Lattice Structures and Functionally Graded Materials Applications in Additive Manufacturing of Orthopedic Implants: A Review

Mahmoud, Dalia; Elbestawi, M.A.

doi:10.3390/jmmp1020013

Cited by 192 publications

(131 citation statements)

References 101 publications

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“…Moreover, Zok et al [50] developed mechanism maps for possible failures of pyramidal metallic truss cores based on beam theory with respect to face and core dimensions. In the past, many researchers have studied the potential use of AM lattice structures for various applications [51][52][53][54]. Yoon et al [55] characterisation and also developed beam and solid elements based FEM.…”

Section: Flexural Results Of Sandwich Panelsmentioning

confidence: 99%

Mechanical properties of 3-D printed truss-like lattice biopolymer non-stochastic structures for sandwich panels with natural fibre composite skins

Azzouz

Chen

Zarrelli

et al. 2019

Composite Structures

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Section: Flexural Results Of Sandwich Panelsmentioning

confidence: 99%

Mechanical properties of 3-D printed truss-like lattice biopolymer non-stochastic structures for sandwich panels with natural fibre composite skins

Azzouz

Chen

Zarrelli

et al. 2019

Composite Structures

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“…FGM is mainly designed by having a variable proportion of composite materials with random or regular microstructures. FGCS typically refers to the variable-density cellular or porous structures design according to the physical and mechanical properties [22][23][24]. Here, we concentrate on discussing FGCS design and optimization based on topology optimization.…”

Section: Related Workmentioning

confidence: 99%

Design and Optimization of Graded Cellular Structures With Triply Periodic Level Surface-Based Topological Shapes

Dai

Tang

et al. 2019

Journal of Mechanical Design

100

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Periodic cellular structures with excellent mechanical properties widely exist in nature. A generative design and optimization method for triply periodic level surface (TPLS)-based functionally graded cellular structures is developed in this work. In the proposed method, by controlling the density distribution, the designed TPLS-based cellular structures can achieve better structural or thermal performances without increasing its weight. The proposed technique can be divided into four steps. First, the modified 3D implicit functions of the triply periodic minimal surfaces are developed to design different types of cellular structures parametrically and generate spatially graded cellular structures. Second, the numerical homogenization method is employed to calculate the elastic tensor and the thermal conductivity tensor of the cellular structures with different densities. Third, the optimal relative density distribution of the object is computed by the scaling laws of the TPLS-based cellular structures added optimization algorithm. Finally, the relative density of the numerical results of structure optimization is mapped into the modified parametric 3D implicit functions, which generates an optimum lightweight cellular structure. The optimized results are validated subjected to different design specifications. The effectiveness and robustness of the obtained structures is analyzed through finite element analysis and experiments. The results show that the functional gradient cellular structure is much stiffer and has better heat conductivity than the uniform cellular structure.

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“…Functionally graded materials (FGM) are technically applied materials, characterized by a graded variation of the chemical composition and/or the microstructure and/or the material properties [1]. The use of functionally graded materials opens up a wide range of possible applications, and it is an area that has been characterized by continuous research and further development [2][3][4].…”

Section: Introductionmentioning

confidence: 99%

Plasma Multiwire Technology with Alternating Wire Feed for Tailor-Made Material Properties in Wire and Arc Additive Manufacturing

Reisgen

Sharma

Oster

2019

Metals

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Wire and arc additive manufacturing (WAAM) is one of the most promising technologies for large-scale 3D printing of metal parts. Besides the high deposition rates, one of the advantages of WAAM is the possibility of using in situ alloying to modify the chemical composition and therefore the material properties of the fabricated workpiece. This can be achieved by feeding multiple wires of different chemical compositions into the molten pool of the welding process and generating a new alloy during the manufacturing process itself. At present, the chemical composition is changed stepwise by keeping the wire feed speeds per layer constant. This article describes the possibilities of generating chemically graded structures by constantly alternating the wire feed speeds of a multiwire WAAM process. This enables the chemical composition to be smoothly changed during the printing process, and generating structures with highly complex material properties. Several material combinations for different possible applications were successfully tested. Furthermore, grading strategies to avoid negative influences of low-ductility intermetallic phases were examined. The results show that low-ductility phases may even have a beneficial influence on the fracture behavior if they are combined with ductile phases. Moreover, prospective possible applications are discussed.

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Lattice Structures and Functionally Graded Materials Applications in Additive Manufacturing of Orthopedic Implants: A Review

Cited by 192 publications

References 101 publications

Mechanical properties of 3-D printed truss-like lattice biopolymer non-stochastic structures for sandwich panels with natural fibre composite skins

Mechanical properties of 3-D printed truss-like lattice biopolymer non-stochastic structures for sandwich panels with natural fibre composite skins

Design and Optimization of Graded Cellular Structures With Triply Periodic Level Surface-Based Topological Shapes

Plasma Multiwire Technology with Alternating Wire Feed for Tailor-Made Material Properties in Wire and Arc Additive Manufacturing

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