1. Material enhancement and modification
Polypropylene filter plates have made significant progress in material enhancement and modification. The introduction of TPE elastomer not only adds excellent elasticity and resilience to the filter plate, but also maintains good mechanical properties in high temperature environments. This modification allows the filter plate to more effectively resist deformation and cracking when subjected to high temperatures and pressures, thereby extending its service life. The use of alkali-free glass fiber polypropylene material significantly improves the rigidity and strength of the filter plate through the reinforcement of glass fiber. This composite material not only has higher heat resistance, but also maintains stable performance under extreme working conditions, ensuring the reliable operation of the filter plate under harsh working conditions.
2. Patented technical support
The research and development of graphite-modified reinforced polypropylene composite materials and filter plate technology is the key to achieving major breakthroughs in the temperature resistance of polypropylene filter plates. This patented technology not only improves the thermal conductivity and heat resistance of polypropylene, but also enhances its mechanical properties and corrosion resistance through the addition of graphite. The uniform distribution of graphite enables the composite material to maintain structural integrity and stability at high temperatures, thereby significantly improving the temperature resistance limit of the filter plate. The acquisition of these two national invention patents also fully proves the advancement and innovation of this technology in improving the performance of polypropylene filter plates.
3. Special flow channel design
The special flow channel design adopted by the polypropylene filter plate is another important means to increase the filtration speed and extend the service life. This design optimizes the flow channel structure and reduces fluid resistance, allowing the filter plate to quickly discharge water and impurities during the filtration process, improving filtration efficiency. Special flow channels also help reduce filter cake formation and accumulation, making cleaning and maintenance easier. The rational design of the flow channel also ensures that the filter plate will not leak and be damaged during high-speed water flow, thus improving the overall performance and reliability of the filter plate.
4. Manufacturing process upgrade
Upgrading the manufacturing process is also crucial to improving the performance of polypropylene filter plates. The high-pressure pressure molding process is used to manufacture the filter plate, which can ensure the compactness and uniformity of the internal structure of the filter plate and reduce internal defects and stress concentration points. This process also allows the filter plate to have higher dimensional accuracy and surface flatness, which is beneficial to reducing the retention and accumulation of fluid on the surface of the filter plate. The application of CNC machining technology has also further improved the processing accuracy and efficiency of filter plates. Using high-precision equipment such as CNC milling machines and CNC drilling machines to process and trim the filter plates can ensure that the size and shape of the filter plates meet the design requirements and improve the interchangeability and versatility of the filter plates. These manufacturing process upgrades have jointly promoted the overall improvement of polypropylene filter plates in terms of performance and quality.