Litcius/Paper detail

A near-zero quiescent power breeze wake-up anemometer based on a rolling-bearing triboelectric nanogenerator

Xian Fu, Zhichao Jiang, Jie Cao, Zefang Dong, Guoxu Liu, Meiling Zhu, Chi Zhang

2024Microsystems & Nanoengineering22 citationsDOIOpen Access PDF

Abstract

Wind sensors have always played an irreplaceable role in environmental information monitoring and are expected to operate with lower power consumption to extend service lifetime. Here, we propose a breeze wake-up anemometer (B-WA) based on a rolling-bearing triboelectric nanogenerator (RB-TENG) with extremely low static power. The B-WA consists of two RB-TENGs, a self-waking-up module (SWM), a signal processing module (SPM), and a wireless transmission unit. The two RB-TENGs are employed for system activation and wind-speed sensing. Once the ambient wind-speed exceeds 2 m/s, the wake TENG (W-TENG) and the SWM can wake up the system within 0.96 s. At the same time, the SPM starts to calculate the signal frequency from the measured TENG (M-TENG) to monitor the wind speed with a sensitivity of 9.45 Hz/(m/s). After the wind stops, the SWM can switch off the B-WA within 0.52 s to decrease the system energy loss. In quiescent on-duty mode, the operating power of the B-WA is less than 30 nW, which can greatly extend the service lifetime of the B-WA. By integrating triboelectric devices and rolling bearings, this work has realized an ultralow quiescent power and self-waked-up wireless wind-speed monitoring system, which has foreseeable applications in remote weather monitoring, IoT nodes, and so on.

Topics & Concepts

Triboelectric effectAnemometerNanogeneratorWakeWind speedElectrical engineeringWind powerRadio frequencySIGNAL (programming language)Power (physics)Bearing (navigation)AcousticsEngineeringPhysicsComputer scienceVoltageMeteorologyAerospace engineeringProgramming languageQuantum mechanicsAstronomyAdvanced Sensor and Energy Harvesting MaterialsTactile and Sensory InteractionsAdvanced Fiber Optic Sensors