Sintering Thermoset Composites at High Temperatures for Aerospace Applications

IMTS

Share this Article

In ‘Laser Sintering of Thermoset Polyimide Composites,’ authors Kathy C. Chuang, Timothy J. Gornet, Kate Schneidu, and Hilmar Koerner explore additive manufacturing with blended materials, meant to refine the process further and offer better performance overall.

Polyamides such as nylon are commonly used in SLS 3D printing, but objects printed may be weaker in comparison to the use of other materials. The researchers attribute this to ‘lack of polymer inter-chain connection in the z-direction.’ They also explain that their true motivation behind development of an SLS process for thermoset resins is to have the capability of 3D printing at higher temperatures (to 250-300 °C) so composites can be used for aerospace.

Their previous study showed that resin viscosity was too low, with the reactive PEPA endcap remaining uncured:

“As a result, the LS-printed resin chips could not hold much integrity upon postcure above 250 °C. To overcome the low viscosity of the resin, the standard RTM370 resin was further staged for 2-4 hours at 300 °C to promote chain extension while still maintaining melt-proccessability and avoiding extensive crosslinking of PEPA endcap,” stated the researchers.

Several sets of six resin chips from one to six scans were manufactured by LS with the RTM370 resin. According to the researchers, while they seemed very uniform at first, they began to soften in the oven at 200 °C, and then began to melt at 250 °C—indicating lack of curing.

DSC of RTM370 resin after staging at 300 °C for 2.5 h

RTM370 resin was mixed with 35% carbon fibers for increased stiffness. All single layer square samples were successfully scanned, and heat transfer to the resin mixture was improved also.

“The depth of penetration (chip thickness) also increased with increasing number of scans, although DSC thermogram still showed significant exotherm of the uncured PEPA endcap at 370 °C, indicating that the green composite disks are not fully cured yet,” stated the researchers. “The thermal conductivity of the carbon fiberfilled RTM370 LS disk in Fig. 6 (0.6 W/m.K, porous) is almost 3 times that of a neat resin disk (0.2 W/m.K, dense). The porosity of the LS disk is ~54% based on gas pycnometer measurement.”

Carbon-fiber-filled RTM370 composite chips by LS

Carbon-fiber-filled LS-printed disk (left) and neat resin disk (right)

They also printed a bracket with the parameters, beginning at a 50 percent scale. The authors report that although the printing process was completed, they could not consider it successful due to the amount of warping and shifting. A 30 percent scaled bracket was built, along with other parts, via LS.

The green bracket was put through the paces, heated gradually in post-cure cycles at 3-5 °C/min from room temperature along with multiple holds at steady temperature for an extended period of time and a final post-cure at 365 °C for 16 hours. This polyimide composite part was the first one to be 3D printed that can be used in aerospace applications—heated to over >300 °C.

“Essentially, a thermoset polyimide composite 3D network was achieved by using melt-processable imide oligomers terminated with reactive PEPA endcaps for LS processing,” concluded the researchers. “To the best of our knowledge, this paper demonstrates the first major advance in the additive manufacturing of high temperature polyimide composites with glass transition temperature (Tg) of 370 °C printed by LS.

“Another advantage of this major breakthrough is that these thermoset oligomers can be 3D printed by a regular laser sintering machine, without the need of using the high temperature laser sintering process (HT-LS, 250-380 °C) required for processing commercial thermoplastic PEEK with 150-185 °C use temperature. In essence, this research ushers in the new era of using additive manufacturing to produce high temperature thermoset polyimide composite parts for >300 °C applications.”

3D printing with composites continues to be a popular area of study for researchers, manufacturers, and many users as they attempt to refine materials to meet specific needs, from working with glass fiber to lignin biocomposites to metal nanocomposites and much more. What do you think of this news? Let us know your thoughts! Join the discussion of this and other 3D printing topics at 3DPrintBoard.com.

Layers shifting during the build and post building

[Source / Images: ‘Laser Sintering of Thermoset Polyimide Composites’]

Share this Article


Recent News

Will There Be a Desktop Manufacturing Revolution outside of 3D Printing?

Know Your Würth: CEO AJ Strandquist on How Würth Additive Can Change 3D Printing



Categories

3D Design

3D Printed Art

3D Printed Food

3D Printed Guns


You May Also Like

Featured

Pressing Refresh: What CEO Brad Kreger and Velo3D Have Learned About Running a 3D Printing Company

To whatever extent a business is successful thanks to specialization, businesses will nonetheless always be holistic entities. A company isn’t a bunch of compartments that all happen to share the...

Würth Additive Launches Digital Inventory Services Platform Driven by 3D Printing

Last week, at the Additive Manufacturing Users’ Group (AMUG) Conference in Chicago (March 10-14), Würth Additive Group (WAG) launched its new inventory management platform, Digital Inventory Services (DIS). WAG is...

Featured

Hypersonic Heats Up: CEO Joe Laurienti on the Success of Ursa Major’s 3D Printed Engine

“It’s only been about 24 hours now, so I’m still digesting it,” Joe Laurienti said. But even via Zoom, it was easy to notice that the CEO was satisfied. The...

Featured

3D Printing’s Next Generation of Leadership: A Conversation with Additive Minds’ Dr. Gregory Hayes

It’s easy to forget sometimes that social media isn’t reality. So, at the end of 2023, when a burst of doom and gloom started to spread across the Western world’s...