Revolutionizing the Building Envelope: A Comprehensive Scientific Review of Innovative Technologies for Reduced Emissions

Narbuts, Jānis; Vanaga, Ruta

doi:10.2478/rtuect-2023-0053

Cited by 5 publications

(1 citation statement)

References 45 publications

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“…On new experimental projects, thermal and comfort indexes must be evaluated because passive systems use sensitive materials that users cannot switch off or work on. Narbuts and Vanaga [21] reviewed innovative building envelope technologies to improve total building energy efficiency and reduce greenhouse gas emissions, showing that active PCM can reduce room temperature by 6.8 • C in summer, aerogel has excellent insulation and low density, silica aerogel outperforms traditional insulation materials by 2-4 times with energy savings of up to 35%, and active and adaptive systems enable real-time control of building envelope performance, improving energy efficiency and indoor comfort. None of these studies specifically address modular building envelopes, let alone the development of envelope panels.…”

Section: Introductionmentioning

confidence: 99%

Thermo-Environmental Performance of Modular Building Envelope Panel Technologies: A Focused Review

Mohammed,

Budaiwi,

Al-Osta

et al. 2024

Buildings

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Modular construction is becoming famous for buildings because it allows a high degree of prefabrication, with individual modules easily transported and installed. Building envelope optimization is vital as it protects buildings from undesirable external environments by expressly preventing the incursion of outside elements. This research uses a systematic literature review to appraise the characteristics of modular envelope panels, focusing on hygrothermal and energy performance. A total of 265 articles were subjected to rigorous filtering and screening measures. The findings reveal notable inconsistencies in modular envelope terminologies and a lack of consistent performance measures, which present significant challenges for research and development efforts. Furthermore, the results indicate a predominant focus on hygrothermal and energy performance in existing studies, with limited attention to environmental impacts and other performance factors. Moreover, the existing literature primarily addresses modular envelope solutions in temperate climates, offering inadequate information for hot and hot–humid climate contexts. To address these gaps, this study proposes categorizing modular envelope panels into four distinct categories: active, passive, smart, and green/vegetated wall panels. These findings will benefit researchers, architects, building envelope designers, policymakers, and organizations developing building performance-related assessment ratings, standards, and codes. The study suggests adopting the categorization of modular envelope panels provided in this study and developing modular panels suitable for hot and humid climates to fill the existing knowledge gap.

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Section: Introductionmentioning

confidence: 99%

Thermo-Environmental Performance of Modular Building Envelope Panel Technologies: A Focused Review

Mohammed,

Budaiwi,

Al-Osta

et al. 2024

Buildings

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Methodology for Designing Adaptive Facade Components: Smart Materials and 4D Printing for Resilient Construction

Battaglia,

Vite,

Morbiducci

2024

Lecture Notes in Civil Engineering

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Bibliometric Analysis of the Modelling of LowQuality Biomass Pellets Combustion

Svedovs,

Dzikevics,

Kirsanovs

et al. 2024

Environmental and Climate Technologies

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Diversification of energy resources is a current objective that several countries want to achieve, including in northern Europe. Demand for wood fuels is increasing in Latvia, which is reflected in consumer expenditure. Using low-quality biomass (LQB) to produce fuel pellets for market stabilisation and diversification is possible. LQB pellets can theoretically and practically be used in low-capacity solid fuel boilers to provide different types of individual heating systems with an alternative energy source. Before starting mass production of LQB fuel pellets, it is necessary to clarify the properties of the raw materials. Any fuel study shall be divided into two phases: determination of the parameters of the fuel or raw material (calorific values, moisture content, and ash content) and analysis of the combustion process. The combustion process can be studied in two ways: experimentally and by mathematical modelling. Knowing the parameters that would need to be clarified during the study of the LQB fuel pellets combustion process (thermodynamics, gaseous emissions, particulate matter emissions, bottom ash, and slag), the authors have set the goal of clarifying the software applied to mathematical modelling of these parameters. A bibliometric analysis method was chosen to identify the software. The bibliometric analysis was carried out in the Scopus database. As a result, two software were identified: ANSYS Fluent software is suitable for modelling thermodynamic processes and gaseous emission streams. At the same time, XDEM software is the most suitable for modelling particle streams and ash/slag generation. This software will be used in future studies.

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Revolutionizing the Building Envelope: A Comprehensive Scientific Review of Innovative Technologies for Reduced Emissions

Cited by 5 publications

References 45 publications

Thermo-Environmental Performance of Modular Building Envelope Panel Technologies: A Focused Review

Thermo-Environmental Performance of Modular Building Envelope Panel Technologies: A Focused Review

Methodology for Designing Adaptive Facade Components: Smart Materials and 4D Printing for Resilient Construction

Bibliometric Analysis of the Modelling of LowQuality Biomass Pellets Combustion

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