International Journal of Engineering Materials and Manufacture (2021) 6(3) 124-131 

https://doi.org/10.26776/ijemm.06.03.2021.03 

 

G. Barragan
1,2 , F. E. Mariani2, and R. T. Coelho2 

1
Grupo de Investigación en Ingeniería Aeroespacial, Universidad Pontificia Bolivariana, Circular 1 # 70-01, Medellín, Colombia.  

2
LAPRAS, Sao Carlos Engineering School, University of Sao Paulo, Av. Trabalhador São Carlense 400, São Carlos, Brazil.   

E-mail: german.barragan@upb.edu.co 

 

Reference: Barragan et al. (2021). Ti6Al4V Thin Walls Production using Laser Directed Energy Deposition (L-DED) Process. 

International Journal of Engineering Materials and Manufacture, 6(3), 124-132. 

 

 

Ti6Al4V Thin Walls Production using Laser Directed Energy Deposition (L-

DED) Process 

 

 

Barragan, G. A., Mariani, F. E. and Coelho, R. T. 

 

 

Received: 26 February 2021 

Accepted: 29 April 2021 

Published: 15 July 2021 

Publisher: Deer Hill Publications 

© 2021 The Author(s) 

Creative Commons: CC BY 4.0 

 

 

ABSTRACT 

One of the main applications of Directed Energy Deposition (DED) is the production of thin-wall structures, where it 

has significant advantages over traditional milling and machining techniques, or even welded analogues. These kinds 

of structures are frequently employed in aerospace components, field where titanium alloys have a primary role to 

play. Amongst them, the most employed is the Ti6Al4V with an alpha + beta alloy containing 6% Aluminium (Al) 

and 4% Vanadium (V). It has an excellent combination of strength and toughness along with excellent corrosion 

resistance. For the study hereby, thin-wall structures were constructed employing a Laser Directed Energy Deposition 

machine (L-DED), working with powder material. Analyse identified some microstructural and mechanical 

characteristics, thorough metallographic study, wear test (micro-adhesive) and micro hardness test. Finding a grain 

refined structure with competitive mechanical properties compared to materials manufactured by traditional 

processes. Results positioning DED as an attractive manufacturing technology, with a huge potential to improve costs 

and material usage, besides almost no restriction on component shape. 

Keywords: Directed Energy Deposition, Titanium, Hardness, Wear test, Mechanical properties. 

 

1 INTRODUCTION 

The Laser Directed energy deposition (L-DED) process allows the fabrication of components that can be used in a 

variety of engineering applications using a layer-by-layer strategy for constructing directly from a CAD data [1]. It 

employs a focused laser beam as heating source to melt in-situ delivered powder. When this occurs, a melt pool is 

formed on the surface of the substrate, or on a previously deposited layer. Therefore, a track is created after 

solidification and the process is repeated according to the planned path until completing the construction of the 

desired part. DED is a complicated process with many interconnected variables [2]. However, some of the advantages 

to justify its use are related to improved mechanical behaviour resulted in the manufactured components and its 

capacity to fabricate complex geometrical elements overcoming the restrictions imposed by the traditional 

manufacturing processes [3]. 

Thin wall structures comprise an important and growing proportion of engineering construction with some 

applications on aircraft, automobiles, turbomachinery, bridges, and machine elements where important benefits in 
terms of weigh reduction could be achieved [4]. When fabrication by traditional manufacturing methods shows 

problematical, DED has been seen a promising, advantageous and a competitive approach [5] and has being 

extensively explored [6-8]. 
The Ti6Al4 V is one of the most used alloys [9] with application at the same fields above mentioned, especially 

in thin-walled structures [10] due to its good mechanical properties even at high temperatures. It is also light in weight 

and corrosion resistant. Considering the laser additive manufacturing (AM) process the relationships between the 

deposition parameters, microstructure, and mechanical properties of that alloy have been studied [11] primarily with 

the use of unit tracks deposition onto a massive substrate [12] or the fabrication of simple geometric solid bodies. It 

was found improved behaviour when compared with their wrought counterparts [13] primarily due to fact that the 

deposited material undergoes rapid cooling enabling some grain refinements.   

For these study thin wall structures were constructed employed a Laser Directed Energy (L-DED) deposition 

machine, working with powder material, to identify its microstructural and some mechanical behaviour, thorough 



Ti6Al4V Thin Walls Production using Laser Directed Energy Deposition (L-DED) Process 

125 

metallographic study, wear test (micro-adhesive) and micro hardness test introducing one step further towards 
industrial applications. 

 

2 MATERIALS, METHODS AND SAMPLES ANALYSIS 

2.1 Materials and Equipment 

For the thin wall fabrication, a plate of Ti6Al4V (substrate) and Ti6Al4V grade 5 powder supplied by GE, as the 

additive manufacturing feedstock were employed. The chemical composition of the powder is in accordance with 

ASTM F2924 – 14 [14] and is presented in Table 1. The fabrication was conducted in Magic 250 machine, this 5 axis 

DED system equipped with a Nd:YAG laser with a maximum nominal power of one (1) kilowatt [15].  

The powder size is between 45-150 µm, with a flow rate of 25s measured in accordance with the ASTM B213 

standard. Figure 1 (a) presents an SEM image of the powder morphology, where is possible to observe its high 

sphericity and low satellite formation; In Figure 1(b) a metallographic image of the powder is shown, where it is 

possible to observe that no internal porosities was found in the selected samples. Therefore, the powder is considered 

with a good quality to be used in the L-DED process. 

 

Table 1: Chemical composition w% - Ti6Al4V powder [16]. 

 

Ti Al V Fe O C N H  

87.6 - 91 5.5 - 6.75 3.5 -4.5 ≤ 0.40 ≤ 0.20 ≤ 0.08 ≤ 0.05 ≤ 0.015  

 

 

 

 

 

Figure 1: Ti6Al4V Powder (a) Morphology; (b) Metallographic image [16]. 
 

 

2.2 Methods 

For the fabrication of the thin wall structures the process parameters listed in table 2 were employed. These 

parameters were selected in accordance with the machine, the material employed and previous tests to prove the 

consistence with an expected bead geometry. As the structure grows higher, some changes, or non-conformities, on 

the bead topography and geometry usually appear due to heat distribution and catchment efficiency. 

After selecting the above parameters for one bead deposition, the powder flow rate for wall construction was 

explored. Six different thin wall structures were fabricated employing different powder flow rate as listed in Table 3. 

The geometry, topography and microhardness of the wall were analysed. The condition which shows the better 

characteristics and more homogenous shape was selected and employed for the other conducted analysis 

(metallographic and wear test).  

 

 

 

 



Barragan et al. (2021): International Journal of Engineering Materials and Manufacture, 6(3), 124-131. 

126 

Table 2: Employed process parameters. 

 

Process parameters  

Laser Power 300 [W] 

Feed Speed 2000 [mm/min] 

Standoff distance 3.5  [mm] 

Atmosphere  Inner condition  Argon (Ar) 

 

 

Table 3: Powder flow rates tested.  

 

Condition Powder flow rate [g/min] 

a 4,75 

b 4,5 

c 4,25 

d 4 

e 3,75 

f 3,5 

 

 

2.3 Sample Analysis 

Microstructures of the deposited Ti6Al4V walls were characterized using the standard metallographic procedure, 

which involved abrasive cutting, hand sand, polishing, and etching. Kroll's reagent (92 ml of distilled water, 6 ml of 

HNO3, and 2 ml of HF) was used as the etching reagent. The cross-sections of the samples were analysed using a 3D 

laser confocal microscope LEXT 4100 by Olympus. 

Vickers microhardness tests on the specimens were carried out using Model 1600 6300 hardness tester by Buehler, 

under ASTM International standard test method E384. Indentations were performed on the cross-section of the 

substrate and deposited walls. The tests used 3.0 N load and a dwell time of 15 s to obtain the microhardness profiles. 

Micro-adhesive wear tests were performed deposited walls of Ti6Al4V. The tested surfaces were ground, and 

polishing. The “calotest” test was then performed using a quenched and tempered AISI 52100 steel ball, with 60 HRC 

hardness and diameter of 25.4 mm, driven by the driving shaft, sliding against the sample, with 1.7 N load.  The 

sphere rotation speed was 275 rpm. The test times were 5, 10, 15, 20, 30 and 40 min for each condition studied, 

resulting in sliding distances of 110, 220, 330, 440, 600 and 880 m, respectively. The volume of material removed 

(V) was calculated according to Equation 1: 

V = πd4/64R; for d << R                 (Eq. 1) 

 

where d represents the diameter of worn caps, measured by optical microscope and R represents the radius of the 

sphere [17]. 

The wear tests were carried out at 29 ºC and a relative humidity of 49%, under dry sliding friction (in air and 

without lubrication), to prevent any interfacial element from causing influences on the effect of microstructural 

features. 

 

3 RESULTS AND DISCUSSION 

Figure 2 shows different walls fabricated, where it is possible to see some topography defects on many of them 

caused for incorrect selections of the powder flow rate.  

Figure 3 shows the Vickers microhardness profiles obtained for the deposited walls. These tests were conducted 

for all the specimens to identify the influence of powder flow rate on the wall shape.  For all walls, it appears that 

hardness remains constant from the top until the interface with the substrate. Values were all close to 400 HV3.0, 

except condition (a), Table 3, which went slightly higher, close to 450 HV3.0. At the interface with substrate, at the 

dilution region and heat affected zone (HAZ), the hardness declines abruptly, remaining in the substrate with values 

close to 330 HV3.0. The average hardness values of the layers were similar, regardless of the deposition parameters.  



Ti6Al4V Thin Walls Production using Laser Directed Energy Deposition (L-DED) Process 

127 

 

 

 

Figure 2: Fabricated walls 
 

 

 

 

Figure 3: Vickers microhardness profiles. Conditions according to Table 3. Etching: Kroll’s Reagent. 



Barragan et al. (2021): International Journal of Engineering Materials and Manufacture, 6(3), 124-131. 

128 

Figure 4 shows the image of the wall (f) in Table 3, which presents the best resulted shape and was selected to 

conduct the metallographic and wear test. Figure 5 shows the optical micrograph of the Ti6Al4V substrate, with an 

average hardness of 330 ± 2 HV3.0. It can be noticed the presence of hexagonal close packed α-phase and body-
centred cubic β-phase structures [18,19]. Figure 6 shows the optical micrograph of the longitudinal section of the 
selected wall (f). 

The deposition pattern is verified layer by layer, indicated by the deposition trajectory (blue arrows). The distance 

between boundaries of layers is 200 µm, consistent with the parameters used for deposition. Microstructure of 

columnar dendrites was observed, which grew epitaxially from the substrate (direction Z), with growth direction 

opposite to the direction of heat flow. During DED deposition, the substrate and/or the deposited layer act as heat 

sinks, which allows the growth of the grains to be against the direction of the heat flow [20]. Figure 7 shows the 

micro-adhesive wear graphs obtained for the Ti6Al4V substrate of the selected wall (f). 

Compared to the substrate, the wear resistance of the deposited selected wall, condition (f) Table 3, initially 

presented a better performance. During the tests there was a convergence behaviour, and, at the end, the 

performances were very close. The wall showed wear resistance 1.1x higher when compared to the substrate. 

The optical micrographs of the worn caps produced by the micro-adhesive wear test are shown in Figure 8. The 

analysed caps refer to the longest sliding distance (test time 40 min - 880 m sliding distance). 

For the substrate and wall, the wear surface indicated two active wear mechanisms. The first type of abrasion is 

two bodies (indicated by red arrows), with the presence of directional scratches in the direction of sliding of the 

sphere. This wear mechanism occurred through the particles of the material itself that detach and adhere to the sphere 

[21]. The second mechanism observed is the adhesive (indicated by yellow arrows), represented by the transferred 

metal films. The same characteristics were observed throughout other similar tests performed in different places of 

the same pieces. 

 

 

 

Figure 4: Selected wall (f) from Table 3 
 

 

 

 

Figure 5: Optical micrograph of the as-built Ti6Al4V alloy. α and β phases highlighted with yellow lines. Etching: 
Kroll’s Reagent. 



Ti6Al4V Thin Walls Production using Laser Directed Energy Deposition (L-DED) Process 

129 

 
 

Figure 6: Longitudinal section of the WALL (f) Etching: Kroll’s Reagent. 
 

 

 

 
 

Figure 7: Micro-adhesive wear graphics obtained for the substrate wall (f). 



Barragan et al. (2021): International Journal of Engineering Materials and Manufacture, 6(3), 124-131. 

130 

 
 

Figure 8: Optical micrograph of the wear caps and interior of the wear caps from the substrate and WALL (f). 

Travelled distance: 880 m (40 min). The yellow and red arrows indicate the mechanisms of adhesive and abrasive 

wear on two bodies, respectively. 

 

4 CONCLUSIONS 

Investigation on the characteristics of Ti6Al4V thin-walled structures with respect to dimensional characteristics, 

hardness and wear behaviour has been carried out, and based upon the findings from the experimental work the 

following conclusions can be drawn: 

1. The use of the DED process for manufacturing thin walls with Ti6Al4V showed to be feasibly and presented 

good results, in terms of shape and geometry of the specimens.  

2. Due to the nature of the process that involves rapid cooling grain refinement appeared on the deposited 

walls.  

3. For all walls, the hardness remains constant from the top to the interface, with values close to 400 HV3.0. 

4. Harness values shown an important improvement over wrought material, used as substrate. 

5. The wear resistance of the best deposited wall, shown a better performance, during the wear tests with 

values around 10% higher. 

 

ACKNOWLEDGEMENT  

The authors would like to appreciate the financial support of the São Paulo Research Foundation - (FAPESP) – grants 

2016/11309-0; 2019/26362-2 and Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - Brazil (CAPES) - 

Finance Code 001.  

 

 

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