Biaxial testing of fibre-reinforced composite laminates

Hemelrijck, Danny Van; Makris, Andreas; Ramault, Carla; Lamkanfi, Ebrahim; Paepegem, Wim Van; Lecompte, David

doi:10.1243/14644207jmda199

Cited by 13 publications

(13 citation statements)

References 11 publications

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“…A solution to improve the mechanical behavior identification is to use the biaxial test. In fact, it presents a high performance to identify material properties by performing a single test instead of multiple uniaxial tests [2]. In addition, it allows the application of biaxial loadings, closer to the real conditions encountered by the composite structure.…”

Section: Introductionmentioning

confidence: 99%

Strength characterization of glass/epoxy plain weave composite under different biaxial loading ratios

Kobeissi

Rahmé

Leotoing

et al. 2020

Journal of Composite Materials

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Over the past years, various studies have been investigated in order to characterize the behavior of composite materials under different multi-axial loading conditions. One of the most used biaxial techniques is the in-plane biaxial test on cruciform specimens. To achieve reliable biaxial failure results, the design of the cruciform specimen presents a crucial part. Previous studies show that there is no well-adapted cruciform geometry for the composite biaxial tests. In this paper, an optimal cruciform specimen has been defined numerically for the composite characterization test. The specimen is composed of two aluminum tabs glued on top and bottom side of the plain-weave glass/epoxy composite. Finite element simulations have been carried out in order to study the influence of the aluminum grade and thickness on the stress distribution in the composite. An experimental validation confirms the failure of the specimen in the central zone under three different biaxial tensile ratios. The experimental strains were evaluated using the digital image correlation method. The traction/traction quadrant of the failure envelop was obtained and compared with different failure criteria. The maximum strain criterion shows a good agreement with the experimental results.

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Section: Introductionmentioning

confidence: 99%

Strength characterization of glass/epoxy plain weave composite under different biaxial loading ratios

Kobeissi

Rahmé

Leotoing

et al. 2020

Journal of Composite Materials

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“…Smits et al [12] and Van Hemelrijck et al [13] investigated the influence of parameters like the radius of the corner fillet and the thickness and the geometry of the biaxially loaded area by finite element simulations and experiments. This investigation led to a suitable specimen for fiber reinforced composite laminates with a reduced thickness area in the center region of the specimen, in combination with a fillet corner between arms.…”

Section: State-of-the-artmentioning

confidence: 99%

Cruciform Specimen Design for Biaxial Tensile Testing of SMC

Schemmann¹,

Lang²,

Helfrich

et al. 2018

J. Compos. Sci.

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This paper presents an investigation of different cruciform specimen designs for the characterization of sheet molding compound (SMC) under biaxial loading. The considered material is a discontinuous glass fiber reinforced thermoset. We define various (material-specific) requirements for an optimal specimen design. One key challenge represents the achievement of a high strain level in the center region of the cruciform specimen in order to observe damage, at the same time prevention of premature failure in the clamped specimen arms. Starting from the ISO norm for sheet metals, we introduce design variations, including two concepts to reinforce the specimens' arms. An experimental evaluation includes two different loading scenarios, uniaxial tension and equi-biaxial tension. The best fit in terms of the defined optimality criteria, is a specimen manufactured in a layup with unidirectional reinforcing outer layers where a gentle milling process exposed the pure SMC in the center region of the specimen. This specimen performed superior for all considered loading conditions, for instance, in the uniaxial loading scenario, the average strain in the center region reached 87% of the failure strain in a uniaxial tensile bone specimen.

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“…A consequence is that the tests will be performed in load‐control. More system specifications can be found in [12, 13].…”

Section: Biaxial Testingmentioning

confidence: 99%

Comparison of Different Techniques for Strain Monitoring of a Biaxially Loaded Cruciform Specimen

Ramault

Makris

Hemelrijck

et al. 2011

Strain

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This study focuses on the evaluation of several strain measuring techniques for the instrumentation of an in-plane biaxial test bench. Strain gages, electronic speckle pattern interferometry (ESPI) and digital image correlation (DIC) were used combined or separately to measure the strains in the central gauge area of a biaxially loaded cruciform composite specimen. Applicability of the technique for this specific test and accuracy of the results are important parameters in the evaluation process of the different strain measuring techniques. The results of the three techniques are compared with the results obtained with a 3D finite element (FE) model. It is shown that DIC is the most promising technique because of its full-field character and ability to cope with vibrations of the test bench. The main drawback remains its incapability to correlate across discontinuities.

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Biaxial testing of fibre-reinforced composite laminates

Cited by 13 publications

References 11 publications

Strength characterization of glass/epoxy plain weave composite under different biaxial loading ratios

Strength characterization of glass/epoxy plain weave composite under different biaxial loading ratios

Cruciform Specimen Design for Biaxial Tensile Testing of SMC

Comparison of Different Techniques for Strain Monitoring of a Biaxially Loaded Cruciform Specimen

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