Using Constrained Multi-Optimization in
Design of Composite for Filament Wound
High Pressure Vessels

Dijana Cvetkoska; Igor Dimovski; Samoil Samak; Mirjana Trompeska; Vladimir Dukovski

doi:https://doi.org/10.14445/22315373/IJMTT-V61P516

International Journal of Mathematics Trends and Technology

Research Article | Open Access | Download PDF

Volume 61 | Number 2 | Year 2018 | Article Id. IJMTT-V61P516 | DOI : https://doi.org/10.14445/22315373/IJMTT-V61P516

Using Constrained Multi-Optimization in Design of Composite for Filament Wound High Pressure Vessels

Dijana Cvetkoska, Igor Dimovski, Samoil Samak, Mirjana Trompeska, Vladimir Dukovski

Citation :

Dijana Cvetkoska, Igor Dimovski, Samoil Samak, Mirjana Trompeska, Vladimir Dukovski, "Using Constrained Multi-Optimization in Design of Composite for Filament Wound High Pressure Vessels," International Journal of Mathematics Trends and Technology (IJMTT), vol. 61, no. 2, pp. 107-116, 2018. Crossref, https://doi.org/10.14445/22315373/IJMTT-V61P516

Abstract

Composites as multiphase materials offer the possibility to influence their properties or to add new functionalities by a proper choice and combination of the different phases. In addition to get best properties for the composite design numerous calculations for different combination of the fibers winding angles should be done. This paper targets the design of a composite laminate structure used for production of high pressure vessel. The application developed in this research manages to design a composite with most effective elastic modules, in a time shorter than the usual composite designing time, taking into account filament winding process, materials price as well as the purpose of the final product. This application uses a database of available materials in order to point out which combination creates a pressure vessel of cheaper composite material with the best strength, bulk modulus and load level of failure.

Keywords

composite design; composite material; database of materials; multi-objective optimization; high pressure vessel

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