Durability of Ultem 9085 in Marine Environments: A Consideration in Fused Filament Fabrication of Structural Components

Wang, Xirong; Travis, Carly; Sorna, Mark; Arola, Dwayne

doi:10.3390/polym16030350

Polymers

2024

DOI: 10.3390/polym16030350

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Durability of Ultem 9085 in Marine Environments: A Consideration in Fused Filament Fabrication of Structural Components

Xirong Wang,

Carly Travis,

Mark Sorna

et al.

Abstract: The long-term durability of polymer components produced by additive manufacturing (AM) in marine conditions is poorly understood. Here, fused filament fabrication (FFF) of Ultem 9085 was conducted and accelerated aging was performed. Two printing orientations (−45/45° and 0/90°) and two sample types (ASTM D638 Type 1 and Type 4) were produced and subjected to accelerated aging in either seawater or air. Results from tensile tests showed that the elastic modulus, yield strength and ultimate tensile strength inc… Show more

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2024

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Cited by 3 publications

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Development of a Novel, All‐Aromatic High Tensile Modulus Liquid Crystalline Polyimide for Fused Filament Fabrication Applications

Yu,

Carrola,

Zheng

et al. 2024

Adv Funct Materials

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Polyimides (PIs), known for their thermal resistance, chemical stability, and mechanical properties, are often considered challenging materials to process, resulting in limited commercial availability of PIs for melt extrusion, injection molding, and fused filament fabrication (FFF). Currently, material and knowledge gaps prevent the ability to rapidly produce parts from PIs that can be used in high strength and elevated temperature applications. To address this, a novel, fully aromatic PI with thermotropic liquid crystalline properties (LCPI) is successfully synthesized. The synthesized LCPI exhibits better solvent tolerance and thermal stability than commercially available counterparts. The LC phase is confirmed by thermal analysis, wide angle X‐ray scattering, and polarized optical microscopy. Rheological behavior clearly demonstrates that the LC phase reduces melt viscosity. These properties enable the LCPI to be processed into both drawn fibers and filaments for FFF, which is demonstrated alongside an injection molding process. The properties of the printed parts rivaled those made with Ultem 1000, exhibiting an average elastic modulus of 4.16 GPa. The injection molding process resulted in tensile moduli as high as 8.59 GPa and tensile strengths as high as 124.70 MPa. The LCPI polymer demonstrates the desired properties required for aerospace applications via melt processing techniques.

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Development of a Novel, All‐Aromatic High Tensile Modulus Liquid Crystalline Polyimide for Fused Filament Fabrication Applications

Yu,

Carrola,

Zheng

et al. 2024

Adv Funct Materials

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Interlaminar tensile properties of raw and carbon fiber‐wrapped additively manufactured polyetherimide

Sankaran,

Rajan,

Selvaraj

et al. 2024

Polymer Engineering & Sci

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High‐performance engineering thermoplastics are important emerging materials, particularly when processed using additive manufacturing technologies. One of the most important among these is polyetherimide, also known as PEI or ULTEM. Using the fused filament fabrication (FFF) additive manufacturing (AM) process to form this material is a good option, but it is difficult to control the properties in some cases due to the very high processing temperature compared with most engineering thermoplastics. One way to “even‐out” the properties is to wrap the specimens in continuous glass or carbon fibers embedded in a thermosetting matrix, as this allows strategic placement and orientation of reinforcement. This also complements the natural structure of the FFF‐manufactured materials, helping to minimize the amount of additional weight that needs to be added to a part. To further knowledge in this area, the present study explored and compared the interlaminar tensile strength of FFF‐processed PEI/ULTEM 9085 specimens and compared them with ones wrapped in carbon fibers with a 2‐part resin matrix. Experiments were performed in accordance with the guidelines given in the ASTM D6415 standard and replicated five times. Variations were introduced in thickness of the specimen and raster angle during the manufacturing process to identify the significant impact of the failure. The results show a fall in interlaminar tensile strength with increasing specimen thickness and a very large effect from natural printing defects in the samples. The carbon fiber wrap decreased the ILTS but made the results far more consistent between experimental runs. This study provides a good, replicated dataset on the performance of raw and fiber‐wrapped FFF‐processed ULTEM 9085 and gives insights into the structural behavior of the material that will be useful for use in design decisions and material selection.Highlights Polyetherimide, also known as PEI/ULTEM, is a high‐performance engineering thermoplastic. Explored the interlaminar tensile properties (ILTS) of this material using ASTM D6415. Raster angle, thickness, and use of fiber wrap were experimental parameters. Fiber wrap was found to have little effect on strength but made results more consistent. Results are useful for material selection and design decisions using PEI.

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High-Performance Polymer Blends: Manufacturing of Polyetherimide (PEI)–Polycarbonate (PC)-Based Filaments for 3D Printing

Singh,

Hubert

2024

Polymers

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The demand for high-performance polymers in 3D printing continues to grow due to their ability to produce intricate and complex structures. However, commercially available high-temperature 3D printing materials often exhibit limitations such as brittleness, warping, thermal sensitivity, and high costs, highlighting the need for advanced filament development. This study investigates the fabrication of polyetherimide (PEI) and polycarbonate (PC) blends via melt extrusion to enhance material properties for stable additive manufacturing. The addition of PC improved the processability of the blends, enabling successful extrusion at temperatures ranging from 290 to 310 °C. Differential scanning calorimetry (DSC) confirmed a shift in the softening temperature (T) of PEI, indicating effective blending. To further improve the properties of the PEI:PC blends, 1 wt% of a compatibilizer was incorporated, resulting in homogeneous microstructures as observed through scanning electron microscopy (SEM). The optimized PEI:PC (70:30) blend with compatibilizer (1 wt%) demonstrated a 49% higher storage modulus than neat PEI and a 40% greater storage modulus than ULTEM9085. Moreover, reduced melt viscosity facilitated consistent and stable printing, making these materials highly suitable for applications in aerospace and transportation, where performance and reliability are critical.

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Durability of Ultem 9085 in Marine Environments: A Consideration in Fused Filament Fabrication of Structural Components

Cited by 3 publications

References 63 publications

Development of a Novel, All‐Aromatic High Tensile Modulus Liquid Crystalline Polyimide for Fused Filament Fabrication Applications

Development of a Novel, All‐Aromatic High Tensile Modulus Liquid Crystalline Polyimide for Fused Filament Fabrication Applications

Interlaminar tensile properties of raw and carbon fiber‐wrapped additively manufactured polyetherimide

High-Performance Polymer Blends: Manufacturing of Polyetherimide (PEI)–Polycarbonate (PC)-Based Filaments for 3D Printing

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