To have their optimum corrosion resistance, stainless steel surfaces must be clean and have an adequate supply of oxygen to maintain their passive surface layer. Rust staining can occur and has been reported as anything from a slight brown ‘bloom’ on the surface to severe surface pitting or rusty scour marks on items such as handrails. These effects are usually due to surface contamination from contact with non-stainless steel items.
Iron contamination can be costly to remedy, and is avoidable. These issues have been well documented and most publications on stainless steels deal with the problem.
Key issues to consider
Avoid contamination during all storage, handling and fabrication stages and also during the service life of the stainless steel item.
If contamination is suspected then test the surface.
Where contamination is detected take steps to remove it all and avoid spreading it around during the removal operation.
Avoiding ‘iron’ contamination
Stainless steel supplied by reputable manufacturers, stockholders or fabricators will normally be clean and contamination free. These items should not show rust staining, unless contamination is introduced.
The use of non-stainless steel processing and handling equipment is a frequent source of contamination. Work table bearers, lifting ‘dogs’ and chain marks have all been noted as causes. Non-metallic contact materials and vacuum lifting equipment should be used to avoid process contamination.
Handling or fabricating stainless steel on equipment, using tools also used for non-stainless steels should be avoided. Working in ‘mixed-metal’ fabrication shops, without taking segregation and cleaning precautions can result in contamination. Cutting or grinding debris from non-stainless steels should not be allowed to settle on stainless steel items.
As soon as any of this contamination becomes wet, rust staining will result.
Testing for ‘iron’ contamination
American standards ASTM A380 and A967 outline iron contamination tests. Some of the tests simply look for rust stains from contact with water or high humidity environments, but for detection of the ’cause’ ie free iron on the surface, rather than the ‘effect’, which is the resulting rust stains, then the ‘ferroxyl test’ is probably the better method. This will detect either free iron or iron oxide and is sensitive enough to detect small levels of contamination. ASTM A380 outlines the procedure in section 7.3.4.
Nitric acid is added to distilled water, followed by the potassium ferricyanide. The ‘recipe’ is shown in the table.
Distilled water94 weight %1000 cm3Nitric acid3 weight %20 cm3Potassium ferricyanide3 weight %30 grams
Preparation of the solution must be done using equipment where no iron or steel comes into contact with the reagents. It should be applied to the stainless steel surfaces preferably using an atomizer spray. A blue stain, appearing in about 15 seconds, indicates the presence of iron. The solution has to be removed from the surface as quickly as possible after testing using either water or 5-20% acetic acid (or vinegar) and scrubbing with a fibre brush, finally rinsing with the solution used, several times.
The standard notes that potassium ferricyanide is not toxic but that the fumes may become toxic if the solution is heated.
Test kits are available commercially from some BSSA member companies.
Removing ‘iron’ contamination
Any cleaning process that can remove embedded iron can be used. It is important to ensure that all the contamination is removed or not spread to other areas of the stainless steel product surfaces, otherwise rust staining can recur. In this respect, chemical, rather than abrasive cleaning may be advisable.
Cleaning and iron recontamination is well documented in stainless steel cleaning product suppliers literature and literature published by the Nickel Development Institute.
As with cleaning, a stepwise approach, depending on the severity of the staining should be considered. Nitric acid or nitric / hydrofluoric acid preparations are the most effective but may cause surface etching, which may be unacceptable on the restored item.
Methods for removing ‘iron’ contamination
Mild staining or surface ‘bloom’
Mild-non scratching domestic cleaning creams or polishes can be used. These usually contain calcium carbonate, with surfactant additions. ‘Jif’ kitchen cream cleaner (Lever Brothers Ltd) is an example of such a product. Domestic stainless steel cleaners, which may contain citric acid can also be used. Shiny Sinks -(Home Products Ltd) is an example of such a product.
Cleaning methods for stainless steels
Fresh iron / steel grinding grit or dust
A saturated solution of oxalic acid, applied with a soft cloth or cotton wool and allowed to stand for a few minutes, without rubbing or abrading. This should etch out the iron particles, without leaving scratches or significantly altering the surface texture of the stainless steel.
Moderate rust staining
Phosphoric acid cleaners can be effective if sufficient time and care is taken, with minimal risk of etching the surface. Alternatively, dilute nitric acid should remove small amounts of embedded iron and will help repassivate the cleaned surface.
More severe rust staining
Nitric / hydrofluoric acid pickling preparations should remove more embedded iron than nitric acid alone. Surface etching is likely and so complete restoration to the original finish and surface texture may not be possible. If these preparations are left on stainless steel surface too long, pitting can be caused.
There is a limit to what can be achieved. Although contamination may be removed, these treatments will not remove any pitting associated with severe staining. In such cases mechanical grinding may have to be considered to ‘bottom-out’ the pits which means that a complete restoration of the surface will then be needed.
Corrosion Prevention for Stainless Steel
1. Keep stainless steel and carbon steel fabrication areas separate. This step reduces the risk of iron contamination. Iron particles can embed into the stainless steel and damage the oxide layer. This could produce localized or pitting corrosion at the site of contamination.
2. Avoid grinding of carbon steels near stainless steels. Grinding can embed carbon steel into the stainless steel causing staining and localized corrosion.
3. Keep stainless and carbon steel inventories separate. This reduces the risk of iron contamination .
4. Steel bands are routinely used to secure fabricated parts to skids and other packaging used to transport. Place cardboard or other appropriate packaging material on top of stainless steel parts, and then wrap the steel bands on top of this packing material, preventing the carbon steel band from making direct contact with the stainless steel.
5. Use stainless steel processing and handling equipment when possible. Use work table bearers, non-metallic contact materials, and vacuum lifting equipment.
6. Do not allow your completed fabrications to ship untarped. Road salts contain high levels of chlorides — a chemical that can produce corrosion in stainless steels. Moreover, do not allow steel chains to come in contact with stainless steel.
Source: wilsonpipeline Pipe Industry Co., Limited (www.wilsonpipeline.com)
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