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More articles from Volume 39, Issue 1, 2024

BANJA LUKA URBAN AXIS AS THE ARCHITECTURAL RECORD OF HISTORICAL DEVELOPMENT

INFLUENCE OF VEHICLE SPEED IN FREE TRAFFIC FLOW ON DISTRIBUTION OF ROADWAY SUPERELEVATION

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EXPLORATION OF THE SUITABLE TENSIONED MEMBRANE PROPERTIES FOR THE PHOTOVOLTAICS INTEGRATION

Vuk Milošević ,
Vuk Milošević
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Janusz Marchwiński ,
Janusz Marchwiński
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Elena Lucchi
Elena Lucchi
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Published: 13.06.2024.

Volume 39, Issue 1 (2024)

pp. 59-66;

https://doi.org/10.62683/zrgaf39.59-66

Abstract

The possibilities for the integration of tensioned membrane structures and photovoltaics have been researched intensively in the past decade. This integration has huge potential and is intended to bring benefits to both of these individual systems. This paper presents a preliminary communication of the research that is intended to facilitate the PV/membrane integration. Upon reviewing the current body of knowledge in the field, it is concluded that the mechanical properties of PV are known, some integration already occurred, both of the systems are still being perfected, however, it is not clear what properties a membrane structure needs to have in order to be suitable for the PV integration. Therefore, the goal of this research is to find out the relation between some of the structural parameters and the strains of the membrane, which are already determined as critical for the photovoltaics efficiency. The methodology of the research is laid out in this paper. A numerical simulation will be conducted in order to achieve membrane strains lower than the critical. For this, a set of variable parameters are selected and altered. The results should help the designers in choosing the values of the structural parameters, with the goal of designing tensioned membrane structures suitable for the integrations with photovoltaics.

References

1.
Fan Z, Bastiani Michele D, Michele G, Carol M, Alessandra Z, Mario C. Experimental investigation of the mechanical robustness of a commercial module and membrane-printed functional layers for flexible organic solar cells. Composites Part B. 2018;69–75.
2.
Qingxiang L, Zanelli A. A review on fabrication and applications of textile envelope integrated flexible photovoltaic systems. Renewable and Sustainable Energy Reviews. 110678;
3.
Vuk M, Janusz M. Photovoltaic Technology Integration with Tensile Membrane Structures -a Critical Review. Tehnički vjesnik. 2022;(2).
4.
Janusz M, Vuk M, Anna S, Elena L. 2023;1–26.
5.
Hend I, Mohamed, Alessandra Z, Cremers J. 2013;290–9.
6.
Vuk M, Dragan K, Miomir V, Dušan R, Janusz M. Fabric Stresses of Numerical Models of Barrel -Shaped Tensile Membrane Structures under Different Loads. International Academic and Technical Conference ARCHBUD 2023 -Problems of Contemporary Architecture and Construction. 2023;461–72.
7.
Vuk M, Dragan K, Miomir V, Dušan R, Janusz M. Deflections of Barrel Vault Shaped Membrane Model under External Loads. 2023;827–36.
8.
Hu J, Chen W, Liu Y, Zhao B, Yang D. Binbin Ge: Two-layer ETFE cushions integrated flexible photovoltaics: Prototype development and thermal performance assessment. Energy and Buildings. 2017;238–46.
9.
Hu J, Chen W, Cai Q, Gao C, Zhao B, Qiu Z, et al. Structural behavior of the PV-ETFE cushion roof. Thin-Walled Structures. 2016;169–80.
10.
Hu J, Chen W, Yin Y, Li Y, Yang D, Wang H, et al. Electrical-thermal-mechanical properties of multifunctional OPV-ETFE foils for large-span transparent membrane buildings. Polymer Testing. 2018;
11.
Andrzej A. Characterization Study on Mechanical Properties of Polyester Coated Fabric. Archives of Civil Engineering. 2020;(2):105–18.
12.
Qingxiang L, Tingjun L, Alara K, Zanelli A. Life cycle cost analysis and life cycle assessment of ETFE cushion integrated transparent organic/perovskite solar cells: Comparison with PV glazing skylight. Journal of Building Engineering. :2024.
13.
Qingxiang L, Carol M, Alara K, Zanelli A. Feasibility of textile envelope integrated flexible photovoltaic in Europe: Carbon footprint assessment and life cycle cost analysis. Journal of Cleaner Production. 139716;2023.
14.
Roberto S, Massimiliano L, Enrico S, Massimo D, Vitaliani R, Roberto. Membranes with embedded photovoltaic flexible cells: Structural and electrical performances under uniaxial and biaxial stresses. Composite Structures. 2016;111–20.
15.
Uhlemann J. Elastic Constants of Architectural Fabrics for Design Purposes. 2016;
16.
Vuk M. Projektovanje membranskih konstrukcija -Analiza ugiba pod opterećenjima, Građevinsko-arhitektonski fakultet. 2022;
17.
Vuk M, Dragan K. Nauka+Praksa. 2022;27–34.

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