Revolutionary Carbon Fiber Solution Boosts Traffic Monitoring

Abstract

Intelligent transportation systems (ITSs) are being investigated as potential solutions for traffic congestion. Triboelectric sensors (TESs) have gained prominence among ITS technologies owing to their efficiency and self-powered capabilities in detecting external changes through friction-generated electrical signals. Herein, a traffic monitoring system using a fiber-reinforced plastic-based TES (FRP-TES) is proposed, designed with high-strength and high-stiffness fiber-reinforced plastic (FRP) as the core material. FRP is a structural composite comprising high-strength fibers impregnated with engineering resin. When the surface of the epoxy, which has a charged layer, reacts with the charged tire, electrostatic induction occurs in the carbon fibers. By leveraging the principles of carbon and glass fiber/epoxy-reinforced infrastructure, along with corresponding electrical properties, we analyze electrical signals produced when a tire traverses the FRP-TES. We subject the FRP-TES to electrical durability and tensile tests to verify signal stability and mechanical properties (strength ≤ 1770.87 MPa, modulus ≤ 41.38 GPa). The analysis proposes an effective method for obtaining the tire position, movement direction, speed, and acceleration using paired FRP-TES units. The proposed approach achieves significant reduction in maximum errors (0.52 % in speed, 3.24 % in acceleration) with eight evenly spaced FRP-TES units in a 240 mm section. A larger FRP-TES is fabricated to demonstrate practicality for personal mobility. Incorporating FRP-TES units into road infrastructure can enhance structural stability while providing reliable real-time data for traffic monitoring, accident response, and prediction.

A breakthrough in traffic monitoring technology has been achieved by a research team, affiliated with UNIST. The team unveiled sensors that can monitor traffic and road conditions in real-time, while strengthening buildings and road structures. These advanced sensors, constructed from carbon fiber composites, enable applications in traffic condition monitoring, traffic accident detection, and traffic accident prediction through real-time tracking of vehicle position, speed, and acceleration.

Professor Young-Bin Park and his research team in the Department of Mechanical Engineering at UNIST developed a structural self-powered FRP-TES grid that exhibited superior electrical and structural stability compared to conventional TES systems. Experimental results revealed that the FRP, composed of carbon fibers, glass fibers, and epoxy, generated electrical energy as tires passed over it. Furthermore, even after subjecting the FRP-TES grid to 10,000 tire passes, no discernible voltage degradation was observed, and its mechanical properties exceeded those of conventional TES systems.

Carbon fiber composite sensors can detect the vehicle, and simultaneously reinforce the structure, enabling real-time monitoring and reinforcement of road infrastructure.

The fiber-reinforced plastic-based triboelectric sensors (FRP-TESs) can detect the vehicle, and simultaneously reinforce the surrounding infrastructure, allowing for real-time monitoring and reinforcement of road infrastructure.

Carbon fiber composites offer excellent mechanical properties, weighing about a quarter as much as iron and possessing 10 times greater strength. These composites are ideal for widespread use in various applications due to their advantages over traditional iron-based materials.

The team demonstrated the versatility of their technology by manufacturing a composite-based self-powered sensor on a large scale and verifying its effectiveness through a vehicle driving test. They also explored the use of friction charging principles, which enable the sensor to respond sensitively to environmental changes. By analyzing the changes in electrical signals generated by friction charging sensors, researchers can accurately track tire movement and calculate its size.

According to Dr. Seongwan Lee, the lead researcher, "Our self-powered sensor has great potential not only for monitoring traffic conditions but also for responding to and predicting traffic accidents." Professor Park added that the sensor's applications extend beyond academia, with potential uses in traffic volume management, vehicle weight and speed measurement, and industrial settings.

"Future research will aim to integrate the triboelectric mechanism of FRP with Structural Health Monitoring (SHM) using carbon fiber to implement intelligent infrastructure capable of traffic monitoring and structural health monitoring," noted the research team. "This advancement is expected to extend to various fields, including robotics."

The findings have been published online in Nano Energy on June 6, 2024, and were supported through the Mid-Career Researcher Project by the National Research Foundation of Korea (NRF).

Journal Reference

Seonghwan Lee and Young-Bin Park, "Self-powered triboelectric sensor based on a carbon fiber/glass fiber/epoxy structural composite for efficient traffic monitoring," Nano Energy, (2024).

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