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Abstract

In-space manufacturing (ISM) enables on-demand fabrication of large space structures that exceed current launch payload volume. While past research has focused on additive manufacturing of thermoplastics and their composites, fiber-reinforced thermoset composites (FRTSC) offer lower energy processing, superior thermomechanical properties, durability, and easy integration of multifunctional material systems through diverse chemistry, composite architecture, and novel processing. The challenges to using thermosets composites in space are containment of fluids, control of the chemical reaction with compact processing equipment, and maturation of processing methods. Recent studies suggest that in-space manufacturing of FRTSC can be advanced using encapsulated catalyzed poly(dicyclopentadiene) (pDCPD) carbon fiber preforms. Structural elements can be processed with modest equipment using frontal polymerization (FP) of pultruded composite tubes, bulk polymerization of solid beams by rapid out-of-oven lamination (ROL), and FP of panels with programmed curvature from flat additively manufactured preforms. Looking ahead, novel chemistry, integrated devices, and in-space manufacturing of FRTSC can be combined to achieve multifunctional space structures with self-healing, self-passivation, and self-sensing and extend the service life of space structures. This review examines the current state of ISM, current challenges, and the emerging role that ISM of multifunctional thermoset composites can have in enabling sustainable space infrastructure.

Keywords

Additive manufacturing composite structures damage detection multifunctional polymers

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References

Abdullah

Zakoworotony

Geubelle

, et al. (2025) Rapid out-of-oven lamination (ROL) for energy efficient manufacturing of carbon fiber reinforced composites. Composites Part A: Applied Science and Manufacturing. https://doi.org/10.1016/j.compositesa.2025.108873

Armstrong

Yue

Kuang

, et al. (2023) A hybrid additive manufacturing process for production of functional fiber-reinforced polymer composite structures. Journal of Composite Materials 57(4): 841–850.

Baur

Abbott

Barnett

, et al. (2022) Mechanical properties of additively printed UV cured continuous fiber unidirectional composites for multifunctional applications. Journal of Composite Materials 57(4): 865-882. https://doi.org/10.1177/00219983221146264

Chang

Das

Salvati

III L

, et al. (2023) Durable and impact-resistant thermoset polymers for the extreme environment of low Earth orbit. Extreme Mechanics Letters 64: 102089.

Chang

Sottos

(2023) Self-healing of transverse crack damage in carbon fiber composites. Composites Science and Technology 242: 110158.

Gardiner

(2023) Orbital Composites wins award from U.S. Space Force to build space factories for antennas. Composite World. https://www.compositesworld.com/news/orbital-composites-wins-award-from-us-space-force-to-build-space-factories-for-antennas

Giusto

Totaro

Spena

, et al. (2021) Composite grid structure technology for space applications. Materials Today: Proceedings 34: 332–340.

Hmeidat

Zakoworotny

Kim

, et al. (2025) Reactive extrusion of frontally polymerizing continuous carbon fiber reinforced polymer composites. Composites Part A: Applied Science and Manufacturing 190: 108609.

Hoyt

Cushing

Slostad

, et al. (2014) Trusselator: On-orbit fabrication of high-performance composite truss structures. AIAA SPACE 2014 Conference and Exposition.

10.

Chen

Peng

, et al. (2019) Composite carbon–epoxy tubes for space structures: Ground vacuum radiant experiments and structural behavior analysis. Journal of Aerospace Engineering 32(6): 04019084.

11.

Knorr

Jr DB

Masser

Elder

, et al. (2015) Overcoming the structural versus energy dissipation trade-off in highly crosslinked polymer networks: Ultrahigh strain rate response in polydicyclopentadiene. Composites Science and Technology 114: 17–25.

12.

Liu

Shen

, et al. (2019) Mechanical performance of carbon fiber/epoxy composites cured by self-resistance electric heating method. The International Journal of Advanced Manufacturing Technology 103: 3479–3493.

13.

Meador

(2019) The role of advanced materials and manufacturing in future NASA exploration missions. American Chemical Society National Meeting 2019.

14.

Melly

Liu

, et al. (2020) Active composites based on shape memory polymers: Overview fabrication methods applications and future prospects. Journal of Materials Science 55: 10975–11051.

15.

Obenchain

Rome

Hartney

, et al. (2024) Technology roadmap for the development of an orbital smallest factory. AIAA SCITECH 2024 Forum.

16.

Patel

Sottos

Wetzel

, et al. (2010) Autonomic healing of low-velocity impact damage in fiber-reinforced composites. Composites Part A: Applied Science and Manufacturing 41(3): 360–368.

17.

Pinto

Maroun

Meo

(2014) Material enabled thermography. NDT & E International 67: 1–9.

18.

Rahman

Gibbon

Islam

, et al. (2024) Adjustment of mechanical properties of 3D printed continuous carbon fiber-reinforced thermoset composites by print parameter adjustments. Polymers 16(21): 2996.

19.

Rahman

Islam

Gibbon

, et al. (2021) 3D printing of continuous carbon fiber reinforced thermoset composites using UV curable resin. Polymer Composites 42(11): 5859–5868.

20.

Robertson

Yourdkhani

Centellas

, et al. (2018) Rapid energy-efficient manufacturing of polymers and composites via frontal polymerization. Nature 557(7704): 223–227.

21.

Sher

(2024) Behind the scenes of the first metal part 3d Printed aboard the ISS. VoxelMatters. https://www.voxelmatters.com/behind-the-scenes-of-the-first-metal-part-3d-printed-aboard-the-iss/

22.

Sudhin

Remanan

Ajeesh

, et al. (2020) Comparison of properties of carbon fiber reinforced thermoplastic and thermosetting composites for aerospace applications. Materials today: proceedings 24: 453–462.

23.

Tenney

Davis

Jr JG

Pipes

, et al. (2009) NASA composite materials development: lessons learned and future challenges. NATO RTO AVT-164 Workshop on Support of Composite Systems.

24.

Shahzad

Vellara

, et al. (2025) Additive continuous tow preform for fiber angle optimized composite tube. In Proceeding of the American Society for Composites (ASC) 39th Annual Technical Conference.

25.

Vayas

Geubelle

, et al. (2025) Morphogenic composites: Frontal polymerization induced autonomously shaped composites. Submitted to Composites Part A: Applied Science and Manufacturing 193: 108827.

26.

Zhang

Tian

Jia

, et al. (2024) Mechanism and performance of thermal radiation recycling for in-space 3D printed continuous carbon fibre-reinforced PEEK composites. Virtual and Physical Prototyping 19(1): e2425823.

27.

Zocca

Wilbig

Waske

, et al. (2022) Challenges in the technology development for additive manufacturing in space. Chinese Journal of Mechanical Engineering: Additive Manufacturing Frontiers 1(1): 100018.

In-space manufacturing of thermoset composite structures: A short review

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