Corrosion of structural steel

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The corrosion of structural steel is an electrochemical process that requires the simultaneous presence of moisture and oxygen. Essentially, the iron in the steel is oxidised to produce rust, which occupies approximately six times the volume of the original material. The rate at which the corrosion process progresses depends on a number of factors, but principally the 'micro-climate' immediately surrounding the structure.

Schematic representation of the corrosion mechanism for steel

[top]The corrosion process

The corrosion of steel can be considered as an electrochemical process that occurs in stages. Initial attack occurs at anodic areas on the surface, where ferrous ions go into solution. Electrons are released from the anode and move through the metallic structure to the adjacent cathodic sites on the surface, where they combine with oxygen and water to form hydroxyl ions. These react with the ferrous ions from the anode to produce ferrous hydroxide, which itself is further oxidised in air to produce hydrated ferric oxide (i.e. red rust.) The sum of these reactions can be represented by the following equation:

Fe + 3O₂ + 2H₂O = 2Fe₂O₃H₂O
(Steel) + (Oxygen) + (Water) = Hydrated ferric oxide (Rust)

However, after a period of time, polarisation effects such as the growth of corrosion products on the surface cause the corrosion process to be stifled. New, reactive anodic sites may be formed thereby allowing further corrosion. In this case, over long periods, the loss of metal is reasonably uniform over the surface, and this is usually described as 'general corrosion'. A schematic representation of the corrosion mechanism is shown (above right).

The corrosion process requires the simultaneous presence of water and oxygen. In the absence of either, corrosion does not occur.

[top]Localised corrosion

Various types of localised corrosion can also occur but these tend not to be significant for structural steelwork.

[top]Bimetallic corrosion

When two dissimilar metals are joined together and in contact with an electrolyte, an electrical current passes between them and corrosion occurs on the anodic metal. Some metals (e.g. stainless steel) cause low alloy structural steel to corrode preferentially whereas other metals (e.g. zinc) corrode preferentially themselves, thereby protecting the low alloy structural steel. The tendency of dissimilar metals to bimetallic corrosion is partly dependent upon their respective positions in the galvanic series. The further apart the two metals in the series the greater the tendency.

Another aspect that influences bimetallic corrosion is the nature of the electrolyte. Bimetallic corrosion is most serious for immersed or buried structures, but in less aggressive environments e.g. stainless steel brick support angles attached to mild steel structural sections, the effect on the steel sections is minimal. No special precautions are required in most practical building or bridge situations. For greater risk situations, gaskets, sleeves and similar electrically insulating materials should be used. Alternatively the application of a suitable paint system over the assembled joint is also effective.

The tendency for bimetallic corrosion is also influenced by the relative surface areas of the cathodic and anodic metals (A_c/A_a). In simple terms, the greater the A_c/A_a ratio, the greater the tendency for bimetallic corrosion.

[top]General galvanic series

Anodic end (More prone to corrosion)

Magnesium
Zinc
Aluminium
Carbon & Low Alloy (Structural) Steels
Cast Iron
Lead
Tin
Copper, Brass, Bronze
Nickel (Passive)
Titanium
Stainless Steels 430/304/316 (In the passive state)

Cathodic end (Less prone to corrosion)

[top]Pitting corrosion

Pitted steel surface

In some circumstances the attack on the original anodic area is not stifled and continues deep into the metal, forming a corrosion pit. Pitting more often occurs with low alloy structural steels in continually wet conditions or buried in soil rather than those exposed in air. Hence, pitting corrosion is rarely encountered on typical modern steel buildings or bridges.

[top]Crevice corrosion

Crevices can be formed by design detailing, welding, surface debris, etc. Available oxygen in the crevice is quickly used by the corrosion process and, because of limited access, cannot be replaced. The entrance to the crevice becomes cathodic, since it can satisfy the oxygen-demanding cathode reaction. The tip of the crevice becomes a localised anode and high corrosion rates occur at this point.

[top]Corrosion rates

The principle factors that determine the rate of corrosion of steel in air are:

Time of wetness
Atmospheric pollution

[top]Time of wetness

This is the proportion of total time during which the surface is wet, due to rainfall, condensation etc. It follows, therefore, that for unprotected steel in dry environments e.g. inside heated buildings, corrosion will be minimal due to the low availability of water. The requirement for the application of paints or coatings becomes unnecessary other than for appearance or fire protection purposes.

[top]Atmospheric pollution

The type and amount of atmospheric pollution and contaminants (e.g. sulphates, chlorides, dust etc.)

[top]Sulphates

These originate from sulphur dioxide gas produced during the combustion of fossil fuels, e.g. sulphur bearing oils and coal. The sulphur dioxide gas reacts with water or moisture in the atmosphere to form sulphurous and sulphuric acids. Industrial environments are a prime source of sulphur dioxide.

[top]Chlorides

These are mainly present in marine environments. The highest concentration of chlorides is to be found in coastal regions and there is a rapid reduction moving inland. In the UK there is evidence to suggest that a 2 kilometre strip around the coast can be considered as being in a marine environment.

Both sulphates and chlorides increase corrosion rates. They react with the surface of the steel to produce soluble salts of iron, which can concentrate in pits and are themselves corrosive.

Within a given local environment, corrosion rates can vary markedly, due to effects of sheltering and prevailing winds etc. It is therefore the 'micro-climate' immediately surrounding the structure, which determines corrosion rates for practical purposes. Because of variations in atmospheric environments, corrosion rate data cannot be generalised. However, environments can be broadly classified, and corresponding measured steel corrosion rates provide a useful indication of likely corrosion rates. More information can be found in BS EN ISO 12944-2^[1] and BS EN ISO 9223^[2].

**Atmospheric corrosivity categories and examples of typical environments (BS EN ISO 12944-2^[1])**
Corrosivity category	Low-carbon steel Thickness loss (μm)^a	Examples of typical environments (informative only)
Corrosivity category	Low-carbon steel Thickness loss (μm)^a	Exterior	Interior
C1 very low	≤ 1.3	-	Heated buildings with clean atmospheres, e.g. offices, shops, schools, hotels
C2 low	> 1.3 to 25	Atmospheres with low level of pollution: mostly rural areas	Unheated buildings where condensation can occur, e.g. depots, sports halls
C3 medium	> 25 to 50	Urban and industrial atmospheres, moderate sulphur dioxide pollution; coastal area with low salinity	Production rooms with high humidity and some air pollution, e.g. food-processing plants, laundries, breweries, dairies
C4 high	> 50 to 80	Industrial areas and coastal areas with moderate salinity	Chemical plants, swimming pools, coastal ship and boatyards
C5 very high	> 80 to 200	Industrial areas with high humidity and aggressive atmosphere and coastal areas with high salinity	Buildings or areas with almost permanent condensation and high pollution
CX extreme	> 200 to 700	Offshore areas with high salinity and industrial areas with extreme humidity and aggressive atmosphere and sub-tropical and tropical atmospheres	Industrial areas with extreme humidity and aggressive atmosphere

Notes:

1μm (1 micron) = 0.001mm
^a The thickness loss values are after the first year of exposure. Losses may reduce over subsequent years.
The loss values used for the corrosivity categories are identical to those given in BS EN ISO 9223^[2].

[top]References

↑ ^1.0 ^1.1 BS EN ISO 12944-2: 2017, Paints and varnishes – Corrosion protection of steel structures by protective paint systems – Part 2: Classification of environments, BSI
↑ ^2.0 ^2.1 BS EN ISO 9223: 2012, Corrosion of metals and alloys – Corrosivity of atmospheres – Classification, determination and estimation. BSI

[top]Resources

Steel Buildings, 2003, The British Constructional Steelwork Association Ltd.
- Chapter 12 – Corrosion Protection

[top]Further reading

D.Deacon & R.Hudson (2012), Steel Designer’s Manual (7th Edition), Chapter 36 - Corrosion and corrosion prevention, The Steel Construction Institute.
D.A. Bayliss & D.H.Deacon (2002), Steelwork Corrosion Control (2nd edition), Spon Press.
PD 6484:1979, Commentary on corrosion at bimetallic contacts and its alleviation, British Standards Institution.

[top]See also

[top]CPD

Corrosion protection

[No1-1] 1.0 ^1.1 BS EN ISO 12944-2: 2017, Paints and varnishes – Corrosion protection of steel structures by protective paint systems – Part 2: Classification of environments, BSI

[No2-2] 2.0 ^2.1 BS EN ISO 9223: 2012, Corrosion of metals and alloys – Corrosivity of atmospheres – Classification, determination and estimation. BSI

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