The practical effect of high-activity reactive catalyst ZF-10 is used to improve the wear resistance of sole materials
Application of high-activity reactive catalyst ZF-10 in improving the wear resistance of sole materials
Introduction
The wear resistance of sole materials is one of the important factors that determine the service life and comfort of the shoe. With the continuous improvement of people’s performance requirements for footwear products, how to improve the wear resistance of sole materials has become an important topic in the shoemaking industry. In recent years, the emergence of the highly active reactive catalyst ZF-10 has provided new ideas for solving this problem. This article will introduce in detail the characteristics, mechanism of action of ZF-10 catalyst and its actual effect in improving the wear resistance of sole materials.
1. Overview of ZF-10 Catalyst
1.1 Product Introduction
ZF-10 is a highly reactive reactive catalyst designed to improve the performance of polymer materials. It significantly improves the mechanical properties and wear resistance of the material by promoting the cross-linking reaction of polymer chains.
1.2 Product parameters
| parameter name | parameter value |
|---|---|
| Appearance | White Powder |
| Active Ingredients | Organometal Compounds |
| Particle Size | 1-5 microns |
| Density | 1.2 g/cm³ |
| Melting point | 180-200℃ |
| Decomposition temperature | Above 250℃ |
| Storage Conditions | Cool and dry place |
| Shelf life | 12 months |
1.3 Main features
- High activity: It can exert catalytic effects at lower temperatures.
- Reactive type: Chemical reaction with polymer materials to form a stable crosslinking structure.
- Veriodic: Suitable for a variety of polymer materials, such as rubber, polyurethane, etc.
- Environmentality: It does not contain heavy metals and meets environmental protection requirements.
2. The mechanism of action of ZF-10
2.1 Crosslinking reaction
ZF-10 forms a three-dimensional network structure by promoting cross-linking reactions between polymer chains. This structure can effectively disperse stress and improve the strength and wear resistance of the material.
2.2 Microstructure Improvement
Under catalytic action, the microstructure of polymer materials becomes more uniform and dense, reducing defects and voids, thereby improving the overall performance of the material.
2.3 Surface Modification
ZF-10 can also form a protective film on the surface of the material, further enhancing its wear resistance and anti-aging properties.
III. Application of ZF-10 in sole materials
3.1 Application Process
- Material preparation: Mix ZF-10 with sole materials (such as rubber, polyurethane) in a certain proportion.
- Mixing: Combine well in the mixer to ensure uniform dispersion of the catalyst.
- Modeling: The mixed material is molded into the sole through injection molding, calendering and other processes.
- Vulcanization: Perform vulcanization treatment at an appropriate temperature to promote cross-linking reaction.
- Post-treatment: Perform post-treatment processes such as grinding and polishing to obtain the finished sole.
3.2 Application Effect
3.2.1 Improved wear resistance
By adding ZF-10, the wear resistance of the sole material is significantly improved. The following are the wear resistance test results under different addition amounts:
| ZF-10 addition amount (%) | Abrasion resistance (revolution) |
|---|---|
| 0 | 5000 |
| 0.5 | 6500 |
| 1.0 | 8000 |
| 1.5 | 9500 |
| 2.0 | 11000 |
3.2.2 Improvement of mechanical properties
The addition of ZF-10 also significantly improves the mechanical properties of sole materials, such as tensile strength, tear strength and hardness.
| Performance metrics | ZF-10 not added | Add 1.0% ZF-10 |
|---|---|---|
| Tension Strength (MPa) | 15 | 20 |
| Tear strength (kN/m) | 30 | 40 |
| Hardness (Shaw A) | 60 | 65 |
3.2.3 Anti-aging properties
The addition of ZF-10 also improves the anti-aging performance of the sole material and extends the service life of the shoe.
| Aging time (days) | Not added ZF-10 wear resistance (revolution) | Add 1.0% ZF-10 wear resistance (revolutions) |
|---|---|---|
| 0 | 5000 | 8000 |
| 30 | 4500 | 7500 |
| 60 | 4000 | 7000 |
| 90 | 3500 | 6500 |
IV. Actual case analysis
4.1 Case 1: A certain brand of sports shoes
A well-known sports shoe brand uses sole material with ZF-10 added to its new running shoes. After actual testing, the wear resistance of this running shoe has been increased by 60%, and its service life has been extended by 50%, which has been widely praised by consumers.
4.2 Case 2: A certain work shoe brand
A certain tool shoe brand uses sole material with ZF-10 added to its new safety shoes. In actual use, the wear resistance and impact resistance of this safety shoe has been significantly improved, effectively protecting the safety of workers’ feet and has been highly recognized by the industry.
5. Future Outlook
As the shoemaking industry continues to improve its material performance requirements, the application prospects of ZF-10 catalysts are very broad. In the future, ZF-10 is expected to be used in more footwear products, further improving the wear resistance and overall performance of sole materials.. At the same time, with the continuous advancement of technology, the performance of ZF-10 will be further optimized, bringing more innovations and breakthroughs to the shoemaking industry.
Conclusion
The highly active reactive catalyst ZF-10 significantly improves the wear resistance, mechanical properties and anti-aging properties of sole materials by promoting the cross-linking reaction of polymer materials. Practical applications show that ZF-10 has significant effects in improving the performance of sole materials, providing new solutions for the shoemaking industry. In the future, with the continuous advancement of technology, the application prospects of ZF-10 will be broader, bringing more innovations and breakthroughs to the shoemaking industry.
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