基于共振自驱动的并联热磁发电机耦合效应

2021 21st International Conference on Solid-State Sensors, Actuators and Microsystems (Transducers) Pub Date : 2021-06-20 DOI:10.1109/Transducers50396.2021.9495569

J. Joseph, Mira Wehr, H. Miki, M. Ohtsuka, M. Kohl

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引用次数: 1

摘要

研究了并联运行的热磁发电机(TMGs)之间的交叉耦合对其动态性能和功率输出的影响。tmg是一种新兴的余热回收技术。在这里，TMG的操作依赖于安装在悬臂前部的Ni-Mn-Ga磁性形状记忆(MSMA)薄膜在居里温度下的磁化突然下降，以及由于薄膜的大表面体积比而导致的快速传热。为了提高功率输出，并行设计是非常必要的。当暴露在110-170°C的热源温度下时，每个悬臂梁的谐振自振荡在50-70 Hz范围内被激发，导致每个TMG的输出功率高达$30\ \text{mW}/\text{cm}^{3}$。在低Ts下，即使悬臂梁之间的距离$D$为0.4 mm，振荡也保持稳定，而在$\text{Ts}\ \geq\ 150^{\circ}\mathrm{C}$下，不稳定发生在$D=1$ mm以下，影响功率输出。

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Coupling Effects in Parallel Thermomagnetic Generators Based on Resonant Self-Actuation

We investigate the cross coupling between parallel operating thermo-magnetic generators (TMGs) on their dynamic performance and power output. TMGs are an emerging technology for waste heat recovery. Here, TMG operation relies on the abrupt drop of magnetization at the Curie temperature of a magnetic shape memory (MSMA) film of Ni-Mn-Ga mounted at the front of a cantilever and on rapid heat transfer due to the film's large surface-to-volume ratio. Parallel designs are highly demanded to increase power output. When exposed to heat source temperatures Ts of 110-170 °C, resonant self-oscillation of each cantilever is excited in the range of 50-70 Hz resulting in a power output up to $30\ \text{mW}/\text{cm}^{3}$ for each TMG. At low Ts, oscillations remain stable even for a small distance $D$ of 0.4 mm between cantilevers, while at $\text{Ts}\ \geq\ 150^{\circ}\mathrm{C}$, instabilities occur below $D=1$ mm affecting power output.

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2021 21st International Conference on Solid-State Sensors, Actuators and Microsystems (Transducers)

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