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• High bond strength
• Excellent moisture, heat and high-temperature resistance
• Excellent insulation performance
• Good flexibility, high tensile strength

• Storage environment: Temperature 5–35℃, humidity 0–65%.
• Shelf life: 12 months;
• Transportation: This product is environmentally friendly and healthy, and should be transported as non-hazardous goods.

• Ceramicization Initiation Temperature and Effect: Understand the temperature at which the tape begins to undergo ceramicization and the fire-resistance limit after complete ceramicization (for example, whether it can withstand flame erosion at 1000℃ or higher). This directly determines its protective performance in the event of a fire.
• Flame-retardant rating: UL94 V-0 is one of the widely recognized high flame-retardant ratings and serves as an entry threshold for many application fields.

• Insulating performance: The volume resistivity and dielectric strength under normal conditions, as well as the retention rate of insulating performance after exposure to high temperatures or flame combustion, are critical. These factors directly determine whether short circuits can be avoided in the event of a fire, thereby ensuring the continuity and stability of electrical systems.
• Mechanical and Construction Performance: Flexibility and Tensile Strength—The tape must possess sufficient flexibility to facilitate wrapping and encasing objects of various shapes (such as wire harnesses and irregular components). At the same time, it needs to have adequate tensile strength and tear resistance to ensure that it does not easily get damaged during construction and can withstand certain mechanical stresses.
• Thickness and Size: Select the appropriate tape thickness and width based on the dimensions of the protected object and the required level of protection.
• Adhesiveness: Many flame-retardant ceramic tapes come with pressure-sensitive adhesives, so it’s important to consider their initial tack and holding power to ensure they can adhere firmly to various substrate surfaces (such as metals, plastics, and cable jackets) without peeling off.

• Chemical Corrosion Resistance: In certain industrial environments—such as chemical plants or automotive interiors—adhesive tapes may need to withstand the corrosive effects of chemicals like oils, coolants, and solvents.
• Environmental protection: Particularly in aerospace, rail transit, and indoor spaces with high population density, the smoke density and toxicity generated by material combustion during a fire are critical evaluation criteria. Halogen-free products should be selected.
• Weather resistance: When used outdoors or in environments with significant temperature fluctuations, it is necessary to consider its aging performance in terms of resistance to ultraviolet radiation, ozone, and cyclic exposure to high and low temperatures.

• Depending on the industry and application area, verify whether the product has obtained the necessary industry certifications, such as UL certification, RoHS, and REACH.
• In the automotive sector, it may be necessary to ensure compliance with relevant automotive standards; in the rail transit sector, attention should be paid to fire safety standards such as EN 45545.

• Surface Preparation: Before construction, ensure that the surface to be bonded is clean, dry, free of oil and grease, and free of dust to guarantee optimal adhesion.
• Construction method: Typically, wire harnesses are wrapped using a half-lap winding method (overlapping 50% of the tape width) to ensure complete coverage with no omissions.
• Environmental conditions: Pay attention to the temperature and humidity of the construction environment, as these factors may affect the adhesion performance and curing (if chemical reaction-based curing is involved) of certain tapes.

Ceramifiable composites are a class of advanced materials designed to provide exceptional fire resistance and thermal stability in high-temperature environments. These composites are formulated from a combination of polymers, fillers, and ceramic-forming additives that undergo a transformation when exposed to extreme heat, forming a stable ceramic-like layer on the surface. This ceramic layer serves as an effective barrier, protecting underlying structures from flames, heat, and thermal degradation. As such, ceramifiable composites have gained significant attention in industries such as construction, aerospace, electrical engineering, and transportation, where fire safety, thermal insulation, and material durability are critical requirements. By combining the flexibility and processability of polymers with the heat resistance of ceramics, these materials offer a unique balance of mechanical performance and thermal protection.

The functionality of ceramifiable composites lies in their unique chemical composition and reaction mechanisms. Under normal conditions, these materials behave like standard polymer composites, providing ease of fabrication, lightweight properties, and structural support. Upon exposure to high temperatures, typically exceeding 800–1000°C, the polymer matrix begins to decompose while the ceramic-forming fillers undergo sintering and phase transformation. This process results in the formation of a dense, cohesive ceramic layer that adheres to the surface of the material, insulating the substrate from further thermal damage. The effectiveness of ceramifiable composites depends on the type and proportion of ceramic fillers, the polymer matrix, and any synergistic additives incorporated into the formulation. Common ceramic fillers include silicates, aluminates, borates, and other refractory materials, which contribute to structural integrity, thermal insulation, and mechanical strength after transformation.

Applications of ceramifiable composites are diverse and increasingly vital for modern safety standards. In the construction sector, they are used in fireproof coatings for structural elements, cable insulation, and panels for high-risk environments such as tunnels, industrial plants, and public buildings. In aerospace and automotive industries, ceramifiable composites provide heat protection for engine components, exhaust systems, and protective panels, enhancing both safety and performance. Electrical and electronic applications benefit from these materials through the use of ceramifiable cable coatings, insulating layers, and protective housings that prevent fire propagation and maintain circuit integrity under extreme thermal conditions. Beyond industrial applications, ongoing research is exploring lightweight, multifunctional ceramifiable composites for next-generation fire-resistant materials that combine mechanical performance, flame retardancy, and environmental sustainability. The continued innovation in this field ensures that ceramifiable composites remain a cornerstone of high-performance, fire-safe, and thermally stable material solutions across industries.