Your search keyword '"Glass fiber reinforced composite"' showing total 2 results

1. The effect of nanoparticle additive on surface milling in glass fiber reinforced composite structures

Author

Ahmet Yapici, Ferhat Ceritbinmez, Erdoğan Kanca, Mühendislik ve Doğa Bilimleri Fakültesi -- Makina Mühendisliği Bölümü, Ceritbinmez, Ferhat, Kanca, Erdoğan, and Yapıcı, Ahmet

Subjects

Machinability, Materials science, Glass fibers, Polymers and Plastics, Abrasion (mechanical), Carbon Fiber Reinforced Plastics, Materials Science, Glass fiber, Composite number, Polymer Science, Mechanical-properties, Nanoparticle, Tool Wear, Cutting Force, Surface roughness, Surface milling, GFRP, Materials Chemistry, Cutting process, Feed-rates, Slot sizes, Strength of materials, Tool wear, Composite material, Hole, Polymer composites, Nanocomposite, Composite structures, Additives, Cutting tools, Fibre-reinforced plastic, Wall carbon nanotubes, Fiber reinforced plastics, Composite layer, Cutting speed, Ceramics and Composites, Nanoparticles, Glass fiber reinforced composite, Abrasion, Graphene, Milling (machining), Laminated composites, Laminated glass

Abstract

In this study, the effect of adding nanosize additive to glass fiber reinforced composite plates on mechanical properties and surface milling was investigated. In the light of the investigations, with the addition of MWCNTs additive in the composite production, the strength of the material has been changed and the more durable composite materials have been obtained. Slots were opened with different cutting speed and feed rate parameters to the composite layers. Surface roughness of the composite layers and slot size were examined and also abrasions of cutting tools used in cutting process were determined. It was observed that the addition of nanoparticles to the laminated glass fiber composite materials played an effective role in the strength of the material and caused cutting tool wear.

Published

2021

2. Effects of Accelerated Climatic Aging on Volume and Surface Resistivity of Glass Fiber Reinforced Thermoset Composites

Author

Josef Pihera, Pavel Prosr, Tereza Krejnicka, Petr Kadlec, Martin Hirman, Radek Polansky, Ondrej Musil, R. Pavlica, and J. Komarek

Subjects

Materials science, Glass fiber, Humidity, Thermosetting polymer, Epoxy, Dielectric, surface resistivity, glass fiber reinforced composite, chemistry.chemical_compound, chemistry, Volume (thermodynamics), volume resistivity, Electrical resistivity and conductivity, visual_art, accelerated climatic aging epoxide resin, visual_art.visual_art_medium, polyurethane resin, Composite material, Polyurethane

Abstract

This paper is focused on the analysis of selected dielectric parameters stability under the conditions of selected accelerated climatic aging. This stability is analyzed for glass fiber reinforced composites with different thermosetting matrix suitable for the production of electrical insulating and also construction elements. Different types of thermosetting resins (epoxy and polyurethane resins) were chosen for the preparation of composites, which are the subject of the presented experiment. Tested composites were firstly characterized in the delivered state and then after the accelerated climatic aging. Important dielectric parameters were evaluated, which are the volume resistivity and the surface resistivity. Two different tests of accelerated climatic aging were realized. The first one was Temperature/humidity cyclic test, which consists of alternated intervals (i) under the temperature of 55 °C and the humidity of 93 %RH and (ii) under the temperature of 25 °C and the humidity of 97.5 %RH. The second one was Damp heat steady state test when samples were exposed to the temperature of 85 °C and the humidity of 85 %RH continuously for 1000 hours. Based on the measured data of resistivities, prospective materials were selected for further activities leading to the production of construction elements with also good electrical insulating properties and with their minimal affection by simulated climatic conditions.

Published

2020