Sintered metal powder filter elements are advanced filter components that have undergone the meticulous process of sintering. This technique enhances their porosity, enabling their versatile use in applications ranging from liquid and gas filtration to gas/liquid flow regulation and ventilation tasks. Distinguished from alternative filter materials like glass fiber, stainless steel wire mesh, ceramics, and filter paper, sintered metal filters exhibit superior mechanical and compressive strength. Particularly in environments with sustained high temperatures and corrosive conditions, sintered metal filter elements excel in refining the filtration process while curbing operational expenses. Specifications Material: Grade 1 Titanium Powder Diameter: 20mm Length: 200mm Pore Size: 10 Micron Connector: Quick-Release Connector Temperature Resistance: Up to 300�°C Features Reusability and adaptability Exceptional filtering efficiency High tolerance to thermal shock Extended service life (cleanable and reusable) Resilient to high pressure and temperature Sturdy and fracture-resistant Corrosion-resistant Exceptional thermal shock resistance Offers a range of geometric possibilities Maintains fine tolerance to preserve physical properties Applications Removal of dust, bacteria, and oil fog from gas and steam Noise reduction and gas buffering Catalyst recycling Decarburization filtration Filtration of viscous liquids Filtration of strong polar solvents Particle retention in off-gas from fluidized beds Filtration and separation in pharmaceutical, beverage, food, metallurgy, petroleum, and other industries Manufacturing Process of Sintered Metal Filters The production of sintered metal filters involves pressing metal powder into a customized mold with precise pressure to ensure particle adhesion at contact points. The 'green' strength of the part pre-sintering is contingent upon various factors of the metal powder like particle size, composition, and shape. Following molding, the 'green' part undergoes controlled heating or sintering at a temperature below the metal's melting point, allowing for controlled shrinkage. The sintering process transforms the original powder particles into a fully interconnected porous metal structure, dictating the filtration medium's micron class. Moreover, the porosity of the sintered medium is a defining characteristic, tailored to the specific demands of individual systems.
