In orbit the temperatures will often rapidly shift anywhere from -150°C to +150°C, sometimes within the space of an hour. There is obviously no air flow in orbit, and electrostatic charges can build up very quickly and short out any delicate electronic components if they’re not shielded properly, leaving behind a very expensive piece of space debris. Space, especially in orbit around our planet, is an extreme environment that is incredibly inhospitable to technology. Any spacecraft that is designed for it needs to take that extreme environment into account, and anything that we launch into it needs to have a very high level of reliability.
Additive manufacturing has provided designers of modern spacecraft with an unprecedented freedom from most design restrictions. As companies continue to develop new 3D printing technologies and 3D printing materials those restrictions are quickly disappearing. Stratasys was asked by the design community for spacecraft and other launch vehicles to develop new materials that help them address the environmental conditions in space, and protect the delicate electronics in their satellites from the dangers of extreme temperatures and the risks of electrostatic discharge.
To make sure that the material that they developed would be up to the challenge, Stratasys Advanced Materials worked closely with their customer to engineer a material capable of meeting the unique challenges of spaceflight. What they ended up with is a thermoplastic material called ESD PEKK (dissipative polyetherketoneketone) that combines the electrostatic dissipative properties of one of their specialty materials ABS-ESD7 with the high durability and heat resistance of their ULTEM 9085 material. To top it off they included the chemical resistance of PEKK’s base resin, which offers a new material that will allow for the faster manufacturing of multi-functional production parts and components. The ESD PEKK material is ideally suited to the production of components like avionics boxes or components that provide the satellites with an internal structure.
Traditionally manufactured thermoplastic parts require post processing treatments like specialized coatings, paintings, and a covering of conductive tape to support the electrostatic dissipative requirements. The conductive filler of ESD PEKK was designed specifically to eliminate this expensive and time consuming step in the manufacturing process. Parts can be used right off the printer bed, and the high tensile strength, heat resistance and chemical resistance means that the production of these parts for spacecraft is ideal for the rapid manufacturing required to keep up with the growing demand.
The Engineered Materials Program, like the ESD PEKK project, is offered as a service to any customers who are in need of solutions for challenging material development problems. Materials can be developed to customer-specified requirements by Stratasys Advanced Materials, which has the ability to develop and produce a wide range of materials customized for any application-specific requirements that may be needed. Currently ESD PEKK is not available through existing Stratasys sales channels because it was a custom developed material. However, the material can be obtained with a custom order for the Fortus 3D Production Systems by contacting Stratasys Advanced Materials directly. Stratasys has collected a wide range of test data on the ESD PEKK material, which they used to produce a white paper about the ESD PEKK project. Discuss your thoughts on this new material in the ESD PEKK 3D Printing forum over at 3DPB.com.