BOILER WATER CHEMISTRY

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BOILER  WATER  CHEMISTRY


(BOILER WATER/ STEAMS ANALYSIS)
 The main objective of feed and boiler water treatment in a power plant is to maintain the plant in a condition where it can operate reliably and efficiently.It aims:-a) To maintain the integrity of the feed, boiler and steam system by minimising corrosion to an acceptable level;b) To maintain the effectiveness of heat transfer surface by minimising the deposition of corrosion products & scale;c) To maintain a high level of steam purity and thus prevent problem in the super heaters,   re heaters, & turbine.
The water has to be treated to obtain required quality before it is allowed to go into the boiler .The ultra-pure water so obtained is further conditioned in the feed system and then within boiler so that water is not aggressive to any of the variety of construction materials used in boiler, feed and steam cycles.
           
Corrosion by oxygen and carbon dioxide in the feed lines and economisers causes small amounts of corrosions debris carried into the boiler and deposited into the tube surfaces.These deposited acts as a potential areas for further corrosion.

In the control of such kind of corrosion certain chemicals are added to the feed water to remove or neutralise gases that have entered into the system and escaped during mechanical deaeration.

HYDRAZINE TREATMENT OF FEED WATER:-
     
Dissolve oxygen is most objectionable species in water.It brings about rapid corrosion by conversion Iron (in steel) into Iron Oxides.The mechanism of corrosion of metals by oxygen is by the formation of differential aeration cells in the system.

To remove oxygen (Dissolve oxygen) from feed water HYDRAZINE is dosed. It reacts according to the reaction:-

N2H4   + O2   → N2 + 2H2O

From the reaction we see that no solids are produced in the system.In fact the product N2 & H2O are completely harmless.Any surplus hydrazine that remains after removing the oxygen is decomposed at high temperature to give ammonia and nitrogen.

3N2H4   → 4 NH3 + N2

Hydrazine also forms protective film on the metal surfaces-

6Fe2O3 + N2H4 → 4Fe3O4 + N2 + 2H2O

DOSING POINT OF HYDRAZINE :-

Hydrazine is usually dosed at Deaerator Outlet after mechanical scavenging of dissolved oxygen in deaerator. Hydrazine dosing is a continuous process.
 
AMMONIA TREATMENT OF FEED WATER :-

Carbonates or bicarbonates salt enters into the boiler due to condenser tube leakage/ seapage, dissociates to produce carbon dioxide under boiler condition. CO2 In the absence of dissolved oxygen in water causes general metal thining ie, uniform attack on metal.

Feed water is ammonated in order to protect steel against corrosion by carbonic acid according to the reaction:-

NH4OH + CO2 → NH4HCO3

NH4HCO3 + CO2 → (NH4)2CO3 + H2O
     
In the boiler, ammonium bicarbonate and carbonate disintegrate into ammonia, carbonic acid and water. The carbonic acid and ammonia thus formed turns into vapour and are removed from the boiler.

When the steam has been cooled and condensed in the condenser,
Ammonia dissolved in the condensate, and carbonic acid is rermoved together with permanent gases.Therefore ammonia should constantly be introduced in the feed water to insure a desired pH value. So the purpose of ammonia dosing is
a) To insure a desired pH value (to protect corrosion) and
b) To neutralise the presence of carbon dioxide.
  
AMINES which decompose to give ammonia can also be used to neutralise carbon dioxide. They are called neutralising amines like
Cyclohexileamine and Morpholine

DOSING POINT OF AMMONIA: -
NH3 is dosed at Deaerator Outlet or at BFP (BOILER FEED PUMP) SUCTION.

PHOSPHATE TREATMENT OF BOILER WATER :-
It is well known that carbon steel has minimum corrosion in the pH range of around  9 to 10 .To achieve this pH  TSP (Tri Sodium Phosphate) is added into the boiler. Some time sodium hydroxide may also be added but it provides an extra ionic load.
TSP reacts with scale forming salts (which may enter by poor quality of make-up or condenser leakage) as follows:-
     
2Na3PO4  + 3CaSO4  → 3Na2SO4 + Ca3(PO4 )

2Na3PO4  + 3MgSO4  → 3Na2SO4 + Mg3( PO4)

So phosphate if present in boiler water will react with scale forming salts and for corresponding phosphate of Ca / Mg which are insoluble and formed sludge. When CBD (Continuous Blow Down) is operated, this sludge is bled-off from the boiler drum and this one gets rid off the scale forming salts.

DOSING POINT OF PO4:- TSP is directly dosed into the boiler drum at the Pressure of 150 Kg/cm2.








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