Ciencias Exactas y Ciencias de la Salud
Permanent URI for this collectionhttps://hdl.handle.net/11285/551014
Pertenecen a esta colección Tesis y Trabajos de grado de los Doctorados correspondientes a las Escuelas de Ingeniería y Ciencias así como a Medicina y Ciencias de la Salud.
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- Hierarchical and fractal mechanical metamaterials: Design, fabrication and characterization.(Instituto Tecnológico y de Estudios Superiores de Monterrey, 2024-06-14) Martínez Magallanes, Mario; Cuan Urquizo, Enrique; emimmayorquin; Pérez Santiago, Rogelio; Escuela de Ingeniería y Ciencias; Campus Monterrey; Román Flores, ArmandoMechanical metamaterials have recently gained much attention due to their unique properties, derived from their sophisticated microstructural design. Advances in additive manufacturing technologies allow us to fabricate complex geometries, that were very challenging to produce with conventional manufacturing techniques. In this study, we explore the use of hierarchy and fractal geometry to create new mechanical metamaterials. A methodology to design, fabricate, and characterize new fractal metamaterials based on diverse self-filling curves is presented here. We designed and parametrized a variety of fractal metamaterials, fabricated them using different additive manufacturing techniques and tested them under various load scenarios. The Hilbert curve was used to cut-extrude a solid cube and obtain a fractal honeycomb design. Samples were fabricated with TPU via Fused Filament Fabrication and tested under quasi-static uniaxial compression. The constituent material was firstly characterized under tension and compression showing a strain dependent behavior. Models of the fractal structure with different iteration orders and matching relative densities were tested under in-plane compression at two different orientations. A fractal decomposition technique was developed to enhance the stiffness of the structures. The results showed increase on stiffness for higher iteration orders and higher fractal decomposition at low strain levels. Lower densities and fractal iteration resulted more flexible and better at energy absorption. Various cellular structures and self-filling curve structures were used as reinforcement on a slender beam using different design approaches. The results showed increase on stiffness on the cellular patterns, specially for the reentrant pattern. Fractal reinforcements resulted into more flexible samples that withstand larger deformations before fracture occurs. Numerical simulations showed good accuracy with the experimental tests and delved the unconventional stress distributions on the fractal beams that caused eccentric deformations. Lower iteration orders resulted into increase of flexural stiffness. Brittle behavior was spotted on the cellular reinforcements. I-shaped structures were tested under out-of-plane loads and in-plane compression to study load-conformability and buckling. The tests revealed high influence of the axially aligned beams on the stiffness of the structures. Higher fractal iteration orders resulted into more flexible structures for both cases. Hybrid structures showed enhanced properties, having greater influence of the geometry in the middle. Higher iteration order structures showed better conformability and flexibility. The fractal structures showed different buckling deformation modes, showing failure tunability through fractal reinforcement.
- Curved-layered additive manufacturing and mechanical properties of non-planar metamaterials(Instituto Tecnológico y de Estudios Superiores de Monterrey, 2023-12-04) Pérez Castillo, José Luis; Cuan Urquizo, Enrique; emimmayorquin; Perez Santiago, Rogelio; Olvera Silva, Oscar; Gomez Espinosa, Alfonso; Roman Flores, ArmandoThis work presents an study of mechanical properties of mechanical lattice structures printed via Fused Filament Fabrication and Curved Layered Fused Filament Fabrication, specially focused in the analysis of Curved Layered ones. Thre experiments where designed, in the first one is analyzed how the volume fraction and distribution of material affect the mechanical behavior of lattice structures. The second experiment analyses how four different design parameters in lattice structures modify the mechanical behavior of lattice structures. The last experiment analyzes how the partitioning of a lattice structure in different regions inside itself, but each region with a different design parameter, affects the mechanical properties of the structure. Chapter 1 describes the main objectives of this research, such an introductory description of basic content that is necessary to understand this work. Chapter 2 provides an overview of the current state of CLFFF manufacturing methods. In Chapter 3, we delve into the computational aspects of lattice design and fabrication. Chapter 4 outlines the mechanical setup and execution of the first experiment detailed in Section 1.5. Moving forward, Chapter 5 delves into the analysis of the second experiment, which investigates various parameters impacting the mechanical stiffness of lattice structures. Chapter 6 focuses on the process of generating structures with diverse patterns within different regions of a single structure, with the goal of achieving distinct mechanical properties within these regions. Lastly, in Chapter 7, we present the conclusions drawn from the data discussed in all three experiments.