Study on the control of mechanical and electrical properties of 3d printed BTO/PDMS flexible porous composites

IF 2.6 4区 化学 Q3 POLYMER SCIENCE Journal of Polymer Research Pub Date : 2024-10-25 DOI:10.1007/s10965-024-04148-4
Yichen Hao, Jun Wang, Qian Wang, Jimin Chen, Yong Zeng
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Abstract

Flexible piezoelectric functional composite materials have the advantages of strong plasticity and good surface adhesion, and show great potential in smart wearable devices, electronic skin and other applications. However, due to the complexity of traditional preparation process, high molding cost and poor air permeability, its further development is limited. Direct ink writing (DIW) 3D printing technology is a rapid prototyping technology, with higher flexibility, faster manufacturing speed and lower manufacturing costs, is widely used in metal, ceramic and composite material molding. In this work, a ink system with polydimethylsiloxane (PDMS) as binder and barium titanate (BTO) ceramic powder as piezoelectric filler was developed, the printing work of flexible porous BTO/PDMS composite material was completed. DIW dual-nozzle printing technology was applied to realise “electrode-piezoelectric-electrode” integrated flexible porous functional gradient structure composites in this study. The results show that the BTO/PDMS ink has the characteristics of shear thinning. When the nozzle diameter is 0.5 mm, the printing speed is 650 mm/min, and the BTO mass fraction is 80%, the flexible porous piezoelectric composite with high precision and complex structure is printed. By phase analysis of BTO/PDMS, it is found that the sample has the characteristic peak of BTO. The microstructure analysis shows that the surface of the sample has good structural fidelity and there are a few island-like pores in the interior. The mechanical test shows that the maximum tensile strength of the sample is 1.33 MPa, the elastic modulus is 1.72 MPa, the longitudinal piezoelectric coefficient d33 is 4.37 Pc/N, and the open circuit voltage VOC is 3.17 V. This work demonstrates an attractive method of moulding flexible piezoelectric materials with an “electrode-piezoelectric-electrode” structure, which provides a reference to current 3D printing flexible material fabrication techniques due to its simplicity of operation, time and manufacturing cost savings.

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关于控制 3d 打印 BTO/PDMS 柔性多孔复合材料机械和电气性能的研究
柔性压电功能复合材料具有可塑性强、表面附着力好等优点,在智能可穿戴设备、电子皮肤等应用领域显示出巨大潜力。然而,由于传统制备工艺复杂、成型成本高、透气性差等原因,限制了其进一步发展。直接墨水写入(DIW)3D 打印技术是一种快速成型技术,具有更高的灵活性、更快的制造速度和更低的制造成本,被广泛应用于金属、陶瓷和复合材料的成型。本研究开发了以聚二甲基硅氧烷(PDMS)为粘结剂、钛酸钡(BTO)陶瓷粉末为压电填料的墨水系统,完成了柔性多孔BTO/PDMS复合材料的打印工作。本研究应用 DIW 双喷嘴印刷技术实现了 "电极-压电-电极 "一体化柔性多孔功能梯度结构复合材料。结果表明,BTO/PDMS 油墨具有剪切稀化的特性。当喷嘴直径为 0.5 mm、印刷速度为 650 mm/min、BTO 质量分数为 80% 时,可印刷出精度高、结构复杂的柔性多孔压电复合材料。通过对 BTO/PDMS 的相分析,发现样品具有 BTO 的特征峰。微观结构分析表明,样品表面具有良好的结构保真度,内部存在少量岛状孔隙。力学测试表明,样品的最大拉伸强度为 1.33 MPa,弹性模量为 1.72 MPa,纵向压电系数 d33 为 4.37 Pc/N,开路电压 VOC 为 3.17 V。这项工作展示了一种具有吸引力的 "电极-压电-电极 "结构柔性压电材料模塑方法,由于其操作简单、节省时间和制造成本,为当前的 3D 打印柔性材料制造技术提供了参考。
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来源期刊
Journal of Polymer Research
Journal of Polymer Research 化学-高分子科学
CiteScore
4.70
自引率
7.10%
发文量
472
审稿时长
3.6 months
期刊介绍: Journal of Polymer Research provides a forum for the prompt publication of articles concerning the fundamental and applied research of polymers. Its great feature lies in the diversity of content which it encompasses, drawing together results from all aspects of polymer science and technology. As polymer research is rapidly growing around the globe, the aim of this journal is to establish itself as a significant information tool not only for the international polymer researchers in academia but also for those working in industry. The scope of the journal covers a wide range of the highly interdisciplinary field of polymer science and technology, including: polymer synthesis; polymer reactions; polymerization kinetics; polymer physics; morphology; structure-property relationships; polymer analysis and characterization; physical and mechanical properties; electrical and optical properties; polymer processing and rheology; application of polymers; supramolecular science of polymers; polymer composites.
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