Effect of manufacturing process parameters on the compression and energy absorption properties of 4D-printed deformable honeycomb structure

Four-dimensional-printed deformable honeycombs can produce pro-programmed shape deformation and different properties under external stimuli, and the manufacturing process parameters are the dominant factors affecting the microstructure and properties of the manufactured honeycomb structures. Althoug...

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Published in	Smart materials and structures Vol. 33; no. 7; pp. 75035 - 75048
Main Authors	Peng, Xiang, Han, Yang, Liu, Guoao, Li, Jiquan, Yi, Bing, Sa, Guodong, Jiang, Shaofei
Format	Journal Article
Language	English
Published	IOP Publishing 01.07.2024
Subjects	4D printing deformable honeycomb mechanical property process parameters
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Abstract	Four-dimensional-printed deformable honeycombs can produce pro-programmed shape deformation and different properties under external stimuli, and the manufacturing process parameters are the dominant factors affecting the microstructure and properties of the manufactured honeycomb structures. Although many researchers have investigated the effects of manufacturing process parameters on the mechanical properties of printed materials, there is still a lack of research on the relationship between manufacturing process parameters and properties of honeycomb structures. Therefore, a novel honeycomb structures which has two configurations under temperature stimuli is proposed, and the optimum manufacturing processes for the printing of this honeycomb are selected considering the compression and energy absorption properties simultaneously. The novel honeycomb is designed and printed with fused deposition modeling technology, which have hexagonal configuration (Structure I) and semi-triangular configuration (Structure II) under external temperature stimulus. The energy absorption capacity of Structure I and compressive properties of Structure II are investigated under different manufacturing process parameters. The experimental results indicate that the layer thickness has the most significant impact on the mechanical performance of deformable honeycombs. The combination of a layer thickness of 0.2 mm, printing speed of 40 mm s −1 , and 100% infill density are the best process parameters for the novel deformable honeycomb structures.
AbstractList	Four-dimensional-printed deformable honeycombs can produce pro-programmed shape deformation and different properties under external stimuli, and the manufacturing process parameters are the dominant factors affecting the microstructure and properties of the manufactured honeycomb structures. Although many researchers have investigated the effects of manufacturing process parameters on the mechanical properties of printed materials, there is still a lack of research on the relationship between manufacturing process parameters and properties of honeycomb structures. Therefore, a novel honeycomb structures which has two configurations under temperature stimuli is proposed, and the optimum manufacturing processes for the printing of this honeycomb are selected considering the compression and energy absorption properties simultaneously. The novel honeycomb is designed and printed with fused deposition modeling technology, which have hexagonal configuration (Structure I) and semi-triangular configuration (Structure II) under external temperature stimulus. The energy absorption capacity of Structure I and compressive properties of Structure II are investigated under different manufacturing process parameters. The experimental results indicate that the layer thickness has the most significant impact on the mechanical performance of deformable honeycombs. The combination of a layer thickness of 0.2 mm, printing speed of 40 mm s −1 , and 100% infill density are the best process parameters for the novel deformable honeycomb structures.
Author	Jiang, Shaofei Liu, Guoao Han, Yang Yi, Bing Li, Jiquan Sa, Guodong Peng, Xiang
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Snippet	Four-dimensional-printed deformable honeycombs can produce pro-programmed shape deformation and different properties under external stimuli, and the...
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SubjectTerms	4D printing deformable honeycomb mechanical property process parameters
Title	Effect of manufacturing process parameters on the compression and energy absorption properties of 4D-printed deformable honeycomb structure
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Volume	33
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