International Journal of Engineering Materials and Manufacture (2018) 3(2) 98-104 

https://doi.org/10.26776/ijemm.03.02.2018.04 

 

M. H. Hasan
1
 , S. Ahmed

2
, R. Voldman

3
 and M. Mehany

4
  

1,3,4
Department of Mechanical and Industrial Engineering 

Ryerson University, Canada 

2
Department of Robotics and Mechatronics Engineering 

University of Dhaka, Dhaka 1000, Bangladesh 

 

1
E-mail: hasibulhasan@ryerson.ca, 

2
E-mail: shugataahmed.rme@du.ac.bd 

3
E-mail: rvoldman@ryerson.ca, 

4
E-mail: mirt.mehany@ryerson.ca 

 

Reference: Hasan, M. H., Ahmed, S., Voldman, R. and Mehany, M. (2018). Parametric Effect on Surface Finish of Three-Dimensional 

Printed Object. International Journal of Engineering Materials and Manufacture, 3(2), 98-104. 

 

 

Parametric Effect on Surface Finish of Three-Dimensional Printed Object 

 

 

Muhammad Hasibul Hasan, Shugata Ahmed, Ron Voldman and Mirt Mehany 

 

 

Received: 20 April 2018 

Accepted: 29 May 2018 

Published: 30 June 2018 

Publisher: Deer Hill Publications 

© 2018 The Author(s) 

Creative Commons: CC BY 4.0 

 

 

ABSTRACT 

The ability to use different parameters and finishing techniques in fused deposition modelling (FDM) depends largely 

on part geometries, materials, printing processes like Z-resolution and post processing to some extent. Low quality 

poor surface finish due to layer ovality, improper Z-resolution parameter selection and fill of the empty shell in three-

dimensional (3D) printing, results unexpected texture and appearance. An investigation is carried out on the effects 

of Z-resolution (0.15 mm to 0.40 mm) and Fill parameters on flat and curved surface objects manufactured using the 

FDM process. Moreover, post surface treatment was performed using acetone. It was found that average surface 

roughness increases with increasing Z-resolution. Solid Fill can create a smoother surface as oppose to Sparse Fill. 

Surface roughness improves significantly after post treatment with organic solvent acetone. 

 

Keywords: Fused deposition modelling, 3D printing, Z- resolution, Surface roughness 

 

 

1 INTRODUCTION 

Three-dimensional (3D) printers are used to fabricate rapid prototypes (RP) for research and analysis purposes. 

Besides rapid prototyping, 3D printing is also used for rapid manufacturing — a new manufacturing technique where 

3D printers are used for short run custom manufacturing. In this method, printed objects are not prototypes but 

actual end user products. The basic principle of fused deposition modelling (FDM), 3D printing or additive 

manufacturing is to manufacture a prototype layer-by-layer at which most of the printing parameters can be adjusted. 

Surface finish is a major concern in FDM process, and as better surface finish is highly recommended for rapid 

prototypes and rapid manufacturing products, a large number of research has been carried out on it. In FDM, surface 

finish can be improved by three methods - Z resolution, fill of filament and post treatment. 

The literature has revealed that Fill parameter affects the surface finish — Fill is the material used to fill the empty 

space inside the shell of an object. Therefore, in order to achieve a better surface finish, the correct type of Fill should 

be used, and choosing a Fill pattern depends on the kind of model, desired structural strength and printing speed. A 

parametric study on the fabrication of a specimen using the FDM 3000 3D printer was conducted by Galantucci et 

al. (2015) The specimen material in use were ABS resins and PLA, in which specimens were fabricated by the hot 

extrusion technique and the objective was to improve  the specimen’s dimensional accuracy. Optimized parameters 

were determined by the factorial analysis design of the experiment (DOE). However, it was observed that after 

depositing the material, shrinkage occurred due to the large temperature difference (217˚C) between deposited 

material and deposition platform. For this reason, a deviation from ideal dimensions was observed. 

Guerrero-de-Mier et al. (2015) focused on reducing warping and deformation due to internal stress occurring in 

FDM. For experimental purposes, hexagonal and square shape bricks were used as test parts. A G code was developed 

to fabricate the brick stacks, which were locked spatially. Authors suggested that warping can be reduced by limiting 

stacking section length. Akande (2015) claimed that low layer thickness, low speed of depositions and low Fill density 

are the optimal parameters to have for a better surface roughness. Khan et al. (2006) investigated the emphasis of 

slice thickness and support parameters on surface roughness — they mentioned that lower slice thickness produces 



Hasan et al. (2018): International Journal of Engineering Materials and Manufacture, 3(2), 98-104 

99 

better surface finish. Bakar et al. (2010) found optimal parameters for dimensional accuracy, better surface finish and 

reduced post-processing time. 

According to Galantucci et al. (2009), chemical treatment is fast, cheap, and easy to use, which significantly improves 

surface finish. In their study, Percoco et al. (2012) investigated the effect of chemical treatment on compressive 

strength and surface roughness of FDM parts. For their chemical treatment, they used a solution composed of 90% 

dimethyl ketone and 10% water, and they had found that the compressive strength of the parts was improved in this 

method. Researchers concluded that the proposed finishing treatment can be used with immersion time up to 300 

sec to reduce roughness up to 90%, which in addition to compressive strength, improves mechanical properties as 

well. Vargas-Alfredo et al. (2018) suggested that surface topography and chemical composition in a 3D printed porous 

object can be improved by immersing the object in polystyrene solution (PS). Fused deposition modelling (FDM) 

technique was utilized to fabricate the 3D parts with different shapes (screws, honeycombs, tubes and scaffolds). 400 

nm to 3 μm size pores were created on the surface of the 3D objects by immersing them in the PS solution — this 
method is known as the Breath Figures approach. Temperature, relative humidity and polymer concentration of the 

solution and time of immersion have significant effects on the pore size, for when the object was immersed in the 

solution for 1s, 1.7 ± 0.4 μm pores were created. For 3s and 5s immersion times, 1.9 ± 0.5 μm and 2.4 ± 0.4 μm 
pores were created on the surface, respectively. BF method was used for chemical modification.  

Rao et al. (2012) discussed that the surface finish of FDM parts can be improved by interacting the surface with 

vapours of tetrahydrofuran. In this process, the part to be smoothed out is placed on a non-soluble support inside a 

closed vessel with a non-air-tight lid. Heat is then applied to evaporate the tetrahydrofuran so that it can interact 

with the object's surface to make it smooth. Ahn et al. (2004) performed post processing to increase optical 

transmissivity by applying elevated temperatures and by providing resin infiltration and surface sanding. Pandey et 

al. (2003) examined the use of hot cutter machining to improve surface finish of FDM parts and it was concluded 

that the proposed machining method was able to produce the surface finish of 0.3 microns, which can be used to 

obtain a better surface finish of an FDM part. Sanatgar et al. (2017) carried out an investigation on 3D printing by 

deposition of polymers on synthetic fabrics. Fused deposition modelling (FDM) technique was used for adhesion. 

Effect of 3D printing process parameters such as extruder temperature, platform temperature and printing speed on 

the adhesion process were all investigated. It was found that effect of the extruder temperature on adhesion is linear. 

However, linear effect of platform temperature on adhesion process was insignificant.  Effect of fabric and filler type 

on adhesion has been found to be significant. The purpose of this study was to investigate how to improve surface 

finish of FDM 3D printing by focusing on Fill and Z-Resolution parameters. Surface finish was also examined after 

post treatment by acetone. 

 

2 EXPERIMENT 

The UP plus 3D printer with UP plus software was used to print the specimens and Acrylonitrile Butadiene Styrene 

(ABS) was used as the object material. Printed samples are shown in Figure 1 and different surfaces of a sample are 

shown in Figure 2. Z-resolution were maintained between 0.15 mm to 0.40 mm even though the smallest particle 

height 0.10 mm or 100 microns could be achieved. The stepper motor of the printer can move the platform by as 

little as 100 microns, however FDM extruders cannot control the flow of filament precisely enough to produce clean 

results. For this reason, low micron prints on FDM machines often end up looking worse than high micron prints 

even though the individual layers may be finer.  

The modelling envelope temperature is regulated to aid in the bonding process. The FDM head deposits material 

as it follows the part geometry that has been constructed from bottom and builds up the model to the top in 

SolidWorks 2013. Starting from the STL file, the geometry of a part can be read by the UP Plus software. Objects are 

printed for different Z-resolutions and Fills. Various Z-resolutions and Fills with relevant sample numbers are 

mentioned in Table 1, and after printing, Ra values were measured by surface measuring instrument Surftest SV.500 

of Mitutoyo. Images of surface texture on specimens were captured by a metallurgical microscope - Nikon Epiphot 

200 and a sample image is given in Figure 3. 

Post treatment was carried out to improve the surface finish of the specimen using acetone. The specimen was 

placed on a non-soluble support of aluminium foil raft inside a closed vessel with a non-air-tight lid. Heat was applied 

to evaporate the acetone for 15 to 20 minutes, so that it can interact with the object’s surface to make the surface 

smooth. After post treatment, Ra values were measured again. In 3D printing, using thinner layers has few to no 

advantages and only serves to increase print time. Thinner layers are most useful for improving the surface finish on 

parts that have diagonal or curved surfaces, such as surface 2 in the study (Figure 2b.) 

 

           

Figure 1: The printed samples 

(a) (b) 



Parametric Effect on Surface Finish of Three-Dimensional Printed Object 

100 

Table 1: Types of Fill and Z-Resolution parameters applied on samples 

 

No. of samples Z-Resolution (mm) Fill 

1 0.15 Solid 

2 0.40 Solid 

3 0.15 Sparse 

4 0.40 Sparse 

5 0.15 Sparse 

6 0.40 Sparse 

 

 

           

 

Figure 2: The view for surface 1 (a), surface 2 (b) and surface 3 (c) used in this study 

 

 

 

 

 

Figure 3: An image of the flat surface for sample 1 taken by microscope with magnification factor of 50X 

 

 

3 RESULTS AND DISCUSSIONS 

Average surface roughness was calculated for all six samples on their three different surfaces and two filling methods, 

as shown in the Table 2. From the Table 2, it can be seen that sample 1 had the lowest value of average surface 

roughness for surface 1, 2 and 3, which were 12.46 µm, 12.27 µm and 7.10 µm, respectively. Meanwhile, sample 4 

had the highest value, which were 31.43 µm, 28.49 µm, and the third surface was out of range due to the higher 

value of surface roughness. Sample 3 had a lower value of surface roughness for surface 1 and 2 compared to sample 

2, which were 15.85 µm and 12.38 µm, respectively. However, sample 2 had a lower value for surface 3 of 24.62 

µm compared to sample 3, which was 36.52 µm. Hence, it is inferred that sample 1 had a better surface finish than 

(a) (b) (c) 



Hasan et al. (2018): International Journal of Engineering Materials and Manufacture, 3(2), 98-104 

101 

other samples as it possessed the lowest average surface roughness values. It is interesting to note that a solid fill with 

higher Z-resolution produces a somewhat better surface finish despite a higher printing time. 

Figure 4 shows the rising trend of the average surface roughness value with the increment of Z-resolution. From 

the figure, it is observed that surface 3 had the lowest value of average surface roughness (7.10 µm) for a 0.15 mm 

Z-resolution. On the other hand, surface 1 had the highest surface roughness value of 31.54 µm for a 0.4 mm Z-

resolution.  In comparison, surface 3 had a better surface finish than other two surfaces for solid Fill parameter since 

it has the lowest roughness value for 0.15 mm and 0.275 mm of Z-resolutions. However, for a 0.4 mm Z-resolution, 

surface 2 had the lowest average surface roughness of 24.52 µm.  

 

 

Table 2: The value of surface roughness for each surfaces of each samples 

 

  Ra Value (µm) 
Average Ra 

Value (µm) 

SAMPLE No. SURFACE No. 1 2 3  

 1 12.40 12.67 12.31 12.46 

1 2 12.20 12.39 12.23 12.27 

 3 7.11 7.11 7.09 7.10 

 1 31.55 31.54 31.52 31.54 

2 2 24.53 24.51 24.51 24.52 

 3 24.62 24.63 24.61 24.62 

 1 15.85 15.86 15.84 15.85 

3 2 12.41 12.39 12.35 12.38 

 3 36.44 36.63 36.49 36.52 

 1 31.39 31.46 31.44 31.43 

4 2 28.52 28.46 28.48 28.49 

 3 Out of range 

 1 15.65 16.66 15.68 16.00 

5 2 12.53 12.50 12.48 12.50 

 3 36.42 36.48 36.45 36.45 

 1 1.56 1.69 1.57 1.61 

6 2 0.84 0.92 0.90 0.89 

 3 Out of range 

 

 

 

 

Figure 4: The Ra value depending on Z-resolution of two Solid Fill samples 

0

5

10

15

20

25

30

35

0 0 . 0 5 0 . 1 0 . 1 5 0 . 2 0 . 2 5 0 . 3 0 . 3 5 0 . 4 0 . 4 5

A
V

E
R

A
G

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O
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G
H

N
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S
S

 (
𝜇
𝑚

)

Z-RESOLUTION(𝑚𝑚)

surface 1

surface 2

surface 3



Parametric Effect on Surface Finish of Three-Dimensional Printed Object 

102 

Similarly, for sparse Fill, better surface finish was found for surface 2 in Figure 5. On the other hand, surface 3 showed 

the highest average roughness for sparse Fill. As the Z-resolution increased from 0.15 mm to 0.45 mm, the surface 

roughness increased relatively linearly - reducing the 3D printing time for sparse fill samples. 

Figure 6 shows the trend of average surface roughness with changing Fill parameters. From the figure, it can be 

seen that the average roughness value for surface 2 and 3 increased as it went from solid to sparse Fill parameter. 

However, there was no value for average roughness of surface 3 with sparse Fill parameter, as the reading was out 

of range. Meanwhile, surface 1 displayed a slightly downward trend when the sample was filled with the sparse Fill 

parameter. Nevertheless, its average surface roughness was the highest between the other two surfaces. 

 

 

 

 

Figure 5: The Ra value depending on Z-resolution of two sparse Fill samples 

 

 

 

 

 

Figure 6: The Ra value depending on Fill parameter of two 0.40 mm Z-Resolution samples 

 

0

5

10

15

20

25

30

35

40

45

0 0 . 0 5 0 . 1 0 . 1 5 0 . 2 0 . 2 5 0 . 3 0 . 3 5 0 . 4 0 . 4 5

A
V

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G

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 R

O
G

H
N

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S

S
 (
𝜇
𝑚

)

Z-RESOLUTION (𝑚𝑚)

surface 1

surface 2

surface 3

0

5

10

15

20

25

30

35

0 0 . 5 1 1 . 5 2 2 . 5 3 3 . 5

A
V

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 R

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T

IO
N

 (
𝜇
𝑚

)

FILL PARAMETER 

Surface 1

Surface 2

Surface 3



Hasan et al. (2018): International Journal of Engineering Materials and Manufacture, 3(2), 98-104 

103 

 

 

 

Figure 7: Comparison of surface roughness between untreated sample and sample after post treatment 

 

 

 

In Figure 7, it is observed that surface roughness of surface 1 and surface 2 of sample 4 were 31.43 µm and 28.49 

µm, respectively, before post treatment. However, after post treatment - the lowest values of surface roughness for 

both surfaces were achieved. This result supports a study conducted by Lalehpour et al. where it was experimentally 

proved that chemical finishing processes in FDM, can meet the conditions of a functional and adequate finishing 

process, as it improves the roughness without negatively affecting the mechanical or geometrical properties of the 

treated parts. [13]. Lalehpour et al. (2018) showed that the maximum reduction percentage of the surface roughness 

due to the treatment reaches 95% and no effect was observed on the build orientation, dimensional accuracy and 

dimensional deviation.  

 

 

4 CONCLUSIONS 

The carried out experiment studies the effect of different parameters on surface roughness of 3D printed objects 

manufactured by the FDM process. The following key factors are determined from the experimental results:  

 

1. Average surface roughness is high for higher values of Z-resolution for a flat surface. For a curved surface, the 

Z-resolution effect is more pronounced. It is recommended to use a higher resolution or a lower Z value for 

better curved surfaces at the expense of a longer printing time.  

2. Solid Fill is better than Sparse Fill for generating smoother surfaces, even though more materials would be 

consumed in making the sample heavy. 

3. Smoother surface was developed after post treatment by organic compound acetone, which can meet the 

conditions of a functional and adequate finishing process, as it improves the roughness without affecting the 

mechanical or geometrical properties of the treated parts.  No effect was observed on the build orientation, 

dimensional accuracy and dimensional deviation.  

 

 

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A
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