NUST Institutions Library Catalogue catalog › Details for: Effects of Topological Parameters on the Lattice Structure for Orthopedic Applications /

Normal view MARC view ISBD view

Effects of Topological Parameters on the Lattice Structure for Orthopedic Applications / Muhammad Umer Khalid

By: Khalid, Muhammad Umer Contributor(s): Supervisor : Dr. Sadaqat Ali Material type: Text

TextIslamabad: SMME- NUST; 2025Description: 105p. Soft Copy, 30cmSubject(s): MS Mechanical EngineeringDDC classification: 621 Online resources: Click here to access online

Tags from this library: No tags from this library for this title. Log in to add tags.

Holdings ( 1 )
Title notes ( 1 )
Comments ( 0 )

Item type	Current location	Home library	Shelving location	Call number	Status	Date due	Barcode	Item holds
Thesis	School of Mechanical & Manufacturing Engineering (SMME)	School of Mechanical & Manufacturing Engineering (SMME)	E-Books	621 (Browse shelf)	Available		SMME-TH-1118

Total holds: 0

Browsing School of Mechanical & Manufacturing Engineering (SMME) shelves, Shelving location: E-Books Close shelf browser

Previous	No cover image available	No cover image available	No cover image available	No cover image available		No cover image available	No cover image available	Next
Previous	621 Maximizing Micro-Channel Heat Transfer Efficiency with Longitudinal Vortex Generators and Advanced Tri-Hybrid Nano-Fluids /	621 Numerical Analysis of Blended Wing Body VTOL UAV: Investigating Aerodynamic Characteristics Under Various Pylon Configurations /	621 Numerical Analysis of Mechanical Response in Various Ti6Al4V Scaffolds for Orthopedic Bone Implants /	621 Effects of Topological Parameters on the Lattice Structure for Orthopedic Applications /	621 AVA Marks' Standard Handbook for Mechanical Engineers /	629 Development and Characterization of ZrO2-Graphene Oxide Reinforced Al6061 Composite using Powder Metallurgy /	629.8 Detection of Lung Diseases through Medical Imaging using Deep Learning /	Next

Conventional solid orthopedic implants face various mechanical and biological issues when
they are implanted in the human body. The most important mechanical problem being faced
due to use of these implants is stress shielding effect which is caused by mismatch of
mechanical properties, Young’s modulus and yield strength, between the implant and host
bone. Porous orthopedic implants designed with lattice structures can overcome this problem
as their mechanical properties can be tailored to match with host bone. For this purpose, it is
important to understand the effects of topological parameters of lattice structure on its
mechanical properties. In this work, eighteen lattice structures have been systematically
modelled keeping in view the predefined porosity range for lattice structures intended to be
used in orthopedic implants. Finite element analyses (FEA) have been carried out on these
lattice structures modelled with IsoTruss, Diamond and Fluorite unit cell types, 0.200mm,
0.225mm and 0.250mm strut thicknesses, and 3.375mm3
and 1 mm3
of unit cell volumes where
each lattice structure contains either value of these topological parameters. Young’s modulus
and yield strength of each lattice structure under uniaxial compression loading are determined
from the results of FEA. The material of lattice structures used in this work is 316L stainless
steel. Sixteen lattice structures have been found within the predefined porosity range. Out of
eighteen lattice structures, Young’s moduli and yield strengths of only nine lattice structures
have been laid within the range of these properties for either trabecular or cortical bones. The
trends of these properties to the change in topological parameters have been observed. The
sensitivity of these properties to the change in topological parameters for various categories of
lattice structures and the efficiency of each lattice structure to use its material content for
increasing the mechanical properties have also been determined. Furthermore, all lattice
structures having similar type of unit cell have been found in conformity with Ashby-Gibson
model.

There are no comments on this title.

to post a comment.