Your search keyword '"Braun, Matías"' showing total 2 results

1. Effect of Printing Orientation on the Mechanical Properties of Low-Force Stereolithography-Manufactured Durable Resin.

Author

Martínez Raya, Antonio, Aranda-Ruiz, Josué, Sal-Anglada, Gastón, Jaureguizahar, Sebastián Martín, and Braun, Matías

Abstract

Featured Application: The strength and rigidity of the durable resin make it ideal for a wide range of applications, including prototyping and product development, automotive and aerospace components, medical devices, consumer goods, custom tooling, and educational models. Its strength and precision are precious in producing functional prototypes, nonstructural automotive parts, custom medical devices, and durable electronic enclosures. This versatile material speeds up design processes and improves the durability and functionality of end products in various industries. This study presents the results of fracture toughness tests conducted on specimens obtained by additive manufacturing techniques, specifically using low-force stereolithography. The samples were manufactured from a transparent 3D printing material for biocompatible applications, the so-called BioMed Durable Resin, which is a Formlabs-patented polymer material that simulates the strength and rigidity of polyethylene. The selected toughness tests in this context were performed following the ASTM D5045-99 guidelines. All tests were conducted under controlled laboratory conditions at 23 °C and 50% relative humidity, ensuring adherence to the standard and the replicability of the experimental results. To investigate the influence of printing plane orientation, specimens were produced at three printing orientation angles (0, 45, and 90 degrees). These angles were selected to provide a comprehensive evaluation of the anisotropy effects in the material. They cover both extreme orientations (0° and 90°) and include an intermediate value (45°), allowing us to assess variations in mechanical behavior across a representative range of printing orientations, consistent with prior research in the field. The experimental tests yielded data on the crack resistance and energy release rate for each angle of orientation. There are various implications of the findings, beyond materials engineering, for applications in biomedicine. Indeed, this same approach opens the door to new research methods for manufacturing certified biocompatible materials from such durable resins. Finally, complementary issues such as related medical applications have been slightly addressed for future work, since biomedicine innovation clusters can contribute to accelerating growth in this crucial field for productive sector activity and the local business environment. [ABSTRACT FROM AUTHOR]

Published

2024

2. Mixed Mode Crack Propagation in Polymers Using a Discrete Lattice Method.

Author

Braun, Matías, Aranda-Ruiz, Josué, and Fernández-Sáez, José

Subjects

*PEAK load, *POLYMERS, *BEND testing, *NUMERICAL analysis, *POLYMETHYLMETHACRYLATE

Abstract

The fracture behavior of polymeric materials has been widely studied in recent years, both experimentally and numerically. Different numerical approaches have been considered in the study of crack propagation processes, from continuum-based numerical formulations to discrete models, many of the latter being limited in the selection of the Poisson's coefficient of the considered material. In this work, we present a numerical and experimental analysis of the crack propagation process of polymethylmethacrylate beams with central and eccentric notches subjected to quasi-static three-point bending tests. The developed discrete numerical model consists of a regular triangular lattice model based on axial and normal interaction springs, accounting for nearest-neighbor interactions. The proposed model allows solving the above mentioned limitation in the selection of Poisson's coefficient, incorporating a fracture criterion defined by a bilinear law with softening that includes the fracture energy in the formulation and allows considering a progressive damage. One of the main objectives of this work is to show the capacity of this lattice to simulate quasi-static fracture problems. The obtained results show that the proposed lattice model is capable of providing results close to the experimental ones in terms of crack pattern, peak load and initial stiffening. [ABSTRACT FROM AUTHOR]

Published

2021