OPTIMIZATION OF LASER POWDER BED FUSION PROCESS IN INCONEL 625 TOWARDS PRODUCTIVITY

KRMASHA, MANAR NAZAR ABD

January 2022

Laser Powder Bed Fusion (L-PBF) is a metal additive manufacturing technique that uses a laser beam as a heat source to melt metal powder selectively. Because of the process small layer thicknesses, laser beam diameter, and powder particle size, L-PBF allows the fabrication of novel geometries and complex internal structures with enhanced properties. However, the main disadvantages of the L-PBF process are high costs and a lengthy production time. As a result, shortening the manufacturing process while maintaining comparable properties is exceptionally beneficial. Inconel 625 (IN625) is a nickel-based superalloy becoming increasingly popular in marine, petroleum, nuclear, and aerospace applications. However, the properties of IN625 parts produced by casting or forging are challenging to control due to their low thermal conductivity, high strength and work hardening rate, and high chemical complexity. Furthermore, IN625 alloy is regarded as a difficult-to-machine material. As a result, it is worthwhile to seek new technologies to manufacture complex-shaped IN625 parts with high dimensional accuracy. IN625 alloy is known for its excellent weldability and high resistance to hot cracking; thus, IN625 alloy appears to be a promising candidate for additive manufacturing. This thesis presents an experimentally focused study on optimizing L-PBF processing parameters in IN625 superalloy to increase process productivity while maintaining high material density and hardness. This study had four stages: preliminary, exploratory, modelling, and optimization. The first stage was devoted to conducting a literature review and determining the initial processing parameters. The second stage concentrated on determining the process window, for which single tracks were printed with two high levels of laser power (300, 400 W), five levels of scan speed (500, 700, 900, 1100, 1300 mm/s), and five levels of powder layer thickness (30, 60, 90, 120, 150 µm). Then, the process window was defined after investigating the top views and cross-sections of the tracks. Stage 3 involved printing 48 cubes (10 × 10 × 10 mm^3) with a laser power of 400 W, scan speeds of (700, 900, 1100, 1300 m/s), layer thicknesses of (60, 90, 120, 150 µm), and overlap percentages of (10, 30, 50%). As a result, the density of cubes was measured, and a statistical multiple regression analysis was used to predict it. Stage 4 involved estimating four sets of ideal processing parameters (based on statistical modelling of relative density) and printing 24 cubes (10 × 10 × 10 mm^3), six samples for each set. Finally, the relative density, hardness, and productivity of the samples were assessed, and a trade-off was determined. Even with the thickest powder layer of 150 µm (highest process productivity), samples with a mean relative density greater than 99% (i.e., 99.31% by Archimedes principle and 99.82% by image analysis) were printed. These findings are consistent with previously published results for L-PBF IN625 samples manufactured with smaller layer thicknesses ranging from 20 to 40 µm while maintaining comparable material hardness. The findings of this study are noteworthy because IN625 parts can be printed with higher powder layer thicknesses (less production time) while retaining similar material properties to those published with typical layer thicknesses ranging from 20 to 40 µm. Reduced production time due to optimized processing parameters can lead to significant energy and cost savings. / Thesis / Master of Applied Science (MASc)

Additive Manufacturing

Laser Powder Bed Fusion

Inconel 625

Process Optimization

Powder Layer Thickness

Density

Hardness

Productivity

Development of a Weldability Testing Strategy for Laser Powder-Bed Fusion Applications

Kemerling, Brandon L.

24 September 2018

No description available.

Engineering

Materials Science

Laser Powder-Bed Fusion

Weldability

Residual Stress

Finite Element Analysis

In-situ Process Monitoring

Process parameter optimization of M300 maraging steel and mechanical characterization of uniformly and selectively scaled M300 cellular structures

Petersen, Haley Elizabeth

10 May 2024

Laser powder bed fusion is a type of metal-based additive manufacturing method that can be customized for a given material through modification of process parameters, resulting in changes to the overall quality and mechanical properties of the as-built component. Optimal mechanical properties are typically achieved by performing experimental builds of fully dense components with multiple parameter sets and comparing the resulting mechanical properties. Additionally, AM allows geometric freedom that can be utilized to produce structures tailored for energy absorption, such as cellular structures or lattice structures. There is limited previous work of scaling effects on mechanical properties of cellular structures. The first part of this work aims to determine process parameters that result in the best overall mechanical properties of L-PBF manufactured maraging 300 steel. This work then uses the optimal parameters to produce cellular structures scaled both uniformly and selectively to perform mechanical and physical analysis on their response.

Feasibility And Characterization Of Leak-Tight Single-Track Thin Walls Produced By Laser Powder Bed Fusion In 316L Stainless Steel

Archibald, Peyton J

01 June 2024

This thesis explores the optimization of process parameters for producing single-track thin walls using Laser Powder Bed Fusion (LPBF) additive manufacturing. Using two different coupon designs, the study assesses the feasibility of creating the thinnest possible leak-tight structures within LPBF and evaluating their mechanical properties, including burst pressure and modulus of elasticity under pressure loads. A series of experimental iterations were conducted, varying laser power and laser speed to identify optimal conditions. The findings indicate that a narrow range of process parameters can produce consistently leak-tight thin walls. The results contribute to understanding how to achieve high quality, reliable thin wall structures in the LPBF process, with implications for industrial applications requiring thin, precise, leak tight, and durable walls.

Additive Manufacturing

Selective Laser Melting

Laser Powder Bed Fusion

Single-Pass Wall

Air-Tight Wall

Manufacturing

Residual stress predictions in L-PBF Ti-6Al-4V NIST bridges using FEM

Luke, Caitlin Delaney

13 August 2024

Finite element modeling (FEM) is used to predict complex phenomena like part deformation and the formation of residual strain resulting from cyclical heating. A gap exists in current literature using FEM to investigate the effect of printing strategies on strain and deformation in Ti-6Al-4V NIST bridges built by laser powder bed fusion (L-PBF). This study compares thermomechanical finite element models incorporating three scan strategies commonly used in literature: meander, stripe, and checkerboard, for the fabrication of Ti-6Al-4V NIST bridges using L-PBF. FEM of each scan strategy uses four mechanical material models: elastic perfectly plastic, Johnson-Cook, eigenstrain, and Hill 1948. The models’ mechanical responses are compared to experimental data. The objective of this work is to compare the predicted strain states, part deflections, and runtimes for each scan strategy and mechanical material model. Ultimately, this work aims to use FEM to predict challenges from the as-printed stress state of the L-PBF part.

Laser Powder Bed Fusion of Low and Negative Thermal Expansion Metamaterials

Dubey, Devashish

January 2024

Laser Powder Bed Fusion (LPBF) is a metal additive manufacturing (AM) technique that creates objects layer by layer from a bed of loose powder, using a laser beam as the heat source. This layer-wise approach allows for the fabrication of highly complex structures and intricate geometries with high accuracy, including solid, porous, and lattice structures. LPBF offers significant potential for use in industries such as aerospace, biomedical, and automotive due to its ability to fabricate unique and sophisticated designs. This technology has recently attracted significant attention for the fabrication of multimaterial parts with improved properties and applicability in different fields. However, challenges persist in understanding the relationship between process parameters and the properties of resulting multimaterial parts and interfaces. Additionally, limitations exist in design and interface selection for multimaterial fabrication using this technique. Negative thermal expansion (NTE) metamaterials, discussed in this research, are mechanical structures that show negative expansion properties by contracting with increase in temperature, while expanding with a decrease in temperature. These metamaterials are typically multimaterial systems where constituents with positive coefficients of thermal expansion (CTE) are strategically integrated, resulting in an overall NTE effect in one or more directions This research focuses on the design, simulation, and fabrication of negative thermal expansion (NTE) metamaterials using Laser Powder Bed Fusion (LPBF) with Grade 304L Stainless Steel (SS304L), Grade 300 Maraging Steel (MS300), and Invar 36 (Invar) alloys. Bimaterial combinations of SS304L-MS300 and SS304L-Invar were explored. After determining the optimal processing parameters, results showed that a robust, defect-free interface could be achieved in both combinations. Various lattice structures were designed based on these alloy pairs and analyzed using finite element analysis. The designs with the high NTE potential were successfully fabricated through LPBF, using optimal interface parameters. Thermal expansion testing of the fabricated structures demonstrated NTE behavior in line with FEA analysis predictions. / Thesis / Master of Applied Science (MASc)

Laser Powder Bed Fusion

Negative Thermal Expansion

Metamaterials

Additive Manufacturing

Lattice Structures

Metals

Evaluation of mechanical and microstructural properties for laser powder-bed fusion 316L

Eriksson, Philip

January 2018

This thesis work was done to get a fundamental knowledge of the mechanical and microstructural properties of 316L stainless steel fabricated with the additive manufacturing technique, laser powder-bed fusion (L-PBF). The aims of the thesis were to study the mechanical and microstructural properties in two different building orientations for samples built in two different machines, and to summarize mechanical data from previous research on additive manufactured 316L. Additive manufacturing (AM) or 3D-printing, is a manufacturing technique that in recent years has been adopted by the industry due to the complexity of parts that can be built and the wide range of materials that can be used. This have made it important to understand the behaviour and properties of the material, since the material differs from conventionally produced material. This also adds to 316L, which is an austenitic stainless steel used in corrosive environments. To study the effect of the building orientation, samples of 316L were built in different orientations on the build plate. The density and amount of pores were also measured. Tensile testing and Charpy-V testing were made at room temperature. Vickers hardness was also measured. Microstructure and fracture surfaces were examined using light optical microscope (LOM) and scanning electron microscope (SEM). The microstructure of the 316L made with L-PBF was found to have meltpools with coarser grains inside them, sometime spanning over several meltpools. Inside these coarser grains was a finer cellular/columnar sub-grain structure. The tensile properties were found to be anisotropic with higher strength values in the orientation perpendicular to the building direction. Also high dense samples had higher tensile properties than low dense samples. The impact toughness was found to be influenced negatively by high porosity. Hardness was similar in different orientations, but lower for less dense samples. Defects due to lack of fusing of particles were found on both the microstructure sample surfaces and fracture surfaces. The values from this study compare well with previous reported research findings.

Additive Manufacturing

Laser Powder-Bed Fusion

L-PBF

316L

Mechanical Properties

Metallurgy and Metallic Materials

Metallurgi och metalliska material

Fabricability of a high alloy tool steel produced with LPBF, with a focus on part geometry / Tillverkningsbarheten av ett höglegerat verktygstål tillverkat i LPBF, med inriktning på delgeometri

Abdelamir, Zulfaqar

January 2021

Additive manufacturing (AM) is a promising manufacturing process that provides that ability to fabricate components with complex geometries with relatively low lead times compared to other manufacturing processes. This allows for more freedom of design, as prototypes can easily be produced throughout the development process. AM is also especially beneficial in tooling applications, where internal geometries such as cooling channels are required in order to improve the quality of the manufactured parts. These geometries are more difficult to produce with more conventional manufacturing methods such as forging or casting. Currently, Laser Powder Bed Fusion (LPBF) shows the most promise in the field of Additive Manufacturing (AM) of metals, as it offers the freedom to produce complex components with little post processing required. Additionally, post processing with Hot Isostatic Pressing (HIP) can be implemented to significantly enhance the final properties of the material.  The LPBF-process can produce many different defects within the parts such as: part porosity and lack of fusion. This is mainly due to the layer-by-layer configuration of the process. Parts can also experience large thermal fluctuations and rapid cooling rates which can generate large residual stresses. This can result in significant cracking in certain high alloyed materials which can impact part quality and  material properties. If the cracking is severe enough, it will result in failure of the entire component and render the entire parts completely useless. Post processing with HIP may remove some of these defects and reduce the residual stresses in the material and thus produce a material with properties that are satisfactory. The purpose of this thesis is to investigate the processability of a high alloy cold work tool steel with LPBF. The main focus is the influence of the processing parameters and part geometry on the quality of the produced parts. Furthermore, the influence of the processing parameters on defects and microstructure will also be investigated. The aim is to produce parts that can be enhanced with HIP as a post processing treatment. Additionally, the impact of HIP on the properties of the part will also be investigated in order to determine if the there are any improvements in terms ofreduction in part defects and the removal of any undesired microstructural features which are produced from the process. The experimental results showed that the processability of the tool steel is difficult. Several sample volumes were produced with varying processing parameters and scanning strategies, and all the specimens from all sample volumes exhibited some cracking. Parts produced with a combination of contouring and hatching strategy, where there is an internal structure showed the most promise, as these parts exhibited the least amount of severe cracking. However, additional research of the processing parameters and scanning strategies is required in order to reduce the amount of cracking of the external shell structure and thus, achieve proper densification of the parts when post processing with HIP. / Additiv tillverkning (AM) är en lovande tillverkningsprocess som ger möjligheten att tillverka komponenter med komplexa geometrier med relativt låga ledtider jämfört med andra tillverkningsprocesser. Detta ger större frihet i under designprocessen eftersom prototyper enkelt kan produceras under hela utvecklingsprocessen. AM är också särskilt fördelaktigt i verktygstillämpningar, där interna geometrier såsom kylkanaler krävs för att förbättra kvaliteten på de tillverkade delarna. Dessa geometrier är svårare att tillverka med mer konventionella tillverkningsmetoder som smidning eller gjutning. För närvarande visar det sig att Laser Powder Bed Fusion (LPBF) är det mest lovande inom området additiv tillverkning av metaller, eftersom processen erbjuder friheten att producera komplexa komponenter samt att efterbearbetning som krävs blir mindre. Dessutom kan efterbearbetning med Hot Isostatic Pressing (HIP) implementeras för att avsevärt förbättra materialets slutliga egenskaper. LPBF-processen kan ge upphov till många olika defekter i delarna såsom: delporositet och lack of fusion. Detta beror främst på att processen sker lagervis vilket kan ge upphov att många småfel. Delar kan också uppleva stora termiska fluktuationer och snabba kylningshastigheter som kan generera stora restspänningar. Det kan resultera i stor sprickbildning i vissa höglegerade material vilket kan påverka delarnas kvalitet och materialegenskaper. Om sprickorna som bildas är stora eller djupa nog kommer detta att resultera i att hela komponenten blir oanvändbar. Efterbearbetning med HIP kan ta bort en del av dessa defekter och minska restspänningarna i materialet och därmed producera ett material med goda egenskaper. Syftet med detta arbete är att undersöka bearbetbarheten hos ett höglegerat kallbearbetningsstål med som produceras med LPBF. Huvudfokus är påverkan av processparametrar och detaljgeometrin på kvaliteten på de producerade delarna. Vidare kommer också processparametrarnas inverkan på defekter och mikrostruktur att undersökas. Syftet är att producera delar som kan förbättras med HIP som efterbehandlingsbehandling. Dessutom kommer effekterna av HIP på delens egenskaper också att undersökas för att avgöra om det finns några förbättringar i termer av minskning av deldefekter och avlägsnande av alla oönskade mikrostrukturella egenskaper som produceras från processen. De experimentella resultaten visade att verktygsstålets bearbetbarhet är svår. Flera provvolymer producerades med varierande processparametrar och skanningsstrategier, och alla prover från alla provvolymer uppvisade viss sprickbildning. Delar som tillverkats med en kombination av kontur och hatch, där det finns en inre struktur visade sig mest lovande, eftersom dessa delar uppvisade minst sprickbildning. Ytterligare arbete av processparametrarna och skanningsstrategier krävs dock för att minska mängden sprickbildning i den yttre skalstrukturen och därmed uppnå korrekt förtätning av delarna vid efterbearbetning med HIP.

Addtive Manufacturing

Laser Powder Bed Fusion

High alloy Cold Work Tool Steel

Addtiv Tillverkning

LPBF

Höglegerat kallbearbetningsstål

Mechanical Engineering

Maskinteknik

Investigation of processing parameters for laser powder bed fusion additive manufacturing of bismuth telluride

Rickert, Kelly Michelle

02 June 2022

No description available.

Engineering

Mechanical Engineering

Additive manufacturing

Laser powder bed fusion

Bismuth telluride

Selective laser melting

Processing parameters

Material characterization

Porosity

Melt pool size modeling and experimental validation for single laser track during LPBF process of NiTi alloy

Javanbakht, Reza

January 2021

No description available.

Mechanical Engineering