Puricare Industrial Enterprises: WATER SOURCES, HYDROLOGIC CYCLE AND IMPURITIES - The physical and chemical characteristics of surface and ground water supply vary considerably over time. A sudden storm can cause a dramatic short term change in the composition of a water supply. Over a longer time period, surface water chemistry varies with the seasons.

Monday, July 4, 2016

WATER SOURCES, HYDROLOGIC CYCLE AND IMPURITIES - The physical and chemical characteristics of surface and ground water supply vary considerably over time. A sudden storm can cause a dramatic short term change in the composition of a water supply. Over a longer time period, surface water chemistry varies with the seasons.

Hydrologic Cycle, Surface and Groundwater Impurities

Abundant supplies of fresh water are essential to the development of industry. Enormous quantities are required for the cooling of products and equipment, for process needs, for boiler feed, and for sanitary and potable water supply.

THE PLANETARY WATER CYCLE

Industry is a small participant in the global water cycle .The finite amount of water on the planet participates in a very complicated recycling scheme that provides for its reuse.

This recycling of water is termed the "Hydrologic Cycle" (see Figure 1-1).

Evaporation under the influence of sunlight takes water from a liquid to a gaseous phase. The water may condense in clouds as the temperature drops in the upper atmosphere.

Wind transports the water over great distances before releasing it in some form of precipitation. As the water condenses and falls to the ground, it absorbs gases from the environment. This is the principal cause of acid rain and acid snow.

WATER AS A SOLVENT

Pure water (H20) is colorless, tasteless, and odorless. It is composed of hydrogen and oxygen. Because water becomes contaminated by the substances with which it comes into contact, it is not available for use in its pure state.

To some degree, water can dissolve every naturally occurring substance on the earth. Because of this

property, water has been termed a "universal solvent." Although beneficial to mankind, the solvency power of water can pose a major threat to industrial equipment.

Corrosion reactions cause the slow dissolution of metals by water. Deposition reactions, which produce scale on heat transfer surfaces, represent a change in the solvency power of water as its temperature is varied.

The control of corrosion and scale is a major focus of water treatment technology.

WATER IMPURITIES

Water impurities include dissolved and suspended solids. Calcium bicarbonate is a soluble salt. A solution of calcium bicarbonate is clear, because the calcium and bicarbonate are present as atomic sized ions which are not large enough to reflect light.

Some soluble minerals impart a color to the solution. Soluble iron salts produce pale yellow or green solutions; some copper salts form intensely blue solutions. Although colored, these solutions are clear.

Suspended solids are substances that are not completely soluble in water and are present as particles. These particles usually impart a visible turbidity to the water. Dissolved and suspended solids are present in most surface waters.

Seawater is very high in soluble sodium chloride; suspended sand and silt make it slightly cloudy.

An extensive list of soluble and suspended impurities found in water is given in Table 1-1.

Table 1-1. Common impurities found in fresh water.

Constituent

Chemical Formula

Difficulties Caused

Means of Treatment

Turbidity

non-expressed in analysis as units

imparts unsightly appearance to water; deposits in water lines, process equipment, etc.; interferes with most process uses

coagulation, settling, and filtration

Hardness

calcium and magnesium salts, expressed as CaCO₃

chief source of scale in heat exchange equipment, boilers, pipe lines, etc.; forms curds with soap, interferes with dyeing, etc.

softening; demineralization; internal boiler water treatment; surface active agents

Alkalinity

bicarbonate(HCO₃^-), carbonate (CO₃^2-), and hydroxide(OH^-), expressed as CaCO₃

foam and carryover of solids with steam; embrittlement of boiler steel; bicarbonate and carbonate produce CO₂ in steam, a source of corrosion in condensate lines

lime and lime-soda softening; acid treatment; hydrogen zeolite softening; demineralization dealkalization by anion exchange

Free Mineral Acid

H₂SO₄ , HCI. etc., expressed as CaCO₃

corrosion

neutralization with alkalies

Carbon Dioxide

CO₂

corrosion in water lines, particularly steam and condensate lines

aeration, deaeration, neutralization with alkalies

hydrogen ion concentration defined as:

pH	=	log	1
			[H⁺]

pH varies according to acidic or alkaline solids in water; most natural waters have a pH of 6.0-8.0

pH can be increased by alkalies and decreased by acids

Sulfate

SO₄^2-

adds to solids content of water, but in itself is not usually significant, combines with calcium to form calcium sulfate scale

demineralization, reverse osmosis, electrodialysis, evaporation

Chloride

Cl ^-

adds to solids content and increases corrosive character of water

demineralization, reverse osmosis, electrodialysis, evaporation

Nitrate

NO₃^-

adds to solids content, but is not usually significant industrially: high concentrations cause methemoglobinemia in infants; useful for control of boiler metal embrittlement

demineralization, reverse osmosis, electrodialysis, evaporation

Fluoride

F^-

cause of mottled enamel in teeth; also used for control of dental decay: not usually significant industrially

adsorption with magnesium hydroxide, calcium phosphate, or bone black; alum coagulation

Sodium

Na⁺

adds to solids content of water: when combined with OH^-, causes corrosion in boilers under certain conditions

demineralization, reverse osmosis, electrodialysis, evaporation

Silica

SiO₂

scale in boilers and cooling water systems; insoluble turbine blade deposits due to silica vaporization

hot and warm process removal by magnesium salts; adsorption by highly basic anion exchange resins, in conjunction with demineralization, reverse osmosis, evaporation

Iron

Fe²⁺ (ferrous)
Fe³⁺ (ferric)

discolors water on precipitation; source of deposits in water lines, boilers. etc.; interferes with dyeing, tanning, papermaking, etc.

aeration; coagulation and filtration; lime softening; cation exchange; contact filtration; surface active agents for iron retention

Manganese

Mn²⁺

same as iron

Aluminum

AI³⁺

usually present as a result of floc carryover from clarifier; can cause deposits in cooling systems and contribute to complex boiler scales

improved clarifier and filter operation

Oxygen

O₂

corrosion of water lines, heat exchange equipment, boilers, return lines, etc.

deaeration; sodium sulfite; corrosion inhibitors

Hydrogen Sulfide

H₂S

cause of "rotten egg" odor; corrosion

aeration; chlorination; highly basic anion exchange

Ammonia

NH₃

corrosion of copper and zinc alloys by formation of complex soluble ion

cation exchange with hydrogen zeolite; chlorination; deaeration

Dissolved Solids

none

refers to total amount of dissolved matter, determined by evaporation; high concentrations are objectionable because of process interference and as a cause of foaming in boilers

lime softening and cation exchange by hydrogen zeolite; demineralization, reverse osmosis, electrodialysis, evaporation

Suspended Solids

none

refers to the measure of undissolved matter, determined gravimetrically; deposits in heat exchange equipment, boilers, water lines, etc.

subsidence; filtration, usually preceded by coagulation and settling

Total Solids

none

refers to the sum of dissolved and suspended solids, determined gravimetrically

see "Dissolved Solids" and "Suspended Solids"

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