Simulation of wrinkling during textile composite reinforcement forming. Influence of tensile, in-plane shear and bending stiffnesses

Boisse, Philippe; Hamila, Nahiene; Vidal‐Sallé, Emmanuelle; Dumont, François

doi:10.1016/j.compscitech.2011.01.011

Cited by 360 publications

(260 citation statements)

References 52 publications

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“…These non-useful zones are cut after the process. Consequently, these wrinkles have no consequences on the quality of the performs, but, these results confirm first the influence of the tension in yarns, due to the blank-holder pressure, on the presence of wrinkle and second the necessity to apply some load to obtain a preform without default [13].…”

Section: Resultssupporting

confidence: 63%

“…Numerical simulations have already been extensively used to investigate the viability of fabric forming by optimization of process control parameters, material selection and tool design to avoid production of costly prototypes. Some of these simulations describe the evolution of the dry reinforcement behaviour by mechanical approach [10][11][12][13]. These numerical works must be validated, compared and complemented by experimental results.…”

Section: Introduction and Context Of The Studymentioning

confidence: 99%

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Experimental preforming of highly double curved shapes with a case corner using an interlock reinforcement

et al. 2012

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:This experimental work concerns the study of the preforming of a specific highly double curved geometry with a triple point (case corner) by the sheet forming process using powdered interlock reinforcement (G1151 ® ). Three different punches (square box, prism, tetrahedron) were used in this study, each of them presenting highly double curved geometry with a case corner. A specific sheet forming device specially designed for the preforming of textile reinforcement was used. The expected shapes with the three punches have been obtained with an optimized blank-holder pressure. No classical defaults such as wrinkling or yarn damage are present in the useful zone of the preforms. However, a new default, not observed for spherical or hemispherical shape has been identified. It concerns the out of plane buckling of yarns. This phenomenon not observed on the square box is visible on some faces and edges of the prismatic and tetrahedron shapes. For the square box, it is easily possible to control the orientation of the yarn within the preform in the faces, whereas this is not possible for triangular faces 2 of the prismatic and tetrahedron shapes. The square box punch is therefore more adapted to preform the highly doubled curved shape with the case corner.

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Section: Resultssupporting

confidence: 63%

Section: Introduction and Context Of The Studymentioning

confidence: 99%

Experimental preforming of highly double curved shapes with a case corner using an interlock reinforcement

et al. 2012

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“…In this investigation it will also be employed to identify both the in-plane bending stiffness (D'Agostino et al, 2015;Dell'Isola and Steigmann, 2014;Ferretti et al, 2014;Giorgio et al, 2016;Harrison, 2016;Scerrato et al, 2016;Turco et al, 2016) and the torsional stiffness of the sheared fabric (Lomov and Verpoest, 2006;Steigmann and Dell'Isola, 2015) by monitoring the sample kinematics, including the shear angle at the centre of the specimen (D'Agostino et al, 2015;Ferretti et al, 2014;Harrison, 2016) and the out-of-plane wrinkling behaviour (Arnold et al, 2016;Boisse et al, 2011;Cherouat and Billoët, 2001;Dangora et al, 2015;Harrison, 2016;ten Thije and Akkerman, 2009;Thompson et al, 2016).…”

Section: Uniaxial Bias Extension (Ube) Test: Methodsmentioning

confidence: 99%

“…glass and carbon) is an important topic due to the role of engineering fabrics in manufacturing advanced composite parts (Long, 2005;Boisse, 2011). This investigation demonstrates an approach to characterising their mechanical forming properties using a combination of experimental testing and inverse modelling.…”

Section: Introductionmentioning

confidence: 99%

Towards comprehensive characterisation and modelling of the forming and wrinkling mechanics of engineering fabrics

Harrison

Alvarez

Anderson

2018

International Journal of Solids and Structures

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Through a combination of direct measurement and inverse modelling, a route to characterising the main mechanical forming properties of engineering fabric is demonstrated. The process involves just two experimental tests, a cantilever bending test and a modified version of the uniaxial bias extension test. The mechanical forming properties of a twill weave carbon fabric have been determined, including estimates of the in-plane bending stiffness and the torsional stiffness of a sheared fabric. As a result of measuring and incorporating all the main mechanical properties of the fabric in forming simulations (tensile, shear, out-of-plane bending, in-plane bending & torsion), the specimen size-dependent shear kinematics and wrinkling response measured in experiments, is faithfully reproduced in simulations of the uniaxial bias extension (UBE) test.

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“…Uniaxial and biaxial tensile behaviours of the studied flax-based woven fabric can also be used as input data for the sheet forming simulation codes [56][57][58] which could be used in an iterative loop to design and optimise the architecture of new reinforcement material that could be used to form complex shape without defects.…”

Section: Discussionmentioning

confidence: 99%

Mechanical characterisation of flax-based woven fabrics and in situ measurements of tow tensile strain during the shape forming

Ouagne

Soulat

Tephany

et al. 2012

Journal of Composite Materials

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Abstract.Forming complex shape composite parts with a good production rate/cost ratio is of particular importance for the automotive industry. The sheet forming of woven reinforcements is a promising technique especially if complex shapes with singularities such as case corners can be obtained. Due to the more and more important recycling needs, the use of flax fibre based reinforcements may be considered for structural or semi-structural parts. During the sheet forming of a tetrahedron shape, the tows constituting the architecture of the reinforcement material are submitted to tensile strains.When using glass or carbon fibre tows, strains to failure are generally not reached. When flax based fabrics are considered, the failure/degradation strength of the tows constituting the fabric may be reached. Even if no apparent failure is visible when observing the tows during forming, the strains measured by a mark tracking method indicate that the degradation limit of particular tows of the preform has been reached. This could lead to local lack of fibre density and to possible zones of weakness for the composite part. As a consequence, it is essential to improve the tensile performances of the tows constituting the fabric without losing their good impregnation characteristics and good ability to reach high mechanical properties for the composite part.

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Simulation of wrinkling during textile composite reinforcement forming. Influence of tensile, in-plane shear and bending stiffnesses

Cited by 360 publications

References 52 publications

Experimental preforming of highly double curved shapes with a case corner using an interlock reinforcement

Experimental preforming of highly double curved shapes with a case corner using an interlock reinforcement

Towards comprehensive characterisation and modelling of the forming and wrinkling mechanics of engineering fabrics

Mechanical characterisation of flax-based woven fabrics and in situ measurements of tow tensile strain during the shape forming

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