Academic Editor:Maria Laura Di Lorenzo

Institute of Polymer Technology, Friedrich-Alexander University of Erlangen-Nürnberg, 91058 Erlangen, Germany

Received 1 June 2016; Revised 26 July 2016; Accepted 17 August 2016; 15 September 2016

This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

1. Introduction

For semicrystalline thermoplastics it is known that crystalline and amorphous areas typically arrange into spherulitic superstructures during the crystallization process especially under quiescent conditions [1]. Next to pressure and shearing, the temperature-time behavior while cooling a polymer mainly influences the formation of the geometry and degree of ordered structures (e.g., crystal modification, spherulite size, and degree of crystallization) since the crystallization process with its nucleation and crystal growth phase takes place at that time [2, 3]. Due to a low nucleation rate and relatively high crystal growth rate the morphology develops coarsely and distinctly for higher isothermal holding temperatures _{T h} (e.g., mold temperature for injection molding and chill-roll temperature for extrusion). With increasing cooling velocity the spherulites become smaller in diameter and the morphology looks more finely distinct up to optically amorphous, since crystal growth is hindered due to a large number of nuclei caused by high thermal nucleation [2-4]. Various forms of previous research have investigated the influence cooling velocity has on the resulting degree of crystallization (amount of the crystalline fraction) for semicrystalline thermoplastics. An increase in cooling velocity can lead to a decrease in the resulting degree of crystallization and by exceeding a critical cooling velocity the melt can solidify amorphously [4-7]. Next to affecting the degree of crystallization, the great majority of semicrystalline thermoplastics can crystallize in different crystal modifications [7-12] depending, for example, on the cooling velocity. Regarding isotactic polypropylene primary four different polymorphs are discussed in the literature: α -phase, β -phase, γ -phase, and a mesomorphic phase [13]. Here, β - and γ -crystals primarily form under certain conditions such as specific nucleating agents or shear-stress during manufacturing [14, 15] (for β -form) and elevated pressure (for γ -form) [16]. The most stable form is discussed to be the monoclinic α -form, which develops when cooling the melt with low to moderate cooling conditions in a temperature range from 50°C to _{T m} [17]. At temperatures less than or equal to 50°C the mesomorphic phase occurs. Brucato et al. [18, 19] asserts that, with an increasing cooling velocity, the amount of the mesomorphic phase increases and the density decreases. With a special focus on the crystalline structure and morphology with respect to the cooling rate Piccarolo et al. [20, 21] described the formation of the mesomorphic phase with isolated, negatively birefringent spherulites for cooling rates greater than 80 K/s. For cooling rates between 20 and 80 K/s mesomorphic and α -monoclinic phases coexist with negatively birefringent spherulites surrounded by a weakly birefringent medium. For cooling rates lower than 20 K/s primarily α -form with impinging spherulites is observed. Further detailed information about the polymorphism and morphologies with a particular focus on the mesomorphic phase of isotactic polypropylene (iPP) is summarized in Androsch et al. [22].

To assess resulting component properties (e.g., mechanical properties and tribological properties), the influence different cooling velocities have on the formation of crystalline and structural properties needs to be considered since they are mainly responsible for the resulting component properties. Here, the effects can hardly be explained with a single structural effect since changing one inner structural property normally leads to a change in the other properties as well (e.g., a change in spherulitic structure often accompanies a change in the degree of crystallization). Keeping this in mind, various works were able to show that increasing the degree of crystallization can increase the stiffness as well as strength and decrease elongation at break [23]. Furthermore, a distinctly fine spherulitic morphology can show higher strength and elongation at break than a coarsely distinct spherulitic morphology [2, 24]. Regarding different crystal modifications, for example, for PA 6, Kolesov et al. [11] estimated the differences in the storage modulus in the chain direction from 300-310 to 50-140 GPa for α and γ , respectively.

In general, regarding the temperature-time behavior of a thermoplastic component during the manufacturing process, for a variety of conventional manufacturing technologies (e.g., injection molding and extrusion) the material's cooling condition is the result of the processing parameters chosen beforehand (e.g., chill-roll temperature, mold temperature, material's melt temperature, and component wall thickness). Considering conventional injection molding and, therefore, a greater wall thickness, current research describes cooling velocities of about 1000 K/s regarding the skin near component area while in the core area values of about 1 K/s are estimated [25, 26]. In the literature the influence of mold temperature on the formation of the geometry and degree of ordered structures and the resulting component properties are often discussed from an application-oriented view. For example, using a higher mold temperature can lead to less wear and greater stiffness [24]. Nevertheless, at dynamic tempering the importance of isothermal holding time _{t h} during manufacturing is normally not taken into account. Therefore, it is the aim of this paper to show the influence of _{t h} at different mold temperatures, particularly chill-roll temperatures (Figure 1), analytically and experimentally with the help of fast scanning calorimetry and flat film extrusion.

Figure 1: Schematical illustration of isothermal holding time during flat film extrusion ( _{t h} = isothermal holding time, _{T c r} = chill-roll temperature, _{T d} = die temperature, and _{T d r} = deflection roller temperature).

[figure omitted; refer to PDF]

2. Materials and Methods

2.1. Material and Test Specimens

For this research, iPP (Sabic 505P), supplied by SABIC, was used. According to the datasheet this PP-type is a homopolymer with medium isotacticity and a melt flow rate of 2 dg/min. For the tensile tests, tensile bars were prepared from the extruded foils along the extrusion direction. The geometry was derived from the Campus tensile bar according to DIN EN ISO 527-2B with a scaling of 1 : 4. Regarding the dynamic-mechanical analyses, rectangular samples with a width of 1 mm and a length of 8 mm were prepared from the extruded foil along the extrusion direction.

2.2. Fast Scanning Calorimetry (FSC)

The FSC measurements were taken using a Flash DSC 1 by Mettler-Toledo. For that purpose, a test sample was prepared from a 10 µ m thin cut using a scalpel and placed on the measuring sensor area of the FSC. For all tests one test sample was used and, therefore, the same sample mass was used for all tests. For depicting the results, the measured heat flow rate was illustrated with respect to temperature. In order to verify that there are no ageing effects comparison measurements were repeated at the end of all measurements, which showed the exact same crystallization effects.

For a better understanding of the process-based crystallization with focus on evaluation of _{t h} first the crystallization at different cooling velocities is examined. Here, different cooling velocities were analyzed in the range of 1 to 2000 K/s. Therefore, the sample first was heated up to 250°C and then cooled down to -20°C with the respective cooling velocity. The second heating was chosen with 500 K/s. This heating velocity was determined in preliminary investigations and was recommended to evaluate the melting behavior of iPP since here cold crystallization and reorganization effects could be measured in good resolution.

Furthermore, a theoretically based temperature-time profile during cooling, derived from the conventional manufacturing cooling step, was investigated; compare Figure 2. Here, the sample first was heated up to 250°C and then cooled down to _{T h} with a cooling velocity ≥ 1000 K/s, Table 1. This temperature represents the mold temperature for the dynamically tempered injection molding process during injection, as well as the chill-roll temperature for extrusion. Afterwards, the temperature was held isothermally for a defined _{t h} in the range between 0.0 and 180.7 seconds and then cooled at a cooling velocity of 30 K/s to (according to the maximum attainable cooling velocities of modern dynamically tempered injection molds [27, 28]) 10°C. Again, the second heating was chosen at 500 K/s.

Table 1: Temperature-time profiles analyzed by FSC.

Figure 2: Simplified temperature-time profile during cooling derived from the conventional manufacturing cooling step with subsequent heating analyzed by FSC ( _{t H} = isothermal holding time, _{T e n d} = end temperature, _{T h} = isothermal holding temperature, _{T m} = melting temperature, _{v C o o l i n g} = cooling velocity, and _{v H e a t i n g} = heating velocity).

[figure omitted; refer to PDF]

2.3. Processing

In addition to the analytically based material characterization using FSC, iPP foils were extruded via flat film extrusion using chill-roll casting. For that, a single screw extruder, Collin E30M, with a 30 mm screw diameter and length/thickness ratio of 25 and a coathanger die of 250 mm width in combination with the chill-roll Collin CR136/350 were used. The die temperature was set to 250°C. Foils were produced at a chill-roll temperature of 55, 80, 100, and 120°C to investigate the influence of _{t h} under different thermodynamic conditions. Here, the minimum chill-roll temperature, that is, _{T h} , was chosen to be greater than 50°C to ensure that primary α -phase was generated. The deflection roller temperature, which represents the end temperature, was chosen with the lowest possible value of 30°C. _{t h} was chosen with 3 s and 20 s, which represented the minimum and maximum possible time to produce high-quality foils by adjusting the screw rotation speed as well as the haul-off speed. Here, for 3 s the screw rotation speed and the haul-off speed were set to 50 min^-1 and 3.6 m/min, respectively. For 20 s the screw rotation speed and the haul-off speed were set to 12 min^-1 and 0.59 m/min, respectively. The foil thickness was set to approximately 100 µ m. During the manufacturing process, the foil temperatures were measured at all relevant positions during the production line with an IR-camera while considering the respective emission coefficients. The derived temperature-time profiles are shown in Figure 3.

Figure 3: Measured temperature-time profile for the extruded foils measured with IR-camera for an isothermal holding time of 3 s (a) and 20 s (b).

(a) [figure omitted; refer to PDF]

(b) [figure omitted; refer to PDF]

2.4. Investigation Methods regarding the Produced Foils

Morphology . The cross-section's morphology of the extruded foils was investigated via linearly polarized light microscopy with an Axio Imager.M2 by Zeiss at 10 µ m thin cuts at under 45°. The cuts were taken from the middle of the foil along the direction of extrusion.

Degree of Crystallization . To calculate the degree of crystallization the melting enthalpy Δ _{H m} was determined with DSC measurements using a Q 1000 TMDSC by TA Instruments according to DIN EN ISO 11357 and correlated with Δ ^{H m 0} (melting enthalpy of 100% crystalline material) which is described to be 205 J/g [29].

Mechanical Parameters . To determine the mechanical parameters tensile tests as well as dynamic-mechanical analyses (DMA) were carried out with specimens prepared from the foil along the extrusion direction. Here, the tensile tests were performed according to DIN EN ISO 527-1 and -3 using a 5948 MicroTester by Instron. As parameters, the secant modulus (ranging from 2 to 10 N/mm² ) and the yield stress were determined with 5 test samples. To determine the storage modulus, dynamic-mechanical analyses according to ISO 6721-4 were carried out using an RSA-G2 by TA Instruments. For both investigatory methods (tensile tests and DMA) the samples were conditioned at 23°C and 50% humidity.

3. Results and Discussion

3.1. FSC

Crystallization with respect to Cooling Velocity . Figures 4 and 5 depict the measured heat flows during cooling and second heating for the investigated cooling velocities from 2000 to 500 K/s and 500 to 100 K/s, respectively. Results correlate well with the results from Schawe [12]. Therefore, during cooling at velocities greater than 300 K/s no significant exothermic effects were able to be measured, which leads to the assumption that the majority of the polymer chains solidify amorphously in a glassy state. This is then confirmed in the second heating. Here, at lower temperatures the amorphous structures melt since (between -10 and 10°C) the glass transition temperature was exceeded. At higher temperatures a significant exothermic peak was measured in the range of 10 to 40°C, which indicates cold crystallization during the heating step. It is assumed that the mesomorphic phase was being formed during this step. By further increasing the temperature the melting of the mesomorphic phase (between 40 and 80°C) and reorganization into the monoclinic α -phase (between 80 and 100°C) assumedly took place. Finally, from 100 to 135°C, the melting of the α -phase takes place. Regarding the different cooling velocities from 2000 to 500 K/s no significant differences during cooling and second heating were able to be measured. By further reducing the cooling velocity, in the range from 200 to 300 K/s, an increase in the exothermal peak's amplitude during cooling and a shift of _{T p c} towards higher temperatures were measured, which may indicate that crystallization takes place. In addition to the exothermic peak in the range of 0 to 30°C for 150 K/s and 100 K/s the beginning of the formation of an exothermic peak at higher temperatures (between 40 and 60°C) was evident. Here, it was assumed that α -phase emerges. Regarding second heating at previous cooling rates at 300 K/s, the cold crystallization peak decreases with decreasing cooling velocity, which can also be correlated with a higher amount of the mesomorphic phase. With a decreasing cooling velocity, at values less than or equal to 150 K/s, the majority of polymer chains were able to crystallize since no significant cold crystallization peak is evident. Furthermore, the decrease in the exothermic shoulder in the range between 80 and 100°C with previous cooling velocities less than or equal to 150 K/s confirms the assumption that a part of the material had been able to crystallize in α -phase during cooling.

Figure 4: Heat flow rate measured during cooling (a) and second heating (b) of iPP with respect to the examined cooling velocities from 2000 to 500 K/s.

(a) [figure omitted; refer to PDF]

(b) [figure omitted; refer to PDF]

Figure 5: Heat flow rate measured during cooling (a) and second heating (b) of iPP with respect to the examined cooling velocities from 500 to 100 K/s.

(a) [figure omitted; refer to PDF]

(b) [figure omitted; refer to PDF]

Figures 6 and 7 show the measured heat flows during cooling and second heating for the investigated cooling velocities from 100 to 50 K/s and 50 to 1 K/s, respectively. As for the cooling the mesomorphic crystallization peak decreases while the α -peak increases. For cooling velocities less than or equal to 20 K/s no mesomorphic crystallization was able to be detected. In the second heating a decrease in the exothermal shoulder is measured under decreasing, prior cooling conditions, which also shows the reduction in the mesomorphic phase amount. Furthermore, with prior formation of the α -phase (previous cooling velocity <= 20 K/s), the melting peak temperature _{T p m} starts to shift towards higher temperatures, since α -structures can form more perfectly.

Figure 6: Heat flow rate measured during cooling (a) and second heating (b) of iPP with respect to the examined cooling velocities from 100 to 50 K/s.

(a) [figure omitted; refer to PDF]

(b) [figure omitted; refer to PDF]

Figure 7: Heat flow rate measured during cooling (a) and second heating (b) of iPP with respect to the examined cooling velocities from 50 to 1 K/s.

(a) [figure omitted; refer to PDF]

(b) [figure omitted; refer to PDF]

Crystallization in Theoretically Based Temperature-Time Profiles . Figures 8 and 9 show the second heating of the FSC measurements for the analyzed cooling conditions derived from a conventional manufacturing process. Regarding the effect of _{T h} for 60, 80, and 100°C with an increasing _{t h} a shift in the melting peak temperature was found, which shows that either a higher amount of and/or more stable crystals had formed, which can be explained by isothermal crystallization. Here, the melting peak of _{t h} of 180 s shows different melting behavior with respect to _{T h} . Therefore, a higher _{T h} leads to crystal melting at higher temperatures. Furthermore, it can be seen, especially when comparing 80°C and 100°C, that with an increasing _{T h} the duration for isothermal crystallization also increases, which can be explained by the lower undercooling of the melt. At 120°C no significant isothermal crystallization was able to be measured. Here, it is assumed that due to the low undercooling of the melt the crystallization kinetics were too low for isothermal crystallization and the main crystallization took place during subsequent cooling with 30 K/s.

Figure 8: Heat flow rate measured during second heating of process-based cooled samples with isothermal holding step at 60°C (a) and 80°C (b).

(a) [figure omitted; refer to PDF]

(b) [figure omitted; refer to PDF]

Figure 9: Heat flow rate measured during second heating of process-based cooled samples with isothermal holding step at 100°C (a) and 120°C (b).

(a) [figure omitted; refer to PDF]

(b) [figure omitted; refer to PDF]

3.2. Foil Characterization

Morphology . The resulting morphologies of the extruded foils manufactured at varying _{t h} and chill-roll temperatures ( _{T h} ) are shown in Figure 10. Considering the effect of _{T h} for foils produced at 20 s _{t h} it can be seen that an increase in temperature led to a significantly more coarsely distinct inner structure. Therefore, the resulting spherulitic structures showed a greater diameter with an increasing _{t h} . Comparing the morphology over the entire foil cross-section, the spherulitic structures located in the middle tend to appear more coarsely distinct. This could possibly be explained by shear-induced nuclei in the layer close to the skin due to melt shearing inside the extrusion die. Regarding the effect of an increasing _{T h} for foils produced with _{t h} of 3 s an increase in the crystalline structure sizes was able to be measured up to 100°C. Nevertheless, at 120°C, especially in the core region, the spherulites appear more finely distinct compared to the spherulitic structures of the foils produced at 100°C. Here, it is assumed that _{t h} of 3 s is not sufficient for primary isothermal crystallization especially in the core region where athermal nucleation, due to shear-induced crystallization, is largely negligible. Comparing the structures in the region near the skin with the core region at 55, 80, and 100°C, for foils produced at 3 s the spherulites near the skin appear more finely distinct, which again can be explained by shear-induced nuclei during manufacturing which act as a crystallization catalyst. Nevertheless, at 120°C the component region near the skin seems to have a more distinct morphology with small spherulitic structures while the core area shows a mixture of large spherulites and very fine spherulitic structures. Again, it is assumed that in the component region near the skin crystallization is facilitated by shear-induced nuclei, which led to athermal and consequently faster crystallization. Within the foil's core region, where the lowest shear stresses are estimated, primary thermal nucleation is assumed. Therefore, due to the resulting slower crystallization kinetics, the component's structure is less distinct in the core region. As summarized, a significant effect of _{t h} was only successfully measured at high _{T h} . Here, a sufficient _{t h} was able to lead to the most distinct spherulitic structures while a short _{t h} led to significantly less distinct inner structures.

Figure 10: Morphology over the cross-section of extruded foils manufactured at different chill-roll temperatures and isothermal holding times.

[figure omitted; refer to PDF]

Comparing the analytical results of the FSC and experimental results from the foil extrusion, it can be shown that during foil manufacturing crystallization effects were able to be measured even at 120°C. With regard to the FSC measurements no isothermal crystallization was able to be measured even at 180 s. Here, it is assumed that during the process a significant influence from athermal nucleation sped up the crystallization kinetics, which has to be considered during manufacturing.

Degree of Crystallization . Figure 11 shows the degree of crystallization X for the different isothermal holding temperatures and isothermal holding times. Regarding the effect of _{T h} for both isothermal holding times an increase in the degree of crystallization was able to be measured for foils produced at 55, 80, and 100°C. Here, for an isothermal holding time of 3 s the degrees of crystallization reach higher values, which could be explained by the higher athermal nucleation due to higher shear stresses during manufacturing. The increase in X with an increasing _{T h} could be explained by the more perfectly formed inner structures. In this context, it is known that crystalline structures that have formed at higher temperatures can crystallize more perfectly, which also leads to a higher degree of crystallization. Nevertheless, at a _{T h} of 120°C a significant decrease in X is measured for foils produced with _{t h} of 3 s. Therefore, _{t h} of 3 s leads to less perfectly developed crystals although there is higher athermal nucleation. In contrast, foils produced at 20 s and 120°C reach the highest degree of crystallization in the produced foils. Therefore, at 120°C the isothermal crystallization kinetics is relatively slow and a longer _{t h} is necessary to attain further gains in the specific melting enthalpy. Nevertheless, for foils produced at 20 s the increase in X with an increasing _{T h} from 100 to 120°C is relatively small. Here, a possible explanation could be _{t h} having been too short [30].

Figure 11: Degree of crystallization of extruded foils manufactured at different chill-roll temperatures and isothermal holding times.

[figure omitted; refer to PDF]

Mechanical Properties . The results of the tensile tests are shown in Figure 12. For both the secant modulus and the yield stress, an increase in the resulting mechanical parameters was measured for _{t h} of 3 and 20 s and _{T h} of 55, 80, and 100°C. Here, the results for the lower isothermal holding times tend to reach higher mechanical parameters, which could be explained by the more distinct crystalline structures and higher degree of crystallization due to athermal nucleation. Regarding _{T h} of 120°C and _{t h} of 20 s a significant further increase in the mechanical parameters was able to be measured. Nevertheless, at 120°C _{T h} and 3 s _{t h} the lowest mechanical parameters were measured, which in turn can be explained by the less distinct geometry and degree of ordered structures. Therefore, a further increase in componential properties by increasing _{T h} can only be achieved by increasing _{t h} .

Figure 12: Secant modulus (a) and yield stress (b) of extruded foils manufactured at different chill-roll temperatures and isothermal holding times.

(a) [figure omitted; refer to PDF]

(b) [figure omitted; refer to PDF]

Figure 13 shows the results of the DMA measurements for the foils produced at 55 and 120°C with respect to the investigated _{t h} . Comparing the results of different _{t h} at _{T h} of 55°C, analogous to the tensile tests, the samples produced at _{t h} of 20 s reach values lower than samples produced at _{t h} of 3 s, which can be explained by the more distinct morphology and degree of crystallization. Nevertheless, the differences are relatively small, especially at temperatures above 60°C. Therefore, _{t h} does not appear to be necessary at low manufacturing temperatures. Regarding the storage modulus for _{T h} of 120°C and _{t h} of 3 s there is no significant improvement in the storage modulus compared to the foils produced at 55°C. Nevertheless, with a longer _{t h} of 20 s and, therefore, an isothermal crystallization at high temperatures a significant improvement in the storage modulus was able to be achieved even with less athermal nucleation. This can be attributed to the more distinct morphology as well as degree of crystallization.

Figure 13: Storage modulus of extruded foils manufactured at chill-roll temperature of 55°C (a) and 120°C (b).

(a) [figure omitted; refer to PDF]

(b) [figure omitted; refer to PDF]

4. Conclusion

Regarding the influence of various cooling velocities with respect to the resulting crystallization, FSC measurements were able to show that different crystal modifications can be achieved. Therefore, cooling velocities above 500 K/s primarily lead to a complete vitrification of the polymer chains in the glassy state. By reducing the cooling velocity, the amount of the mesomorphic crystal phase increases in the temperature range of 10 to 40°C. At approximately 150 K/s it is assumed that the highest amount of mesomorphic crystal phase has developed. A further reduction in the cooling velocity leads to an increase in the monoclinic α -phase, which is asserted to be the most stable form of isotactic polypropylene. At approximately 20 K/s no crystallization of the mesomorphic phase was detected and the majority of the polymer chains had formed into the monoclinic α -phase. Therefore, with a decreasing cooling velocity the polymorphs of the solid material may range from primarily amorphous to primarily mesomorphic to primary α -monoclinic, meaning that a decreasing cooling velocity can lead to an increase (primarily amorphous > _{v c} > primarily mesomorphic phase) as well as a decrease of the mesomorphic phase (primarily mesomorphic phase > _{v c} > primarily α -monoclinic). Regarding the analytically analyzed influence of _{t h} at different isothermal holding temperatures, investigations indicated that for the temperatures 60, 80, and 100°C an increase in _{t h} can lead to an increase in the resulting melting peak temperature during the second heating. Furthermore, it was shown that with increasing temperatures the time needed for isothermal crystallization also increases, as explained by the poor thermodynamic conditions due to a lower undercooling of the melt. Consequently, at 120°C no isothermal crystallization was able to be measured.

Evaluating the results of the experimental setup it was shown that an increase of chill-roll temperature ( _{T h} ) from 55 up to 100°C leads to a more distinct geometry and degree of ordered structures as well as an increase in the resulting mechanical parameters such as secant modulus, yield stress, and storage modulus for all investigated isothermal holding times. Further, a decrease in _{t h} leads to a decrease in the spherulitic structures in the area near the skin as well as an increase in the resulting degree of crystallization, which is attributed to the higher athermal nucleation due to higher shear stresses caused by the higher rotational speed of the extruder screw. Nevertheless, the influence of _{t h} seems to be less important at temperatures less than or equal to 100°C. However, at _{T h} of 120°C a significant effect of _{t h} emerged. There, at _{t h} of 20 s a further increase in the spherulite size and the melting enthalpy and the resulting mechanical properties were achieved as compared to the lower chill-roll temperatures. However, at _{t h} of 3 s despite the higher athermal nucleation, the lowest mechanical parameters were successfully measured. Here, it is assumed that due to the high chill-roll temperatures and the resulting slow crystallization kinetics the crystallization primarily occurred during cooling and not isothermally. This leads to a poor inner structure and degree of crystallization as well as poor resulting mechanical properties. Therefore, _{t h} has to be taken into account especially at higher chill-roll temperatures.

In future work, the FSC measurements should be taken by varying the sample mass to verify the results. Here, the sample mass and, therefore, the melting enthalpy should also be calculated by means of a comparison between DSC and FSC measurements. Doing so could thus facilitate comparing quantitative results. Furthermore, aside from iPP, other semicrystalline materials should be investigated. Finally, transferring the knowledge gained through this research to the injection molding process by considering further influences on the crystallization such as pressure and shear should be a central focus of future endeavors. Here, the possibility of investigating the first heating of an injection molded sample section with the FSC could give an indication of local cooling conditions during the injection molding process.

Acknowledgments

The authors thank the German Research Foundation (DFG) for funding this work within Project JU 2944/1-1. The authors are also grateful to the company SABIC for providing the material.