Polyurethane (PU) is a polymer material widely used in all walks of life, and is highly favored for its excellent mechanical properties, chemical resistance, wear resistance and processability. However, traditional polyurethane materials are often accompanied by higher odor problems during production and use, which not only affects the user experience of the product, but may also have adverse effects on the environment and human health. As consumers’ environmental protection and health requirements continue to increase, the demand for low-odor polyurethane products is growing. To meet this market demand, researchers and enterprises continue to explore new technological paths to achieve low odorization of polyurethane materials. <\/p>\n
Polyurethane delay catalyst 8154 (hereinafter referred to as “8154”) is a new catalyst, which shows excellent catalytic performance and low odor characteristics in the process of polyurethane synthesis, and has become one of the hot topics in recent years. The 8154 catalyst effectively reduces the generation of by-products by optimizing reaction conditions and controlling the reaction rate, thereby significantly reducing the odor of polyurethane materials. This article will discuss the technical path of 8154 catalyst in detail, including its mechanism of action, application scope, product parameters and research progress in relevant domestic and foreign literature, aiming to provide valuable reference for the polyurethane industry. <\/p>\n
8154 Catalyst is a delayed catalyst based on organometallic compounds, and its main component is an organic bismuth compound. Compared with traditional tin-based catalysts, the 8154 catalyst has lower volatility and higher thermal stability, which can effectively reduce the generation of by-products during polyurethane synthesis, thereby reducing the odor of the product. The following are the main mechanisms of action of the 8154 catalyst:<\/p>\n
The major feature of 8154 catalyst is its delayed catalytic effect. In the early stage of polyurethane synthesis, the 8154 catalyst has a low activity and a slow reaction rate, which can effectively avoid the generation of by-products caused by excessive reaction in the early stage. As the reaction temperature increases, the 8154 catalyst gradually activates, and the catalytic efficiency is significantly improved, promoting the reaction between isocyanate and polyol, and finally forming a polyurethane macromolecular chain. This delayed catalytic effect not only helps control the reaction rate, but also effectively reduces the volatile organic compounds (VOCs) generated during the reaction, thereby reducing the odor of the product. <\/p>\n
8154 catalyst has high selectivity and can preferentially catalyze the reaction between isocyanate and polyol, while the catalytic effect on other side reactions is weak. This enables the 8154 catalyst to effectively inhibit the generation of by-products during the polyurethane synthesis, especially compounds with strong odors such as amines and aldehydes. Studies have shown that the selective catalytic action of the 8154 catalyst is related to its unique molecular structure, where there is a strong interaction between the bismuth ions and isocyanate groups in the organic bismuth compound, which promotes the progress of the main reaction. <\/p>\n
8154 catalyst has excellent thermal stability and can maintain good catalytic activity at higher temperatures. Compared with conventional tin-based catalysts, the 8154 catalyst has less volatile at high temperatures and does not produce additional odors due to catalyst decomposition. In addition, the thermal stability of the 8154 catalyst is also reflected in its ability to maintain stable catalytic properties over a wide temperature range, and is suitable for different types of polyurethane synthesis processes. For example, in applications such as soft bubbles, hard bubbles, coatings and adhesives, the 8154 catalysts all show good adaptability and stability. <\/p>\n
Another important feature of the 8154 catalyst is its low toxicity. Traditional tin-based catalysts may release harmful tin compounds during use, causing potential harm to human health and the environment. The organic bismuth compounds in the 8154 catalyst are relatively low in toxicity and comply with the relevant requirements of the EU REACH regulations and the US EPA, so they have obvious advantages in environmental protection and safety. Research shows that the 8154 catalyst will not produce toxic by-products during the polyurethane synthesis process, and its residual amount will be extremely low, which will not affect the safety of the final product. <\/p>\n
8154 catalysts are widely used in various types of polyurethane products due to their unique performance characteristics. Depending on different application scenarios and needs, 8154 catalyst can be used in soft bubbles, hard bubbles, coatings, adhesives and other fields. The following are the specific manifestations of 8154 catalyst in different applications:<\/p>\n
Soft foam polyurethane is mainly used in furniture, mattresses, car seats and other fields, and the materials are required to have good elasticity and comfort. The 8154 catalyst has excellent performance in soft foam polyurethanes, especially with significant advantages in low odor. Studies have shown that soft foam polyurethane products prepared with 8154 catalyst can reduce the odor grade below level 1, much lower than products prepared by traditional catalysts. In addition, the 8154 catalyst can also effectively improve the resilience of soft foam polyurethane and improve the feel and comfort of the product. Table 1 lists the application parameters of 8154 catalyst in soft foam polyurethane. <\/p>\n
| parameters<\/th>\n | Unit<\/th>\n | 8154 Catalyst<\/th>\n | Traditional tin-based catalyst<\/th>\n<\/tr>\n | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
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| Odor level<\/td>\n | \u2013<\/td>\n | \u22641<\/td>\n | 3-4<\/td>\n<\/tr>\n | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Resilience<\/td>\n | %<\/td>\n | 70-80<\/td>\n | 60-70<\/td>\n<\/tr>\n | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Cell structure<\/td>\n | \u2013<\/td>\n | Details\ufffdAlternate<\/td>\n | Rough and uneven<\/td>\n<\/tr>\n | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Initial hardness<\/td>\n | N\/mm\u00b2<\/td>\n | 2.5-3.0<\/td>\n | 2.0-2.5<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n2. Hard foam polyurethane<\/h4>\nHard foam polyurethane is widely used in building insulation, refrigeration equipment and other fields, and requires the materials to have high strength and thermal insulation properties. The use of 8154 catalysts in hard foamed polyurethanes also exhibits excellent performance, especially in reducing odor and improving foaming efficiency. Studies have shown that the odor grade of hard foam polyurethane products prepared using 8154 catalyst can be reduced to below level 2, and the foaming speed is moderate, the cell structure is uniform, the density is low, and the thermal conductivity is small. Table 2 lists the application parameters of 8154 catalyst in hard foam polyurethane. <\/p>\n
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