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基于宽带振动的频率上变频无线传感器应用能量收集。

Broadband Vibration-Based Energy Harvesting for Wireless Sensor Applications Using Frequency Upconversion.

机构信息

Department of Mechanical, Aerospace, and Nuclear Engineering, Rensselaer Polytechnic Institute, Troy, NY 12180, USA.

Department of Microsystems, University of South-Eastern Norway, 3184 Borre, Norway.

出版信息

Sensors (Basel). 2023 Jun 2;23(11):5296. doi: 10.3390/s23115296.

DOI:10.3390/s23115296
PMID:37300023
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10256111/
Abstract

Silicon-based kinetic energy converters employing variable capacitors, also known as electrostatic vibration energy harvesters, hold promise as power sources for Internet of Things devices. However, for most wireless applications, such as wearable technology or environmental and structural monitoring, the ambient vibration is often at relatively low frequencies (1-100 Hz). Since the power output of electrostatic harvesters is positively correlated to the frequency of capacitance oscillation, typical electrostatic energy harvesters, designed to match the natural frequency of ambient vibrations, do not produce sufficient power output. Moreover, energy conversion is limited to a narrow range of input frequencies. To address these shortcomings, an impacted-based electrostatic energy harvester is explored experimentally. The impact refers to electrode collision and it triggers frequency upconversion, namely a secondary high-frequency free oscillation of the electrodes overlapping with primary device oscillation tuned to input vibration frequency. The main purpose of high-frequency oscillation is to enable additional energy conversion cycles since this will increase the energy output. The devices investigated were fabricated using a commercial microfabrication foundry process and were experimentally studied. These devices exhibit non-uniform cross-section electrodes and a springless mass. The non-uniform width electrodes were used to prevent pull-in following electrode collision. Springless masses from different materials and sizes, such as 0.5 mm diameter Tungsten carbide, 0.8 mm diameter Tungsten carbide, zirconium dioxide, and silicon nitride, were added in an attempt to force collisions over a range of applied frequencies that would not otherwise result in collisions. The results show that the system operates over a relatively wide frequency range (up to 700 Hz frequency range), with the lower limit far below the natural frequency of the device. The addition of the springless mass successfully increased the device bandwidth. For example, at a low peak-to-peak vibration acceleration of 0.5 g (peak-to-peak), the addition of a zirconium dioxide ball doubled the device's bandwidth. Testing with different balls indicates that the different sizes and material properties have different effects on the device's performance, altering its mechanical and electrical damping.

摘要

基于硅的动能转换器采用可变电容器,也称为静电振动能量收集器,有望成为物联网设备的电源。然而,对于大多数无线应用,如可穿戴技术或环境和结构监测,环境振动通常处于相对较低的频率(1-100 Hz)。由于静电收集器的功率输出与电容振荡的频率成正比,因此为匹配环境振动的固有频率而设计的典型静电能量收集器不会产生足够的功率输出。此外,能量转换仅限于输入频率的窄范围。为了解决这些缺点,实验探索了基于冲击的静电能量收集器。冲击是指电极碰撞,它触发频率上变频,即与调谐到输入振动频率的初级器件振荡重叠的电极的二次高频自由振荡。高频振荡的主要目的是实现额外的能量转换周期,因为这将增加能量输出。所研究的器件使用商业微制造铸造工艺制造,并进行了实验研究。这些器件具有非均匀横截面电极和无弹簧质量。非均匀宽度的电极用于防止电极碰撞后的拉入。不同材料和尺寸的无弹簧质量,如 0.5 毫米直径碳化钨、0.8 毫米直径碳化钨、二氧化锆和氮化硅,被添加到系统中,试图在不会导致碰撞的应用频率范围内强制碰撞。结果表明,该系统在相对较宽的频率范围内(高达 700 Hz 频率范围)运行,下限远低于器件的固有频率。无弹簧质量的添加成功地增加了器件带宽。例如,在低峰峰值振动加速度为 0.5 g(峰峰值)的情况下,添加二氧化锆球将器件的带宽增加了一倍。使用不同球的测试表明,不同的尺寸和材料特性对器件的性能有不同的影响,改变了其机械和电气阻尼。

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