Fundamental influences on quasistatic and cyclic material behavior of short glass fiber reinforced polyamide illustrated on microscopic scale

Brunbauer, Julia; Mösenbacher, Andreas; Guster, Christoph; Pinter, Gerald

doi:10.1002/app.40842

Cited by 28 publications

(18 citation statements)

References 17 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Bernasconi et al [16] showed that increasing specimen orientation angle decreases elastic modulus, ultimate tensile stress and fatigue strength. The same results was found by Zhou and Mallick [15] and Brunbauer et al [17]. Recently, Benaarbia et al [18], reported that ratcheting for fibre reinforced composites oriented at 45° and 90° was much higher than that for 0° composites Moreover, Mallick and Zhou [19] evaluated the effect of the stress ratio on the fatigue behaviour of the PA66-GF33.…”

supporting

confidence: 73%

Fatigue Behavior of Short Glass Fiber Reinforced Polyamide 66: Experimental Study and Fatigue Damage Modelling

Chebbi

Mars

Wali

et al. 2016

Period. Polytech. Mech. Eng.

View full text Add to dashboard Cite

The aim of the present paper is to study and model the fatigue behavior of short glass fibers reinforced polyamide-66. The effect of fiber content on the fatigue and static behavior of this composite is investigated. In such composites fatigue damage growth exhibits three stages. A continuum damage based model is presented to predict damage evolution during these three stages. Experimental results show that increasing the fiber content increases the elastic modulus and the tensile strength of the studied materials under tensile tests. However, the rupture behavior changes from ductile to brittle. Moreover increasing the fiber percentage changes the S-N curves slope and decreases the fatigue life. Analytical results predicted by the proposed model, compared to experimental ones shows good agreement and the developed model predicted fatigue damage growth in its three stages of evolution with good performance. IntroductionThe use of short fibre reinforced thermoplastic composites is rapidly growing, because of their high specific properties. Their good mechanical and chemical properties, low weight and ease of processing in complex forms would make them a reliable substitute for metallic materials. Moreover, fibre composite materials are used in automotive applications, under the hood where environmental conditions are very severe.Large number of mechanical components are subjected to cyclic loading in their real operating conditions, which may causes fatigue failure even for loading levels below the elastic limit of the material. Therefore, the knowledge of the fatigue behaviour and mechanical properties of composite materials is vital, to optimize the design, to ensure the reliability and to guarantee the safe service use of components made of these materials. However, short glass fibre reinforced polyamide (PA-GFs) are very inhomogeneous since their mechanical properties result from the combination of the matrix, the glass fibres and of the interface (matrix/glass fibre) properties. Consequently, the mechanical behaviour of PA-GFs is a quite complex phenomenon since it is influenced by a large number of loading and structural parameter. Their mechanical properties are governed by the diameter, the length, the orientation and the quantity of fibres [1,2]. Also processing conditions: speed and pressure of injection and temperature of the mould may affect the behaviour of composite material [3]. Experimental variables (deformation speed, test temperature, frequency, etc.) have an important influence on the fatigue behaviour of these materials [4][5][6][7]. Environmental conditions such, as temperatures and humidity are very important consideration. In the open literature, the effect of several parameters on the fatigue behaviour of PA-GFs was studied.Several early studies have dealt with the influence of ambient temperature on the fatigue behaviour of PA66-GFs. It was shown that ambient temperature effect is related to the glass transition temperature (Tg) of the studied material. Handa et al. [8], demonstrated that...

show abstract

supporting

confidence: 73%

Fatigue Behavior of Short Glass Fiber Reinforced Polyamide 66: Experimental Study and Fatigue Damage Modelling

Chebbi

Mars

Wali

et al. 2016

Period. Polytech. Mech. Eng.

View full text Add to dashboard Cite

show abstract

“…Matrix brittle failure and fiber pull-out were observed in mold flow oriented samples, while brittle fracture surface was observed in samples perpendicular to the mold flow direction of short glass fiber polyamide-6.6 in [15]. As temperature increased, crazes in fibril structure were more pronounced.…”

Section: Introductionmentioning

confidence: 87%

“…Evolution of hysteresis loops in either their size or slope [2,5], hysteretic energy [7,8], strain energy [9,10], and nonlinear viscoelasticity [11,12] are the parameters typically used for modeling of fatigue damage and accumulation. Fiber orientation is another important factor controlling fatigue performance and the degree of anisotropy of SFRPCs [13][14][15]. The orientation distribution of fibers is mainly controlled by a complex flow field in the injection molding process and also dependent on the geometry of fibers and the component, viscoelastic behavior of matrix, and melt and mold temperatures [16].…”

Section: Introductionmentioning

confidence: 99%

Fatigue behavior and modeling of short fiber reinforced polymer composites including anisotropy and temperature effects

Mortazavian

Fatemi

2015

International Journal of Fatigue

View full text Add to dashboard Cite

“…The work of Horst and Spoormaker [ 28,29 ] on the damage mechanisms of short glass fiber polyamide 6.6 in quasi‐static and fatigue allowed proposing a scenario of damage in fatigue similar to that of Sato, [ 30,31 ] mainly based on the creation of a vacuum at the matrix fiber interface. Since then, this scenario has been widely validated in the literature [ 32,33 ] and has affirmed its independence from many parameters, including the type of loading and the temperature. For both researchers, the difference between each loading would lead to the level of the kinetics of the damage propagation.…”

Section: Introductionmentioning

confidence: 98%

Multi‐scale analysis of short glass fiber‐reinforced polypropylene under monotonic and fatigue loading

et al. 2020

View full text Add to dashboard Cite

Short fiber-reinforced polypropylene is largely used in the automotive industry. Fatigue failure is one of the most failure modes observed in this class of materials. In order to better understand the damage mechanisms and plasticity evolution, this article provides an overall experimental investigation of the mechanical properties of a PPGF40 composite (polypropylene matrix reinforced by a 40% weight content of short glass fibers) including monotonic and cyclic loading. The effect of various parameters such as the loading direction, the strain rate, the temperature, and the fatigue are analyzed. The evolutions of the loss of stiffness and plastic strain during monotonic and fatigue tests are analyzed. Self-heating during cyclic loading is also studied. Moreover, the coupling effect of damage and plasticity is analyzed by plotting the evolution of the relative loss of stiffness vs the plastic strain increment for monotonic and cyclic loadings. For quasi-static loading, the results emphasize an intrinsic curve independent of the loading direction. Moreover, a sharp increase in the damage and plasticity levels due to the local effect occurring during cyclic loading is observed and correlated to SEM fracture surface analysis.

show abstract

Fundamental influences on quasistatic and cyclic material behavior of short glass fiber reinforced polyamide illustrated on microscopic scale

Cited by 28 publications

References 17 publications

Fatigue Behavior of Short Glass Fiber Reinforced Polyamide 66: Experimental Study and Fatigue Damage Modelling

Fatigue Behavior of Short Glass Fiber Reinforced Polyamide 66: Experimental Study and Fatigue Damage Modelling

Fatigue behavior and modeling of short fiber reinforced polymer composites including anisotropy and temperature effects

Multi‐scale analysis of short glass fiber‐reinforced polypropylene under monotonic and fatigue loading

Contact Info

Product

Resources

About