Your search keyword '"Schlothauer, Arthur"' showing total 2 results

1. FLEXIBLE SILICONE MOLDS FOR THE RAPID MANUFACTURING OF ULTRA-THIN FIBER REINFORCED STRUCTURES.

Author

Schlothauer, Arthur, Royer, Fabien, Pellegrino, Sergio, and Ermanni, Paolo

Subjects

FIBROUS composites, MOLDS (Casts & casting), MECHANICAL behavior of materials, LAMINATED materials, THREE-dimensional printing

Abstract

Ultra-thin fiber reinforced structures with shell thicknesses below 100 μm are receiving increasing attention, mainly in the field of deployable satellite structures. These structures are prone to post-cure deformation, induced by residual stresses resulting from the cure. This study presents a novel manufacturing technique for quick and efficient prototyping of ultra-thin fiber reinforced structures fabricated from carbon fiber prepreg. The technique relies on sandwiching the composite layup in between silicone molds constrained by a metal cage. The molds are cast using 3D-printed molds. Thermal expansion inside the closed vessel can be used to pressurize the part, enabling an out-of-autoclave process. Several ultra-thin fiber reinforced parts have been manufactured and investigated with regard to their post-cure distortion by means of a noncontact measurement system, showing increased post-cure shape accuracy compared to conventional methods. Microscopic investigations of the shell thickness were performed, revealing sufficient pressure distribution over the part, making the process a promising manufacturing technique for the rapid prototyping of ultra-thin structures. [ABSTRACT FROM AUTHOR]

Published

2018

2. Stiff Composite Cylinders for Extremely Expandable Structures.

Author

Schlothauer, Arthur and Ermanni, Paolo

Subjects

AIR-supported structures, CYLINDER (Shapes), WIRE netting, COMPOSITE materials, ELASTIC deformation, DRUG delivery devices

Abstract

The realization of concurrently largely expandable and selectively rigid structures poses a fundamental challenge in modern engineering and materials research. Radially expanding structures in particular are known to require a high degree of deformability to achieve considerable dimension change, which restrains achievable stiffness in the direction of expanding motion. Mechanically hinged or plastically deformable wire-mesh structures and pressurized soft materials are known to achieve large expansion ratios, however often lack stiffness and require complex actuation. Cardiovascular or drug delivery implants are one example which can benefit from a largely expandable architecture that is simple in geometry and intrinsically stiff. Continuous shell cylinders offer a solution with these properties. However, no designs exist that achieve large expansion ratios in such shells when utilizing materials which can provide considerable stiffness. We introduce a new design paradigm for expanding continuous shells that overcomes intrinsic limitations such as poor deformability, insufficient stiffness and brittle behaviour by exploiting purely elastic deformation for self-expandable and ultra-thin polymer composite cylinders. By utilizing shell-foldability coupled with exploitation of elastic instabilities, we create continuous cylinders that can change their diameter by more than 2.5 times, which are stiff enough to stretch a confining vessel with their elastic energy. Based on folding experiments and analytical models we predict feasible radial expansion ratios, currently unmatched by comparable cylindrical structures. To emphasize the potential as a future concept for novel simple and durable expanding implants, we demonstrate the functionality on a to-scale prototype in packaging and expansion and predict feasible constellations of deployment environments. [ABSTRACT FROM AUTHOR]

Published

2019