693.932 PEOPLE
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| Naji, M. |
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Mahamood, Rasheedat
Northumbria University
in Cooperation with on an Cooperation-Score of 37%
Topics
Publications (70/70 displayed)
- 2023Study on joint characteristics in laser butt welding of AMed and wrought Ti6Al4V platescitations
- 2023TIG WeldInG of Ti6Al4Vcitations
- 2023Characterizing the Effect of Post Weld Heat Treatment on the Mechanical Properties of Laser Beam Welded Additive Manufactured Ti6Al4V
- 2022Constitutive analysis of hot forming process of P91 steelcitations
- 2022Tribology of additively manufactured titanium alloy for medical implantcitations
- 2022Joint integrity evaluation of laser beam welded additive manufactured Ti6Al4V sheetscitations
- 2022Soft computing-based process optimization in laser metal deposition of Ti-6Al-4 Vcitations
- 2022Effect of laser power on the microstructure and mechanical properties of laser deposited titanium aluminide compositecitations
- 2022Effects of forming parameters on metal flow behaviour during the MDF processcitations
- 2021Laser butt welding of thin ti6al4v sheetscitations
- 2021Investigation of the Mechanical and Microstructural Properties of TIG Welded Ti6Al4V Alloycitations
- 2021Impact of process parameters of laser welding on the mechanical properties of TI6AL4V
- 2021Corrosion resistance of heat treated Ti6Al4V in NaClcitations
- 2020Wear behavior of laser metal deposited 17-4 PH SS-W composite at varied tungsten powder flow ratecitations
- 2020Laser metal deposition of titanium compositescitations
- 2020Effect of process parameters on the hardness property of laser metal deposited al–cu–ti coatings on ti–6al–4v alloycitations
- 2020Experimental investigation of laser metal deposited al–cu–ti coatings on ti–6al–4v alloy
- 2020Additive manufacturing technology: laser material processing and functionally graded materials
- 2020Effect of processing parameters on corrosion behaviour of Al reinforced with Ni-40Fe-10Ti alloy fabricated by FSPcitations
- 2020Study of additive manufactured ti–al–si–cu/ti–6al–4v composite coating by direct laser metal deposition (dlmd) techniquecitations
- 2019Wear Resistance Behaviour of Laser Additive Manufacture Materialscitations
- 2019Laser Metal Deposition of Titanium Alloy (Ti6Al4V)citations
- 2019Modelling and Optimization of Laser Additive Manufacturing Process of Ti Alloy Compositecitations
- 2019Characteristics of laser metal deposited titanium aluminidecitations
- 2018Influence of laser power on the microhardness and wear resistance properties of laser metal deposited 17-4 PH stainless steelcitations
- 2018Corrosion behavior of laser additive manufactured titanium alloycitations
- 2018Microstructural evolution of laser metal deposited 17-4 PH SS-tungsten composite with varying volume percent tungstencitations
- 2018Manufacturing of aluminium composite materialscitations
- 2018Advanced manufacturing of compositionally graded composite materialscitations
- 2018Effect of Laser Power and Gas Flow Rate on Properties of Directed Energy Deposition of Titanium Alloycitations
- 2017Influence of Powder Flow Rate on Properties of Laser Deposited Titanium Alloy -Ti6Al4Vcitations
- 2017Additive manufacturingcitations
- 2017Processing Methods of Functionally Graded Materials
- 2017Scanning Speed Influence on the Microstructure and Micro hardness Properties of Titanium Alloy Produced by Laser Metal Deposition Processcitations
- 2017Gas Flow Rate and Scanning Speed influence on microstructure and Microhardness Property of Laser Metal Deposited Titanium-alloy
- 2017Influence of scanning speed on the intermetallic produced in-situ in laser-metal-deposited TiC/Ti6Al4V composite
- 2017Introduction to Functionally Graded Materials
- 2017Future Research Direction in Functionally Graded Materials and Summary
- 2017Effect of the Scanning Speed of Treatment on the Microstructure, Microhardness, Wear, and Corrosion Behavior of Laser Metal-Deposited Ti–6AL–4V/TiC Compositecitations
- 2017Laser Power and Powder flow rate influence on the metallurgy and microhardness of Laser metal Deposited Titanium alloy.citations
- 2017Experimental Analysis of Functionally Graded Materials Using Laser Metal Deposition Process (Case Study)
- 2017Laser Metal Deposition Process of Metals, Alloys, and Composite Materialscitations
- 2017Laser-Assisted Additive Fabrication of Micro-Sized Coatingscitations
- 2017Scanning speed and powder flow rate influence on the properties of laser metal deposition of titanium alloycitations
- 2017Effect of laser power and powder flow rate on dilution rate and surface finish produced during laser metal deposition of Titanium alloycitations
- 2016Laser additive manufacturing in surface modification of metals
- 2016Laser metal deposition of Ti6Al4V/TiC composites using optimized process parameters
- 2016Effect of scanning speed and gas flow rate on surface roughness of LMD titanium-alloy
- 2016Laser Additive Manufacturing
- 2016Laser metal deposition process
- 2016A review of laser additive manufacturing of titanium and its alloys
- 2016Laser power and scanning speed influence on intermetallic and wear behaviour of Laser metal deposited titanium alloy composite
- 2016Properties of titanium alloy manufactured by laser metal deposition process
- 2016Processing Parameters Optimization for Material Deposition Efficiency in Laser Metal Deposited Titanium Alloycitations
- 2015Effect of processing parameter on wear resistance property of laser material deposited titanium-alloy composite
- 2015Laser metal deposition of functionally graded Ti6Al4V/TiCcitations
- 2015Effect of Laser Power and Powder Flow Rate on the Wear Resistance Behaviour of Laser Metal Deposited TiC/Ti6Al4V Compositescitations
- 2015Laser power and Scanning Speed Influence on the Mechanical Property of Laser Metal Deposited Titanium-Alloycitations
- 2014Characterization of laser deposited Ti6Al4V/TiC composite powders on a Ti6Al4V substrate
- 2014Laser additive manufacturing in surface modification of metals
- 2014Improving surface integrity using laser metal deposition process
- 2014Effect of processing parameters on the properties of laser metal deposited Ti6Al4V using design of experiment
- 2014Processing parameters influence on wear resistance behaviour of friction stir processed Al-TiC compositescitations
- 2014Modelling of Process Parameters Influence on Degree of Porosity in Laser Metal Deposition Processcitations
- 2013Gas flow rate and powder flow rate effect on properties of laser metal deposited Ti6Al4V
- 2013Material efficiency of laser metal deposited TI6AL4V: Effect of laser power
- 2013Scanning velocity influence on microstructure, microhardness and wear resistance performance of laser deposited Ti6Al4V/TiC compositecitations
- 2013The role of transverse speed on deposition height and material efficiency in laser deposited titanium alloy
- 2013Laser metal deposition of Ti6Al4V: A study on the effect of laser power on microstructure and microhardness
- 2013Characterizing the effect of laser power density on microstructure, microhardness, and surface finish of laser deposited titanium alloycitations
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booksection
A review of laser additive manufacturing of titanium and its alloys
Abstract
<p>The unique characteristic of laser which is coherency and directionality that enables it to be focused in the needed area makes it an important tool for advance manufacturing processes. Laser additive manufacturing, produces part by using the laser as the energy source to produce parts from the computer aided design (CAD) model of the part. Three most important laser additive manufacturing process for processing titanium and its alloys are presented in this chapter. They are: laser metal deposition process and selective laser sintering and selective laser melting. These processes have been proved to be feasible for manufacturing components, using any materials, to near-net shape as well as with mechanical properties almost approaching or in some cases exceeding the properties achievable in the conventionally processed materials. The process of manufacturing complex parts directly from the three dimensional (3D) CAD model of the part, by adding materials layer by layer and in one single step using additive manufacturing, brings about producing part that is lighter: due to elimination of joining of smaller parts which is the practice in the traditional manufacturing processes. This technology is still fairly new and future development is still needed for these manufacturing processes to be able to expand the area of application of the process for producing critical parts. Some of the recent research efforts in laser additive manufacturing of titanium and its alloys are reviewed in this chapter.</p>