Flexible and Self-Powered Thermal Sensor Based on Graphene-Modified Intumescent Flame-Retardant Coating with Hybridized Nanogenerators

The number of fire events that risk human life, the economy, and the environment has significantly increased in recent years. Uncontrolled fires are one of the main causes of building collapse. Due to the high smoke concentration threshold or infrared detection temperature required to activate the fire detector, the response time is long, and the fire warning and prevention effect are not ideal. For effective monitoring and early warning of fires, an innovative fire alarm system was fabricated in this study. This system combines a highly flexible and self-powered thermal sensor (FSTS) as well as a commercial light emitting diode (LED). The FSTS is a fire-retardant sensor and very easy to install. The innovation of this paper is the hierarchical structure of the FSTS. It combines a graphene-modified intumescent flame retardant (GIFR) flame-retardant coating layer with a self-powered PVDF-based nanogenerator, which shows an innovative design in the area of fire sensors. The structure integrates poly(vinylidenefluoride-co-trifluoroethylene) (PVDF-TrFE) micro/nano fibers (MNFs) deposited by a near-field electrospinning (NFES) process and an electrostatic friction layer by polydimethylsiloxane (PDMS) rolling over technology with a fully encapsulated GIFR coating. It can be used as a motion-induced energy harvester with a self-powered fire alarm system. The voltage output of the FSTS reaches 11.8 V, which can be easily matched with a bridge rectifier circuit to charge capacitors in daily life. The unique feature of the FSTS is that, at room temperature, the FSTS is electrically insulating; however, it conducts electricity at high temperatures. In a fire, high temperatures cause the coating to char and expand transitioning from an electrically insulating state to a conducting state. In this way, warning lights connected to the FSTS will respond within a short period (similar to 3 s), alerting people immediately so that urgent action can be taken.

Automated summary

The number of fire events has increased, posing risks to people, the economy, and the environment. Uncontrolled fires can lead to building collapse. To address this issue, an innovative fire alarm system was developed, comprising a flexible and self-powered thermal sensor (FSTS) and a commercial LED. The FSTS is fire-retardant and easy to install, with a hierarchical structure that includes a graphene-modified intumescent flame retardant coating and a self-powered PVDF-based nanogenerator.