*Corr. Author’s Address: Kahramanmaras Sutcu Imam University, Department of Mechanical Engineering, Turkey, oguzdogan@ksu.edu.tr 451
Strojniški vestnik - Journal of Mechanical Engineering 68(2022)7-8, 451-460 Received for review: 2022-05-08
© 2022 The Authors. CC BY 4.0 Int. Licensee: SV-JME Received revised form: 2022-06-22
DOI:10.5545/sv-jme.2022.191 Original Scientific Paper Accepted for publication: 2022-08-05
Short-term Creep Behaviour of Different Polymers Used in 
Additive Manufacturing under Different Thermal  
and Loading Conditions
Dogan, O.
Oguz Dogan
*
Kahramanmaras Sutcu Imam University, Department of Mechanical Engineering, Turkey
Polymer materials produced by additive manufacturing undergo significant changes in their dimensions under continuous loading conditions. 
This situation affects the operation of polymer structures produced by additive manufacturing within safe limits. Therefore, it is crucial to 
determine the creep behaviour of polymers produced by the additive manufacturing method. This study investigates the creep behaviour of 
six different materials, acrylonitrile butadiene styrene (ABS), chlorinated polyethylene (CPE), polylactic acid (PLA), tough polylactic acid (TPLA), 
polycarbonates (PC), and nylon most commonly used in additive manufacturing. The creep test specimens are firstly produced with a three-
dimensional (3D) printer, and then their final dimensions are given using computer numerical control (CNC) milling. The creep experiments are 
carried out at three different ambient temperatures (25 °C, 40 °C, and 60 °C) and two different stress levels (10 MPa, 20 MPa). According to 
the test results, it was determined that the material type, temperature, and loading levels significantly influenced the creep behaviour of the 
3D printed polymer materials.
Keywords: Additive manufacturing, creep experiments, polymer materials, thermal effect
Highlights
• 	 Creep test specimens are produced with a 3D printer and CNC milling.
• 	 Creep tests are performed for different temperatures and loading conditions.
• 	 Short-term creep behaviours of polymers are investigated experimentally.
• 	 Material type, heat, and loading significantly affected the creep behaviour of the polymer materials.
0  INTRODUCTION
Fused deposition modelling (FDM) is a production 
method that allows parts to be processed layer by 
layer and produced as one piece. As a basic principle, 
in FDM, the raw material is heated, fluidized, and 
passed through a nozzle to produce the part in layers. 
With this production technique, products that cannot 
be produced in one step with traditional production 
methods have become easily produced. The FDM 
technique has started to increase its importance 
in practical life day by day with the increase and 
cheapening of three-dimensional (3D) printers. The 
advantages of FDM are summarized by Ngo et al. [1] 
as design freedom, customization, waste minimization, 
and the ability to produce complex structures.
The FDM method allows many different polymer 
materials to be used in 3D production. PLA, TPLA, 
ABS, PC, nylon, and CPE are the most commonly 
used polymer materials in the studies carried out 
with the FDM method in the literature. PLA is the 
most commonly used biopolymer and thermoplastic 
produced from corn starch and sugar cane in 3D 
printing. PLA enables fast and reliable 3D production 
with high surface quality [2]. ABS is also commonly 
used in 3D printing; it is tough and durable, provides 
high dimensional stability, and is resistant to 
physical impacts and chemical corrosion [3]. PC is a 
thermoplastic with a wide range of uses in the modern 
manufacturing industry; it can be defined as strong, 
temperature resistant, and tough. PC provides high 
mechanical strength, ultimate printing quality, and 
thermal resistance up to 110 °C [4]. Nylon is well 
known for good elongation, abrasion resistance, high 
strength-to-weight ratio, and low friction coefficient 
but a much lower strength [5]. Compared to other 
materials, the use of CPE with FDM is limited. CPE is 
defined as chemically resistant and tough [6]. 
The determination of the mechanical properties 
of the products produced using the FDM method 
has attracted great interest with the widespread use 
of FDM technology. Thus, many researchers have 
carried out extensive studies on the determination of 
the mechanical properties of the products produced 
by FDM. In these studies, generally, the tensile [7], 
bending [8], and impact [9] strengths of materials 
produced by the FDM method are experimentally 
investigated. While the mechanical properties of 
different materials have been investigated [10], the 
effects of FDM process parameters on mechanical 
properties have also been studied [11]. In addition, 
the fatigue strength of the materials produced with 3D 
printers has been experimentally investigated [12].

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452 Dogan, O.
Creep is the permanent deformation that occurs 
over time in materials under the influence of a 
constant temperature, stress, or loading. The creep 
behaviour of polymer materials is significant in 
industrial applications where dimensional stability 
is essential. For this reason, the creep behaviour of 
polymer materials should be determined, and the 
designs should be carried out accordingly. Many 
studies examine the creep behaviour of different 
polymer materials in the literature. Generally, the 
researchers are focused on the effects of the printing 
process parameters on the creep behaviour of the 
3D printed materials. Zhang et al. [13] investigated 
the tensile, creep, and fatigue behaviour of the 3D 
printed ABS samples. The effects of the printing 
orientation on the creep properties of the ABS test 
samples were defined experimentally. The effect of 
printing orientation on short-term creep behaviour of 
the 3D printed PLA samples is investigated in another 
comprehensive study [14]. In addition, the effects of 
layer thickness and different PLA types on creep are 
investigated experimentally. Mohammed et al. [15] 
investigated the flexural creep stiffness behaviour of 
PC-ABS material produced with FDM. In another 
study, the authors experimentally investigated the 
effects of process parameters on the creep and 
recovery behaviours of samples produced using the 
FDM method [16]. The creep and recovery behaviour 
of the reinforced 3D composites are investigated by 
Al Rashid and Koҫ [17]. Waseem et al. define the 
most effective process parameters on the tensile creep 
behaviour of the 3D printed PLA parts. They proposed 
the optimal combination of the process parameters 
using categorical response surface methodology [18]. 
Some researchers have experimentally investigated 
the effects of environment variables on creep. 
Temperature-humidity [19] and creep load [20] are 
considered variable parameters when these studies are 
examined. Various models have been used to predict 
creep in some studies. Lim et al. [21] developed a 
long-term creep model using the short-term creep 
test results for PC and ABS. Ye et al. [22] proposed a 
modified Burger model to predict the creep behaviour 
of the 3D printed test samples. The proposed model 
is validated with the creep experiments. As a result of 
the study, the modified model can accurately calculate 
the creep behaviour of the PLA-max samples with 
different printing angles.
According to the literature review, it is seen that 
the effect of process parameters on the creep behaviour 
of materials produced by the FDM method has been 
generally investigated. No study has been found 
that investigated the creep behaviour of different 
materials produced by the FDM method. In addition, 
temperature is one of the most influential parameters 
on the creep behaviour of the polymer materials. 
Similarly, when the literature is examined, the studies 
examining the effects on the creep behaviour of the 
samples produced with FDM temperature are very 
limited. These shortcomings in the literature have 
been the biggest motivation for this study. 
The present investigates the creep behaviour of 
six different polymer materials (ABS, CPE, PLA, 
TPLA PC, nylon) produced by the FDM method. In 
addition, experiments are carried out for each material 
type at three different temperatures (room temperature, 
40 °C, and 60 °C) and two different stress levels (10 
MPa and 20 MPa). The effect of temperature and 
stress on the creep behaviour of materials produced by 
the FDM method has been explained.
1  MATERIAL METHOD
2.1  Production of Creep Test Specimens
In this study, the creep behaviour of the different 
polymer materials produced with a 3D printer was 
experimentally investigated. The polymer test 
specimens were produced by combining FDM and 
CNC milling operations. The creep test specimens 
were produced with the Ultimaker 2+ Extended 3D 
printer. The printing area is 230 mm × 230 mm × 305 
mm, and the resolution is 12.5 µm – 12.5 µm – 5 µm 
for the x – y – z axes, respectively. The dimensions of 
the creep test specimens were determined according 
to ASTM D638 Type IV [23]. The computer-aided 
design (CAD) data of the test specimens were 
created in Solidworks software. The designed data 
were converted into the stl file format and sent to the 
Ultimaker Cura (version 4.13.1) software to define 
the 3D printing parameters. The G – codes of the test 
specimens were created in Ultimaker Cura software. 
The manufacturing parameters of the test specimens 
determined in Ultimaker Cure are given in Table 1.
The creep test specimens were produced with 
the Ultimaker brand filaments with a diameter of 
2.75 mm. The 3D printing parameters of the test 
samples were defined according to the manufacturer’s 
technical data sheets [24] to [29]. The test samples 
were produced with the same G – codes and one by 
one in the middle of the printing table in order to 
produce the test samples as similar as possible. Each 
specimen was produced three times for the repeatable 
experiments. 
When the samples are produced in a 3D printer, 
the notch effect and different wall pattern geometries 

Strojniški vestnik - Journal of Mechanical Engineering 68(2022)7-8, 451-460
453 Short-term Creep Behaviour of Different Polymers Used in Additive Manufacturing under Different Thermal and Loading Conditions 
occur on the test samples. To eliminate this problem, 
the creep test samples were subjected to CNC milling 
after the 3D printing process, minimizing the notch 
effect and possible size and dimensional defects. The 
CNC milling process was completed in two steps. 
First, holes were drilled to connect the specimens 
to the creep test device. Then, 2 mm from the outer 
region of the creep test specimen was machined to 
achieve a homogeneous structure. To carry out these 
operations, two special drilling and milling dies were 
designed and produced. The produced special drilling 
and milling dies are seen in Fig. 1a.
Creep test specimens produced with a 3D printer 
for CNC milling were produced in sizes 2 mm larger 
than the dimensions specified in ASTM D638 Type 
IV. After the CNC milling process, the samples 
were brought to the dimensions in ASTM D638 
Type IV (Fig. 1b). Four flutes milling cutter, with 6 
mm diameter, were used in both drilling and milling 
operations. The cutting direction is defined as climb. 
The spindle speed is selected at 3500 rpm, and the x-, 
y-axis speeds are defined as 500 mm/min.
2.2  Creep Tests
The primary purpose of this study is to determine 
the creep behaviour of different polymer materials 
produced in 3D printers with the FDM method under 
different temperatures and loads. Various creep 
tests have been carried out to achieve this aim. The 
experiments were performed on the standard creep 
test device shown in Fig. 2. As seen in the figure, two 
measurement devices on the creep test device measure 
the temperature and the amount of test sample 
elongation. An Etopoo brand electronic micrometer 
was used to measure the time-dependent creep 
deformations of the test samples. The micrometer can 
measure between 0 mm to 12.7 mm with an accuracy 
of 1 µm. The temperature of the test area was 
measured instantaneously with the PT100 temperature 
sensor. This sensor can measure the temperature 
between –50 °C and 250 °C with an accuracy of 0.1 
°C. The temperature and elongation data collected 
over the temperature sensor and micrometer are sent 
to the PLC module on the creep tester. The data on the 
PLC module is instantly transferred to the computer 
environment. The data transmitted to the computer 
environment can be obtained in Excel format with the 
software of the creep test device.
Creep tests were carried out as specified in the 
ASTM D2990-17 [30] standard. Moreover, the creep 
tests were performed in a climate-controlled room 
and on a vibration-insulated table. The creep tests 
were performed for three different temperatures (25 
°C, 40 °C, and 60 °C) and two various stress levels 
(10 MPa and 20 MPa). The temperature is set to the 
Table 1.  3D printing parameters of the test samples
Material
Extrusion 
temperature [°C]
Table 
temperature [°C]
Printing speed 
[mms
-1
]
Nozzle diameter 
[mm]
Layer thickness 
[mm]
Infill density 
[%]
Infill pattern
PLA [24] (Pearl-White) 200 60 60
0.4 0.2 200 Lines
ABS [25] (Yellow) 230 80 55
Nylon [26] (Black) 245 60 45
PC [27] (Transparent) 270 110 45
CPE [28] (Yellow) 240 85 45
TPLA [29] (Black) 205 60 60
a)              b) 
Fig. 1.  Production of creep test specimens; a) produced drilling and milling dies, and b) machining stages

Strojniški vestnik - Journal of Mechanical Engineering 68(2022)7-8, 451-460
454 Dogan, O.
desired level in the creep tests, and the heater starts 
to heat the test area. When the ambient temperature 
reaches the desired temperature, the heater turns off. 
If the ambient temperature drops 1 degree below 
the desired temperature, the heater works again and 
brings the environment to the desired level. In this 
way, the ambient temperature is controlled with 
minimal fluctuations. Creep tests are started when 
the test zone temperature reaches equilibrium at the 
desired temperature. Experiments begin by lowering 
the protective latch, and temperature and elongation 
data are instantaneously collected and recorded from 
the computer environment. Each creep test was 
carried out for 3 hours (10800 s); during this time, the 
creep elongation was measured and recorded with a 
micrometer.
2  RESULTS AND DISCUSSIONS
This study performed creep tests for six different 
materials (ABS, PLA, TPLA, CPE, PC, and nylon) 
under three different temperatures and two different 
loading conditions. Each experiment was repeated 
until three successful results were obtained. The 
amount of elongation obtained depending on time has 
been interpreted by presenting different graphs. Result 
graphs were created by considering the test result 
closest to the mean for each material, temperature, 
and loading condition. Short-term creep behaviours 
(primary and secondary creep phases) of different 
materials are investigated in this study. Tertiary 
creep behaviour is also seen under specific ambient 
temperature and stress levels in some cases. However, 
this study is mainly interested in the short-term creep 
behaviour of different polymers.
The creep test results for ABS material for 
different ambient temperatures and stress levels are 
seen in Fig. 3. The creep characteristic’s first and 
second stages can be seen for all tests except the 60 °C 
and 20 MPa case. The ABS sample ruptured quickly in 
approximately 3 min at 60 °C temperature and 20 MPa 
stress conditions. The first stage creep region extends 
over a longer period with the increase in temperature. 
In the first creep stage, the sample elongates due to the 
Fig. 2.  General view of the creep test device and detailed view of the test region
            
Fig. 3.  Creep test results of ABS under different ambient temperatures for; a) 10 MPa, and b) 20 MPa stress levels

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455 Short-term Creep Behaviour of Different Polymers Used in Additive Manufacturing under Different Thermal and Loading Conditions 
            
            
            
            
Fig. 4.  Creep test results of PLA and TPLA under different ambient temperatures and stress levels;  
a) 10 MPa PLA, b) 20 MPa PLA, c) 10 MPa TPLA, and d) 20 MPa TPLA (left column normal, right column zoomed views)

Strojniški vestnik - Journal of Mechanical Engineering 68(2022)7-8, 451-460
456 Dogan, O.
effect of the load, where the dislocation movements 
are pretty large. As the temperature increases, the first 
stage creep zone expands because the ability to move 
on dislocations in the material increases. The creep 
resistance of the ABS material decreases with the 
increase in the ambient temperature and stress levels.
Fig. 4 indicates the creep test results for PLA and 
TPLA for different ambient temperatures and stress 
levels. As the figures are unclear at high temperatures 
and loads, a zoomed-in view of each figure is shown 
in the right column of the Fig. 4. The creep samples 
produced from PLA are exposed to much more creep 
under the same test conditions than the samples 
produced from ABS. It is determined that the increase 
in temperature and applied load reduces the creep 
strength of the samples produced from PLA more than 
ABS samples. In addition, it has been tested that the 
sample breaks after a while in the case of 60 °C and 
            
Fig. 5.  Creep test results of CPE under different ambient temperatures for; a) 10 MPa, and b) 20 MPa stress levels
            
Fig. 6.  Creep test results of PC under different ambient temperatures for; a) 10 MPa, and b) 20 MPa stress levels
            
Fig. 7.  Creep test results of nylon under different ambient temperatures for; a) 10 MPa, and b) 20 MPa stress levels

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457 Short-term Creep Behaviour of Different Polymers Used in Additive Manufacturing under Different Thermal and Loading Conditions 
10 MPa. However, the time to rupture is much longer 
than the 60 °C – 20 MPa case. According to the test 
results, although PLA is the most commonly used 
polymer in additive manufacturing, its creep strength 
is quite low. It can be said that both temperature and 
load significantly reduce the creep strength; therefore, 
parts made of PLA material are suitable for use 
at room temperature and very low constant loads. 
Similar to ABS and PLA materials, the creep increases 
in creep test specimens produced from TPLA with the 
increase in ambient temperature and load. When the 
total creep values are examined, the samples produced 
from TPLA showed less creep than PLA but more than 
ABS. The creep test samples were damaged quickly 
under both loading conditions at 60 ˚C. In short, the 
TPLA material has better creep strength than PLA and 
worse strength than ABS.
Fig. 5 illustrates the creep test results of CPE 
test samples under different ambient temperatures 
and stress levels. Similar to other materials, the creep 
rate of the CPE increases with the increase in the 
ambient temperature and stress levels. However, the 
creep resistance of the CPE materials is better than 
ABS, PLA, and TPLA. The CPE creep test samples 
break after a short amount of time in the case of 60 
°C and 20 MPa test conditions. This time is much 
longer compared to PLA, ABS, and TPLA samples. 
This shows that the creep strength of CPE samples is 
higher than PLA, ABS, and TPLA.
The creep test results of PC test samples for 
different ambient temperature and loading conditions 
are illustrated in Fig. 6. According to the results 
obtained from the creep tests, it has been determined 
that the creep strength of PC material is very high 
compared to all other materials. In addition, the test 
samples produced from PC are the least affected by 
temperature and loading conditions. No damage 
occurred in the samples produced from PC material 
under this study’s applied loading and temperature 
conditions. For this reason, PC materials should be 
used in parts that will operate under high temperature 
and high constant static loading conditions since creep 
is very low.
The creep test results for the nylon samples are 
seen in Fig. 7. The first and second creep stages are 
clearly seen for the nylon test specimens. Because, 
the maximum creep values are seen for the nylon test 
samples. The flexibility of the nylon is much higher 
than the other materials. However, no damage is seen 
for this material, even in the case of 60 °C and 20 
MPa test conditions. The experiment was terminated 
because it went out of the measuring range of the 
micrometer. Parts produced from nylon with a 3D 
printer should be used in low loading and temperature 
conditions where flexibility is at the forefront.
The comparison of the creep test results of the 
five different materials under 10 MPa stress levels and 
different ambient temperatures is shown in Fig. 8. The 
first and second stage of the creep is seen clearly from 
the figures; also, the tertiary (accelerated) creep phase 
is seen only in PLA and TPLA under 60 °C and 10 
MPa test conditions. During the first stage of creep, 
the elongation rate is high. However, due to the strain 
Fig. 8.  Comparison of creep test results of different materials 
under 10 MPa stress level and different ambient temperatures; a) 
25 °C, b) 40 °C, and c) 60 °C

Strojniški vestnik - Journal of Mechanical Engineering 68(2022)7-8, 451-460
458 Dogan, O.
loading and different temperatures. No rupture was 
observed in the experiments carried out at 25 °C 
and 40 °C ambient temperatures. However, in the 
experiments carried out at an ambient temperature of 
60 °C, all other materials, except PC material, break 
quickly after a certain period of time. The amount of 
creep increases with the increase of the stress value 
from 10 MPa to 20 MPa. This increase in the amount 
of creep increases more with increasing temperature. 
Similar results are found in [14] to [20]. In addition, 
the increase in the maximum creep value increases 
with the increase in the stress level. Therefore, it 
cannot be said that there is a direct linear relationship 
between stress level and creep.
3  CONCLUSIONS
In this study, the creep behaviour of test specimens 
produced from six different materials (PLA, ABS, 
TPLA, CPE, nylon, PC) by the additive manufacturing 
method was investigated experimentally under three 
different temperatures (25 °C, 40 °C, and 60 °C)  and 
two different stress values (10 MPa, and 20 MPa). The 
creep test samples are produced by using Ultimaker 
2+ Extended 3D printer and CNC milling to obtain 
a homogeneous structure. Creep experiments were 
carried out for three hours. The results of the creep 
tests performed in this study can be summarized as 
follows.
• The creep rate increases with the increase in 
ambient temperature and stress level for all 
materials used in this study. 
• According to the test results, the load is a more 
effective parameter on creep than the temperature.
• PLA, which is the most commonly used polymer 
in 3D printers, is determined as the material 
with the worst creep resistance. For this reason, 
it is recommended that the parts produced using 
PLA with a 3D printer should be used at room 
temperature with no load or under very low static 
loads.
• Although TPLA has slightly better creep 
behaviour than PLA, it is not suitable for high 
temperatures and loads.
• According to the results obtained from ABS and 
CPE samples, these materials can be used at 
medium loads and moderate temperatures, but 
they are not suitable for use at high loads and 
temperatures.
• Although more creep occurred in the test 
specimens made of nylon compared to other 
materials, no rupture was observed.
hardening, the elongation rate slows down over time 
and reaches the lowest level, and remains constant. 
During the second stage of creep, the elongation 
increases approximately linearly with time. After the 
second stage creep zone, the elongation increases 
rapidly, and the specimens break. This region is called 
the creep region. The tertiary stage of creep is only 
seen for PLA and TPLA.
Fig. 9 shows the creep behaviour of samples 
produced from five different materials under 20 MPa 
Fig. 9.  Comparison of creep test results of different materials 
under 20 MPa stress level and different ambient temperatures;  
a) 25 °C, b) 40 °C, and c) 60 °C

Strojniški vestnik - Journal of Mechanical Engineering 68(2022)7-8, 451-460
459 Short-term Creep Behaviour of Different Polymers Used in Additive Manufacturing under Different Thermal and Loading Conditions 
• PC is determined to be the most resistant material 
against creep. The lowest creep amounts are 
observed in PC material in all experimental 
scenarios. Therefore, PC material can be used 
more safely than other materials under high load 
and temperature conditions.
After this study, the creep behaviour of polymer 
materials produced with 3D printers can be better 
understood by examining the effect of 3D printer 
production parameters (printing angle, nozzle 
diameter, layer thickness, extrusion temperature, 
printing speed, etc.) on creep under different 
temperature and loading conditions.
4  ACKNOWLEDGEMENTS
This work has been partially supported by the 
Scientific Research Projects Coordination Unit of the 
Rectorate of Kahramanmaras Sutcu Imam University 
with the project number 2020/7-17M.
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