Your search keyword '"filigree structures"' showing total 8 results

1. Thin-Walled Slab Elements Made of FRP-Reinforced HPC and UHPC: Development, Experimental Investigation and LCA

Author

Hammerl, Mathias, Reichenbach, Sara, Kromoser, Benjamin, di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Ilki, Alper, editor, Çavunt, Derya, editor, and Çavunt, Yavuz Selim, editor

Published

2023

2. Characterization of Filigree Additively Manufactured NiTi Structures Using Micro Tomography and Micromechanical Testing for Metamaterial Material Models.

Author

Straub, Thomas, Fell, Jonas, Zabler, Simon, Gustmann, Tobias, Korn, Hannes, and Fischer, Sarah C. L.

Subjects

*MATERIALS testing, *PHASE transitions, *TOMOGRAPHY, *MANUFACTURING processes, *NICKEL-titanium alloys, *SHAPE memory alloys

Abstract

This study focuses on the influence of additive manufacturing process strategies on the specimen geometry, porosity, microstructure and mechanical properties as well as their impacts on the design of metamaterials. Filigree additively manufactured NiTi specimens with diameters between 180 and 350 µm and a nominal composition of Ni50.9Ti49.1 (at %) were processed by laser powder bed fusion in a first step. Secondly, they structures were characterized by optical and electron microscopy as well as micro tomography to investigate the interrelations between the process parameters, specimen diameters and microstructure. Each specimen was finally tested in a micro tensile machine to acquire the mechanical performance. The process strategy had, besides the resulting specimen diameter, an impact on the microstructure (grain size) without negatively influencing its quality (porosity). All specimens revealed a superelastic response while the critical martensitic phase transition stress decreased with the applied vector length. As a conclusion, and since the design of programmable metamaterials relies on the accuracy of FEM simulations, precise and resource-efficient testing of filigree and complex structures remains an important part of creating a new type of metamaterials with locally adjusted material behavior. [ABSTRACT FROM AUTHOR]

Published

2023

3. Bending Behaviour of Prestressed T-Shaped Concrete Beams Reinforced with FRP—Experimental and Analytical Investigations.

Author

Hammerl, Mathias and Kromoser, Benjamin

Subjects

*PRESTRESSED concrete beams, *REINFORCED concrete, *CONCRETE construction, *THIN-walled structures, *CONCRETE beams, *CONCRETE slabs

Abstract

Materials such as high performance (HPC) or ultra-high performance concrete (UHPC), and fibre-reinforced polymer (FRP) reinforcement can be used to improve the resource efficiency in concrete construction by, for example, enabling the production of thin-walled structures. When building filigree concrete beams two essential factors must be considered: the low stiffness of the structure and the bond between the materials. By prestressing the structural stiffness is improved while an adequate concrete cover ensures sufficient bond strength. Based on this the bending behaviour of prestressed T-shaped beams reinforced with FRP, focussing on determining the influence of four parameters on the bearing capacity, bond behaviour and failure mode, is investigated in this paper. Comprehensive experimental investigations prove the potential of the approach and show that a reduction of the web thickness down to 40 mm, a lower concrete quality, and the use of glass FRP instead of carbon FRP allow a more resource-efficient structure while the applied prestressing leads to a higher utilisation of the high performance materials. [ABSTRACT FROM AUTHOR]

Published

2022

4. An Integrative Experimental Approach to Design Optimization and Removal Strategies of Supporting Structures Used during L-PBF of SS316L Aortic Stents.

Author

Grad, Marius, Nadammal, Naresh, Schultheiss, Ulrich, Lulla, Philipp, and Noster, Ulf

Subjects

INTRA-aortic balloon counterpulsation, AORTA, STRUCTURAL optimization, SAND blasting, EXPERIMENTAL design, LASER beams

Abstract

Featured Application: The work presented in this manuscript is part of the preliminary investigations to optimize the patient-specific manufacturing of aortic stents using laser powder bed fusion (L-PBF) additive manufacturing (AM). The filigree structure of stents requires the use of support structures for their manufacture. An optimal structural design was identified and the influence of three post-processing strategies on the removal of supporting structures was investigated. One of the fundamental challenges in L-PBF of filigree geometries, such as aortic stents used in biomedical applications, is the requirement for a robust yet easily removable support structure that allows each component to be successfully fabricated without distortion. To solve this challenge, an integrative experimental approach was attempted in the present study by identifying an optimal support structure design and an optimized support removal strategy for this design. The specimens were manufactured using four different support structure designs based on the geometry exposed to the laser beam during the L-PBF. Support removal procedures included sand blasting (SB), glass bead blasting (GB), and electrochemical polishing (ECP). The two best-performing designs (line and cross) were chosen due to shorter lead times and lower material consumption. As an additional factor that indicates a stable design, the breaking load requirement to remove the support structures was determined. A modified line support with a 145° included angle was shown to be the best support structure design in terms of breaking load, material consumption, and manufacturing time. All three procedures were used to ensure residue-free support removal for this modified line support design, with ECP proving to be the most effective. [ABSTRACT FROM AUTHOR]

Published

2021

5. An Integrative Experimental Approach to Design Optimization and Removal Strategies of Supporting Structures Used during L-PBF of SS316L Aortic Stents

Author

Marius Grad, Naresh Nadammal, Ulrich Schultheiss, Philipp Lulla, and Ulf Noster

Subjects

aortic stents, filigree structures, laser powder bed fusion, additive manufacturing, SS 316L, supporting structures, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

One of the fundamental challenges in L-PBF of filigree geometries, such as aortic stents used in biomedical applications, is the requirement for a robust yet easily removable support structure that allows each component to be successfully fabricated without distortion. To solve this challenge, an integrative experimental approach was attempted in the present study by identifying an optimal support structure design and an optimized support removal strategy for this design. The specimens were manufactured using four different support structure designs based on the geometry exposed to the laser beam during the L-PBF. Support removal procedures included sand blasting (SB), glass bead blasting (GB), and electrochemical polishing (ECP). The two best-performing designs (line and cross) were chosen due to shorter lead times and lower material consumption. As an additional factor that indicates a stable design, the breaking load requirement to remove the support structures was determined. A modified line support with a 145° included angle was shown to be the best support structure design in terms of breaking load, material consumption, and manufacturing time. All three procedures were used to ensure residue-free support removal for this modified line support design, with ECP proving to be the most effective.

Published

2021

6. An Integrative Experimental Approach to Design Optimization and Removal Strategies of Supporting Structures Used during L-PBF of SS316L Aortic Stents

Author

Naresh Nadammal, Ulrich Schultheiss, Philipp Lulla, Marius Grad, and Ulf Noster

Subjects

laser powder bed fusion, Technology, Computer science, QH301-705.5, QC1-999, Mechanical engineering, Polishing, supporting structures, Distortion, Component (UML), Sand blasting, General Materials Science, Biology (General), Lead (electronics), Instrumentation, QD1-999, Laser beams, Fluid Flow and Transfer Processes, filigree structures, Process Chemistry and Technology, Physics, General Engineering, Engineering (General). Civil engineering (General), Computer Science Applications, aortic stents, Chemistry, Support removal, Line (geometry), TA1-2040, optimization, additive manufacturing, SS 316L

Abstract

One of the fundamental challenges in L-PBF of filigree geometries, such as aortic stents used in biomedical applications, is the requirement for a robust yet easily removable support structure that allows each component to be successfully fabricated without distortion. To solve this challenge, an integrative experimental approach was attempted in the present study by identifying an optimal support structure design and an optimized support removal strategy for this design. The specimens were manufactured using four different support structure designs based on the geometry exposed to the laser beam during the L-PBF. Support removal procedures included sand blasting (SB), glass bead blasting (GB), and electrochemical polishing (ECP). The two best-performing designs (line and cross) were chosen due to shorter lead times and lower material consumption. As an additional factor that indicates a stable design, the breaking load requirement to remove the support structures was determined. A modified line support with a 145° included angle was shown to be the best support structure design in terms of breaking load, material consumption, and manufacturing time. All three procedures were used to ensure residue-free support removal for this modified line support design, with ECP proving to be the most effective.

Published

2021

7. Additive Manufacturing of Information Carriers Based on Shape Memory Polyester Urethane

Author

Sarah Staub, Thorsten Pretsch, Heiko Andrä, Dilip Chalissery, and Publica

Subjects

Materials science, Polymers and Plastics, Mechanical engineering, 3D printing, Fused filament fabrication, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Article, lcsh:QD241-441, shape memory polymer, lcsh:Organic chemistry, Fused Filament Fabrication, Manufacturing technology, filigree structures, business.industry, filigree structure, General Chemistry, Shape-memory alloy, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Polyester, Shape-memory polymer, thermoplastic polyurethane, 0210 nano-technology, business, additive manufacturing, QR code carrier

Abstract

Shape memory polymers (SMPs) are stimuli-responsive materials, which are able to retain an imposed, temporary shape and recover the initial, permanent shape through an external stimulus like heat. In this work, a novel manufacturing method is introduced for thermoresponsive quick response (QR) code carriers, which originally were developed as anticounterfeiting technology. Motivated by the fact that earlier manufacturing processes were sometimes too time-consuming for production, filaments of a polyester urethane (PEU) with and without dye were extruded and processed into QR code carriers using fused filament fabrication (FFF). Once programmed, the distinct shape memory properties enabled a heating-initiated switching from non-decodable to machine-readable QR codes. The results demonstrate that FFF constitutes a promising additive manufacturing technology to create complex, filigree structures with adjustable horizontal and vertical print resolution and, thus, an excellent basis to realize further technically demanding application concepts for shape memory polymers.

Published

2019

8. Additive Manufacturing of Information Carriers Based on Shape Memory Polyester Urethane.

Author

Chalissery, Dilip, Pretsch, Thorsten, Staub, Sarah, and Andrä, Heiko

Subjects

*SHAPE memory polymers, *THREE-dimensional printing, *URETHANE, *POLYESTERS, *MANUFACTURING processes, *GEOMETRIC shapes

Abstract

Shape memory polymers (SMPs) are stimuli-responsive materials, which are able to retain an imposed, temporary shape and recover the initial, permanent shape through an external stimulus like heat. In this work, a novel manufacturing method is introduced for thermoresponsive quick response (QR) code carriers, which originally were developed as anticounterfeiting technology. Motivated by the fact that earlier manufacturing processes were sometimes too time-consuming for production, filaments of a polyester urethane (PEU) with and without dye were extruded and processed into QR code carriers using fused filament fabrication (FFF). Once programmed, the distinct shape memory properties enabled a heating-initiated switching from non-decodable to machine-readable QR codes. The results demonstrate that FFF constitutes a promising additive manufacturing technology to create complex, filigree structures with adjustable horizontal and vertical print resolution and, thus, an excellent basis to realize further technically demanding application concepts for shape memory polymers. [ABSTRACT FROM AUTHOR]

Published

2019