Publications

2022
E. - A. Ali-Alkebsi, T. Outtas, A. Almutawakel, H. Ameddah, and T. Kanit, “Design of mechanically compatible lattice structures cancellous bone fabricated by fused filament fabrication of Z-ABS material,” Mechanics of Advanced Materials and Structures , 2022. Publisher's VersionAbstract

Designing and manufacturing replacement cancellous bone structures by lattice structures and Additive Manufacturing (AM) techniques is an effective method to create lightweight orthopedic implants while ensuring that they are mechanically compatible and their osseointegration ability with the host bone. In this article, we suggest a new design based on three lattice structures from triply periodic minimal surfaces (TPMS) with a different volume porosity to replace cancellous bone based on predicting the mechanical stiffness. To predict the mechanical stiffness, the relationship between the effective modulus of elasticity and different porosity ratios of the lattice structures was determined by using three methods: i) finite element modeling (FEM) simulation, ii) Gibson and Ashby method and iii) a uniaxial compression test after manufacturing the lattice structures by using Fused Filament Fabrication (FFF) Technology. To demonstrate the efficiency of our approach, the comparison of both numerical and experimental results showed that the effect of structure difference and porosity ratio of lattice structures on the mechanical stiffness values effectively match the cancellous bone in terms of elastic modulus and porosity ratio.

R. Selloum, H. Ameddah, and M. Brioua, “Computer Aided Inspection by Reverse Engineering for Reproduction of Gear Teeth,” in International Conference on Advanced Materials Mechanics & Manufacturing, 2022, pp. 292–298. Publisher's VersionAbstract

In the industry, automated inspection is important for ensuring the high quality and allows acceleration of procedures for quality control of parts or mechanical assemblies. Although significant progress has been made in precision machining of complex surfaces, precision inspection of such surfaces remains a difficult problem. Thus the problem of the conformity of the parts of complex geometry is felt more and more. Motivated by the need to increase quality and reduce costs, and supported by the progress made in the field of it as well as the automation of production which in recent years has seen a considerable evolution in all these stages: from design to control through manufacturing. Due to, we used a 3D computer aided inspection technique on a physical gear using a coordinate measuring machine equipped with a “PC-DMIS” measurement and inspection software. Our work consists in developing a procedure for inspection for reproduction of gear profile by reconstruction of a circle involute gear from a cloud point’s measurement. In order to obtain a reliable result. In this works, we design the CAD-model of the part as accurately as possible (using a mathematical model) and matched with the 3D points cloud that represents the measurement that obtained from scanner. we compare the measurement cloud points from coordinate measurement machine with the mathematical model of construction by ICP (Iterative Closest Point) methods in order to obtain a conformed result and to show the impact of the dimensional inspection and geometric.

2021
H. Ameddah, S. Lounansa, and H. Mazouz, “Fatigue behavior study of the biodegradabe cardiovascular stent.,” 5th Tunisian Congress on Mechanics  COTUME 2020  Hammamet 22 au 24 Mars . 2021.
R. Selloum, H. Ameddah, and M. Brioua, “Computer Aided Inspection by Reverse Engineering for Reproduction of Gear Teeth,” 5th Tunisian Congress on Mechanics  COTUME 2020  22 au 24 Mars . 2021.
3D Printing Analysis by Powder Bed Printer (PBP) of a Thoracic Aorta Under Simufact Additive
H. Ameddah and H. Mazouz, “3D Printing Analysis by Powder Bed Printer (PBP) of a Thoracic Aorta Under Simufact Additive,” in Research Anthology on Emerging Technologies and Ethical Implications in Human Enhancement, 2021, pp. 774-785.Abstract

In recent decades, vascular surgery has seen the arrival of endovascular techniques for the treatment of vascular diseases such as aortic diseases (aneurysms, dissections, and atherosclerosis). The 3D printing process by addition of material gives an effector of choice to the digital chain, opening the way to the manufacture of shapes and complex geometries, impossible to achieve before with conventional methods. This chapter focuses on the bio-design study of the thoracic aorta in adults. A bio-design protocol was established based on medical imaging, extraction of the shape, and finally, the 3D modeling of the aorta; secondly, a bio-printing method based on 3D printing that could serve as regenerative medicine has been proposed. A simulation of the bio-printing process was carried out under the software Simufact Additive whose purpose is to predict the distortion and residual stress of the printed model. The binder injection printing technique in a Powder Bed Printer (PBP) bed is used. The results obtained are very acceptable compared with the results of the error elements found.

A Particle Swarm Optimization-Based Approach for Finding Reliability in a Total Hip Prosthesis
L. Bouakkar, H. Ameddah, and H. Mazouz, “A Particle Swarm Optimization-Based Approach for Finding Reliability in a Total Hip Prosthesis,” in Artificial Neural Network Applications in Business and Engineering, vol. 10, 2021, pp. 222-242.Abstract

Nowadays, we assist the global extension of reliability optimization problems from the design phase of systems and sub-systems to the design and operational phases, not only of systems and sub-systems, but also of bio functionality design. This chapter investigates the relative performances of particle swarm optimization (PSO) variants when used to find reliability in the total hip prosthesis by finding the maximization of jumping distance (JD) to avoid dislocation and the minimization of system's stability to offer mobility. Statistical analysis of different cases of head diameters of 22, 28, 36, 40 mm has been conducted to survey the convergence and relative performances of the main PSO variants when applied to solve reliability in the total hip prosthesis.

Integrated Kinematic Machining Error Compensation for Impeller Rough Tool Paths Programming in a Step-Nc Format Using Neural Network Approach Prediction
H. Ameddah, “Integrated Kinematic Machining Error Compensation for Impeller Rough Tool Paths Programming in a Step-Nc Format Using Neural Network Approach Prediction,” in Artificial Neural Network Applications in Business and Engineering, vol. 7, 2021, pp. 144-170.Abstract

The most important components used in aerospace, ships, and automobiles are designed with free form surfaces. An impeller is one of the most important components that are difficult to machine because of its twisted blades. This research book is based on the premise that a STEP-NC program can document “generic” manufacturing information for an impeller. This way, a STEP-NC program can be made machine-independent and has an advantage over the conventional G-code-based NC program that is always generated for a specific CNC machine. Rough machining is recognized as the most crucial procedure influencing machining efficiency and is critical for the finishing process. The research work reported in this chapter focuses on introduces a fully STEP-compliant CNC by putting forward an interpolation algorithm for non uniform rational basic spline (NURBS) curve system for rough milling tool paths with an aim to solve the problems of kinematic errors solutions in five axis machine by neural network implementation.

F. Khalid, R. Manaa, S. Saad, and H. Ameddah, “A Study of the Thermo-Mechanical Behavior of a Gas Turbine Blade in Composite Materials Reinforced with Mast,” Revue des Composites et des Matériaux Avancés , vol. 31, no. 2, pp. 101-108, 2021. Publisher's VersionAbstract

The turbine blades are subjected to high operating temperatures and high centrifugal tensile stress due to rotational speeds. The maximum temperature at the inlet of the turbine is currently limited by the resistance of the materials used for the blades. The present paper is focused on the thermo-mechanical behavior of the blade in composite materials with reinforced mast under two different types of loading. The material studied in this work is a composite material, the selected matrix is a technical ceramic which is alumina (aluminum oxide Al2O3) and the reinforcement is carried out by short fibers of high modulus carbon to optimize a percentage of 40% carbon and 60% of ceramics. The simulation was performed numerically by Ansys (Workbench 16.0) software. The comparative analysis was conducted to determine displacements, strains and Von Mises stress of composite material and then compared to other materials such as Titanium Alloy, Stainless Steel Alloy, and Aluminum 2024 Alloy. The results were compared in order to select the material with the best performance in terms of rigidity under thermomechanical stresses. While comparing these materials, it is found that composite material is better suited for high temperature applications. On evaluating the graphs drawn for, strains and displacements, the blade in composite materials reinforced with mast is considered as optimum.

E. - A. Ali-Alkebsi, H. Ameddah, T. Outtas, and A. Almutawakel, “Design of graded lattice structures in turbine blades using topology optimization,” International Journal of Computer Integrated Manufacturing, vol. 34, no. 4, 2021. Publisher's VersionAbstract

Designing and manufacturing lattice structures with Topology Optimization (TO) and Additive Manufacturing (AM) techniques is a novel method to create light-weight components with promising potential and high design flexibility. This paper proposes a new design of lightweight-graded lattice structures to replace the internal solid volume of the turbine blade to increase its endurance of high thermal stresses effects. The microstructure design of unit cells in a 3D framework is conducted by using the lattice structure topology optimization (LSTO) technique. The role of the LSTO is to find an optimal density distribution of lattice structures in the design space under specific stress constraints and fill the inner solid part of the blade with graded lattice structures. The derived implicit surfaces modelling is used from a triply periodic minimal surfaces (TPMS) to optimize the mechanical performances of lattice structures. Numerical results show the validity of the proposed method. The effectiveness and robustness of the constructed models are analysed by using finite element analysis. The simulation results show that the graded lattice structures in the improved designs have better efficiency in terms of lightweight (33.41–40.32%), stress (25.52–48.55%) and deformation (7.35–19.58%) compared to the initial design.

C. Rebiai, E. Bahloul, and, “A new strain based membrane element for dynamic elastoplastic analysis.,” SÉMINAIRE INTERNATIONAL SUR L’INDUSTRIE ET LA TECHNOLOGIE en ligne (webinaire), organisé par Algerian Journal of Engineering, Architecture and Urbanism le 12 et 13 Mars . 2021.
C. Rebiai, “A new membrane finite element based on the strain Formulation for the analysis of 2-D structures,” International Asian Congress on Contemporary Sciences-v June 1-2, . 2021.
C. Rebiai, N. Saidani, and E. Bahloul, “NUMERICAL INVESTIGATION IN ELASTOPLASTIC DYNAMIC PROBLEMS BY STRAIN BASED APPROACH,” Symposium on Scientific Research- 3 October 29-30,. 2021.
S. Chichoune, C. Rebiai, and E. Bahloul, “AN EFFECTIVE STRAIN BASED SOLID ELEMENT FOR LINEAR ANALYSIS,” 7th International Scientific Researches Conference, September 7-8, . 2021.
S. Mansouri and E. Klaa, “Épreuve de qualification des soudeurs selon la norme 9606-1-2013 Soudage par fusion des aciers,” 1ères Journées Nationales des Sciences des Matériaux (JNSM2021), les 17 et 18 Novembre. 2021.
R. Mekhloufi, A. Boussaha, R. Benbouta, and L. Baroura, “Anisotropic and Isotropic Elasticity Applied for the Study of Elastic Fields Generated by Interfacial Dislocations in a Heterostructure of InAs/(001)GaAs Semiconductors,” Journal of Solid Mechanics, vol. 13, no. 4, pp. 503-512, 2021. Publisher's VersionAbstract

This work is a study of the elastic fields’ effect (stresses and displacements) caused by dislocations networks at a heterostructure interface of a InAs / GaAs semiconductors thin system in the cases of isotropic and anisotropic elasticity. The numerical study of this type of heterostructure aims to predict the behavior of the interface with respect to these elastic fields satisfying the boundary conditions. The method used is based on a development in Fourier series. The deformation near the dislocation is greater than the other locations far from the dislocation.     

H. Ameddah, R. Selloum, and M. Brioua, “Inspection on a Three-Dimensional Measuring Machine for a Virtual Model for Additive Manufacturing,” in International Conference on Advances in Mechanical Engineering and Mechanics, 2021, pp. 138–143. Publisher's VersionAbstract

Today, and to quickly meet the high demands of variability, supply chain efficiency and energy optimization, business markets are looking for modern manufacturing technologies and as a solution, industry 4.0 is using the benefits of integrating modern manufacturing technologies and information systems to promote production capabilities. In this context, intelligent industry represents a new generation of automatic production systems based on the concepts of intelligent industry, intelligent manufacturing, control and intelligent inspection, such as inspection on coordinate measuring machines (CMMs). This technology allows many machines to be integrated into a plant and controlled online using the MBD (Model Based Design) quality system. The problem of conformity of parts with complex geometry is becoming more and more important. The objective of this work is to present a 3D inspection technique on a virtual model (MBD: Model Based Design), using a coordinate measuring machine equipped with a “POWER INSPECT” measurement and inspection software. The interest of this technique is to show the impact of the dimensional inspection and geometric tolerance process of the CAD model for the CAI (Computer aided Inspection) approach on the fidelity of the finished product for additive manufacturing (AM) including intelligent industry.

2020
H. Ameddah, S. Lounansa, and H. Mazouz, “Comportement à la fatigue du stent biodégradable : Cas de la diastole et de la systole,” Congres Algérien de Mécanique CAM2019 Ghardaia 23-26 Février. 2020.
L. Hamadi, A. Kareche, S. Mansouri, and S. Benbouta, “Corrosion inhibition of Fe-19Cr stainless steel by glutamic acid in 1M HCl,” Chemical Data Collections, vol. 28, 2020. Publisher's VersionAbstract
Electrochemical methods, weight loss and surface analysis technique were used to study the effect of glutamic acid on the corrosion of Fe-19Cr stainless steel in 1 M hydrochloric acid solution. Results revealed that the corrosion inhibition of glutamic acid of Fe-19Cr in 1 M HCl was enhanced in the presence of the iodide ions due to synergistic effect. In the absence of KI, the inhibition of Fe-19Cr corrosion by glutamic acid was glutamic acid concentration dependent. Potentiodynamic polarization curves demonstrated that glutamic acid acts as a mixed type inhibitor. Self-Assembled Monolayers of glutamic acid were able to protect stainless steel from corrosion effectively. The adsorption of the inhibitor onto the stainless steel surface follows Langmuir adsorption isotherm. The value of free energy of the adsorption indicated that there is a physical interaction between the glutamic acid and the stainless steel surface.
M. Bendifallah, M. Brioua, and A. Belloufi, “CUTTING TOOL LIFE AND ITS EFFECT ON SURFACE ROUGHNESS WHEN TURNING WITH WC-6% CO,” International Journal of Modern Manufacturing Technologies, vol. XII, no. 2, 2020. Publisher's VersionAbstract
During turning operations, tool-part-chip contact causes wear to the cutting tool. The objective of this work is to study the wear of the clearance faces of tungsten carbide cutting tools during turning operations. Experimental tests on tool life for dry turning operations were carried out at four different cutting speeds, where the feed rate and the depth of cut are kept at constant values: 0.08 mm/rev for feed rate and 0.5 mm for depth of cut. An analysis of the influence of cutting parameters on the tools wear and consequently tool life (Τ) was presented, then the roughness of the machined surface Ra and the morphology of the chips produced were studied. This study makes it possible to identify that the wear mechanisms and the tool life are strongly linked to the roughness of the machined surfaces and to the morphology of the chips produced during the turning operations.
R. Selloum, H. Ameddah, and M. Brioua, “Improvement Inspection Method for Rapid Prototyping of an involute spur gears for an Additive Manufacturing process.,” International Conference on 3D Printing and Additive Manufacturing November 23-24, Webinar, From your imagination to a 3D model. 2020.

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