Advancements in Functionally Graded Polyether Ether Ketone Components: Design, Manufacturing, and Characterisation Using a Modified 3D Printer
Abstract
:1. Introduction
2. Materials and Methods
2.1. Aim and Objectives
- SEM analysis was performed to evaluate the correlation between individual material beads during printing and the level of porosity in the printed samples.
- Mechanical tests (tensile and hardness tests) were performed to understand how the process condition affects the properties of the material.
- A crystallinity assessment of test samples 3D printed with different configurations was investigated.
- A demonstrator was 3D printed.
2.2. Materials and 3D Printing
2.3. Testing Methodologies
2.3.1. Tensile Testing
2.3.2. Hardness Testing
2.3.3. SEM Testing
2.4. Crystallinity Assessment
3. Results and Discussion
4. Conclusions
- Several optimisations have been conducted to able a low-price/low temperature 3D printer to print high temperature polymers such as PEEK materials.
- FGM capability of the modified machine was proven and achieved through the control of temperature within the build environment as demonstrated. The functional gradient in a single part was achieved in a novel manner by the application of heat treatment during the manufacturing process removing the requirement for post processing.
- Parts printed at high enclosure temperatures exhibited greater strength than parts printed without the active addition of heat via the heater, due to improved bond formation between individual layers of the print and a large degree of crystallinity through maintenance at these elevated temperatures.
- It was measured that the maximum tensile strength of the PEEK specimens tested was approximately 44% less than the tensile strength of PEEK of approximately 90 MPa. This discrepancy in strength is likely due to pores or reduced layer adhesion resulting in a significantly less solid part than one machined from bulk PEEK.
- The specimen printed at 45 °C displayed the lowest hardness on the Rockwell scale at 49.2, with the sample printed at 120 °C exhibiting the highest strength of the samples tested.
- From the SEM results, it was found that the porosity of printed samples was at the level of 4%. Using the calculated porosities, the expected tensile strengths of the samples were calculated, however, there was still a large degree of error between the tested results and the predicted results.
- Effectively, the infill pattern and slicing of the physical specimen had a large effect on the resulting crystallinity of the produced parts.
Author Contributions
Funding
Institutional Review Board Statement
Data Availability Statement
Conflicts of Interest
References
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Concept | Advantages | Disadvantages |
---|---|---|
Hot air delivery | Allows precise temperature control of extruded material. High inter-laminar shear strength is possible. Localised high temperature has a low risk of thermal damage to electronics. Can also actively cool the part. | May cause deformation on site due to forced air. Formation of bubbles on the surface is possible and potentially leading to unwanted pores. Air velocity may reduce the dimensional accuracy of print. |
Dual nozzle design | No wait time when a higher extruding temperature is required (i.e., one extruder will always be at the correct temperature for the next phase of printing while the other extruder is in use). Compact design does not limit the build area. Off-the-shelf component can be used with modifications. Cost effective. | The heat from the “hot” head may be too high and influence the “cold” printing. Unsure of the underlying assumption of there being enough thermal energy in the extruded “hot” material. |
Ambient temperature control and enclosure | Cost effective. Exact control over ambient conditions. Active cooling can be achieved. | May not provide fine enough control. Isolation of electronics from high ambient temperatures may prove difficult. Can only achieve functional gradient in one axis. |
Supplementary Heated Plate | Inter-laminar shear strength increased from localised heat at the print site. Easy to control as very few components are required. No moving parts. Localised high temperature has a low risk of thermal damage to electronics. | Cannot affect previous layers, only the top layer. Limited by convection. Can only achieve functional gradient in one axis. |
Infrared Lamp | Precise control of crystallisation in two axes. Easy control of temperature using a microcontroller. Even distribution of heat is possible. Easy to test and implement (i.e., off-the-shelf components). | No active cooling. Can only achieve functional gradient in one axis. |
Bed Preparation | Cleaned after each use and a thin layer of Pritt stick applied |
Adhesion Type | Brim (12 mm) |
Print Speed | 20 mm/s |
Outer Perimeter speed | 10 mm/s |
Inner Perimeter Speed | 10 mm/s |
Infill Speed | 20 mm/s |
Infill Pattern | +/−45° |
Infill | 100% |
Flow Rate | 75% |
Extruder Temperature | 390 °C |
Bed Temperature | 120–140 °C |
Test 1 | Test 2 | |
---|---|---|
Bed temperature (°C) | 120 | 140 |
Ambient air temperature (°C) | 50 | 140 |
Radiation temperature (°C) | N/A | 150 |
Nozzle temperature (°C) | 390 | 390 |
Sample | Extruder T °C | Bed T °C | Enclosure T (°C) | Bulkhead | Air Flow | Measured UTS (MPa) |
---|---|---|---|---|---|---|
1 | 370 | 120 | 55 | No | 65% | 24.08 |
2 | 380 | 125 | 55 | No | 70% | 29.85 |
3 | 380 | 125 | 55 | No | 80% | 32.70 |
4 | 370 | 120 | 55 | Yes | 80% | 31.97 |
5 | 380 | 120 | 55 | Yes | 80% | 36.44 |
6 | 390 | 125 | 55 | Yes | 80% | 46.65 |
H1 | 390 | 135 | 120 | Yes | 80% | 49.87 |
H2 | 390 | 130 | 120 | Yes | 75% | 43.39 |
H3 | 390 | 150 | 120 | Yes | 75% | 47.57 |
H4 | 390 | 125 | 120 | Yes | 75% | 43.67 |
H5 | 390 | 140 | 120 | Yes | 75% | 47.44 |
H6 | 390 | 125 | 120 | Yes | 75% | 47.10 |
H7 | 390 | 125 | 140 | Yes | 75% | 30.07 |
H8 | 390 | 130 | 140 | Yes | 75% | 47.07 |
H9 | 390 | 140 | 140 | Yes | 75% | 32.09 |
H10 | 390 | 145 | 140 | Yes | 75% | 48.40 |
Sample | Condition | Average |
---|---|---|
1 | Ambient: 45 °C | 49.2 ± 1.2 |
2 | Ambient: 120 °C, Bed: 150 °C | 75.2 ± 2.3 |
3 | Ambient: 140 °C, Bed 140 °C | 57.4 ± 1.1 |
4 | Rod Cut-off | 92.9 ± 2.6 |
Image | Sample Name | Adjusted Area | Tested UTS (MPa) | Calculated UTS (MPa) | Infrared Temperature (°C) | Bed Temperature (°C) | Print Speed (mm/s) |
---|---|---|---|---|---|---|---|
(a) | 3 | 0.39539 | 32.7 | 13.84 | 55 | 125 | 40 |
(b) | 2 | 0.17495 | 29.85 | 41.69 | 55 | 125 | 60 |
(c) | 6 | 0.09052 | 46.65 | 63.59 | 55 | 125 | 40 |
(d) | H1 | 0.04234 | 49.87 | 80.92 | 120 | 135 | 40 |
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McNiffe, E.; Ritter, T.; Higgins, T.; Sam-Daliri, O.; Flanagan, T.; Walls, M.; Ghabezi, P.; Finnegan, W.; Mitchell, S.; Harrison, N.M. Advancements in Functionally Graded Polyether Ether Ketone Components: Design, Manufacturing, and Characterisation Using a Modified 3D Printer. Polymers 2023, 15, 2992. https://doi.org/10.3390/polym15142992
McNiffe E, Ritter T, Higgins T, Sam-Daliri O, Flanagan T, Walls M, Ghabezi P, Finnegan W, Mitchell S, Harrison NM. Advancements in Functionally Graded Polyether Ether Ketone Components: Design, Manufacturing, and Characterisation Using a Modified 3D Printer. Polymers. 2023; 15(14):2992. https://doi.org/10.3390/polym15142992
Chicago/Turabian StyleMcNiffe, Eric, Tobias Ritter, Tom Higgins, Omid Sam-Daliri, Tomas Flanagan, Michael Walls, Pouyan Ghabezi, William Finnegan, Sinéad Mitchell, and Noel M. Harrison. 2023. "Advancements in Functionally Graded Polyether Ether Ketone Components: Design, Manufacturing, and Characterisation Using a Modified 3D Printer" Polymers 15, no. 14: 2992. https://doi.org/10.3390/polym15142992
APA StyleMcNiffe, E., Ritter, T., Higgins, T., Sam-Daliri, O., Flanagan, T., Walls, M., Ghabezi, P., Finnegan, W., Mitchell, S., & Harrison, N. M. (2023). Advancements in Functionally Graded Polyether Ether Ketone Components: Design, Manufacturing, and Characterisation Using a Modified 3D Printer. Polymers, 15(14), 2992. https://doi.org/10.3390/polym15142992