Mga Katanungan :
- What are the Physical Properties of Water?
- What is the Chemical Composition of Water?
- At Temperatures Does Water Boil?
- Why is Steam Ideal for "Carrying" Heat Energy?
- Why is Water Not Always Satisfactory for Boiler Use?
- What General Type of Impurities Does Water Contain?
- What Dissolved Minerals Do Natural Waters Contain?
- What is Water Hardness?
- What Gases are Dissolved in Natural Waters?
- What Types of Other Impurities May Water Contain?
- What is the Difference between Sea Water and Fresh Water?
- What are the Sources of Fresh Water and How do they Vary in Composition?
- How Does Water Composition Vary from Geographical Standpoint?
- What is Boiler Feed-Water?
- Is there any Relationship between Good water for drinking use and for Boiler Feed?
- How Pure Must Feed-Water be?
- How does Operating Pressure Influence Boiler Water Composition requirements?
- What is Meant by 'External' and 'Internal' Feed-water Treatment?
- What Causes Boiler Deposists?
- Which are some Common Types of Boiler Deposits?
- What are the Characteristics of a carbonate deposi?
- What are the Characteristics of a Sulphate Deposit?
- What are the Characteristics of a Silica Deposit?
- What are the Characteristics of an Iron Deposit?
- What Problems do Deposits Cause?
- What is Carrosion?
- Where is Corrosion Usually Experienced?
- What is Corrosion Fatigue?
- What is Caustic Cracking?
- What Problems does Corrosion Cause?
- What Measures are taken to Prevent Boiler System Corrosion?
- What is Boiler Water Carry-over?
- What Causes Foaming?
- What Causes Priming?
- How Does Oil Affect Carry-over?
- How Do Suspended Solids Affect Carry-over?
- What is Selective Silica Carry-over?
- What Problems are Caused by Carry-over?
- What Measures are Usually Taken to Prevent Carry-over?
- What is Clarification?
- What is Coagulation?
- What Various Types of Coagulants are Used?
- What is Chemical Precipitation?
- How Does Lime React in the softening Process ?
- How Does soda Ash React in the Softening Process?
- What are the Various Methods of Lime-Soda Softening?
- Why are Coagulants Used in the Lime-Soda Process?
- Under What Conditions Are Phosphate Softeners Use?
- What are the Disadvantages of Lime-Soda Softening?
- What are the Advantages of Lime-Soda Softening?
- What is Ion Exchange?
- What are the Various Types of Ion Exchange Materials?
- What is Boiler Water Carry-over?
- What are the Disadvantages of Ion Exchange?
- What are the Advantages of Ion Exchange?
- How Does Oil Affect Carry-over?
- How Do Suspended Solids Affect Carry-over?
- What is Selective Silica Carry-over?
- What Problems are Caused by Carry-over?
- What Measures are Usually Taken to Prevent Carry-over?
- What is Clarification?
- What is Coagulation?
- What Various Types of Coagulants are Used?
- What is Chemical Precipitation?
- What is the Purpose of Deaeration?
- How are Evaporators Employed?
- What Combinations of External Treatment Methods are Generally Used?
- When is Internal Treatment of Boiler Feed-water Necessary?
- What Should a Good Internal Water Treatment Programme Accomplish?
- What Chemicals are Used in Internal Treatment?
- How are Carbonates Reacted on by Internal Treatment?
- How are Sulphates Reacted on by Internal Treatment?
- How is Silica Reacted upon by Internal Treatment?
- How is Sludge Conditioned in Internal Treatment?
- What Difficulties are Encountered in Internal Treatment?
- What are the Advantages of Internal Treatment?
- How are Internal Treatment Chemicals Fed?
- How are Chemical Dosages Controlled?
- What Boiler Water Tests are Used for Treatment Control?
- What Tests are Usually Made as a Check for Contaminants?
- What Units are Used in Expressing Water Analysis Results?
- Why are some Analysis Results Expresse 羨s CaCO2・
- What is Blow-down?
- How much Blow-down is Needed?
- What Tests are Made in Regulating Blow-down?
- What is the Difference between Continous and 善uff・Blow-down?
- What Causes Corrosion in Steam Condensate Systems?
- How is Steam Condensate Corrosion Prevented?
- How do Chemical Oxygen Scavengers Help Control Condensate System Corrosion?
- What is the Basis for Choice between Neutralizing and Filming Inhibitors?
- What Characteristics Should a Good Condensate Corrosion Inhibitor Have?
- How are Deposits and Corrosion Prevented in Feed-water Systems?
- What is the Wet Method of Boiler Lay-Up?
- What is the Dry Method of Boiler Lay-Up?
Answer to :back
What are the Physical Properties of Water?
Water is a tasteless, odourless, colourless liquid in its pure state. It is
the only inorganic material which occurs in three forms (ice, water, steam)
within the natural temperature range on earth. Because water can be converted
to steam at a convenient temperature.
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What is the Chemical Composition of Water?
Pure water is a simple combination of hydrogen and wxygen. The common formula
is H2O. As a matter of general interest, however, there are several
'hybrid' forms of water whcih are present in all supplies. Water contains
about 300 ppm of deuterium oxide (D.,O) or "heavy water". This doesn't quench
thrist or make plants grow but in a pure form it has found use in moderating
nuclear reactors. Another form of water, tritium oxide (T2O),
is made radioactive by cosmic rays. Although only a minute fraction of water
exists in this form, its radioactivity serves as a means of measuring the
age of a water supply. For all practical purposes, though, only ordinary
water (H2O) is considered for use in boilers.
Answer to :back
At Temperature Does Water Boil?
The boiling point of water depends on the
pressure to which the water is subjected. At atmospheric pressure
water boils at about 100°C. As pressure increases the boiling
point also increases. At the critical pressure near 22.000kPa
(where water can be converted to steam without a change in
volume) the boiling point is lowered. Under extreme vacuum
conditions, water will boil at temperatures as low as 2°C.
Answer to :back
Why is Steam Ideal for "Carrying" Heat Energy?
The Traditional formula was : 1 Btu raises
1 pound of water 1°F. This can be converted to 4.2 kJ to
raise 1 kg. of water 1°C. It takes an additional 2256 kJ/kg.
to change 1 kg. of water (at the boiling point) to steam. This
amount of heat (the heat of vaporization) is then "stored" in
the steam. When steam condenses, this heat energy is given
off. Consider, for example, the amount of heat which can be "carried" by
1 kg. of water. If the water temperature is origainally 38°C
(100°F) it takes 260 kJ/kg. to heat it to 100°C and
2256 kJ/kg. to convert it to steam. A total of 2516 kJ/kg.
has been added and will be released as the water is condensed
and cooled back to 38°C. Since this transfer is never 100
percent efficient, some of the heat energy will be disipated
in the process. But much of the heat from burning fuel can
be absorbed by boiler water, transported with the steam, and
released at the desired points.
Answer to :back
Why is Water Not Always Satisfactory for Boiler use?
Completely pure water is non-existent. All
natural waters contain various types and amounts of impurities.
Sionce water impurities cause boiler problems, careful consideration
must be given to the quality of the water used for generating
steam.
Answer to :back
What General Types of Impurities Does Water Contain?
Impurities picked up by natural waters may
be classed as : (a) dissolved solids, (b) dissolved gases,
and (c) suspended matter. Water is a good solvet; it dissolves
the rocks and soil it contacts. It dissolves gases from the
air and gases given off from organics is the soil. It picks
up suspended matter from the earth. It is also subject ot contamination
with trade wastes, oils and process materials. In general,
the type of impurities water contains depends on what it contacts;
the amount of impurities depens on the contact times.
Answer to :back
What Dissolved Minerals Do Natural Waters Contain?
The minerals which water picks up from rocks
consist chiefly of calcium carbonate (limestone); magnesium
carbonate (dolomite); calcium sulphate (gypsum), magnesium
sulphate (epsomsalts); silica (sand); sodium chloride (common
salt); sodium sulphate (Glaubers salts); and small quantities
of iron, manganese, fluorides, alumunium, and other substances.
Wastes from mines and certain industrial processes make some
surface waters very acin, while minerals in the earth make
some ground waters very alkaline. Sometimes Nitrates are found
in water and in many cases, this is associate with sewage contamination.
Answer to :back
What is Hardness?
Waters which contain large amounts of calcium
and magnesium minerals are "hard to wash with". The calcium
and magnesium compounds react with soap to form a curb in the
water. These compounds are therefore referred to as water hardness.
The amount of hardness in a naturalwater may vary from several
parts per million to over 500 parts per million. Since calcium
and magnesium compounds are relatively insoluble in water,
they tend to precipitate out to cause scale and deposit problems.
Water hardness, therefore, is an important consideration in
determining suitability of a water or use in generating steam.
Answer to :back
What Gases are Dissolved in Natural Waters?
Water dissolves varying amounts of air which
is composed of 21% oxygen, 78% nitrogen, 1% other gases (including
0.03 - 0.06% carbon dioxide). Oxygen is solublein water at
room temperature and atmospheric pressure to the extent of
about 9ppm. The solubility of wxygen decreases as the temperature
of the water goes up, but water under presure can hold larger
quantities of dissolved oxygen. Although nitrogen is dissolved
in natural water it is inert gas and has little effect on the
character of water used in boilers. Water doesn't usually pick
up more than 10 ppm of carbon dioxide from the air. Carbon
dioxide may be dissolved in water to a much greater extent,
though, through the decay of vegetation and organics in the
soil. Hydrogensulphate and methane may be dissolved in some
waters, but this is not a general occurrence. These gases,
however, can be important when they occur as contaminants.
Answer to :back
What Types of Other Impurities May Water Contain?
Natural waters may contain turbidity, colour,
soil, and precipitated minerals, as well as oil and other trade
wastes. Colour comes from decaying vegetable matter. Turbidity
may consist of very finely divided organic material and mivro-organisms,
as well as suspendd clay and silt. Oils, fats, greases, sewage
and other wastes may contaminate water supplies.
Answer to :back
What is the Difference between Sea Water and Fresh Water?
The main difference is in the amount of dissolved
minerals. Sea water contains about 30 kg. of minerals per 1000
litres (mostly salt). The mineral content of fresh water supplies
is much lower and generally ranges form 5 g. to 1 kg. per 10001.
While work is now in progress on methods of purifying sea and
brackish water at the present time only fresh water supplies
are generally used for boiler feed purposes.
Answer to :back
What are the Sources of Fresh Water and How do they Vary in
Composition?
Fresh water supplies may be either surface
water (rivers, streams, reservoirs, etc.) or ground water (shallow
or deep well waters). In general, ground water supplies are
more consistent in composition and contain less suspended matter
and trubidity than surface supplies which ar affected directly
by rainfall, soil erosion, and trade wastes. On the other hand,
ground waters are usually harder than surface waters. For example,
an average surface supply will contain about 95 ppm total hardnessas
opposed to an average of about 200 ppm total hardness for ground
supplies. In some instances where the ground water is normally
encountered in surface supplies.
Answer to :back
How Does Water Composition Vary from Geographical Standpoint?
Water composition varies throughout the states
depending upon the type and strata of the earth formations.
In the limestone areas the waters contain large quantities
of calcium cabonate. In parts of the country where there is
more of the granite type of rock formation, much less mineral
matter is dissolved and the water will not contain much hardness.
Throughout some state, there are deposits of alkali which the
water will pick up. These are the general geographic variations,
but local conditions in any area may greatly influence the
composition of the water.
Answer to :back
What is Boiler Feed-Water?
The water added to a boiler to rplave evaporation
and blow-down losses is termed 'feed water'. In may cases,
stam is condensed and returned to the boiler as part of the
feed-water. Whatever water is needed to supplement the condensate
returned is termed 'make-up water'. The make-up water is usually
natural water either in its raw state, or treated by some process
before use. Feed-water composition therefore depends on the
quality of the make-up water and the amount of condensate returned
to the boiler.
Answer to :back
Is there any Relationship between Good water for drinking
use and for Boiler Feed?
Except that wewage pollution is harmful to both, there is
not a great deal of similarity between the requirements for drinkable water
and the requirements for boiler feed-water. The minerals in drinking water,
while they might affect the taste, are absorbed by the body and many so-called
'health waters' are high in minerals. On the other hand, water impurities cannot
be handled as well by boilers. Although a boiler is a mass of steel, it is
generally more sensitive about what it consumes than is the human stomach.
For this reason, much care is needed in selecting water treatment.
Answer to :back
How Pure Must Feed-Water be?
Feed-water purity is a matter both of quantity of impurities
and nature of impurities... some impurities such as hardness, iron and silica
are of more concern, for example, than sodium salts, The purity requirements
for any feed-water depnd on how much feed water is used as well as what the
particular boiler design (pressure, heat transfer rate, etc.) can tolerate.
Feed-water purity requirements therefore can vary widely. A low pressure fire-tube
boiler can usually tolerate high feed-water hardness with proper treatment
while virtually all impurities must be removed from water used in some modern,
high pressure boilers.
Answer to :back
How does Operating Pressure Influence Boiler Water Composition requirements?
The Boiler and affiliated Industries Manufacturers' Association
has established limits for boiler water composition with respect to operating
pressure to assure good quality steam. Pending the evolving of new, round-figure
ratios in S.I. units, we literally convert the p.s.i.g. column below :
BOILER PRESSURE |
TOTAL SOLIDS |
ALKALINITY |
SUSPENDED |
(kPa) |
(psig) |
(ppm) |
(ppm) |
solids |
silica* |
0-2070 |
0-300 |
3500 |
700 |
300 |
125 |
2070-3100 |
301-450 |
3000 |
600 |
250 |
90 |
3100-4135 |
451-600 |
2500 |
500 |
150 |
50 |
4135-5170 |
601-750 |
2000 |
400 |
100 |
35 |
5170-6200 |
751-900 |
150 |
300 |
60 |
20 |
6200-6890 |
901-1000 |
1250 |
25 |
40 |
8 |
6890-10335 |
1001-1500 |
1000 |
20 |
20 |
2.5 |
10335-13780 |
1501-2000 |
750 |
50 |
10 |
1.5 |
over 13780 |
over 2000 |
500 |
100 |
5 |
0.5 |
(*) Silica limits based on limiting silica in steam to 0.02-0.03 ppm.
Answer to :back
What is Meant by 'External' and 'Internal' Feed-water Treatment?
External treatment is the reduction or removal of impurities
from water outside the boiler. In general, external treatment is used when
the amount of one or more of the feed=water impurities is too high to be tolerated
by the boiler system in question. There are many types of external treatment
(softening, evaporation, deaerarion, etc.) which can be used to tailor-make
feed-water for a particular system. Internal treatment is the conditioning
of impurities within the boiler system. The reactions occur either in the feed-lines
or in the boiler proper. Internal treatment may be used alone or in conjunction
with external treatment. Its purpose is to properly react with feed-water hardness,
condition slidge, scavenge oxygen and prevent boiler water foaming.
Answer to :back
What Causes Boiler Deposists?
Boiler scale is caused by impurities being precipitated out
of the water directly on heat transfer surfaces or by suspended matter in water
settling out on the metal and becoming hard and adherent. Evaporation in a
boiler causes impurities to concentrate. The high temperatures break down some
minerals, cause others to become less soluble. In general, water in contact
with hot metal will tend to deposit out impurities as it evaporates.
Answer to :back
Which are some Common Types of Boiler Deposits?
In untreated boiler-water, the formation of deposits is like
a back-to-nature movement. That is as minerals are deposited out from water
they form many types of crystalline and rock-like structures such as are encountered
in the earth's strata. Deposits are seldom composed of one constituent alone
but are generally a mixture of various types of minerals, corrosion products
and other water contaminants. The most common types of boiler deposits may
contain : Calcium cabonate, sulphate or silicate; magnesium hydroxide or silicate,
iron oxide, and silica, sludge deposits form boiler water which has been treated
may also contain calcium and magnesium phosphates.
Answer to :back
What are the Characteristics of a carbonate deposi?
A carbonate deposit is usually granular and some-times of
a very porous nature. The crystals of calcium carbonate are large but usually
are matted together with finely divided particles of other materials so that
the scale looks dense and uniform. A carbonate deposit can be easily identified
by dropping it in a solution of acid. Bubbles of carbon dioxide will effervsce
from the scale.
Answer to :back
What are the Characteristics of a Sulphate Deposit?
A sulphate deposit is much harder and more dense than a carbonate
deposit because the crystals are smaller and cement together tighter. A sulphate
deposit is brittle, does not pulverize easily, and does not effervesce when
dropped into acid.
Answer to :back
What are the Characteristics of a Silica Deposit?
A high silica deposit is very hard, resembling percelain.
The crystal of silica are extremely small, forming a very dense and impervious
scale. This scale is extremely brittle and very difficult to pulverize. It
is not soluble in hydrochloric acid and is usually very light coloured.
Answer to :back
What are the Characteristics of an Iron Deposit?
Iron deposits, due either to corrosion or iron contamination
in the water, are very dark coloured. Iron deposits in boilers are most often
magnetic. They are soluble in hot acid giving a dark brown coloured solution.
Answer to :back
What Problems do Deposits Cause?
The biggest problem that deposits cause is over-heating and
failure of boiler tubes. A deposit acts as an insulator and excessive deposits
prevent an efficient transfer of heat through the tubes to the circulating
water. This causes the metal itself to become over heated. When the overheating
is severe enough the metal fails. Boiler deposits can also cause plugging or
partial obstruction of corrosive attack underneath the deposits may occur.
In general, boiler deposits can cut operating efficiency, produce boiler damage,
cause unscheduled boiler outages, and increase cleaning expense.
Answer to :back
What is Carrosion?
Stated simply, general corrosion is the reversion of a metal
to itsore form. Iron, for example, reverts to iron oxide as the result of corrosion.
The process of corrosion, however is a complex electro chemical reaction and
it takes many forms. Corrosion may produce general attach over a large metal
surface or it may result in pinpoint penetration of metal. While basic corrosion
in boilers may be primarily due to reaction of the metal with oxygen, other
factors such as stresses, acid conditions, and specific chemical corrodents
may have an important influence and produce different forms of attack.
Answer to :back
Where is Corrosion Usually Experienced?
Corrosion may occur in the feed-water system as a result
of low pH water and the presence of dissolved oxygen and carbon dioxide. Corrosion
in the boiler proper generally occurs when the boiler water alkalinity is low
or when the metal is exposed to wxygen bearing water either during operation
or idle periods. High temperatures and stresses in the boiler metal tend to
accelerate the corrosive mechanisms. In the boiler metal tend to accelerate
the corrosive mechanisms. In the steam and condensate system corrosion is generally
the result of c ontamination with carbon dioxide and oxygen. Specific contaminants
such as ammonia or sulphur bearing gases may increase attack on copper alloys
in the system.
Answer to :back
What is Corrosion Fatigue?
This type of cracking in boiler metal may occur by two different
mechanisms. In the first mechanism, cyclic stresses such as are created by
rapid heating and cooling are concentrated at points where corrosion has roughened
or pitted the metal surface. This is usually associated with improper corrosion
prevention. The second type of corrosion fatigue cracking occures in boilers
with properly treated water. In these cases corrosion fatigue is probably a
misnomer. These cracks often originate where the metal surfaces are covered
by a dense protective oxide film and cracking occurs from the action of applied
cyclic stresses. Corrosion fatigue cracks are usually thick, blunt and cross
the metal grains. They usually start at internal tube surfaces and are most
often circumferential on the tube.
Answer to :back
What is Caustic Cracking?
Caustic cracking (caustic embrittlement) is a serious type
of boiler metal failure characterized by continous, mostly intergranular cracks.
The following conditions appear to be necessary for this type of cracking to
occure :
- The metal mus be stressed,
- the boiler-water must contain caustic,
- at least a trace of silica must be present in the boiler-water,
and
- some mechanisms, such as a slight leak, must be present to allow
the boiler water to concentrate on the stressed metal.
Answer to :back
What Problems does Corrosion Cause?
Corrosion, in general, causes difficulty from two standpoints.
The first is deterioration of the metal itself, and the second is deposition
of the corrosion products to form deposits. Generally, uniform corrosion
of boiler surfaces is seldom of real concern. Corrosion, however, takes many
insidious forms and deep pits resulting in only a minimum of iron loss may
cause pentration and leaking of boiler tubes. Corrosion underneath certain
types of boiler deposits can so weaken the metal that failure of tubes occurs.
In steam condensate system, replacement of lines and equipment due to corrosion
can be a costly problem.
Answer to :back
What Measures are taken to Prevent Boiler System Corrosion?
Corrosion, in general, causes difficulty from two stand-points.
The first is deterioration of the metal itself, and the second is deposition
of the corrosion products to form deposits. Generally, uniform corrosion
of boiler surfaces is seldom of real concern. Corrosion, however, takes many
insidious forms and deep pits resulting in only a minimum of iron loss may
cause penetration and leaking of boiler tubes. Corrosion underneath certain
types of boiler deposits can so weaken the metal that failure of tubes occurs.
In steam condensate system, replacement of lines and equipment due to corrosion
can be a costly problem.
Why Water Treatment is Needed :
As feed-water enters a boiler the heat causes hardness (cal-cium and magnesium
salts) to come out of solution. Untreated the hardness deposits on the hot
boiler metal to from scale. As water evaporates in the boiler the feed-water
impurities concentrate. Even small amounts ot iron, copper, and silica can
accumulate in the boiler-water and cause serious deposit problems in higher
pressure boilers. Since scale can cause overheating and failure of boiler metal,
preventive water treatment is needed. The corrosion of boiler system metal
is a complex process and takes many forms: general attack, localized pitting,
and various types of cracking in stressed metal. In general, the main factors
causing corrosion are dissolved gases in the water (primarily oxygen) and acid
conditions. High temper-atures speed up the corrosion process.Corrosion is
damaging from several standpoints: it causes weakening and failure of metal
and produces corrosion products which can cause boiler deposits. High concentrations
of dissolved and suspended matter in boiler-water can cause foaming of the
water at the steam release surface. This produces carry-over of the water and
its impurities into the steam. Carry-over results in deposits and other problems
in turbines, engines and other processes using steam. While mechanical and
operational factors also cause carry-over, proper control of water conditions
is important in producing pure steam.
Answer to :back
What is Boiler Water Carry-over?
Boiler water carry-over is the contamination of the steam
with boiler-water solids. There are four common types of boiler-water carry-over.
In one bubbles or froth actually build up on the surface of the boiler-water
and pass out with the steam. This is called foaming and can be compared to
the stable foam found on beer. In the second type small droplets of water
in the form of spray or mist are thrown up into the steam space by the bursting
of the rising steam bubbles at the steam release sur-face. This is sometimes
called 疎quaglobejection・and is like ginger ale or champagne
where no stable foam is formed but drop-lets of liquid are ejected from the
liquid surface. The third condition of carry-over, called priming, is a sudden
surge of boiler-water that carries over with the steam, similar to the effects
produced in uncapping a bottle of charged water. stem contamination may also
occur from leakage of water through im-properly designed or installed steam
separating equipment in a boiler drum.
Answer to :back
What Causes Foaming?
Very high concentrations of any solids in boiler-water
cause foaming. It is generally believed, however, that specific substances
such as alkalis, oils, fats, greases, certain types of organic matter and
suspended solids are particularly conducive to foaming.
Answer to :back
What Causes Priming?
Priming may be caused by improper construction of boiler,
excessive ratings, or sudden fluctuations in steam demand. prim-ing is sometimes
aggravated by impurities in the boiler-water
Answer to :back
How Does Oil Affect Carry-over?
Oil contamination in boiler feed-water, usually form recip-rocating
engines, pumps, etc., can cause serious foaming. This is generally attributed
to the formation of soaps in the boiler-water due to saponification of the
oil by boiler-water alakalis.
Answer to :back
How Do Suspended Solids Affect Carry-over?
The theory advanced is that suspended solids collect in
the surface film surrounding a steam bubble and make it tougher. The steam
bubble therefore resists breaking and builds up a foam. It is believed that
the finer the suspended particles the greater their collection in the bubble.
Experience indicates, however, that many boilers operate with exceedingly
high suspended solids without carry-over while others have carry-over with
only a trace of suspended solids. This would seem to indicate that the type
as well as the quantity of suspended solids has much to do with carry-over.
Answer to :back
What is Selective Silica Carry-over?
Silica can carry over into the steam in two ways. It can
be present in the steam as the result of general boiler-water carry-over
or it can go into steam in a volatile form. In the latter case silica acts
much like a gas and is considered to be selec-tively carried over. As Pressures
increase above 2760 kPa (400 p.s.i), there is an increased tendency for silica
to be selectively carried into the steam in amounts proportionate to the
amount of silica in the boiler-water.
Answer to :back
What Problems are Caused by Carry-over?
The disadvantages of wet steam include a general decrease
in operating efficiency and erosion of turbines and engines. In addition
any dissolved or suspended solids in the boiler-water tend to deposit out
in the steam and condensate syste,. when the solids deposit in superheaters
and turbine, overheating and failure of superheater tubes and reduction in
turbine efficiency can result. Impurities carried over with the can cause
difficul-ties in many processes for which the steam is used.
Answer to :back
What Measures are Usually Taken to Prevent Carry-over?
The most common measure is to maintain the concetratino
of solids in the boiler water at reasonably low levels. Avoiding high water
levels, excessive boiler loads, and sudden load chang-es also helps. Very
often contaminated condensate returned to the boiler system causes carry-over
problems. In these cases the condensate should be temporarily wasted until
the source of contamination is found and eliminated. The use of chemical
anti-foam agents can be very effective in preventing carry-over due to high
concentrations of impurities in the boiler-water.
Removing Impurities from Water :
Coagulants are chemicals to enmesh fine particles of suspended matter in a
water supply to form a floc which settles or can be filtered out. Adding softening
chemicals (lime, soda, ash, etc.) to a water causes some dissolved hardness
salts to precipitate and the suspended matter can then be coagulated and filtered
out. Precipitation processes such as lime soda softening can effectively remove
suspendedmatter, hardness and alkalinity and in some cases reduce the silica
content of the water. When a salt dissolves in water it forms positive ions
(cations) and negative ions (anions). For example, calcium carbonate (CaCO3)
forms a calcium cation (Ca++) and a car-bonate anion (CO3=). The most common
form of ion exchange involves passing water through material which substitutes
sodium for calcium and magnesium cations. This is a typical softening treatment.
Anions can also be removed from water by the use of special ion exchange resins.
Demineralization or complete removal of dissolved minerals involves the use
of both cation and anion exchange materials. In removing impurities from water
htere are many possible combinations of coagulation, precipitation and ion
exchange methods. Other methods of treatment include: deaeration (heating the
water and venting the gases) for reduction of oxygen and carbon dioxide; and
evaporation to produce distilled water.
Answer to :back
What is Clarification?
Clarification is the removal of suspended matter and/or
colour from water supplis. The suspended matter may consist of large particles
which settle out readily. In these cases clarifi-cation equipment merely
involves the use of settling basins and/or filters. Most often, however,
suspended matter in water consists of particles so small that they do not
settle out and even pass through filters. The removal of these finely divided
or colloidal substances therefor requires the use of coagulants.
Answer to :back
What is Coagulation?
Coagulation is the clumping together of finely divided
and coloidal impurities in water into masses which will settle rapid-ly and/or
can be filtered out of the water. Colloidal particles have large surface
areas which keep them in suspension and in addition the particles have negative
electrical charges which cause them to repel each other and resist adhering
together. Coagulation, therefore, involves neutralizing the negative charg-es
and providing a nucleus for the suspended particles to adhere to.
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What Various Types of Coagulants are Used?
The most common coagulants are iron and alumunium salts
such as ferric sulphate, ferric chloride, alumunium sulphate (alum) and sodium
aluminate. Ferric and alumina ions each have three positive charges and therefore
their effectiveness is related their ability to react with the negatively
charged colloidal particles. With proper use these coagulants form a floc
in the water which serves as a kind of net for collecting suspended matter.
In recent years synthetic materials called plyelectro-lytes have been developed
for coagulation purposes. these consist of long chain like meolecules with
positive charges. In some cases organic polymers and special types of clay
are used in the coagulation in making the floc heavier, causing it to settle
out more rapidly.
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What is Chemical Precipitation?
In precipitatino processes the chemicals added react with
dissolved minerals in the water to produce a relatively insoluble reaction
product. Precipitation methods are used in reducing dissolved hardness, alkalinity
and in some silica. The most common example of chemical precipitation in
water treatment is lime-soda softening.
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How Does Lime React in the softening Process ?
Hydrated lime (calcium hydroxyde) reacts with soluble calci-um
and magnesium bicarboantes to form insoluble precipitates. This is shown
by the following equations:
Ca(OH)2 |
+ |
Ca(HCO3)2 |
======> |
2CaCO3 |
+ |
2H2O |
Lime |
|
Calcium |
|
Calcium |
|
Water |
|
|
Bicarbonate |
|
Carbonate |
|
|
Ca(OH)2 |
+ |
Mg(HCO3)2 |
======> |
Mg(OH)2 |
+ |
2CaCO3 |
+ |
2H2O |
Lime |
|
Magnesium |
|
Magnesium |
|
Calcium |
|
Water |
|
|
Bicarbonate |
|
Hydroxide |
|
Carbonate |
|
|
Most of the calcium carbonate and magnesium hydroxide come
out of solution as a sludge and can be removed by settling and filtra-tion.
Lime, therefore, can be used to reduce hardness present in the bocarbonate
form (temporary hardness) as well as decrease the amount of bicarbonate alkalinity
in a water. Lime reacts with magnesium sulphate and chloride and precipitates
magnesium hy-droxide but in this process soluble calcium sulphate and chloride
are formed. Lime is not effective in removing calcium sulphate and chlorides.
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How Does soda Ash React in the Softening Process?
Soda ash is used primarily to reduce non-bicarbonate hard-ness
(also called sulphate hardness or permanent hardness). It reacts as follows:
Na2CO3 |
+ |
CaSO4 |
======> |
CaCO3 |
+ |
Na2SO4 |
Soda Ash |
|
Calcium |
|
Calcium |
|
Sodium |
|
|
Sulphate |
|
Carbonate |
|
Sulphate |
Na2CO3 |
+ |
CaC12 |
======> |
CaCO2 |
+ |
2NaCl |
|
|
Calcium |
|
Calcium |
|
Sodium |
|
|
Chloride |
|
Carbonate |
|
Chloride |
The calcium carbonate formed by the reaction tends to
come out of solution as a sludge. The sodium sulphate and chloride formed
are highly soluble and non-scale forming.
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What are the Various Methods of Lime-Soda Softening?
The two general types are intermittent (batch type) and
continous. The older method of intermittent softening consists of mixing
the chemicals with the water in a tank, allowing time for reaction and
settling of the sludge, and drawing off the clear water. The more modern
method of continous lime-soda softening involves the use of specially compartmented
tanks with prvisions for
- proportioning chemicals continously to the incoming water
- retention time for chemical reactions and settling of sludge,
and
- continous draw-off of softened water. Lime-soda softening may
also be calssified as hot or cold, depending on the tempera-ture
of the water. Hot process softeners increase the rate of chemical
reactions and give better quality water.
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Why are Coagulants Used in the Lime-Soda Process?
Just as coagulants are used for removing suspended matter
in clarification processes, they serve to clump togehter precipi-tates
in the softening process. Coagulants can speed up settling of sludge as
much as 25 - 50 per cent. Sodium aluminate has a special advantage as a
coagulant in lime-soda softening since unlike most other coagulants it
is alkaline and also contributes to the softening readtions, particularly
in reducing magnesium. Effective use of coagulants helps remove silica
in hte softening process. Silica tends to be absorbed in the floc produced
by coagulation of sludge.
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Under What Conditions Are Phosphate Softeners Use?
Sodium phosphates react readily with calcium and magnesium
salts. Phosphate softeners are generally used only on naturally soft or
presoftened waters, however, becauser relatively high amounts of magnesium
in the water cause a very sticky precipitate in reacting with phosphate.
Properly used, phosphate softeners can effectively reduce hardness to very
low levels. Improved ion exchange softening methods have largely supplanted
phosphate softners in new installations.
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What are the Disadvantages of Lime-Soda Softening?
The main disadvantage is that while hardness is reduced
it is not completely removed. Wide variations in raw water composi-tion
and flow rate also make control of this method difficult since this involves
adjusting the amounts of lime and soda ash being fed.
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What are the Advantages of Lime-Soda Softening?
The main advantage is that in reducing hardness, alkalinity
and silica can also be reduced. In addition, prior clarification of the
water is not usually necessary since suspended matter and turbidity are
also removed in the process. Another advantage is that with continous hot
process softening some removal of oxygen and carcon dioxide can be achieved.
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What is Ion Exchange?
When minerals dissolve in water they form electrically
charge particles called ions. Calcium carbonate, for example, forms a calcium
ion with plus charges (a cation) and a carbonate ion with negative charges
(an anion). Certain natural and synthetic materials have the ability to
remove mineral ions from water in exchange for others. For exam-ple, in
passing water through a simple cation excahnge softener all of calcium
and magnesium ions are removed and replaced with sodium ions. Ion exchange
materials usually are provided in the form of small beads or crystals which
compose a bed several feet deep through which the water is passed.
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What are the Various Types of Ion Exchange Materials?
Ion exchange materials are basically of two types: cation
and anion exchangers. Cation exchange materials react only with positively
charged ions such as Ca++ and Mh++. Anion exchanger materials react only
with the negatively charged ions such as carbonate (CO3-) and sulphate
(SO4-). Zeolite materials are cation exchangers composed chiefly of sodium,
alumunium and silica. There are several other types of cation exchange
materials of an organic or resinous nature. The anion materials are usually
organic in nature and are of two basic types: weak base and strong base
types. Weak base exchagers don稚 take out carbon dioxide or silica
(actually carbonic acid and silica acid) but remove strong acid anions
by a process that is more like adsorption than ion exchange. Strong base
anion exchangers on the other hand can redce silica and carbon dioxide
to very low values. Cation exchangers usually opcles which settle out readily.
In these cases clarifi-cation equipment merely involves the use of settling
basins and/erate on either a sodium or hydrogen 祖ycle・ That
is, they may be designed to replace all cations in the water with either
sodium or hydrogen. Strong base anion exchangers are generally operated
on a hydroxide・weak base on a carbonate cycle. Chloride anion exchange
is also used in some processe.
Why Water Treatment is Needed :
As feed-water enters a boiler the heat causes hardness (cal-cium and magnesium
salts) to come out of solution. Untreated the hardness deposits on the hot
boiler metal to from scale. As water evaporates in the boiler the feed-water
impurities concentrate. Even small amounts ot iron, copper, and silica can
accumulate in the boiler-water and cause serious deposit problems in higher
pressure boilers. Since scale can cause overheating and failure of boiler
metal, preventive water treatment is needed. The corrosion of boiler system
metal is a complex process and takes many forms: general attack, localized
pitting, and various types of cracking in stressed metal. In general, the
main factors causing corrosion are dissolved gases in the water (primarily
oxygen) and acid conditions. High temper-atures speed up the corrosion process.Corrosion
is damaging from several standpoints: it causes weakening and failure of
metal and produces corrosion products which can cause boiler deposits. High
concentrations of dissolved and suspended matter in boiler-water can cause
foaming of the water at the steam release surface. This produces carry-over
of the water and its impurities into the steam. Carry-over results in deposits
and other problems in turbines, engines and other processes using steam.
While mechanical and operational factors also cause carry-over, proper control
of water conditions is important in producing pure steam.
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What is Boiler Water Carry-over?
Boiler water carry-over is the contamination of the
steam with boiler-water solids. There are four common types of boiler-water
carry-over. In one bubbles or froth actually build up on the surface
of the boiler-water and pass out with the steam. This is called foaming
and can be compared to the stable foam found on beer. In the second type
small droplets of water in the form of spray or mist are thrown up into
the steam space by the bursting of the rising steam bubbles at the steam
release sur-face. This is sometimes called 疎quaglobejection・and
is like ginger ale or champagne where no stable foam is formed but drop-lets
of liquid are ejected from the liquid surface. The third condition of
carry-over, called priming, is a sudden surge of boiler-water that carries
over with the steam, similar to the effects produced in uncapping a bottle
of charged water. stem contamination may also occur from leakage of water
through im-properly designed or installed steam separating equipment
in a boiler drum.
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What are the Disadvantages of Ion Exchange?
The main disadvantage with sodium cycle ion exchange
soften-ing is that the total solids, alkalinity and silica contents of
the raw water are not reduce. A problem encountered with cation exchange
on the hydrogen cycle is corrrosion from acidity of the effluent. With
demineralization the chief difficulties are with cost particularly on
high solids raw waters, and the corrosive nature of the effluent water.
In general, fouling of the ion exchange material with suspended or colliodal
matter in the raw water can produce difficulties and some water impurities
cause degradation of the material. In many cases, therefor, ion ex-change
processes require paretreatment of the water supply.
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What are the Advantages of Ion Exchange?
The main advantage of zeolite softening is ease of
control. Ordinary variations of hardness in the raw water or in flow
rate do not affect completeness of softening. Also the system general-ly
takes up less space than the lime-soda system and in most cases gives
a softer water. The use of acid exchangers has advan-tages when a low
alkalinity soft water is required. The main advantage of ion exchange
demineralization is its ability to produce better quality water than
can be obtained by any other method.
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How Does Oil Affect Carry-over?
Oil contamination in boiler feed-water, usually form
recip-rocating engines, pumps, etc., can cause serious foaming. This
is generally attributed to the formation of soaps in the boiler-water
due to saponification of the oil by boiler-water alakalis.
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How Do Suspended Solids Affect Carry-over?
The theory advanced is that suspended solids collect
in the surface film surrounding a steam bubble and make it tougher. The
steam bubble therefore resists breaking and builds up a foam. It is believed
that the finer the suspended particles the greater their collection in
the bubble. Experience indicates, however, that many boilers operate
with exceedingly high suspended solids without carry-over while others
have carry-over with only a trace of suspended solids. This would seem
to indicate that the type as well as the quantity of suspended solids
has much to do with carry-over.
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What is Selective Silica Carry-over?
Silica can carry over into the steam in two ways. It
can be present in the steam as the result of general boiler-water carry-over
or it can go into steam in a volatile form. In the latter case silica
acts much like a gas and is considered to be selec-tively carried over.
As Pressures increase above 2760 kPa (400 p.s.i), there is an increased
tendency for silica to be selectively carried into the steam in amounts
proportionate to the amount of silica in the boiler-water.
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What Problems are Caused by Carry-over?
The disadvantages of wet steam include a general decrease
in operating efficiency and erosion of turbines and engines. In addition
any dissolved or suspended solids in the boiler-water tend to deposit
out in the steam and condensate syste,. when the solids deposit in superheaters
and turbine, overheating and failure of superheater tubes and reduction
in turbine efficiency can result. Impurities carried over with the can
cause difficul-ties in many processes for which the steam is used.
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What Measures are Usually Taken to Prevent Carry-over?
The most common measure is to maintain the concetratino
of solids in the boiler water at reasonably low levels. Avoiding high
water levels, excessive boiler loads, and sudden load chang-es also helps.
Very often contaminated condensate returned to the boiler system causes
carry-over problems. In these cases the condensate should be temporarily
wasted until the source of contamination is found and eliminated. The
use of chemical anti-foam agents can be very effective in preventing
carry-over due to high concentrations of impurities in the boiler-water.
Removing Impurities from Water :
Coagulants are chemicals to enmesh fine particles of suspended matter in a
water supply to form a floc which settles or can be filtered out. Adding
softening chemicals (lime, soda, ash, etc.) to a water causes some dissolved
hardness salts to precipitate and the suspended matter can then be coagulated
and filtered out. Precipitation processes such as lime soda softening can
effectively remove suspendedmatter, hardness and alkalinity and in some cases
reduce the silica content of the water. When a salt dissolves in water it
forms positive ions (cations) and negative ions (anions). For example, calcium
carbonate (CaCO3) forms a calcium cation (Ca++) and a car-bonate anion (CO3=).
The most common form of ion exchange involves passing water through material
which substitutes sodium for calcium and magnesium cations. This is a typical
softening treatment. Anions can also be removed from water by the use of
special ion exchange resins. Demineralization or complete removal of dissolved
minerals involves the use of both cation and anion exchange materials. In
removing impurities from water htere are many possible combinations of coagulation,
precipitation and ion exchange methods. Other methods of treatment include:
deaeration (heating the water and venting the gases) for reduction of oxygen
and carbon dioxide; and evaporation to produce distilled water.
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What is Coagulation?
Coagulation is the clumping together of finely divided
and coloidal impurities in water into masses which will settle rapid-ly
and/or can be filtered out of the water. Colloidal particles have large
surface areas which keep them in suspension and in addition the particles
have negative electrical charges which cause them to repel each other
and resist adhering together. Coagulation, therefore, involves neutralizing
the negative charg-es and providing a nucleus for the suspended particles
to adhere to.
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What Various Types of Coagulants are Used?
The most common coagulants are iron and alumunium salts
such as ferric sulphate, ferric chloride, alumunium sulphate (alum) and
sodium aluminate. Ferric and alumina ions each have three positive charges
and therefore their effectiveness is related their ability to react with
the negatively charged colloidal particles. With proper use these coagulants
form a floc in the water which serves as a kind of net for collecting
suspended matter. In recent years synthetic materials called plyelectro-lytes
have been developed for coagulation purposes. these consist of long chain
like meolecules with positive charges. In some cases organic polymers
and special types of clay are used in the coagulation in making the floc
heavier, causing it to settle out more rapidly.
Answer to :back
What is Chemical Precipitation?
In precipitatino processes the chemicals added react
with dissolved minerals in the water to produce a relatively insoluble
reaction product. Precipitation methods are used in reducing dissolved
hardness, alkalinity and in some silica. The most common example of chemical
precipitation in water treatment is lime-soda softening.
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What is the Purpose of Deaeration?
Since dissolved oxygen in water is a big factor in
corrosion in boiler systems it is desirable that this be removed before
the water is put into a boiler. Feed-water deaeration is accomplished
by intimately mixing the water and steam in a de-aerating heater. Part
of the steam is vented, arrying with it the bulk of the dissolved oxygen
from the water. There are two basic types of steam de-aerators: the spray
type and the tray type. In the spray de-aerator a jet of steam mixes
intimately with the feed water being sprayed into the unit. In the tray
type the incoming water is allowed to fall over a series of trays causing
the water to be broken up into small droplets to permit intimate contact
with incoming steam.
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How are Evaporators Employed?
Water is sometimes pretreated by evaporation to produce
relatively pure vapour which is then condensed and used for boiler feed
purposes. Evaporators are of several different types, the simplest being
a tank of water through which steam coils are passed to heat the water
to the boiling point. Sometimes to increase the efficiency the vapour
from the first tank is passed through coils in a second tank of water
to produce additional heating and evaporation. Other types of evaporation
include a 素lash type・which operates under a partial vacuum
causing a lowering of the voiling point of water and evaporation at lower
temperatures. Evaporators have advantages where steam as a sources of
heat is readily available. They also have particular advantages over
demineralization, for example, when the dissolved solids in the raw water
are very high.
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What Combinations of External Treatment Methods are Generally Used?
As mentioned previously, water containing suspended
solids,organics, and/or turbidity usually requires clarifications prior
to ion exchange methods. Also, since simple cation exchange does not
reduce the total solids of the water supply, it is sometimes used in
conjunction with precipitation type softening. One of the most common
and efficient combination treatments is the hot lime-zeolite precess.
This involves pretreatment of the water with lime to reduce hardness,
alkalinity and in some cases silica, and subsquent treatment with a cation
exchange softener. This system of treatment accomplishes several functions:
soften-ing, alkalinity and silica reduction, some oxygen reduction, and
removal of suspended matter and turbidity.
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When is Internal Treatment of Boiler Feed-water Necessary?
Chemical treatment of water inside the boiler is usually
essential whether or not the water has been pretreated. Internal treatment,
therefor, complements external treatment by taking care of any impurities
entering the boiler with the feed water (hardness, oxygen, silica, etc.)
regardless of whether the quant- ity is large or small. In many cases
external treatment of the water supply is not necessary and the water
can be treated by internal methods alone. Internal treatment can constitute
the sole treatment when boileers operate at low or moderate pressure,
when large amounts of condensed steam are used for feed water, or when
the raw water available is of good quality.
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What Should a Good Internal Water Treatment Programme Accomplish?
The purpose of an internal treatment programme is fourfold:
(1) react with any feed-water hardness and prevent it from pre-cipitating
on the boiler metal as scale, (2) condition any sus-pended matter such
as hardness sludge or iron oxide in the boiler and make it non-adherent
to the boiler metal, (3) provide anti-foam protection to permit a reasonable
concentration of dissolved and suspended solids in the boiler water without
foam carry-over, and (4) eliminate oxygen from the water and provide
enough alka-linity to prevent boiler corrosion. In addition, as supplementary
measures an internal treatment should prevent corrosion and scaling of
the feed-water system and protect againts corrosion in the steam-condensate
systems.
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What chemicals are Used in Internal Treatment?
The softening chemicals used include soda ash, caustic
and various sypes of sodium phosphates. These chemicals react with calcium
and magnesium compounds in the feed water. At times sodium silicate is
used to contributed alkalinity as well as react selectively with magnesium
hardness. The materials used for conditioning sludge include various
organic materials of the tannin, lignin or alginate classes. It is important
that these organics are so selected and processed that they are voth
effec-tive and stad stable at the boiler operating pressure. Certain
synthetic organic materials are used as anti-foam agents. The chemicals
used to scavenge oxygen include sodium sulphite and hydrazine. Various
combinations of polyphosphates and organics are used for preventing scale
and corrosion in feed-water sys-tems. Volatile neutralizing amines and
filming inhibitors are used for preventing condensate corrosion.
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How are Carbonates Reacted on by INternal Treatment?
Calcium bicarbonate entering with the feed water is
broken down at boiler temperatures or reacts with caustic soda to form
calcium carbonate. Since calcium carbonate is relatively insolu-ble it
tends to come out of solution. Sodium carbonate partially breaks down
at high temperature to sodium hydroxide (caustic) and carbon dioxide.
When phosphates are used in internal treatment they react with calcium
carbonate to form calcium phosphate and sodium carbonate (soda ash).
In the presence of sufficeint hy-droxide (caustic) alkalinity, mahnesium
bicarbonate will pre-cipitate as magnesium hydroxide or will react with
any silica present to form magnesium silicate. The minerals precipitated
from solution (calcium carbonate, calcium phosphate, magnesium hydroxide,
magnesium silicate, ect.) form sludge in the water which must be conditioned
to prevent its sticking to the metal. The conditioned sludge is removed
from the boiler by blow-down.
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How are Sulphates Reacted on by Internal Treatment?
High temperatures in the boiler water reduce the solubility
of calcium culphate and tend to make it precipitate out directly on the
boiler metal as scale. Consequently calcium sulphate must be reacted
upon chemically to cause a precipitate to form in the water where it
can be conditioned and removed by blow-down. Calcium sulphate is reacted
on either by sodium carbonate, sodium phophate or sodium silicate to
form insoluble calcium carbonate, phosphate or silicate. Magnesium sulphate
is reacted upon by caustic soda to form a precipitate of magnesium hydroxide.
some magnesium may react with silica to form magnesium silicate. Sodium
sulphate is highly soluble and remains in solution unless the water is
evaporated almost to dryness.
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How is Silica Reacted upon by Internal Treatment?
In untreated waters silica tends to precipitate out
directly as scale at hot spots on the boiler metal or it may combine
with calcium to produce a hard calcium silicate scale.Treatment for silica
involves keeping the boiler-water alkalinity high enough to hold silica
in solution. Usually there is enough magnesium in the water to precipitate
some of the silica as sludge. At times proper treatment with magnesium
can tie up silica when it is a special problem. Some organic materials
such as starches tend to prevent the adherence of silica to the boiler
metal probably by a physical action.
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How is Sludge Conditioned in Internal Treatment?
There are two general approaches to conditioning sludge
inside a boiler: by coagulation or dispersion. When the total amount
of sludge is great (as the result of high feed-water hardness) it is
practical to coagulate the sludge to form large flocculent particles.
Thes flow readily with the boiler water and can be removed by blow-down.
This can be accomplished by careful adjustment of the amounts of alkalis,
phosphates and organics used for treatment, based on the fee-water analysis.
When the amount of sludge is not great (low hardness feed-waters) it
is more practical to use a higher percentage of phosphates in the treatment.
Phosphates form finely divided sludge particles. A higher percentage
of organic sludge dispersants is used in the treatment to keep the sludge
particles dispersed throughout the boiler water.
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What Difficulties are Encountered in Internal Treatment?
The main difficulty is the presence of a large amount
of sludge formed when feed-water hardness is high. This may increase
the amount of blow-down required. When internal treatment is used alone
(without pretreatment of the water by external means) there is more possibility
for scale in the preboiler system and fee-water lines. it is important
that someone experienced in the technology helps to set up an internal
treatment programme which will minimize these difficulties.
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What are the Advantages of Internal Treatment?
The prime advantage is that in many instances internal
treatment can eliminate the need for extensive external treatment equipment.
This gives a definite economic advantage. In addition, the simplicity
of an internal treatment programme offers a decid-ed savings in manpower
for feeding and control. A qualified consultant can help decide what
water quality is required for a specific boiler system, and choose the
most economical means of obtaining the required quality.
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How are Internal Treatment Chemicals Fed?
Common feeding methods include the use of chemical
solution tanks and proportioning pumps or special ball briquette chemical
feeders. In general, softening chemical (phosphates, soda ash, causti,
etc.) are added directly to the fee-water at a point near the entrance
to the boiler drum. They may also be fed through a separate line discharging
in the feed-water drum of the boiler. The chemicals should discharge
in the fee-water section of the boiler so that reactions occur in the
water before it enters thesteam generating areas. Softening chemicals
may be added continously or intermittently depending on feed-water hardeness
and other factors. Chemicals added to react with dissolved oxygen (sulphate,
hydrazine, etc.) preferably should be fed continously as far back in
the feed-water system as possible. Similarly, chemicals used to prevent
scale and corrosion in the feed-water system (polyphosphates, organics,
etc.) should be fed continous-ly. Chemicals used to prevent condensate
system corrosion may be fed directly to the steam or into the feed-water
system, depend-ing on the specific chemical used. continous feeding is
preferred bu intermittent application will suffice in some cases.
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How are Chemical Dosages Controlled?
Chemical dosages are based primarily on the amount
of impu-rities in the feed-water. For example, the amount of softening
chemicals needed depends on fee-water hardness;the amount of sodium sulphate
needed depends on the amount of dissolved oxygen in the feed-water. In
addition, however, a set amount of extra chemical treatment is added
to provide a residual is akind of insurance and serves as the basis for
treatment control.
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What Boiler Water Tests are Used for Treatment Control?
Routinge control teste of the boiler water vary according
to the type of chemical treatment used but they may include tests for:
alkalinity,m phosphate, sulphate and organic color. Boiler water hardness
tests are not often made because it is generally assumed that if there
is enough alkalinity and/or phosphate present in the boiler-water, the
hardness has reacted completely. In testing for sulphate it is assumed
that if an adequate ridual is present, the feed-water oxygen has been
removed;this may not always be true, especially if the sulphate feed
is not continous and if ordinary uncatalyzed sodium sulphate is used.
Generally antifoams are incorporated in organic treatments so testing
for organic color gives an indication both of sludge conditioner present
as well as level of antifoam treatment.
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What Tests are Usually Made as a Check for Contaminants?
Here, again, the specific tests made vary with the
type of contamination suspected. Some checks made fairly often, however,
include teste for: iron, oil and silica. Usually the iron test serves
as a check on corrosion products brought back with the condensate but
may also be used when appreciable iron is present in the maka up water.
Oil tests usually require laboratory facil-ities but visual inspection
of samples can show up gross contami-nation. While silica is usually
present to some extent in boiler waters, periodic checks are sometimes
made to detect unusual contamination or to indicate when additional blow-down
is needed to keep silica concentrations below a preset limit.
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What Units are Used in Expressing Water Analysis Results?
The most common unit is parts per million. One p.p.m.
of a substance in a water sample represents one unit mass of the substance
in each million unit mass of the water. For example, one p.p.m of salt
(NaCl) means one kg of salt per million kg of water. There is still some
die-hard use of the classic unit grains per gallon (g.p.g.) but this
expected to disappear due to universal S.I. usage as will the unit equivalents
per million (e.p.m). This mention is therefore made merely as a matter
of record.
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Why are some Analysis Results Expresse 羨s CaCO2・
Water treatment reactions are based on the combining
mass of the reacting substances. For example, 106 kilograms of soda ash
(molecular mass 106) reacts with 136 kilograms of calcium sulphate (molecular
weight 136). The molecular mass of calcium carbonate (CaCO3) is the round
number 100. In order to simplify chemical dosage calculations all hardness
and alkilinity results are usually based on the molecular mass of calsium
carbonate and are expressed as 舛aCO3・ For example, using
this system, one p.p.m of calcium culphate (expressed as CaCO3). This
is the same as converting English pounds, German marks, or frech francs
into a 100 cent dollar.
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What is Blow-down?
Blow-down is the removal from the boiler of water containing
concetrated dissolved and suspended solids. As the blow-down water is
replaced with lower solids feed water the boiler water is essentially
being diluted. By regulating the amount of blow-down, therefore, the
amount of solids in the boiler-water can be controlled.
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How much Blow-down is Needed?
This depends on how many concetrations of the various
feed-water impurities a given boiler can tolerate;the more concentra-tions
possible the less blow-down needed. For example, with 10 feedwater concentrations
in a boiler, blow-down equal to 10 per cent of the feed-water flow rate
is needed;with 20 concentrations only 5 per cent blow-down is needed.
To illustrate how blow-down requirements are calculated let us assume
that the maximum amount of suspended solids (sludge) in the boiler water
that a particu-lar boiler can tolerate is 500 p.p.m. If the fee-water
contains 50 p.p.m. of hardness it can be concentrated only about 10 times
(since feed water hardness is precipitated as suspended solids in the
boiler water). This means that for every 50 kg of water fed to the boiler
about 5 kh of boiler water must be blown down to keep the suspended solids
from exceeding 500 p.p.m. Suspended solids, however, may not be the limiting
factor in all cases; other factors which may limit feed-water concentrations
include dissolved solids, alkalinity, silica or iron.
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What Tests are Made in Regulating Blow-down?
Since there are no simple test for routinely checking
the amount of suspended solids in boiler-water, blow-down is usually
controlled through use of a simple instrument which measures the electrical
conductivity of the water. This test gives an estimate of the dissolved
solids present in the boiler-water. Chloride tests are also used for
blow-down control since chlorides are not reacted on by chemical treatment.
By checking both the fee-water and boiler-water chlorides the number
of feed-water concentra-tions can be calculated. In some higher pressure
boilers, silica or iron tests may also be made to control blow-down.
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What is the Difference between Continous and 善uff・Blow-down?
All boilers have blow-down connections located at low
points where sludge is likely to collect. Operning these blow-down valves
periodically for shot intervals gives a 叢uff・or intermittent
removal of sludge and conctrated solids. Many boil-ers also have vlow-down
connections consisting of an offtake located just below the water level
in the steam release area. A small amount of water is continously removed
through these con-nections. The use of continous blow-down in addition
to 叢uff・or bottom blow-down kes it possible to maintain
the solids and chemical residuals at more consistent levels in the boiler
water. Continous blow-down also minimizes the amount of blo-down re-quired
with resultant savings in heat and chemicals. Continous blow-down also
causes less upset in boiler water circulation and operation.
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What Causes Corrosion in Steam Condensate Systems?
Most condensate system corrosion is caused by carbon
dioxide and oxygen, arried into the system with the steam. Carbon diox-ide,
dissolved in the pure condensed steam, form corrosive car-bonic acid.
if oxygen is present with carbon dioxide, the corro-sion rate is much
higher, and is likely to produce localised pitting. Ammonia, in combination
with carbon dioxide or oxygen, attacks copper alloys.
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How is Steam Condensate Corrosion Prevented?
The general approach may involve removing oxygen from
the feed-water mechanically and chemically, and providing pretreatment
of the make-up water to minimize potential carbon dioxide formation in
the boiler. In addition, an effective chemi-cal treatment programme is
required. This may consist of using volatile amines to neutralise carbon
dioxide and/or a volatile filming inhibitor to form a barrier between
the metal and the corrosive condensate. Mechanical conditions such as
poor trapping and draining of lines, and air in-leakage may need to be
correct-ed.
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How do Chemical Oxygen Scavengers Help Control Condensate System Corrosion?
As previously mentioned mechanical equipment (de-aerator)
is often used to reduce feed-water oxygen. The best designed and operated
de-aerators can reduce oxygen to as low as 0.007 parts per million or
less. Most de-aerators or feed-water heaters are less effective. Since
very samll amounts of oxygen, however, can cause boiler corrosion and
corrosion in steam condensate system, chemical treatment is therefor,
needed to assure complete oxygen removal. Sodium sulphate is the chemical
most commonly used for this purpose. Greatly improved oxygen removal
is obtained, hoev-er, when the sulphate is catalyzed. Catalyzed sodium
sulphate can reduce oxygen content of water (at room temperature) from
the saturation point to zero in less than 30 seconds. Without a catalyst
it takes up to 10 minutes under the same conditionis to reduce the oxygen
content by only about 30 per cent. Fast reac-tions are important since
oxygen should be removed before the water enters the boiler. Otherwise
some oxygen will escape form the boiling water into the steam lines and
aggrave corrosion in the condensate system.
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What is the Basis for Choice between Neutralizing and Filming Inhibitors?
The proper choice of ingibitor depends on the boiler
system, plant lay-out operating conditions and fee-water composition.
In general, colatile amines are better with low make-up, low feed-water
alkalinity, and good oxygen control. Filming inhibitors usually give
more economical protection with high make-up, air in-leakage high feed-water
alkalinity or where the system is operated interminently. In some cases
a combination of treatments is needed.
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What Characteristics Should a Good Condensate Corrosion Inhibitor Have?
A goog volatile neutralizing amine should have a favourable
distribution ratio in steam and condensate so that it protects the entire
steam-condensate system. It should have no insoluble reaction products
and should be stable at high temperatures and pressures. A goo filming
inhibitor should be easy to disperse in water so that it can be fed uniformly.
It should be stale under usage conditions and form a thin protective
film without causing deposits in either the boiler or the steam-condensate
system.
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How are Deposits and Corrosion Prevented in Feed-water Systems?
Deposits in feed-water systems are most frequently
caused by hardness coming out of solution as the water goes through feed-
water heaters or as the feedlines enter the boiler. Deposits also can
occur from premature reaction of treatment chemicals with hardness in
the feed-water. Prevention involves the use of stabi-lizing chemicals
fed continously to retard hardenss precipita-tion. Proper design of the
chemical feed system can minimize premature chmical reactions. Corrosion
of feed-water system generally results from low alkalinity or dissolved
oxygen in the water. Raising the pH of the water and the continous feed
of catalyzed sodium sulphate will minimize this problem.
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What is the Wet Method of Boiler Lay-Up?
This is a method of storing boilers full of water so
that they can be readily returned to service. it involves adding extra
chemicals (usually caustic, organics, and sodium sulphite to the boiler-water.)
The water level is raised in the idle boiler to eliminate air spaces
and the boiler is kept completely full of treated water. Special considerations
are needed for protecting superheaters.
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What is the Dry Method of Boiler Lay-Up?
This method of lay-up is usually for longer boiler
outages. It involves draining, cleaning and drying out the boiler. a
material which absorbs moisture such as hydrated lime or silica gel is
placed in trays inside the boiler. The boiler is then sealed carefully
to prevent inleakage of air. Periodic inspection and replacement of the
drying chemical is required during long storage periods.
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