The development of a valveless piezoelectric micropump

2010 26th Annual IEEE Semiconductor Thermal Measurement and Management Symposium (SEMI-THERM) Pub Date : 2010-04-08 DOI:10.1109/STHERM.2010.5444312

H. K. Ma, B. R. Chen

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引用次数: 3

Abstract

Previous studies have indicated that the performance of the micropump is influenced by the driving voltage, frequency, valves, and pump chambers. In this study, an innovative one-side actuating valveless micropump is proposed and developed to actuate liquid in one direction with high flow rates and pump heads. The three-dimensional, transition numerical models of the micropumps were also employed to predict its performance. It was found that the inlet choking phenomenon was the major reason to make the one-side actuating micropump valve-free, with a flow rate of 0.088 mL/s and a pump head of 45.6 Pa. By adding the secondary chamber, the performance can be improved to 0.989 mL/s and 1291.0 Pa. The maximum pump head in this study was obtained at 1522.5 Pa by using the 0.3-mm-thick secondary diaphragm. In addition, the performance of the micropump can be further improved by adding a nozzle/diffuser element, thus enabling it to achieve the maximum flow rate of 1.133 mL/s at the frequency of 150 Hz. Without additional check valves, the one-side actuating piezoelectric valveless micropump with compact design can perform more accurately and reliably in the applications of biomedical and electronics cooling.

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无阀压电微泵的研制

以往的研究表明，微泵的性能受驱动电压、频率、阀和泵腔的影响。在本研究中，提出并开发了一种创新的单侧驱动无阀微泵，可以在一个方向上以高流量和泵扬程驱动液体。利用三维跃迁数值模型对微泵的性能进行了预测。结果表明，进口堵塞现象是导致单侧微泵无阀的主要原因，流量为0.088 mL/s，泵扬程为45.6 Pa。通过增加二级腔室，可将性能提高到0.989 mL/s和1291.0 Pa。采用0.3 mm厚的二次隔膜，本研究的最大泵扬程为1522.5 Pa。此外，通过增加喷嘴/扩散器元件，可以进一步提高微泵的性能，使其在150 Hz频率下达到1.133 mL/s的最大流量。无需额外的止回阀，设计紧凑的单侧驱动压电无阀微泵可以在生物医学和电子冷却应用中更准确可靠地执行。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2010 26th Annual IEEE Semiconductor Thermal Measurement and Management Symposium (SEMI-THERM)

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