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储能系统技术
★ 5.0
基于优化偏置的贝内特倍压-扩展转换器以增强摩擦纳米发电机的能量提取
Bennet's Doubler-Extended Converter With Optimized Bias for Enhanced Energy Extraction From Triboelectric Nanogenerators
| 作者 | Yirui Su · Youhua Shi |
| 期刊 | IEEE Transactions on Power Electronics |
| 出版日期 | 2025年5月 |
| 技术分类 | 储能系统技术 |
| 相关度评分 | ★★★★★ 5.0 / 5.0 |
| 关键词 | Bennet倍增器 摩擦纳米发电机 BD扩展电路 能量转换效率 输出增益 |
语言:
中文摘要
本内特倍增器(BD)通过在串联和并联配置之间切换两个存储电容器,并向摩擦纳米发电机(TENG)施加偏置电压,显著提高了摩擦纳米发电机的输出。然而,诸如阻抗匹配以及偏置电压过高导致的击穿风险等问题,会显著降低总输出能量,进而降低能量转换效率,并增加意外放电的风险。为解决这些问题,我们提出了一种具有双输出的BD扩展电路以改善性能。该设计不仅考虑了TENG器件的击穿电压,还能在自供电模式下提高能量提取效率。我们在1.5 Hz和3 Hz的激励频率下,结合负载电阻和直流负载对我们的电路进行了评估。在3 Hz时,我们的电路输出增益比现有最先进设计高出达2.43倍,且实现了53.49%的转换效率。此外,与全波整流器(FWR)的最大输出相比,输出增益在1.5 Hz时为7.67倍,在3 Hz时为6.75倍;与轻负载(100 KΩ)下的FWR输出相比,在1.5 Hz时为9506倍,在3 Hz时为2202倍。这些结果显著证明了我们的方法相对于现有整流器设计的有效性,为实现基于TENG的系统提供了一种有前景的途径。
English Abstract
Bennet's doubler (BD) significantly enhances the output of triboelectric nanogenerators (TENGs) by alternating two storage capacitors between series and parallel configurations and applying a bias voltage to the TENG. However, challenges, such as impedance matching and the risk of breakdown due to excessively high bias voltages, can significantly reduce overall output energy, thus decreasing energy conversion efficiency and increasing the risk of unintended electrical discharges. To address these issues, we propose a BD-extended circuit with dual outputs for performance improvement. This design not only considers the breakdown voltage of TENG devices but also enhances efficient energy extraction in a self-powered mode. We evaluated our circuit at excitation frequencies of 1.5 and 3 Hz with load resistance and dc load. At 3 Hz, the output gain with our circuit was up to 2.43 times greater than that achieved with state-of-the-art designs, and obtained the conversion efficiency of 53.49%. Moreover, output gains of 7.67× (at 1.5 Hz) and 6.75× (at 3 Hz) compared to the maximum output of the full-wave rectifier (FWR), and 9506× (at 1.5 Hz) and 2202× (at 3 Hz) those of FWRs at a light load with 100 K . These results significantly demonstrate our method's effectiveness over existing rectifier designs, presenting a promising approach for implementing TENG-based systems.
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SunView 深度解读
从阳光电源的业务视角来看,这项基于Bennet倍压器的摩擦纳米发电机(TENG)能量提取技术,为我们在分布式能源采集和微能量管理领域提供了新的技术储备方向。
该技术的核心价值在于显著提升了TENG的能量转换效率,在3Hz工作频率下实现53.49%的转换效率,相比全波整流器在轻载条件下获得高达9506倍的输出增益。这种突破性提升对我们储能系统的辅助供电和物联网监测节点具有实际意义。特别是在光伏电站和风电场的大规模部署中,可利用环境振动、风力摆动等机械能为传感器网络、无线监测设备提供自供电解决方案,降低运维成本。
从技术成熟度评估,该技术仍处于实验室验证阶段,距离工业化应用存在明显差距。主要挑战包括:TENG器件在实际环境中的耐久性和稳定性问题,低频激励(1.5-3Hz)限制了应用场景,以及与我们现有高压直流系统的接口兼容性需要深度优化。此外,论文中提到的击穿电压风险管控,与我们在逆变器和储能变流器中积累的高压防护技术存在协同空间。
战略机遇方面,这项技术可与我们的储能微网系统形成互补,特别是在偏远地区微电网和海上风电平台等场景,作为应急备用电源或传感网络的持续供电方案。建议跟踪该技术的工程化进展,评估在特定细分市场的试点应用可行性,同时关注其在氢能制储运环节振动能量回收的潜在价值。