Fabrication of Multi-Material Structures Using Ultrasonic Consolidation and Laser-Engineered Net Shaping

Obielodan, John Olorunshola

01 December 2010

This research explores the use of two additive manufacturing processes for the fabrication of multi-material structures. Ultrasonic consolidation (UC) and laser- engineered net shaping (LENS) processes were used for parallel systematic investigations of the process parameters and methodologies for the development of multi-material structures. The UC process uses ultrasonic energy at low temperature to bond metallic foils. A wide range of metallic materials including nickel; titanium; copper; molybdenum; tantalum; MetPreg®; silver; stainless steel; and aluminum alloys 1100, 3003, and 6061 were bonded in different combinations. Material domains are inherently discrete in ultrasonically consolidated structures. The mechanical properties of some of the bonded structures were characterized to lay the groundwork for their real-life applications. LENS uses a laser beam to deposit metallic powder materials for the fabrication of fully dense structures. Mechanical testing was used to characterize the flexural and tensile properties of dual-material structures made of Ti6Al4V/10wt%TiC composite and Ti6Al4V materials. Experimental results show that the strength of transition joints in multi-material structures significantly depends on the joint design. Dual-material minimum weight structures, representing geometrically and materially complex structures, were fabricated using the results of the process parameters and fabrication methodologies developed in this work. The structures performed well under loading test conditions. It shows that function-specific multi-material structures ultrasonically consolidated and LENS fabricated can perform well in real-life applications.

Additive manufacturing

Composites

Laser-engineered net shaping

Minimum weight structures

Ultrasonic consolidation

Welding

Mechanical Engineering

Thermomechanical modeling predictions of the directed energy deposition process using a dislocation mechanics based internal state variable model

Dantin, Matthew Joseph

06 August 2021

The overall goal of this work is to predict the mechanical response of an as-built Ti-6Al-4V directed energy deposition component by a dislocation mechanics-based internal state variable model based on the component's geometry and processing parameters. Previous research has been performed to connect additive manufacturing (AM) process parameters including laser power and scanning strategy to different aspects of part quality, such as porosity, mechanical properties, fatigue life, microstructure, residual stresses, and distortion. The lack of predictive capabilities to fully estimate residual stresses and distortion within parts produced via AM have hindered part qualification; however, modeling the AM process can aide in process and geometry optimization compared to traditional trial-and-error methods. The presence of unwanted thermally induced residual stresses and distortion can lead to tolerancing issues, reduced fatigue life, and decreased mechanical performance compared to similar components fabricated with traditional manufacturing methods such as casting and machining. A three-dimensional thermomechanical finite element model calibrated using dual-wave pyrometer thermal image datasets along with temperature- and strain rate-dependent mechanical data is utilized for this work. The purpose of this work is to understand the relationship between a component's temperature history and its resultant distortion and residual stresses.

Additive manufacturing

finite element analysis

laser engineered net shaping

Ti-6Al-4V

residual stress

Process Models for Laser Engineered Net Shaping

Kummailil, John

29 April 2004

The goal of this dissertation is to develop a model relating LENSâ„¢ process parameters to deposited thickness, incorporating the effect of substrate heating. A design review was carried out, adapting the technique of functional decomposition borrowed from axiomatic design. The review revealed that coupling between the laser path and laser power caused substrate heating. The material delivery mechanism was modeled and verified using experimental data. It was used in the derivation of the average deposition model which predicted deposition based on build parameters, but did not incorporate substrate heating. The average deposition model appeared capable of predicting deposited thickness for single line, 1- layer and 2-layer builds, performing best for the 1- layer builds which were built under essentially isothermal conditions. This model was extended to incorporate the effect of substrate heating, estimated using an energy partition approach. The energy used for substrate heating was modeled as a series of timed heating events from an instantaneous point heat source along the path of the laser. The result was called the spatial deposition model, and was verified using the same set of experimental data. The model appeared capable of predicting deposited thickness for single line, 1- layer and 2- layer builds and was able to predict the characteristic temperature rise near the borders as the laser reversed direction.

rapid prototyping

solid freeform fabrication

LENS

laser engineered net shaping

laser

titanium

Pulsed laser deposition

Titanium

Prototypes

Engineering

ADVANCED PROCESSING OF NICKEL-TITANIUM-GRAPHITE BASED METAL MATRIX COMPOSITES

Patil, Amit k.

12 June 2019

No description available.

Mechanical Engineering

Materials Science

Metal Matrix Composites

In situ reactions

Mechanical Alloying

A Framework for Uncertainty Quantification in Microstructural Characterization with Application to Additive Manufacturing of Ti-6Al-4V

Loughnane, Gregory Thomas

10 September 2015

No description available.

Materials Science

Mechanical Engineering

Aerospace Materials

3D microstructural characterization

phantom microstructures

uncertainty quantification

additive manufacturing

laser engineered net shaping

Ti-6Al-4V alpha beta

A material based approach to creating wear resistant surfaces for hot forging

Babu, Sailesh

22 December 2004

No description available.

Hot forging

Die wear

Thermal softening

In-service tempering

Tempering parameters

Laser engineered net shaping (LENS)

Nickel aluminide

AISI H13 tool steel

Cladding

Microstructural Phase Evolution In Laser Deposited Compositionally Graded Titanium Chromium Alloys

Thomas, Jonova

05 1900

A compositionally graded Ti-xCr (10≤x≤30 wt%) alloy has been fabricated using Laser Engineered Net Shaping (LENSTM) to study the microstructural phase evolution along a compositional gradient in both as-deposited and heat treated conditions (1000°C followed by furnace cooling or air cooling). The alloys were characterized by SEM BSE imaging, XRD, EBSD, TEM and micro-hardness measurements to determine processing-structure-property relations. For the as-deposited alloy, α-Ti, β-Ti, and TiCr2 (C15 Laves) phases exist in varying phase fractions, which were influential in determining hardness values. With the furnace cooled alloy, there was more homogeneous nucleation of α phase throughout the sample with a larger phase fraction of TiCr2 resulting in increased hardness values. When compared to the air cooled alloy, there was absence of wide scale nucleation of α phase and formation of ω phase within the β phase due to the quicker cooling from elevated temperature. At lower concentrations of Cr, the kinetics resulted in a diffusionless phase transformation of ω phase with increased hardness and a lower phase fraction of TiCr2. In contrast at higher Cr concentrations, α phase separation reaction occurs where the β phase is spinodally decomposed to Cr solute-lean β1 and solute-rich β2 resulting in reduced hardness.

Laser Engineered Net Shaping

Titanium alloys

Microstructure evolution

Material characterization

SEM

XRD

EDS

TEM

EBSD

Microhardness

Titanium-Chromium Binary alloy

Heat Treatment

Phase transformation

Compositional Gradient

β stabilized Ti alloy.

Titanium alloys -- Microstructure.

Lasers in engineering.

Chromium alloys -- Microstructure.

Additive Manufacturing of Maraging 250 Steels for the Rejuvenation and Repurposing of Die Casting Tooling

Kottman, Michael Andrew

09 February 2015

No description available.

Metallurgy

Engineering

Materials Science

Additive Manufacturing

Maraging

Die Casting

Repair

Laser Hot Wire

LHW

Direct Metal Deposition

DMD

Gas Metal Arc Welding

GMAW

Rapid Pulsed Arc

RPA

Laser Engineered Net Shaping

LENS

Electron Beam Freeform Fabrication

EBF3

Design and LENS® Fabrication of Bi-metallic Cu-H13 Tooling for Die Casting

Jain, Akshay Ashok

January 2013

No description available.

Engineering

Industrial Engineering

Mechanical Engineering

Metallurgy

Die Casting

Bi-metallic tooling

Copper

H13

Die Casting Tooling

Ansys

Finite Element Analysis

FEA

Thermal Fatigue Die Casting

Laser Engineered Net Shaping

Laser Additive Manufacturing

Copper-H13

H13-Copper

Cu-H13

H13-Cu

Dunk Test