Multi-Material Fused Filament Fabrication of TPU Composite Honeycombs Featuring Out-of-Plane Gradient Stiffness

محفوظ في:

التفاصيل البيبلوغرافية
الحاوية / القاعدة:	Journal of Composites Science vol. 9, no. 11 (2025), p. 588-603
المؤلف الرئيسي:	Koltsakidis Savvas
مؤلفون آخرون:	Tsongas Konstantinos, Papas Nikolaos, Pechlivani, Eleftheria Maria, Tzetzis Dimitrios
منشور في:	MDPI AG
الموضوعات:	Load Compression zone Mechanical properties Fused deposition modeling Carbon fibers Printers (data processing) Densification Porous materials Energy absorption Polyurethane resins Urethane thermoplastic elastomers Carbon fiber reinforced plastics Stiffness Energy dissipation Blowing agents Design Energy efficiency Stress-strain curves Thickness Additive manufacturing
الوصول للمادة أونلاين:	Citation/Abstract Full Text + Graphics Full Text - PDF
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الوصف
مستخلص:	Gradient stiffness structures are increasingly recognized for their excellent energy absorption capabilities, particularly under challenging loading conditions. Most studies focus on varying the thickness of the structure in order to produce gradient stiffness. This work introduces an innovative approach to design honeycomb architectures with controlled gradient stiffness along the out-of-plane direction achieved by materials’ microstructure variations. The gradient is achieved by combining three types of thermoplastic polyurethane (TPU) materials: porous TPU, plain TPU, and carbon fiber (CF)-reinforced TPU. By varying the material distribution across the honeycomb layers, a smooth transition in stiffness is formed, improving both mechanical resilience and energy dissipation. To fabricate these structures, a dual-head 3D printer was employed with one head printed processed TPU with a chemical blowing agent to produce porous and plain sections, while the other printed a CF-reinforced TPU. By alternating between the two print heads and modifying the processing temperatures, honeycombs with up to three distinct stiffness zones were produced. Compression testing under out-of-plane loading revealed clear plateau and densification regions in the stress–strain curves. Pure CF-reinforced honeycombs absorbed the most energy at stress levels above ~4.5 MPa, while porous TPU honeycombs were more effective under stress levels below ~1 MPa. Importantly, the gradient stiffness honeycombs achieved a balanced energy absorption profile across a broader range of stress levels, offering enhanced performance and adaptability for applications like protective equipment, packaging, and automotive structures.
تدمد:	2504-477X
DOI:	10.3390/jcs9110588
المصدر:	Materials Science Database