Description/instructions – Fulton Edge ICX or FB-F Vertical Tubeless Boilers (Steam), Gas Fired User Manual

38-G 1/01

pH: pH is a measure of the degree

of acid or base of solution. Normal

pH ranges of 6.5-9.0 will have little

influence on the corrosion rate of

cooling waters. If for some reason,

pollution, etc., the pH is lowered into

the acid range, increased corrosion

can be expected. The solution lies in

determining the cause of the low pH

and correcting that condition. A low

pH can result in corrosion of metals,

while a high pH can result in scale

formation.

In order to control boilers and

equipment used for the external

treatment of make up water, it is

essential that reliable pH measure-

ments be made.
Phosphates: Ground or surface

waters seldom contain large amounts

of phosphates. If present, it generally

indicates fertilizer runoff or pollution.

Phosphate from raw water can be the

cause of scale problems in open recir-

culating cooling water systems after

the water is concentrated.
Chlorides: Chlorides are involved in

most cooling water corrosion cells.

Other factors being equal, it can be

assumed the higher the chloride con-

tent, the more corrosive the water.

When pits or cracks occur on stain-

less steel or other metals, chlorides

are always suspect.

High chloride levels can cause severe

corrosion. Corrosion from chlorides

can be controlled by increasing the

amount of corrosion inhibitor or

changing to a more effective inhibitor.
Oil: Oil is not a natural constituent of

boiler water; still it can frequently enter

a system through leaks in a con-

denser or other heat exchanger. Oil

can also enter a system through the

lubrication of steam driven reciprocat-

ing equipment. Whatever the source,

the presence of oil in boiler water is

undesirable. Oil can act as a binder to

form scale. In high heat-transfer

areas oil can carbonize and further

contribute to the formation of scale.

Foaming is one indication of oil in

boiler water. Its presence can also

be confirmed by first shaking a bot-

tle containing boiler water. If oil is

present foam will result. To ensure

the foaming is being caused by oil,

add a small amount of powdered

activated carbon to the bottle con-

taining the boiler water and shake.

Little or no foam will appear if the

foaming is caused by oil.

Often oil in boiler water will origi-

nate in the condensate. This conta-

minated condensate should be

directed to the sewer until the

source of the oil is determined and

corrective steps taken.
Silica: Silica in boiler deposits is usu-

ally combined with other constitutents.

Silicates form a number of different

scale complexes with calcium, mag-

nesium, aluminum, sodium, and iron.

Since there is at present no effective

dispersant for silicate deposits, the

scale problem can be alleviated by

maintaining close control of calcium,

aluminum, and iron as well as silica.
Iron (oxides): Iron in any of its oxide

or complex forms is undesirable in

boiler water. It is very difficult to dis-

perse so that it can be removed the

bottom blow off lines.

Iron in its various forms can originate

in the raw water makeup, condensate

return water, or form directly in the

boiler as a result of corrosion. Most

iron oxide originates outside the boil-

er. It does not concentrate in the boil-

er and it tends to collect in stagnant

areas. If a boiler is using raw water

makeup, iron is almost certain to be a

major component of developing scale.
Water Hardness: Water hardness

is the measure of calcium and mag-

nesium content as calcium carbon-

ate equivalents. Water hardness is

a primary source of scale in boiler

equipment.
Feedwater: Feedwater is the com-

bination of fresh makeup and return-

ing condensate that is pumped to

the boiler.
Condensate: Condensate is con-

densed steam that is normally low in

dissolved solids. Hence, it does not

contribute to the dissolved solid con-

tent of the feedwater. In addition, con-

densate is very expensive to waste.

It's been chemically treated, heated,

pumped, converted to steam, and

condensed. This costs money and

when condensate is returned to the

boiler, money is saved.

Description/Instructions