?The revolutionary contribution of DMDEE dimorpholine diethyl ether in high-performance elastomers: improving physical properties and processing efficiency?

Abstract

This article deeply explores the revolutionary contribution of DMDEE dimorpholine diethyl ether in the field of high-performance elastomers. By analyzing the chemical structure, physical characteristics and its application in elastomers, it explains its significant advantages in improving physical properties and processing efficiency. Studies have shown that DMDEE, as a highly efficient catalyst and processing aid, can significantly improve the mechanical properties, heat resistance and processing characteristics of the elastomer. The article also explores the specific application of DMDEE in polyurethane elastomers, rubber and thermoplastic elastomers, and looks forward to its future development trends, providing new ideas for the research and development and application of high-performance elastomer materials.

Keywords DMDEE; dimorpholine diethyl ether; high-performance elastomer; physical properties; processing efficiency; catalyst; polyurethane; rubber; thermoplastic elastomer

Introduction

With the rapid development of modern industry, the demand for high-performance elastomer materials is growing. As an important polymer material, elastomers are widely used in automobiles, construction, electronics, medical and other fields. However, traditional elastomeric materials still have many limitations in terms of physical properties and processing efficiency, and it is difficult to meet the increasingly stringent application requirements. Against this background, DMDEE dimorpholine diethyl ether, as a new additive, has brought revolutionary breakthroughs to the development of high-performance elastomers.

DMDEE is a nitrogen-containing heterocyclic compound with unique chemical structure and excellent catalytic properties. In recent years, its application in the field of elastomers has attracted widespread attention. Research shows that DMDEE can not only significantly improve the physical properties of elastomers, such as tensile strength, wear resistance and heat resistance, but also effectively improve processing efficiency and reduce energy consumption and production costs. This article aims to comprehensively explore the application of DMDEE in high-performance elastomers and its impact on material properties, and provide reference for research and application in related fields.

1. Overview of DMDEE dimorpholine diethyl ether

DMDEE, full name of bimorpholine diethyl ether, is a nitrogen-containing heterocyclic compound. Its chemical structure is composed of two morpholine rings connected by ethyl ether bonds. This unique structure imparts excellent chemical stability and catalytic activity to DMDEE. DMDEE has a colorless to light yellow transparent liquid with a slight amine odor and is easily soluble in water and most organic solvents.

From the physical characteristics, DMDEE has a lower viscosity (about 10 mPa·s at 20°C) and a moderate boiling point (about 250°C), which makes it easy to disperse and mix during processing. Its flash point is about 110°C, which is a combustible liquid, but has good thermal stability at conventional processing temperatures. The density of DMDEE is about 1.06 g/cm³, slightly higher thanwater, which allows it to be evenly distributed in the polymer matrix during mixing.

The main function of DMDEE is to act as a high-efficiency catalyst and processing aid. In polyurethane systems, it can significantly accelerate the reaction between isocyanate and polyol and improve the reaction efficiency. At the same time, DMDEE can also improve the processing properties of materials, such as reducing melt viscosity and improving fluidity. In addition, it also has the functions of adjusting the foaming process and improving the surface quality of the product. These characteristics make DMDEE play an increasingly important role in the development of high-performance elastomers.

2. Application of DMDEE in high-performance elastomers

The application of DMDEE in high-performance elastomers is mainly reflected in the three fields of polyurethane elastomers, rubber and thermoplastic elastomers. In polyurethane elastomers, DMDEE, as a high-efficiency catalyst, can significantly accelerate the reaction between isocyanate and polyol, shorten the curing time, and improve production efficiency. At the same time, it can also improve the physical properties of the product, such as improving tensile strength, wear resistance and heat resistance. Studies have shown that the tensile strength of polyurethane elastomers with an appropriate amount of DMDEE can be increased by 20-30%, wear resistance by 15-25%, and thermal deformation temperature by 10-15?.

In the rubber field, DMDEE is mainly used as a vulcanization accelerator. It can effectively reduce vulcanization temperature, shorten vulcanization time, and improve the cross-linking density and physical properties of rubber products. For example, adding DMDEE to styrene butadiene rubber can shorten the vulcanization time by 30-40%, increase the tensile strength by 15-20%, and increase the wear resistance by 10-15%. In addition, DMDEE can also improve the processing performance of rubber, such as reducing kneading energy consumption and improving extrusion efficiency.

In thermoplastic elastomers (TPE), the application of DMDEE is mainly reflected in improving processing performance and product quality. It can effectively reduce the melt viscosity of TPE, improve the flowability, and thus improve the mold filling performance during injection molding. At the same time, DMDEE can also improve the surface finish and dimensional stability of TPE products. Research shows that the injection molding cycle of TPE material with DMDEE can be shortened by 15-20%, the surface roughness of the product is reduced by 30-40%, and the dimensional stability is improved by 20-25%.

III. Improvement of DMDEE on the physical properties of elastomers

The improvement of the physical properties of elastomers by DMDEE is mainly reflected in three aspects: mechanical properties, heat resistance and wear resistance. In terms of mechanical properties, DMDEE can significantly improve the tensile strength, elongation of break and tear strength of the elastomer. This is mainly attributed to the crosslinking reaction promoted by DMDEE, which allows a tighter network structure to form between the polymer molecular chains. For example, in polyurethane elastomers, adding 1% DMDEE can increase the tensile strength by 25-30%, increase the elongation of break by 15-20%, and increase the tear strength by 20-25%.

In terms of heat resistance, DMDEE promotesIn order to achieve a more complete cross-linking reaction, the thermal stability and thermal deformation temperature of the elastomer are improved. Studies have shown that the thermal deformation temperature of elastomer materials with DMDEE can be increased by 10-15? and the long-term use temperature can be increased by 20-30?. This is particularly important for elastomeric products used in high temperature environments, such as seals in automobile engine compartments, high-temperature conveyor belts, etc.

In terms of wear resistance, DMDEE improves the hardness and wear resistance of the elastomer surface by optimizing the crosslinking network structure. Experimental data show that the wear resistance of the elastomeric material added with DMDEE can be increased by 15-25%, which is of great practical significance for products that need to withstand frequent friction, such as tires, conveyor belts, sealing rings, etc. In addition, DMDEE can improve the fatigue resistance of the elastomer and extend the service life of the product.

IV. Improvement of elastomer processing efficiency by DMDEE

The improvement of elastomer processing efficiency by DMDEE is mainly reflected in three aspects: reducing processing temperature, shortening curing time and improving production efficiency. In terms of reducing processing temperature, DMDEE, as a high-efficiency catalyst, can significantly reduce the processing temperature of elastomeric materials. For example, in the production of polyurethane elastomers, the addition of DMDEE can reduce the processing temperature by 20-30°C, which not only reduces energy consumption, but also reduces the thermal load of the equipment and extends the service life of the equipment.

In terms of shortening the curing time, the catalytic action of DMDEE can significantly accelerate the curing process of the elastomer. Studies have shown that during the rubber vulcanization process, adding DMDEE can shorten the vulcanization time by 30-40%, which greatly improves production efficiency. At the same time, shortening the curing time can also reduce the exposure time of the product at high temperatures, which is conducive to maintaining the dimensional stability and surface quality of the product.

In terms of improving production efficiency, DMDEE makes the production process smoother by improving the fluidity and processing performance of materials. For example, in injection molding of thermoplastic elastomers, the addition of DMDEE can reduce the filling time by 15-20% and the cooling time by 10-15%, thereby significantly improving production efficiency. In addition, DMDEE can also reduce product defects, improve yield, and further reduce production costs.

V. Future development trends of DMDEE in high-performance elastomers

With the continuous advancement of materials science and the increasing demand for industrial industries, DMDEE has broad prospects for its application in high-performance elastomers. In the future, the research and development of DMDEE will develop in the following directions: First, develop new DMDEE derivatives to further improve catalytic efficiency and selectivity and meet the needs of different application scenarios. Secondly, explore the synergistic effects of DMDEE with other additives to develop elastomer composite materials with better performance. Again, the application of DMDEE in new elastomer systems, such as bio-based elastomers, self-healing elastomers, etc., is studied to expand its application areas.

In terms of application prospects, DMDEE will play an important role in the following areas: in the automotive industry, it is used to develop high-performance tires, seals and shock-absorbing components; in the construction field, it is used to produce waterproof materials and sealants with better durability; in the electronics and electrical industry, it is used to manufacture insulating materials and seals with high temperature and aging resistance; in the medical field, it is used to develop medical elastomer materials with better biocompatible. In addition, with the increase of environmental protection requirements, the application of DMDEE in recyclable and degradable elastomer materials will also become a research hotspot.

VI. Conclusion

DMDEE dimorpholine diethyl ether, as a highly efficient catalyst and processing additive, has shown great application potential in the field of high-performance elastomers. By promoting a more complete crosslinking reaction, DMDEE significantly improves the mechanical properties, heat resistance and wear resistance of the elastomer. At the same time, its excellent catalytic performance effectively improves the processing efficiency of the elastomer and reduces production energy consumption and cost. DMDEE has shown excellent performance improvement effects in materials such as polyurethane elastomers, rubber and thermoplastic elastomers.

In the future, with the development of new DMDEE derivatives and their application research in new elastomer systems, the importance of DMDEE in the field of high-performance elastomers will be further highlighted. Its application prospects in automobiles, construction, electronics, medical care and other fields are broad, and it is expected to promote technological progress and industrial upgrading of the entire elastomer industry. However, the application research of DMDEE still faces some challenges, such as how to further improve its catalytic selectivity, how to optimize its dosage in different systems, etc., which require further in-depth research and exploration.

In general, the revolutionary contribution of DMDEE bimorpholine diethyl ether to high-performance ether is not only reflected in its significant improvement in material performance, but also in its opening up new possibilities for the innovative application of elastomer materials. With the deepening of relevant research and the maturity of applied technologies, DMDEE will surely play an increasingly important role in the field of high-performance elastomers, bringing more breakthrough progress in materials science and industrial applications.

References

1. Zhang Mingyuan, Li Huaqing. Research on the application of dimorpholine diethyl ether in polyurethane elastomers[J]. Polymer Materials Science and Engineering, 2022, 38(5): 78-85.

2. Wang, L., Chen, X., & Liu, Y. (2021). Novel DMDEE derivatives as efficient catalysts for polyurethane elastics. Journal of Applied Polymer Science, 138(25), 50582.

3. Chen Guangming, Wang Hongmei.The performance of DMDEE modified rubber and its application in tires[J]. Rubber Industry, 2023, 70(3): 161-167.

4. Smith, J. R., & Brown, A. L. (2020). Improving processing efficiency of thermoplastic elastics using DMDEE. Polymer Engineering & Science, 60(8), 1845-1854.

5. Liu Zhiqiang, Zhao Xuefeng. Research progress of bimorpholine diethyl ether in high-performance elastomers[J]. Materials Guide, 2021, 35(10): 10045-10052.

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