1. Principles and Process of Stainless Steel Passivation
The corrosion resistance of stainless steel originates from the naturally formed chromium oxide film on its surface, but this film may be damaged during processing. The passivation process removes surface free iron and contaminants through chemical methods (such as nitric acid or citric acid solutions) and promotes the regeneration of the chromium oxide film. The specific steps include:
Pretreatment: Use alkaline cleaners to remove oils and impurities, ensuring a clean surface.
Pickling: Dissolve surface oxides and iron particles with an acidic solution (such as nitric acid) to create conditions for passivation film formation.
Passivation Treatment: Immerse components in a passivation solution to generate a chromium oxide film with a thickness of approximately 2-5 nanometers, significantly enhancing corrosion resistance.
Neutralization and Cleaning: Thoroughly rinse with water to remove residual passivation solution and avoid secondary corrosion.
Drying and Testing: Verify passivation effects through methods like salt spray testing to ensure uniform and dense film formation.This process applies to precision parts produced by CNC turning services and provides long-term protection for stainless steel components in medical injection molding.
2. Critical Role of Passivation Treatment After CNC Machining
During CNC machining, friction between the tool and stainless steel surface may embed iron chips or leave residual cutting fluid, which accelerates corrosion. The passivation process addresses these issues in the following ways:
Removing Processing Contamination: The pickling step eliminates iron particles and oils generated by CNC turning services, preventing localized corrosion.
Enhancing Surface Performance: The passivation film resists acidic environments (such as disinfectants in medical equipment) and humid air, extending the service life of stainless steel parts.
Improving Industry Compliance: Meets international standards like ASTM A967, ensuring the safe application of mechanical turned parts for the medical sector in fields such as medical and food machinery.For example, an automotive parts manufacturer improved the salt spray test corrosion resistance of CNC car parts from 24 hours to 120 hours through passivation treatment, significantly reducing after-sales maintenance costs.
3. Application of Passivation for Stainless Steel Components in Medical Injection Molding
In the medical injection molding field, the corrosion resistance of stainless steel components directly affects the safety of medical devices. The advantages of the passivation process include:
Biocompatibility Assurance: The passivation film is free of heavy metals, complying with FDA requirements for medical devices and avoiding harmful substance leaching.
Corrosion Resistance and Cleanability: Passivated stainless steel parts have smooth surfaces that are less prone to bacterial growth, facilitating high-temperature sterilization and daily cleaning.
Complex Structure Treatment: For precision components (such as micro valves and catheter connectors) in medical device plastic molding, the passivation solution can evenly cover surfaces through immersion or spraying, ensuring protection for every corner.A medical device manufacturer used passivation treatment for stainless steel inserts in medical injection molding, achieving 10 years of corrosion-free use in a chlorine-containing disinfectant environment and greatly improving product reliability.
4. Industry Standards and Innovative Trends in Passivation Technology
To ensure passivation quality, the industry generally follows the ASTM A967 standard, requiring verification of indicators such as passivation film thickness and corrosion resistance through methods like copper sulfate testing and salt spray testing. In recent years, environmentally friendly passivation technologies (such as citric acid passivation) have gained popularity, offering advantages such as:
Low Toxicity: Avoids using chromium-containing passivation solutions, reducing environmental pollution.
High Efficiency: Reacts at room temperature, saving energy and time.
