A self-powered and self-monitoring ultra-low frequency wave energy harvester for smart ocean ranches.

The ocean ranch environment contains ultra-low-frequency wave energy that can be utilized for powering low-power equipment. Therefore, this article proposes a smart ocean ranch self-powered and self-monitoring system (SOR-SSS) which consists of several key components: a mass pendulum ball (MPB), a commutation wheel system (CWS), an electromagnetic energy harvesting unit (EEHU), and four piezoelectric energy harvesting units (PEHU). Through six-degree-of-freedom vibration test bench experiments, the SOR-SSS achieved a maximum output power of 17.56 mW under a working condition of 0.4 Hz, which was sufficient to power 152 LED lights. Additionally, by training the experimental base data using the LSTM algorithm, two different tasks were trained with a maximum accuracy of 99.72% and 99.80%, respectively. These results indicate that the SOR-SSS holds significant potential for collecting and predicting ultra-low-frequency blue energy. It can provide an effective energy supply and monitoring solution for smart ocean ranch.

A vibration energy harvester for freight train track self-powered application.

The safe and stable operation of the widely distributed freight trains urgently needs to solve the power supply problem of the freight train track monitoring network. In this article, an innovative and efficient energy harvesting mechanism is designed based on a mechanical vibration rectifier (MVR), with four modules of motion conversion, motion rectification, generator, and storage. The motion conversion module converts the linear vibration of the rail into rotational motion through the ball screw. The motion rectification module integrates mechanical rectification and transmission speed-up and converts the bidirectional rotation of the transmission shaft into a faster unidirectional rotation of the generator. Experiments show that the power and mechanical efficiency of the proposed vibration energy harvester can reach 28.0416W and 75.92%, respectively. This high-performance MVR can meet the power demand of wireless sensor networks by harvesting vibration energy to ensure the normal operation of freight trains.