The type of corrosion classified with respect to outward appearance or altered
physical properties are:-
- Uniform attack
- Pitting
- Cavitations erosion
- Dezincification & parting
- Intergrannular corrosion
- Cracking
Oxygen Corrosion:-
Water coming out of deaerators has residual oxygen. As explained earlier even a
trace amount of oxygen can cause corrosion. This last trace of oxygen is removed
chemically. Sodium Sulphite and hydrazine or one of its product is used for
removal of residual oxygen. Sodium Sulphite is used for low pressure boiler.
Amine is preferred in high pressure boiler because it does not add to TDS,
unlike Sodium Sulphite.
Effect of pH :-
Both high and low pH can cause corrosion in boiler. In acidic range the
protective layer of magnetite is not able to form and it cause corrosion. In
very high pH range the protective layer of magnetite breaks down and this leads
to caustic corrosion. For corrosion prevention maintaining proper pH and
alkalinity is very important.
Acid Corrosion:-
Excess acid cause damage at more rapid rate than excess base. Simply because
this happens, it should not be taken as an operating guideline. Magnetite film
forms due to corrosion but once formed adhere tightly and acts as a barrier
between boiler water and steel. Acids are capable of destroying this film and
hence water chemistry must be so maintained that the protective film is not
disrupted. This can be done by keeping the water in alkaline range.
Caustic Corrosion:-
Feed water is maintained at alkaline pH. Alkali is added to provide optimum pH
in the feed water to prevent corrosion of piping and equipment. Caustic soda
(sodium hydroxide) is generally added for this purpose. Sometimes sodium
carbonate is also added. Even though caustic soda is added with control, there
are occasions when pH increases and cause corrosion as shown by the equation
below. The damaged caused by excess alkali is because it dissolves the magnetite
film forming sodium hypo ferrite and sodium ferrite both of which are soluble in
hot concentrated caustic soda. In addition concentrated reacts directly and more
rapidly with iron to form hydrogen and sodium Ferro rate.
- Fe3O4 + 4NaOH ® 2 NaFeO2 + Na2FeO2 +H2O
- Fe + 2NaOH ® Na2FeO2
Caustic attack on boiler can two forms - Gouging or cracking. Caustic cracking
is also known as caustic embrittlement.Caustic gouging causes deep elliptical
depression in boiler metal surface. This occur in areas of high heat flux or
under heavy porous deposits. Underneath these deposits , boiler water can
concentrate to the point where high concentrate of caustic can accumulate
causing a localized corrosion. This action can be rapid.Boiler water chemistry
if properly maintained will prevent caustic gouging.
Caustic embrittlement or cracking is a form of stress corrosion. Cracks occur
rapidly and are often undetectable leading to sudden failure of boiler –at times
causing a violent failure. All parts of boiler are subjected to this type of
corrosion. The only way to stop this type of corrosion is to prevent high
concentration from forming.
Caustic corrosion is generally confined to:-
- a) Water cooled tubes in region of high heat flux.
- b) Slanted and horizontal tubes.
- c) Location beneath heavy deposits.
- d) Heat transfer region at or adjacent to packing rings.
Caustic corrosion is prevented by coordinate caustic program. Phosphate ions act
as a buffer ion. It does not allow pH to increase in water, no matter how
concentrated OH ions become. Buffer ions are also useful in avoiding similar
high OH concentration which leads to stress corrosion cracking (caustic
embrittlement). In low pressure boiler sodium nitrate is added in a definite
ratio to caustic alkalinity to prevent caustic embrittlement.
Galvanic corrosion:-
We have already explained what galvanic corrosion is. A metal or alloy if it is
electrically coupled, galvanic corrosion occurs. Corrosion by copper is the most
common form of galvanic corrosion in boiler system. Copper can be carried from
pre boiler section. Water deposits copper as decomposition of bicarbonates or as
ammonia complexes. Pitting of boiler tubes has been reported due to copper
deposit.
Iron Oxide deposits:-
In boiler the steel reacts with water in absence of oxygen to form a magnetite
film. This film than acts as a protective layer for further corrosion. Iron
oxide also enters with feed water into boiler as corrosion product. This layer
is very porous and can be easily penetrated. This allows boiler water to seep
through and flash into steam leaving behind dissolved solids which concentrates
in localized areas. This excessive concentration can lead to metal dissolution
and metal failure.
Condensate corrosion:-
Steam generated in boiler is transported to point of use through pipes. Steam
condensate is also returned to boiler feed water. Corrosion of steam lines and
condensate return line occurs because of the low pH. The chief source of acid in
steam is carbon di oxide. High temperature and pressure decomposes alkalinity to
carbon di oxide, some of which dissolves in steam making it acidic. This lowers
the condensate pH and leads to corrosion of return lines. Oxygen can enter a
condensate system from other sources even if the deaerator is functioning
properly. Oxygen causes a deep pitting of condensate lines.
High Velocity and low pH can result in extremely severe corrosion conditions.
The best way to minimize this is by keeping the pH above 9.0 Other gases which
can be corrosive in the condensate system are Ammonia, Hydrogen sulphide and
sulphur di oxide.