Abstract
A promising approach to address the mismatch of bone and implant stiffness, leading to the stress-shielding phenomenon, is the application of functionally graded materials with adjusted porosity. Although defect formation and porosity in laser-based powder bed fusion of metals (PBF-LB/M) are already widely investigated, so far there is little research on the influences and parameter interactions regarding the pore characteristics. This work therefore aims to provide an empirical process model for the generation of gas porosity in the PBF-LB process of Ti-6Al-4V. Parts with closed locally adjusted porosity of sim 6 % achieved through gaseous pores instead of lack of fusion defects or lattice structures were built by PBF-LB. Parameter variation and evaluation of relative density, pore size and sphericity was done in accordance with the design of experiments approach. A parameter set for maximum gas porosity (laser power of 189 W, scanning speed of 375 mm/s, hatch spacing of 150 μm) was determined for a constant layer thickness of 30 μm and a spot diameter of 35 μm. Tensile tests were conducted with specimens consisting of a core with maximum gas porosity or lack of fusion porosity, respectively, and a dense skin as well as fully dense specimens. Whereas lack of fusion defects can lead to significant reduction of stiffness of 32.2 %, the elastic modulus remained unchanged at 110.0 GPa when implementing spherical pores. Nevertheless, the found superior strength and ductility of specimens with gas porous core (> 1100 MPa and > 0.05 mm/mm, respectively) underline the advantages of adjusted porosity for the application in functionally graded materials and lightweight applications.
Highlights
Additive manufacturing (AM) technologies allow the production of individually shaped parts and small lot sizes without additional costs
The results of the described experiments are presented below. This includes the development and verification of an empirical process model from the data obtained in the screening, main and verification run, which describes the relationship between the response variables and the factors
As this study focused on the spherical gas porosity, the parameter ranges for the main and verification runs were adjusted so that porosity due to lack of fusion (LOF) defects was excluded
Summary
Additive manufacturing (AM) technologies allow the production of individually shaped parts and small lot sizes without additional costs. PBF-LB offers the advantages of a wide range of processable materials [6,7,8,9] and the ability to manufacture high-resolution parts [10]. The (α+β)-titanium alloy is known for its low density, high strength, fracture toughness and corrosion resistance as well as excellent biocompatibility [17,18,19]. It is a suitable material for load bearing implants. By shielding the bone from the stress applied to load-bearing implants, it is insufficiently loaded so that, based on Wolff’s law [22], bone resorption is increased and bone atrophy (reduction and loss of bone tissue) occurs. The resulting eventual loosening of the implant leads to a reduction in implant lifetime [20]
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