Abstract
Unique functional properties such as the low stiffness, superelasticity, and biocompatibility of nickel–titanium shape-memory alloys provide many applications for such materials. Selective laser melting of NiTi enables low-cost customization of devices and the manufacturing of highly complex geometries without subsequent machining. However, the technology requires optimization of process parameters in order to guarantee high mass density and to avoid deterioration of functional properties. In this work, the melt pool geometry, surface morphology, formation mode, and thermal behavior were studied. Multiple combinations of laser power and scanning speed were used for single-track preparation from pre-alloyed NiTi powder on a nitinol substrate. The experimental results show the influence of laser power and scanning speed on the depth, width, and depth-to-width aspect ratio. Additionally, a transient 3D FE model was employed to predict thermal behavior in the melt pool for different regimes. In this paper, the coefficients for a volumetric double-ellipsoid heat source were calibrated with bound optimization by a quadratic approximation algorithm, the design of experiments technique, and experimentally obtained data. The results of the simulation reveal the necessary conditions of transition from conduction to keyhole mode welding. Finally, by combining experimental and FE modeling results, the optimal SLM process parameters were evaluated as P = 77 W, V = 400 mm/s, h = 70 μm, and t = 50 μm, without printing of 3D samples.
Highlights
Shape-memory alloys (SMAs) are a type of smart material that have additional properties, such as the shape-memory (SM) effect or superelasticity (SE) behavior
This work aims to study the correlation between the melt pool dimensions, thermal behavior, and process parameters—i.e., laser power and scanning speed—in order to evaluate the optimal regimes for Selective laser melting (SLM) of NiTi powder
An experimental analysis of the melt pool geometry formed during the SLM of intermetallic nitinol powder was carried out in the present work
Summary
Shape-memory alloys (SMAs) are a type of smart material that have additional properties, such as the shape-memory (SM) effect or superelasticity (SE) behavior. SMAs are capable of returning to their original shape due to reverse martensite phase transformation, which can be induced by temperature or stress. The behavior of the SMA near ambient temperature is close to that of hard tissues such as human bone or tendons. High mechanical strength and relatively low modulus of elasticity are essential characteristics of the NiTi alloy as a biomedical material [3]. These properties make this SMA an excellent material for various implants, such as dental implants, joints, spine fixators, etc. These properties make this SMA an excellent material for various implants, such as dental implants, joints, spine fixators, etc. [4]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
