Review on the Life Cycle Assessment of Thermal Energy Storage Used in Building Applications

Hayatina, Isye; Auckaili, Amar

doi:10.3390/en16031170

Cited by 17 publications

(4 citation statements)

References 49 publications

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“…While sensible heat storage is widely used in practical applications, latent heat storage, such as phase-change materials (PCMs), offers substantially higher energy storage density. PCMs exhibit minimal temperature variation during both charging and discharging processes, making them highly efficient for thermal energy storage [24][25][26]. The next sections will provide a qualitative description of common methods and techniques for PCM usage inside TSCs, as well as for the use of nanomaterials to enhance PCM performance.…”

Section: Thermal Energy Storage Systems Using Phase-change Materials ...mentioning

confidence: 99%

Section: Thermal Energy Storage Systems Using Phase-change Materials ...mentioning

confidence: 99%

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Harnessing Nanomaterials for Enhanced Energy Efficiency in Transpired Solar Collectors: A Review of Their Integration in Phase-Change Materials

Croitoru,

Bode,

Calotă

et al. 2024

Energies

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The building sector plays an important role in the global climate change mitigation objectives. The reduction of CO2 emissions and energy consumption in the building sector has been intensively investigated in the last decades, with solar thermal energy considered to be one of the most promising solutions due to its abundance and accessibility. However, the discontinuity of solar energy has led to the study of thermal energy storage to improve the thermal performance of solar thermal systems. In this review paper, the integration of various types of phase-change materials (PCMs) in transpired solar collectors (TSC) is reviewed and discussed, with an emphasis on heat transfer enhancements, including nanomaterials. Thermal energy storage applied to TSC is studied in terms of design criteria, materials technologies, and its impact on thermal conductivity. This review highlights the potential of nanomaterial technology integration in terms of thermal performance improvements. The utilization of nanomaterials in solar walls holds the potential to significantly enhance their performance. The integration of diverse materials such as graphene, graphite, metal oxides, and carbon nanoparticles can pave the way for improving thermal conductivity.

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Section: Thermal Energy Storage Systems Using Phase-change Materials ...mentioning

confidence: 99%

Section: Thermal Energy Storage Systems Using Phase-change Materials ...mentioning

confidence: 99%

Harnessing Nanomaterials for Enhanced Energy Efficiency in Transpired Solar Collectors: A Review of Their Integration in Phase-Change Materials

Croitoru,

Bode,

Calotă

et al. 2024

Energies

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“…A further challenge is confirming salt hydrate THT's economic competitiveness and environmental benefit compared to the existing heat recovery technologies. A preliminary techno-economic analysis and a screening level Life Cycle Assessment (LCA) could be employed for this purpose, which is limited even for TCES applications [94].…”

Section: Research Gaps Challenges and Opportunitiesmentioning

confidence: 99%

Review on Salt Hydrate Thermochemical Heat Transformer

2023

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The industrial sector utilizes approximately 40% of global energy consumption. A sizeable amount of waste energy is rejected at low temperatures due to difficulty recovering with existing technologies. Thermochemical heat transformers (THT) can play a role in recovering low-temperature industrial waste heat by storing it during high supply and discharging it on demand at a higher temperature. Thus, THT will enable waste heat reintegration into industrial processes, improving overall energy efficiency and lowering greenhouse gas emissions from the industrial sector. Salt hydrate is a promising thermochemical material (TCM) because it requires a low charging temperature which can be supplied by waste heat. Furthermore, its non-toxic nature allows the implementation of a simpler and less costly open system. Despite extensive research into salt hydrate materials for thermochemical energy storage (TCES) applications, a research gap is identified in their use in THT applications. This paper aims to provide a comprehensive literature review of the advancement of THT applications, particularly for systems employing salt hydrates material. A discussion on existing salt hydrate materials used in the THT prototype will be covered in this paper, including the challenges, opportunities, and suggested future research works related to salt hydrate THT application.

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“…Globally, electrochemical energy storage devices have been regarded as the most prevalent energy storage technology. This category includes Li-ion batteries [2], supercapacitors and fuels cells [3], with Li-ion batteries enjoying preeminence over the others [4][5][6]. Nevertheless, their employment is limited in many applications due to issues of lower cycle life, restricted power performance, and over-heating, as highlighted in several studies [7][8][9].…”

Section: Introductionmentioning

confidence: 99%

Mos2 as the Supporting Material the Supercapacitor (Sc) Performance of the Mos2/Fe3o4 /Paninew Composite

Bayat,

karami,

Tavakoli

et al. 2023

Preprint

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Review on the Life Cycle Assessment of Thermal Energy Storage Used in Building Applications

Cited by 17 publications

References 49 publications

Harnessing Nanomaterials for Enhanced Energy Efficiency in Transpired Solar Collectors: A Review of Their Integration in Phase-Change Materials

Harnessing Nanomaterials for Enhanced Energy Efficiency in Transpired Solar Collectors: A Review of Their Integration in Phase-Change Materials

Review on Salt Hydrate Thermochemical Heat Transformer

Mos2 as the Supporting Material the Supercapacitor (Sc) Performance of the Mos2/Fe3o4 /Paninew Composite

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