Mechanical Behavior of Loops with Small Diameters

Anna Lang; Oliver Focke; Axel S. Herrmann

doi:10.4028/www.scientific.net/KEM.742.374

Paper Titles

Improved Adhesion Strength of Metal Textile Composites by Surface Texturing Using TIG Arc or CW Laser Process
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TFP Reinforced Metal - One Way to Increase the Specific Strength
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Characterization of Hybrid Joining Techniques for FRP/Steel-Structures under Combined Mechanical and Thermal Loading
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Influence of Laser Surface Treatment for Process-Integrated Joining of Textile Reinforced Thermoplastic Composites to Metal Sheets
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Mechanical Behavior of Loops with Small Diameters
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Injection Molded Aluminum-Polymer-Composites - Integral Lightweight Structures with Potential
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Polyelectrolyte Treatment of Cellulose Fibers for the Manufacture of Novel Bio-Hybrid Fiber Composites (Bio-HFC) for Lightweight Applications
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Ultrasonic Torsion Welding of Aging Resistant Al/CFRP Joints - Concepts, Mechanical and Microstructural Properties
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Aspects of Preloaded Bolted Joints of Fiber Reinforced Polymers and Metals
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HomeKey Engineering MaterialsKey Engineering Materials Vol. 742Mechanical Behavior of Loops with Small Diameters

Mechanical Behavior of Loops with Small Diameters

Abstract:

To meet the comprehensive requirements of lightweight design, a material minded design method will be aimed. A fiber minded solution for load application in fiber reinforced plastics are loop joints, which are mainly applied for introducing high concentrated tensile loads, e.g. in mountings for rotor blades, or in pre-tensioned supporting structures. Usually, these loop joints consist of, diameters in centimeter scale. Miniaturized loop joints with diameters in millimeter scale are applied in transition structures for carbon reinforced plastic-aluminum multi material designs. Factors of miniaturization influencing the mechanical behavior are decoupled for tensile testing. Data from computer tomography provides information on the failure behavior of loop joints. To validate the non-destructive test method microsections will be used.

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Periodical:

Key Engineering Materials (Volume 742)

Pages:

374-380

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.742.374

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Online since:

July 2017

Authors:

Anna Lang*, Oliver Focke, Axel S. Herrmann

Keywords:

CFRP-Aluminium Transition Structures, Computed Tomography, Failure Behavior, Loop Joints, Multi Material Design, Small Diameters

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References

[1] H. Schürmann, Konstruieren mit Faserkunststoffverbunden, Berlin: Springer Verlag, (2005).

Google Scholar

[2] K. Moser, Faser-Kunststoff Verbund: Entwurf- und Berechnungsgrundlagen. Berlin: Springer Verlag, (1992).

Google Scholar

[3] T. Havar, Beitrag zur Gestaltung und Auslegung von 3D-verstärkten Faserverbundschlaufen. Institut für Flugzeugbau der Universität Stuttgart, (2007).

Google Scholar

[4] P. Schiebel, A. Lang, A.S. Herrmann, K. Schimanski, A. von Hehl, H. Bomas, H. -W. Zoch, Bauweisen für CFK-Aluminium-Übergangsstrukturen im Leichtbau, in: Werkstoffe und werkstofftechnische Anwendungen, Bd. 41, Eigenverlag Chemnitz, 2011, ISBN 978-3-00-033801-4, pp.393-398.

Google Scholar

[5] A. Lang, Lisa Husemann, Axel S. Herrmann, Influence Of Textile Process Parameter On Joint Strength For Integral CFRP-Aluminum Transition Structures, in: Procedia Materials Science, Volume 2, 2013, pp.212-219.

DOI: 10.1016/j.mspro.2013.02.026

Google Scholar

[6] Shu-Ang ZhouF, Anders Brahme; Development of phase-contrast X-ray imaging techniques and potential medical applications; ScienceDirect; Physica Medica, 2008, 24, pp.129-148.

DOI: 10.1016/j.ejmp.2008.05.006

Google Scholar