Sintered metal powder filter cartridge

Note: The above are common reference values, and specific parameters can be customized according to the medium, temperature, pressure, and accuracy requirements.

1. Raw material preparation: Select qualified metal powder (particle size, chemical composition), and add binders or additives if necessary.

2. Powder batching and screening: Screen and mix according to the formula to ensure the particle size distribution and uniformity of the powder.

3. Molding: compression molding or injection molding; Sometimes isostatic pressing is used to improve density uniformity.

4. Pre burning/degreasing (if containing organic binders): Low temperature heating to remove organic matter and prevent sintering defects.

5. Sintering (high temperature): Heat up according to the process curve in a protective atmosphere or vacuum to the sintering temperature and keep it warm to form a dense/porous metal skeleton.

6. Heat treatment/tempering (if necessary): Improve mechanical properties or eliminate stress.

7. Mechanical processing and finished product processing: cutting, turning end faces, punching, welding flanges or joints, flanging, etc.

8. Surface treatment and cleaning: such as acid pickling passivation, sandblasting or polishing, ultrasonic or chemical cleaning to remove residual impurities.

9. Inspection and testing: size, porosity, gas permeability, filtration efficiency, pressure resistance, metallographic examination, etc.

10. Packaging and shipping: Protection, cleanliness level labeling, and accompanying inspection reports.

-High mechanical strength: The metal substrate can withstand large pressure differentials and impacts, making it more durable than sintered ceramics or fiber filter materials.

-High temperature and pressure resistance: suitable for high temperature and high pressure working conditions, long-term stable operation.

-Corrosion resistance (depending on the material): Stainless steel, nickel based materials, and other materials perform well in various chemical media.

-Washable/Renewable: Supports multiple regeneration methods such as backwashing, ultrasonic, chemical cleaning, heat treatment, etc., with long lifespan and low usage cost.

-Controllable pore structure: By adjusting the particle size and sintering process of the powder, the pore size and porosity can be adjusted to achieve the desired retention performance and flow rate requirements.

-No fiber shedding, no need for adhesive residue: suitable for occasions with high cleanliness requirements (such as pharmaceuticals, food, semiconductors, etc.).

-Customizable design: Shape, size, interface, and surface treatment can be customized as needed for complex system integration.

-Petrochemical and refining: liquid/gas pretreatment, catalyst protection, oil filtration, degassing/deslagging.

-Pharmaceutical and Bioengineering: Process filtration without fiber contamination, pre-treatment before sterilization, gas dialysis, and liquid clarification.

-Food and Beverage: Syrup, Beverage, Alcohol Clarification, Liquid Recycling and Purification.

-Automotive and aviation: fuel/lubricant filtration, hydraulic system protection, fuel injection pre filtration.

-Electricity and Energy: Steam Turbine, Gas Turbine Inlet and Oil System Filtration, Compressed Air Purification, Hydrogen, Natural Gas Purification.

-Precision Manufacturing and Semiconductors: Ultra pure Gas and Chemical Filtration, Vacuum System Protection.

-Environmental Protection and Water Treatment: Industrial wastewater filtration, oil-water separation, front-end filtration for flue gas desulfurization/denitrification.

-Metallurgy and casting: metal liquid filtration (specific materials), gas distributor, slag interception.

-Laboratory and scientific research: as a filtering device, gas distribution and diffuser, catalytic bed carrier, etc.

-Select the rated pore size based on the filtered medium (gas/liquid), particle size distribution, and required retention efficiency.

-Considering the working temperature and corrosiveness, choose suitable materials (such as 316L or more corrosion-resistant nickel based alloys).

-If frequent cleaning is required, choose a structure that is easy to disassemble or can be backwashed in situ.

-The maximum allowable pressure difference should have a safety margin to avoid exceeding the design pressure difference when the filter is clogged.

-Cleaning methods: backwashing (liquid/gas), ultrasonic cleaning, acid washing/alkali washing (note material compatibility), high-temperature burning to remove organic matter.

-Regularly check the filtration efficiency and pressure drop curve, and clean or replace if there is a significant increase in pressure drop or decrease in efficiency.

If needed, I can:

-Based on your working conditions (medium, temperature, pressure, target particle size, flow rate, etc.), help recommend specific model parameters;

-Provide standardized technical parameter tables (which can be directly used for quotation or technical specifications);

-Explain the specific operational steps and precautions for common cleaning and regeneration processes.