Stainless Steel Micron Wire Mesh Filter Tube
5 - 100 /Piece
Min.Order:1 Piece
Baoji Yinggao Metal Materials Co., Ltd.
The stainless steel micron wire mesh filter tube is a filter element made primarily of 304 or 316 stainless steel wire mesh. It is manufactured using stainless steel wire mesh woven in various mesh shapes to achieve the desired filtration grade. The stainless steel wire mesh filter tube has uniform surface filtration performance and employs multi-layered sintered stainless steel mesh as the main filter material. The mesh has interlaced pores, making it resistant to high temperatures, sudden temperature changes, and corrosion, making it suitable for various corrosive media such as acids and alkalis.
The stainless steel micron wire mesh filter tube is a filter element with extremely high compressive strength, making it suitable for filtration applications where high-pressure fluids flow. Due to the inherent advantages of stainless steel filter cartridges, they can be easily customized to meet specific material, strength, flow rate requirements, thickness, micron rating, and environmental conditions.
Parameters
Diameter: 20 mm
Wall Thickness: 2 mm
Operating Temperature: 600°C
Filtration Precision: 100 microns
Connections: Open on both ends
Features
High Pressure Differential: It is a filter element with high pressure resistance, commonly used in high-pressure fluid filtration applications to ensure long-term operation of equipment in high-pressure pipelines.
High Temperature Resistance: Stainless steel material can withstand prolonged operation at high temperatures. While other materials may deform under high temperatures, stainless steel filter cartridges remain stable.
Cleanable: The material is stainless steel, which is easy to clean and reuse. Cleaning the equipment involves removing impurities and reinstalling it for further operations. It allows for fluid backwashing, ensuring no residual contaminants on the surface of the stainless steel filter cartridge.
Long Lifespan: The filter element has certain corrosion resistance and a longer service life. Its corrosion resistance makes it an ideal filtration element for preventing secondary contamination of fluids.
Customizable Sizes: It comes in different sizes to be used in a wide range of industrial applications. Different sizes can easily adapt to different types of equipment. It also offers different sealing rings or gasket attachments for various applications.
Stable Aperture: The filtration medium has a fixed pore structure, preventing contaminated particles from returning to the clean fluid. The absolute rated value of the pores provides consistent and reliable fluid filtration, improving filtration efficiency.
Applications
Petrochemical and oilfield pipeline filtration
Gasoline filtration for engineering machines and refueling equipment
Water treatment equipment filtration
Pharmaceutical and food processing industries
Chemical liquid filtration
Suitable for pre-processing and post-processing systems in industries such as electronics, petroleum, chemical, pharmaceuticals, and food.
Filtration Mechanism
Depending on the type of stainless steel filter cartridge application, the contaminated fluid can be filtered from inside to outside or from outside to inside.
Air filtration with stainless steel filter cartridges typically removes particulate contaminants through the following mechanisms:
Inertial Impaction: Larger, high-density particles are typically captured through inertial impaction, where inertia causes particles to separate from the airflow and collide with fibers.
Interception: Medium-sized particles that are too small to possess inertia can be removed through interception. These pollutants are suspended in the airflow and, when in contact with the fibers, adhere to the media and get captured.
Diffusion: The smallest particles are captured through diffusion. These tiny particles undergo random, irregular motion similar to gas molecules, a phenomenon known as Brownian motion. The random motion increases the likelihood of particle collisions and adhesion to the media surface.