The double-edged sword of flame retardants in building cables: fire suppression vs. arc hazard amplification

With the rapid development of modern industrial technology, the demand for power in building electrical equipment continues to rise, rendering the existing rated current standards for cables inadequate to meet actual needs. Frequent overcurrent phenomena lead to abnormal temperature rise in cables, which has become the main cause of major electrical fire accidents. To effectively enhance the related fire resistance, flame retardants are added to the insulating materials of cables. In this study, the dual role of flame retardants in PVC-sheathed building cables is investigated, focusing on their fire-suppression capabilities and potential amplification of arc hazards under overcurrent conditions. Through TG-FTIR analysis and cone calorimeter tests, it is revealed that flame retardants effectively improve the fire resistance of insulating materials by delaying thermal degradation, generating HCl earlier to dilute flammable gases, and forming a protective carbon layer. However, by systematically investigating the fault characteristics of flame-retardant (FR) and non-flame-retardant (NFR) PVC-sheathed cables under different overcurrent conditions, combined with real-time oscilloscope monitoring data, two typical types of failure modes of PVC-sheathed cables in electrical fires are identified. In addition, comparing with that observed in NFR PVC-sheathed cables, the increase of the energy of the arc and an extension of the duration of the arc in FR PVC-sheathed cables are also observed for the same failure mode. All these facts can be attributed to the coating effect of metal chlorides and metal oxides, which inadvertently facilitates wires to be closer to each other and intensifies arc formation. This study not only emphasizes the need for a comprehensive evaluation system for the selection of flame retardants, which assesses both FR performance and impact on electrical faults, but also highlights the importance of a multi-layered defense strategy in electrical fire safety, combining FR materials with arc prevention to reduce fire risks in buildings.