增材制造压电陶瓷的现状与展望

doi:10.15541/jim20210599

无机材料学报 ›› 2022, Vol. 37 ›› Issue (3): 278-288.DOI: 10.15541/jim20210599 CSTR: 32189.14.10.15541/jim20210599

所属专题： 2022年度中国知网高下载论文

增材制造压电陶瓷的现状与展望

刘凯¹^,²(), 孙策², 史玉升³, 胡佳明², 张庆庆², 孙云飞², 章嵩⁴, 涂溶⁴, 闫春泽³, 陈张伟⁵, 黄尚宇², 孙华君¹()

1.武汉理工大学硅酸盐建筑材料国家重点实验室, 武汉 430070
2.武汉理工大学材料科学与工程学院, 武汉 430070
3.华中科技大学材料成形与模具技术国家重点实验室, 武汉 430074
4.武汉理工大学材料复合新技术国家重点实验室, 武汉 430070
5.深圳大学增材制造研究所, 深圳 518060

收稿日期:2021-09-28 修回日期:2021-11-21 出版日期:2022-03-20 网络出版日期:2021-12-24
通讯作者: 孙华君, 教授. E-mail: huajunsun@whut.edu.cn
作者简介:刘凯(1987-), 男, 副教授. E-mail: victor_liu@whut.edu.cn
基金资助:
国家重点研发计划(2021YFB3703100);国家自然科学基金(51672198);国家自然科学基金(U1806221);山东半岛国家自主创新示范区建设发展项目(2017-41-1);山东半岛国家自主创新示范区建设发展项目(2017-41-3);山东半岛国家自主创新示范区建设发展项目(2018ZCQZB01);山东半岛国家自主创新示范区建设发展项目(2019ZCQZB03);中央引导地方科技发展专项资金(2060503);山东省重点研发项目(2019GGX102011)

Current Status and Prospect of Additive Manufacturing Piezoceramics

LIU Kai¹^,²(), SUN Ce², SHI Yusheng³, HU Jiaming², ZHANG Qingqing², SUN Yunfei², ZHANG Song⁴, TU Rong⁴, YAN Chunze³, CHEN Zhangwei⁵, HUANG Shangyu², SUN Huajun¹()

1. State Key Laboratory of Silicate Materials for Architectures, Wuhan University of Technology, Wuhan 430070, China
2. College of Materials Science and Engineering, Wuhan University of Technology, Wuhan 430070, China
3. State Key Laboratory of Materials Processing and Die & Mould Technology, Huazhong University of Science and Technology, Wuhan, 430074, China
4. State Key Laboratory of Advanced Technology for Materials Synthesis and Processing, Wuhan University of Technology, Wuhan 430070, China
5. Additive Manufacturing Institute, Shenzhen University, Shenzhen 518060, China

Received:2021-09-28 Revised:2021-11-21 Published:2022-03-20 Online:2021-12-24
Contact: SUN Huajun, professor. E-mail: huajunsun@whut.edu.cn
About author:LIU Kai (1987-), male, associate professor. E-mail: victor_liu@whut.edu.cn
Supported by:
National Key Research and Development Plan(2021YFB3703100);National Natural Science Foundation of China(51672198);National Natural Science Foundation of China(U1806221);Instruction & Development Project for National Funding Innovation Demonstration Zone of Shandong Province(2017-41-1);Instruction & Development Project for National Funding Innovation Demonstration Zone of Shandong Province(2017-41-3);Instruction & Development Project for National Funding Innovation Demonstration Zone of Shandong Province(2018ZCQZB01);Instruction & Development Project for National Funding Innovation Demonstration Zone of Shandong Province(2019ZCQZB03);Special Funds for Guiding Local Scientific and Technological Development by the Central Government(2060503);Key Research & Design Program of Shandong Province(2019GGX102011)

摘要/Abstract

摘要：

压电陶瓷作为一类重要的功能陶瓷材料, 具备高强度、高硬度、耐腐蚀等优点, 可实现机械能和电能间的相互转换, 常被用于制备传感器、驱动器、电容器等压电器件, 在海洋探测、生物医疗、电子通讯等高端装备中发挥着重要作用。针对高端技术领域对压电功能器件智能化、集成化、轻量化的发展需求, 压电陶瓷的外形和结构越来越复杂。注浆、注射、模压、切割等传统的压电陶瓷制造工艺, 大多需借助模具或刀具完成, 很难甚至无法制造具有中空、悬垂等复杂结构的压电陶瓷, 制约了压电功能器件的进一步发展。增材制造技术基于逐层累加原理可实现任意复杂结构快速定制, 具有成型效率高、无需模具等优点, 可满足个性化、整体化、复杂化制造需求, 近年来受到国内外压电陶瓷领域研究人员的广泛关注。本文从粉体、浆料、块材三种原材料形态角度, 综述了当前增材制造压电陶瓷的主要工艺种类及发展现状, 综合对比了各种工艺成型特点; 介绍了增材制造压电陶瓷在不同领域的应用进展; 最后, 总结和展望了增材制造压电陶瓷所面临的挑战和未来可能的发展趋势。

关键词: 压电陶瓷, 增材制造, 工艺种类, 结构, 应用, 综述

Abstract:

As an important functional material, piezoelectric ceramics not only have the characteristics of high strength, high hardness, corrosion resistance, etc., but also can realize the mutual conversion between mechanical energy and electrical energy. Piezoelectric ceramics are widely used in sensors, drivers, capacitors and other piezoelectric parts, playing an important role in high-end equipment such as marine exploration, biomedicine, and electronic communications. The development requirements of intelligent, integrated, and lightweight piezoelectric functional devices in advanced technology fields have pushed their shape more and more complex. However, traditional fabricating processes, such as slip casting, injection molding, mould pressing, and machining, depend on molds or grinding tools. It is difficult to design and fabricate complex shape piezoelectric ceramics, especially with hollows and overhangs. Additive manufacturing technology can rapidly fabricate any complex structure parts based on the layer-by-layer fabricating principle with advantages of high molding efficiency and without molds. It can meet the needs of individualized, integration and complex manufacturing. In recent years, it has received extensive attention from researchers in the field of piezoelectric ceramics in both domestic and abroad. This article summarizes the main types of current additive manufacturing piezoelectric ceramics and their development status from the perspective of three raw material forms: powder, slurry and bulk materials, then comprehensively compares the characteristics of various processes. Application of additive manufacturing of piezoelectric ceramics in different fields has also been introduced. Finally, the challenges faced by additive manufacturing piezoelectric ceramics and the possible future development trends are summarized and prospected.

Key words: piezoceramic, additive manufacturing, process types, structure, application, review

中图分类号:

TB321

刘凯, 孙策, 史玉升, 胡佳明, 张庆庆, 孙云飞, 章嵩, 涂溶, 闫春泽, 陈张伟, 黄尚宇, 孙华君. 增材制造压电陶瓷的现状与展望[J]. 无机材料学报, 2022, 37(3): 278-288.

LIU Kai, SUN Ce, SHI Yusheng, HU Jiaming, ZHANG Qingqing, SUN Yunfei, ZHANG Song, TU Rong, YAN Chunze, CHEN Zhangwei, HUANG Shangyu, SUN Huajun. Current Status and Prospect of Additive Manufacturing Piezoceramics[J]. Journal of Inorganic Materials, 2022, 37(3): 278-288.

图/表 7

图1 增材制造压电陶瓷论文发表情况(SCI数据库)

Fig. 1 Papers published on additive manufacturing of piezoceramics (data from Web of Science) (a) Proportion of published literature of each process; (b) Number of papers published at each stage SLS: Selective laser sintering; BJ: Binder jetting; SLA: Stereolithography apparatus; IJP: Ink-jet printing; DLP: Digital light processing; DIW: Direct ink writing; FDM: Fused deposition modeling; LOM: Laminated object manufacturing

图2 黏结剂喷射技术成型晶格结构压电陶瓷[18]

Fig. 2 Piezoceramic with lattice structure formed by Binder Jetting[18] Left: Green body; Right: Sintering part

图3 分层曝光策略示意图(a)及烧结件微观形貌照片(b)[32], 数字光处理成型前驱体坯体照片(c)及烧结后的BTO样品照片(d)[35], 黏结剂喷射成型PZT陶瓷微阵列照片(e)[37]

Fig. 3 Schematic diagram of layered exposure strategy (a) and micro-topography photo of sintered part[32] (b), photo of precursor body fabricated by Digital Light Processing (c), photos of BTO sample after sintering[35] (d), photos of PZT ceramic microarrays fabricated by Binder Jetting[37] (e)

图4 不同烧结温度下PZT陶瓷微观形貌照片(a)及墨水直写成型PZT陶瓷烧结件照片(b)[41], 熔融沉积成型梯度压电陶瓷截面照片(c)[51,52]

Fig. 4 Micro-morphology photos of the PZT ceramics sintered at different temperatures (a) and photos of sintered PZT ceramics fabricated by Direct Ink Writing (b)[41], and cross-section photo of gradient piezoelectric ceramics fabricated by Fused Deposition Modeling (c)[51,52]

表1 增材制造压电陶瓷性能对比

Table 1 Comparison of properties of piezoceramics formed by additive manufacturing

Materials	Process	Density/(g·cm^-3)	Relative density/%	d₃₃/(pC·N^-1)	Relative dielectric constant (ε_r)	Dielectric loss (tan δ)	Ref.
BTO	SLS	-	97	-	1800	-	[7]
PZT	SLS	4	50.6	-	-	-	[12]
PZT	LENS	-	90	-	430	0.05	[14]
BTO	BJ	-	93-94	183	-	-	[18]
BTO	SLA	5.69	95	163	2762	0.016	[23]
BTO	DIW	5.13	85.24	204.61	2551	-	[44]
PZT	DIW	(7.21±0.06)	94.9	678	(4132±575)	(3.4±1%)	[45]
BTO	DIW	5.42	90	200	2200	-	[46]
BTO	DIW	-	89.97	350	2576	-	[47]
PLZT	DIW	-	98	481	1986	-	[48]
BCZT	DIW	-	93	100	1046	0.021	[49]
BTO	DIW	-	96	159	1900	-	[50]
BTO	BJ	2.21	37	113(Horizontal) 152.7(Vertical)	581.6(Horizontal) 698(Vertical)	-	[56]
KNN	SLA	4.32	96	-	1800-1900	0.2-0.3	[57]
PMN-PT	DLP	7.98	97.8	620	-	-	[58]
PZT	DLP	7	-	345	1390	0.021	[59]
KNN	DLP	4.09	92	170	2150	0.058	[60]
PZT-5H	DLP	7.35	96	600	2875	0.029	[61]
BTO	DLP	5.44	90	200	1965	0.017	[62]
PZT	IJP	-	(86±3)	-	190	0.05	[63]
BTO	DIW	3.93	65.3	200	4730	0.033	[64]
BTO	DIW	-	98	195	-	-	[65]
BTO	DIW	-	97.8	-	533	-	[66]
BTO	DIW	5.66	94	420	4380	0.02	[67]
PZT	FDM	7.7	-	664	3340	0.023	[68]

图5 黏结剂喷射成型BTO/HA压电陶瓷(a)及MC3T3-E1细胞24 h体外培养结果显微照片(b)[70], 数字光处理成型压电陶瓷照片及其压电复合材料(c), 水声测试装置及不同声激励频率下水听器的输出电压(d)[32], 数字光处理成型CPE样品照片(e)及其封装的超声扫描设备(f)和猪眼超声成像结果(g)[74]

Fig. 5 Photos of BTO/HA piezoelectric ceramics fabricated by Binder Jetting (a) and SEM images of the sample after 24 h MC3T3-E1 cells incubation (b)[70], piezoelectric ceramics and piezoelectric composite materials fabricated by Digital Light Processing (c), the underwater acoustic testing device and the output voltage of the hydrophone under different acoustic excitation frequencies (d) [32], the photo of CPE sample (e) and the packaged ultrasound scanning equipment (f), and pig eye ultrasound imaging results (g)[74]

图6 压电传感器示意图(a)及照片(b)[31]

Fig. 6 Schematic (a) and picture (b) of piezoelectric sensor device[31]

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增材制造压电陶瓷的现状与展望

Current Status and Prospect of Additive Manufacturing Piezoceramics

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