Hot-Wire Anemometer Based on D-Shaped Optical Fiber

This article proposes a hot-wire anemometer based on optical fiber embedding a fiber Bragg grating (FBG) and having a D-shaped transversal Section on whose flat surface a thin metallic layer has been deposited. Due to this geometrical structure, the optical power flowing through the fiber core can achieve the metallic layer and can be converted into heat. The embedded FBG can measure the resulting temperature increase and the temperature fluctuation of the D-fiber caused by the wind flowing. Numerical simulations have been performed in order to select the appropriate design parameters, such as thickness of the metallic layer and its distance from the core. Then, the fabrication process of the device and the experimental results of its characterization in temperature and wind assess its working principle. The developed sensor can work at low power levels of the source and is characterized by small size and high accuracy. Furthermore, it shows high cost-effectiveness and the possibility to modulate its wind sensitivity by setting the source power.

Automated summary

This article proposes a hot-wire anemometer based on an optical fiber with a fiber Bragg grating (FBG) and a D-shaped transversal section with a thin metallic layer. The embedded FBG can measure the temperature increase and fluctuation caused by the wind flowing. Numerical simulations were performed to determine the appropriate design parameters, and the device was fabricated and tested to validate its working principle. The developed sensor has low power requirements, small size, high accuracy, cost-effectiveness, and adjustable wind sensitivity.