiérrez, Andrea; Miró, Laia; Gil, Antoni; Rodríguez‐Aseguinolaza, Javier; Barreneche, Camila; Calvet, Nicolas; Py, Xavier; Fernández, A. Inés; Grágeda, Mario; Ushak, Svetlana; Cabeza, Luisa F.

doi:10.1063/1.4949117

Cited by 11 publications

(14 citation statements)

References 18 publications

(16 reference statements)

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“…The use of by-products or waste materials to store thermal energy is becoming a promising option to be used as TES materials due to their low-cost, close to zero, as was stated by Gutierrez et al [12]. In addition, Chile is an important non-metallic mining producer obtaining more than 60,646 ton of lithium compounds, 1.901.215 ton of potassium compounds, 6,576,960 ton of sodium chloride and 759,384 ton of nitrates among others every year [13].…”

Section: 7mentioning

confidence: 98%

Characterization of wastes based on inorganic double salt hydrates as potential thermal energy storage materials

Gutiérrez

Ushak

Mamani

et al. 2017

Solar Energy Materials and Solar Cells

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Thermal energy storage (TES) is seen today as a key technology to reduce the existing gap between energy demand and energy supply in many energy systems. There are, currently, three well known methods to store thermal energy and they are: sensible heat storage (SHS), latent heat storage (LHT) and thermochemical heat storage. Every method has its own thermophysical requirements for the mediums of storage, such as thermal stability, high enthalpy of phase change or reaction, high heat capacity and suitable temperature of the thermal phenomenon for a respective application, among others. In this regard, the composition of materials usually needs to be modified in order to improve their performance or to reach a determined requirement. As a consequence, the costs of potential TES materials to be applied in renewable energy systems are too high to compete with traditional systems using fossil fuels. On the other hand, several wastes and by-products from the non-metallic mining, such as salt hydrates and double salts, are available without any application but accumulating in the mining sites. This is the case for astrakanite (Na 2 SO 4 •MgSO 4 •4H 2 O) and lithium carnallite (LiCl•MgCl 2 •7H 2 O) with no current application, and potassium carnallite (KCl•MgCl 2 •6H 2 O) used as a supplementary raw material to obtain KCl. Since the costs of these materials are close to zero, they were characterized as TES materials taking into account the properties required for the three methods of storage. Results showed that astrakanite and potassium carnallite have potential to be applied as thermochemical material at low-medium temperature (<300°C). Also, a dehydrated product obtained from astrakanite showed potential to be applied as phase change material (PCM) at high temperature, from 550°C to 750°C. Nevertheless, lithium Δ H H Enthalpy of Hydration J/g wt.% Percentage of weight loss %

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Section: 7mentioning

confidence: 98%

Characterization of wastes based on inorganic double salt hydrates as potential thermal energy storage materials

Gutiérrez

Ushak

Mamani

et al. 2017

Solar Energy Materials and Solar Cells

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“…materials being used for CSP applications [Gil 2010;Tiskatine 2017]. Some recent developments are also reported, such as on the use of industrial wastes or by-products [Ortega-Fernández 2015;Gutierrez 2016], chloride salts [Myers 2016], lithium coupled with molten salts [Cabeza 2015], or solid particles [Zhang 2017a;Calderón 2018]. However, their limited energy density (usually between 60 kWhth•m −3 (200 °C-300 °C) for sand, rock and mineral oil, and 150 kWhth•m −3 for cast iron (200 °C-400 °C) [Fernandes 2012]) increases significantly the size of TES systems.…”

Section: Introductionmentioning

confidence: 99%

Integration of a thermochemical energy storage system in a Rankine cycle driven by concentrating solar power: Energy and exergy analyses

Pelay

Luo

Fan

et al. 2019

Energy

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This paper proposes and investigates novel concepts on the integration of a thermochemical energy storage (TCS) system in a concentrating solar power (CSP) plant. The TCS material used is calcium oxide reacting with water and the power cycle studied is a Rankine cycle driven by CSP.Firstly, three integration concepts on the coupling of the TCS system with the Rankine cycle are proposed, including the thermal integration concept, the mass integration concept and the double turbine concept. Then, an energy analysis is performed to determine and compare the theoretical overall energy efficiency of the proposed concepts. After that, an exergy analysis is also carried out for the selected integration concepts so as to evaluate and compare the overall exergy efficiency of the installation with TCS integration.The results show that the turbine integration concept has the highest overall energy efficiency (0.392), followed by the thermal integration concept (0.358) and the mass integration concept (0.349) under ideal conditions with 11 h of charging and 13 h of discharging. The energy storage density using calcium hydroxide as the storage media is estimated to be about 100 kWhel•t -1 . Exergy analysis results also indicate that the turbine integration concept seems to be the best option under the tested conditions.

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“…Most of this waste is toxic and contains hazardous and health-threatening chemicals. Proper waste management is the best way to maintain a clean atmosphere by reducing, reusing, and recycling our waste [ 16 , 17 ]. Among the different types of waste, electronic waste (e-waste) is of serious concern to society and arises from discarding electronic equipment after the end of its useful life.…”

Section: Introductionmentioning

confidence: 99%

Dendritic Nanostructured Waste Copper Wires for High-Energy Alkaline Battery

et al. 2019

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HIGHLIGHTS • Electronic waste Cu wires were successfully used as a cost-effective current collector for high-energy wire-type rechargeable alkaline batteries. • The scalable approach was applied to reduce, reuse, and recycle electronic waste. • A developed wire-type rechargeable alkaline battery exhibited a high-energy-density of 82.42 Wh kg −1 with long-term cycling stability. ABSTRACT Rechargeable alkaline batteries (RABs) have received remarkable attention in the past decade for their high energy, low cost, safe operation, facile manufacture, and ecofriendly nature. To date, expensive electrode materials and current collectors were predominantly applied for RABs, which have limited their real-world efficacy. In the present work, we propose a scalable process to utilize electronic waste (e-waste) Cu wires as a cost-effective current collector for high-energy wire-type RABs. Initially, the vertically aligned CuO nanowires were prepared over the waste Cu wires via in situ alkaline corrosion. Then, both atomiclayer-deposited NiO and NiCo-hydroxide were applied to the CuO nanowires to form a uniform dendritic-structured NiCo-hydroxide/ NiO/CuO/Cu electrode. When the prepared dendritic-structured electrode was applied to the RAB, it showed excellent electrochemical features, namely high-energy-density (82.42 Wh kg −1), excellent specific capacity (219 mAh g −1), and long-term cycling stability (94% capacity retention over 5000 cycles). The presented approach and material meet the requirements of a cost-effective, abundant, and highly efficient electrode for advanced eco-friendly RABs. More importantly, the present method provides an efficient path to recycle e-waste for value-added energy storage applications.

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Industrial waste materials and by-products as thermal energy storage (TES) materials: A review

Cited by 11 publications

References 18 publications

Characterization of wastes based on inorganic double salt hydrates as potential thermal energy storage materials

Characterization of wastes based on inorganic double salt hydrates as potential thermal energy storage materials

Integration of a thermochemical energy storage system in a Rankine cycle driven by concentrating solar power: Energy and exergy analyses

Dendritic Nanostructured Waste Copper Wires for High-Energy Alkaline Battery

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