Orientation-Graded Morphologies in Microcellular Foams through Additive Manufacturing

IF 3.8 3区工程技术 Q2 ENGINEERING, CHEMICAL

Industrial & Engineering Chemistry Research Pub Date : 2024-10-12 DOI:10.1021/acs.iecr.4c02307

Claudio Esposito, Daniele Tammaro, Pasquale Posabella, Massimiliano Maria Villone, Gaetano D’Avino, Pier Luca Maffettone

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Abstract

We present experimental findings and modeling insights into the expansion of bubbles within a Newtonian fluid, observed during an advanced process integrating additive manufacturing and physical foaming techniques to fabricate complex microcellular foams with orientation-graded morphologies. A physical and sustainable blowing agent (CO₂) is solubilized into a biopolymer (PLA) that is 3D-printed through a cylindrical nozzle, and, at the nozzle outlet, the blowing agent foams inside the polymeric strand due to pressure drop or/and temperature rise. The experimental results show that, by engineering the temperature gradient at high printing velocities, corresponding to values of the Graetz number (i.e., the ratio of heat diffusion time and residence time inside the printer hot-end) larger than one, the microcellular foamed strands have a microstructure characterized by anisotropic bubbles oriented along two different directions. The microbubbles at the center of the strands are stretched in the extrusion direction, whereas those in the periphery are stretched radially. A foam morphology with microbubbles having two different orientations, smoothly changing within the cross section, has never been reported before. We investigate the formation mechanism of such a morphology by simplified modeling and numerical simulations. Simulation results support the experimental findings and rationalize the effects of the Graetz number on the microcellular foamed strands and on the expansion of gas bubbles in a Newtonian fluid, suggesting that the different orientations of the bubbles are due to the combined effect of high Graetz number and the radial expansion of the strand.

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通过增材制造实现微孔泡沫的定向分级形态

我们介绍了牛顿流体中气泡膨胀的实验发现和建模见解，这些发现和见解是在集成了快速成型制造和物理发泡技术的先进工艺中观察到的，该工艺可制造出具有取向分级形态的复杂微孔泡沫。物理可持续发泡剂（二氧化碳）被溶解到生物聚合物（聚乳酸）中，通过圆柱形喷嘴进行三维打印，在喷嘴出口处，发泡剂因压力下降或/和温度升高而在聚合物股内发泡。实验结果表明，在打印速度较高时，格拉茨数（即热扩散时间与打印机热端内停留时间之比）大于 1 时，通过调节温度梯度，微孔发泡股的微观结构具有沿两个不同方向定向的各向异性气泡。股中心的微气泡沿挤压方向拉伸，而外围的微气泡则沿径向拉伸。微泡具有两种不同的取向，并在横截面上平滑变化，这种泡沫形态以前从未报道过。我们通过简化建模和数值模拟研究了这种形态的形成机制。模拟结果支持实验结果，并合理解释了格拉茨数对微孔泡沫股和牛顿流体中气泡膨胀的影响，表明气泡的不同取向是由高格拉茨数和股的径向膨胀共同作用造成的。

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来源期刊

Industrial & Engineering Chemistry Research 工程技术-工程：化工

CiteScore

7.40

自引率

7.10%

发文量

1467

审稿时长

2.8 months

期刊介绍： ndustrial & Engineering Chemistry, with variations in title and format, has been published since 1909 by the American Chemical Society. Industrial & Engineering Chemistry Research is a weekly publication that reports industrial and academic research in the broad fields of applied chemistry and chemical engineering with special focus on fundamentals, processes, and products.