Investigation Of Coating Properties In Cr2O3 +TiO2 Coatings Of Glass Fiber Reinforced Composite Materials By Flame Spray Coating Method
DOI:
https://doi.org/10.5281/zenodo.11220772Keywords:
Fiber reinforced composite materials Flame spray coating Mechanical propertiesAbstract
In this study, the coating properties of glass fiber reinforced composite materials were examined in Cr2O3 +TiO2 coating by flame spray coating method. In the manufacture of the composite materials to be coated, glass fiber woven fabrics with different fiber densities (200, 300 and 500 g/m2) and epoxy resin were used as matrix material. Composite materials were manufactured using the hand lay-up method. Coating processes of Cr2O3 +TiO2 ceramic powders were performed on the composite materials manufactured in the form of plates using the flame spray coating method. In order to examine the coating quality of the coated materials, samples were prepared from the coated plates in accordance with the standards and experiments were carried out to determine microstructure examinations, hardness measurements, surface roughness measurements and adhesion strength values. Microstructural examinations of the samples were carried out under optical microscope and SEM microscope. Measurements of porosity amounts of the coatings were made with the Clemex image analysis program on the optical microscope. The microhardness values of the coatings were measured on the surface of the samples using a micro hardness measuring device. The adhesion strength of the samples was determined in the tensile test device according to ASTM C-63 standard. It has been determined that the properties of the coated composite material affect the coating quality. The highest adhesion strength values among the coated samples were obtained in the coating made on glass fiber reinforced (500 g/m2) composite material, which has the highest fiber density. Hardness values and adhesion strength values of coatings with high porosity amount were low.
References
Atlıhan, G. & Ergene, B. (2018). Vibration analysis of layered composite beam with variable section in terms of delamination and orientation angle in analytical and numerical methods. Acta Physica Polonica A. 134(1), 13-17.
Bradaia, M.A., Bounarb, N., Benabbasb, A. & Ati, A. (2008). Study of microstructure, phases and microhardness of metallic coatings deposited by flame thermal spray, Journal of materials Processing Technology 200, 410–415.
Bunsell, A.R., Joannès, S. & Thionnet A. (2005). Fundamentals of Fibre Reinforced Composite Materials, Oxon, CRC Press.
Chawla, K.K. (2019). Composite Materials: Science and Engineering, Fourth Edition, Springer, SwitzerlandAG, 139-197.
Gonzalez, R., Ashrafizadeh, H., Lopera, A., Mertiny P. & McDonald A. (2016). A Review of Thermal Spray Metallization of Polymer-Based Structures, Journal of Thermal Spray Technology, 25(5), 897.
Lopera-Valle A. & McDonald A., (2015). Application of Flame-Sprayed Coatings as Heating Elements for Polymer-Based Composite Structures, Journal of Thermal Spray Technology, 24(7), 1289.
Lopera-Valle A. & McDonald A. (2016). Flame-sprayed coatings as de-icing elements for fiber-reinforced polymer composite structures: Modeling and experimentation, International Journal of Heat and Mass Transfer 97, 56–65.
Pawlowski, L. (2008). The Science and Engineering of Thermal Spray Coatings, Second Edition, John Wiley & Sons Ltd, England, 67-74.
Thakur, L. & Vasudev, H. (2022). Thermal Spray Coatings, Oxon, CRC Press, 1-37.
Visconti, I.C., Paesano, A. & Penasa, M., (1992). An investigation of antiwear coatings on fibre-reinforced plastics, Composites Manufacturing, Vol. 3, No.1, 14-19.
Downloads
Published
How to Cite
Issue
Section
License
Copyright (c) 2024 EJONS INTERNATIONAL JOURNAL
This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.
