期刊
JOURNAL OF REINFORCED PLASTICS AND COMPOSITES
卷 40, 期 21-22, 页码 827-844出版社
SAGE PUBLICATIONS LTD
DOI: 10.1177/07316844211014006
关键词
Fiberglass; PA66-based polymers; high fluidity; laminates; composite; uniaxial tensile testing; damage; fracture mechanisms
资金
- Agence Nationale pour la Recherche (ANR)
- Delegation Generale a l' Armement (DGA) [ANR-11-RMNP-0020]
- Agence Nationale de la Recherche (ANR) [ANR-11-RMNP-0020] Funding Source: Agence Nationale de la Recherche (ANR)
This study investigates the relationship between microstructure and mechanical properties of glass fiber-reinforced polyamide 6,6 composite materials. The addition of a spacer not only enhances permeability but also improves physical and mechanical properties. Analysis of the microstructure and rheological behaviors of polymers confirm the results obtained from mechanical performance tests.
In this work, we examine the relationships between the microstructure and the mechanical properties of glass fiber-reinforced polyamide 6,6 composite materials (V- f = 54%). These materials made by thermocompression incorporate different grades of high fluidity polyamide-based polymers and two types of quasi-UD glass fiber reinforcement. One is a classic commercial fabric, while the other specially designed and manufactured incorporates weaker tex glass yarns (the spacer) to increase the planar permeability of the preform. The effects of the viscosity of the polymers and their composition on the wettability of the reinforcements were analyzed by scanning electron microscopy observations of the microstructure. The respective influences of the polymers and the spacer on the mechanical performance were determined by uniaxial tensile and compression tests in the directions parallel and transverse to the warp yarns. Not only does the spacer enhance permeability but it also improves physical and mechanical properties: tensile longitudinal Young's modulus increased from 38.2 GPa to 42.9 GPa (13% growth), tensile strength increased from 618.9 MPa to 697 MPa (3% growth), and decrease in ultimate strain from 1.8% to 1.7% (5% reduction). The correlation of these results with the damage observed post mortem confirms those acquired from analyses of the microstructure of composites and the rheological behaviors of polymers.
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