Mirror polished surfaces, as the name implies, have a bright reflective surface which give a mirror like image. They are the most labour intensive mechanically finished surface with an obvious impact on cost and time of production. As flat product, mirror finishes are produced by post mill abrasive polishing of either hot rolled or cold rolled sheet or strip.

Although mirror finishes are only defined in standards for flat products, it is also possible to generate a mirror polish on surfaces where there is sufficient access for the grinders and polishing mops. The exception to this is materials with large or variable microstructures such as some castings or heavily cold worked items or welds. In these cases, it may not be possible to obtain a mirror surface with a clear image or a uniform lustre.

Mirror polished surfaces are produced by grinding with successively finer abrasives where the next grit size is not selected until all the scratches produced in the previous stage have been removed. The surface is then buffed with “mops” (which may be soft or hard) and sticks compounded with binders and rouge of whose particle size depends on the required finish.

The buffering stage does not remove much material and, if there are scratches from earlier grinding stages, they will show up as rounded furrows. Contamination with a larger grit particle will give isolated, but very unsightly, scratches. A mirror finish is the only one that will produce a clear image of its surroundings. Finishes such as the cold rolled BA or an electropolished 2B or even a No 4 finish with a very low Ra that is then electropolished, will be brilliant and reflective but they will not form a sharp reflected image.

Specifications

Both ASTM A480 and EN10088-2 include mirror finish specifications called No 8 and 2P respectively. Mirror finish is described as a non-directional finish which is reflective and has good image clarity. The surface will be essentially free from grit lines due to the initial grinding stages but there will be visual differences between surfaces produced by different suppliers to these specifications.

For mirror finishes, requiring that the surface has a specific surface roughness (Ra) is not very useful. Gloss measurements are a useful technique on o at surfaces especially if both diffuse and specular reflection are measured. Not surprisingly, diffuse reflectance is always higher. If a higher level of confidence is required for critical applications, then agreement on comparison with a finished sample in agreed conditions is recommended. It is the most reliable method of detecting random scratches.

Applications and Limitations

Mirror finish is most widely used for plates in presses, on the interior surface of moulds and also for small mirrors, reflectors and architectural panels.

The two primary limitations are: the most commonly used grades (304 and 316) are quite soft so that any cleaning process must avoid scratching the surface with residual dust or applied cleaning compounds, and large flat areas of mirror polish throw scratches, grease or dirt markings into sharp contrast.

The first limitation is overcome by careful cleaning protocols using adequate water rinsing. The effect of random marks and scratches is reduced if the surface is corrugated at the macro level described below when using surfaces that are texturised (single sided deformation) or embossed/rigidised (through thickness deformation). However, while mirror sheet may be profiled, it is more common to apply profiling treatments to cold rolled sheet.

Profiled or Patterned Surfaces

EN10088-2 uses categories 1M and 2M for sheet material that has been patterned on one side only. The 1M group applies to hot rolled base materials while the much more common 2M applies to cold rolled base materials, usually with a 2B, 2D or 2R (BA) finish. In corrosive environments it is essential to orient the pattern to allow free drainage.

Through thickness deformation

EN10088-2 lists 2W for cold rolled sheet that has been cold rolled into a through thickness corrugated pattern. The cold work strengthens the sheet and may permit the use of thinner sheet. The rigidity also helps control oil-canning, i.e. local buckling caused by thermal expansion during fixing or temperature changes during the year or day. The surfaces are often described as embossed or rigidised.

Coloured Stainless Steel

Stainless steel can be painted provided that the surface is scrupulously clean and has sufficient profile to mechanically anchor the paint. Using a stainless steel base metal offers the advantage that, even if the coating is damaged, any rusting is superficial and will not lead to long term structural failure as has occurred when protective coatings fail on steel or aluminium structures.

However, painted organic coatings are clumsy means of colouring stainless steel. If it is simply to be blackened, then the molten sodium dichromate process or a hot sulphuric acid treatment or even an electrodeposited and baked organic coating could offer greater durability. Other colours are offered by an electrochemical deposition process that deposits and hardens an enhanced oxide film on the stainless steel although usually only on 304. The colour depends on the thickness of the oxide and progresses from blue to gold to mauve and green with time of exposure.

The colour is similar to the interference colours in an oil slick or soap bubble with interference between the light reflected from the top of the oxide and base metal. In theory the colouring could be reproduced on any simple shape but in practice, it is only available on sheets. The coated sheets may be deep drawn, formed, bent and fixed mechanically but welding destroys the coloured film. While the oxide film is harder and more resistant to scratching than the basic 304 substrate, it is still susceptible to mechanical damage and so is not suitable in areas subject to heavy traffic. Corrosion tests on blue coatings on 304 showed slightly improved resistance to atmospheric and acidic chloride exposure over the resistance of 304.