From the desk of Mrs. Baby Abraham . . . . . .

Each country generates their share of effluence depending upon the manufacturing capacity because this is inevitable to happen. When we eat a plantain, its peel is the waste that we produce. If we throw it on the road, some one may fall. It can become degenerate and cause nuisance, attract rats and flies. Produce nasty smell.

 When the whole amount of industrial effluence  starts acting according to their inherent nature and qualities, we get fire  and fumes and froth on the water in lakes as it occurred in Bangalore, well water getting contaminated near tanneries, and chemical factories  etc.

Now these effluence will have the same characteristics of their fine products which is despatched to the markets nationally and internationally, why not make use of the bi- products from them. When milk is

made into cheese and whey,  people throw away the whey. Now major companies collect all the whey and produce excellent health and energy  and stamina boosting products for our athletes who  compete in Olympic !!!

The rare earth production in China left so much waste and discarded them until it was found that even more valuable minerals were hidden in the waste !!

The cotton industry did not knew what to do with the cotton seed which amounts to tons and tons of waste , till some one found that we could produce cotton seed oil from this waste  . !!!

From all these high powered waste we produce fuel also, since just a small portion of vegetables can  produce enough fuel to sustain a small family’s needs, how much more powerful and clean  and  efficient fuel can be generated from these   powerful waste . Instead of destroying the earth by leaving it to flow

everywhere , inflicting diseases to man and animals and  polluting the atmosphere,  let us harness its utility side .

POINT SOURCES OF POLLUTION: LOCAL EFFECTS AND IT’S CONTROL – Vol. I –

Industrial Wastewater-Types, Amounts and Effects - Hanchang SHI INDUSTRIAL WASTEWATER-TYPES, AMOUNTS AND EFFECTS Hanchang SHI Department of Environmental Science and Engineering, Tsinghua University, Beijing, China Keywords: Wastewater, industry, environment, pollution, effect, amount, types Contents 1. Introduction 2. The types of industrial waste water 3. The amounts of industrial wastewater 4. The effects of industrial wastewater 5. Other factors related to the effect of industrial wastewater Glossary Bibliography Biographical Sketch Summary Industrial wastewater is one of the important pollution sources in the pollution of the water environment. During the last century a huge amount of industrial wastewater was discharged into rivers, lakes and coastal areas. This resulted in serious pollution problems in the water environment and caused negative effects to the eco-system and human’s life. There are many types of industrial wastewater based on different industries and contaminants; each sector produces its own particular combination of pollutants. Like the various characteristics of industrial wastewater, the treatment of industrial wastewater must be designed specifically for the particular type of effluent produced. The amount of wastewater depends on the technical level of process in each industry sector and will be gradually reduced with the improvement of industrial technologies. The increasing rates of industrial wastewater in developing countries are thought to be much higher than those in developed countries. This fact predicts that industrial wastewater pollution, as a mean environment pollution problem, will move from developed countries to developing countries in the early 21st century. 1. Introduction Until the mid 18th century, water pollution was essentially limited to small, localized areas. Then came the Industrial Revolution, the development of the internal combustion engine, and the petroleum-fuelled explosion of the chemical industry. With the rapid development of various industries, a huge amount of fresh water is used as a raw material, as a means of production (process water), and for cooling purposes. Many kinds of raw material, intermediate products and wastes are brought into the water when water passes through the industrial process. So in fact the wastewater is an "essential by-product” of modern industry, and it plays a major role as a pollution sources in the pollution of water ©Encyclopedia of Life Support Systems (EOLSS) 191 POINT SOURCES OF POLLUTION: LOCAL EFFECTS AND IT’S CO

environment. 2. The types of industrial waste water There are many types of industrial wastewater based on the different industries and the contaminants; each sector produces its own particular combination of pollutants (see Table 1). Sector Pollutant Iron and steel BOD, COD, oil, metals, acids, phenols, and cyanide Textiles and leather BOD, solids, sulfates and chromium Pulp and paper BOD, COD, solids, Chlorinated organic compounds Petrochemicals and refineries BOD, COD, mineral oils, phenols, and chromium Chemicals COD, organic chemicals, heavy metals, SS, and cyanide Non-ferrous metals Fluorine and SS Microelectronics COD and organic chemicals Mining SS, metals, acids and salts Table 1: Water Pollutants by the Industrial Sector The metal-working industries discharge chromium, nickel, zinc, cadmium, lead, iron and titanium compounds, among them the electroplating industry is an important pollution distributor. Photo processing shops produce silver, dry cleaning and car repair shops generate solvent waste, and printing plants release inks and dyes. The pulp and paper industry relies heavily on chlorine-based substances, and as a result, pulp and paper mill effluents contain chloride organics and dioxins, as well as suspended solids and organic wastes. The petrochemical industry discharges a lot of phenols and mineral oils. Also wastewater from food processing plants is high in suspended solids and organic material. Like the various characteristics of industrial wastewater, the treatment of industrial wastewater must be designed specifically for the particular type of effluent produced. Generally, industrial wastewater can be divided into two types: inorganic industrial wastewater and organic industrial wastewater. 2.1 Inorganic industrial wastewater Inorganic industrial wastewater is produced mainly in the coal and steel industry, in the nonmetallic minerals industry, and in commercial enterprises and industries for the surface processing of metals (iron picking works and electroplating plants). These wastewaters contain a large proportion of suspended matter, which can be eliminated by sedimentation, often together with chemical flocculation through the addition of iron or aluminum salts, flocculation agents and some kinds of organic polymers. The purification of warm and dust-laden waste gases from blast furn

POINT SOURCES OF POLLUTION: LOCAL EFFECTS AND IT’S CONTROL – Vol. I - Industrial Wastewater-Types, Amounts and Effects - Hanchang SHI cupola furnaces, refuse and sludge incineration plants, and aluminum works results in wastewater containing mineral and inorganic substances in dissolved and undissolved form. The pre-cooling and subsequent purification of blast-furnace gases requires up to 20 m3 water per t of pig iron. On its way into the gas cooler the water absorbs fine particles of ore, iron and coke, which do not easily settle. Gases dissolve in it, especially carbon dioxide and compounds of the alkali and alkaline earth metals, if they are water-soluble or if they are dissolved out of the solid substances by gases washed out along with them. In the separation of coal from dead rock, the normal means of transport and separation is water, which then contains large amounts of coal and rock particles and is called coalwashing water. Coal-washing water is recycled after removal of the coal and rock particles through flotation and sedimentation processes. Other wastewater from rolling mills contain mineral oil and require additional installations, such as scum boards and skim-off apparatus, for the retention and removal of mineral oils. Residues of emulsified oil remaining in the water also need chemical flocculation. In many cases, wastewater is produced in addition to solid substances and oils, and also contains extremely harmful solutes. These include blast-furnace gas-washing wastewater containing cyanide, wastes from the metal processing industry containing acids or alkaline solutions (mostly containing non-ferrous metals and often cyanide or chromate), wastewater from eloxal works and from the waste gas purification of aluminum works, which in both cases contain fluoride. Small and medium sized non-metallic-minerals plants and metal processing plants are so situated that they discharge their wastewater into municipal wastewater systems and have to treat or purify their effluents before discharge, in compliance with local regulations. 2.2 Organic industrial wastewater Organic industrial wastewater contains organic industrial waste flow from those chemical industries and large-scale chemical works, which mainly use organic substances for chemical reactions. The effluents contain organic substances having various origins and properties. These can only be removed by special pretreatment of the wastewater, followed by biological treatment. Most organic industrial wastewaters are produced by the following industries and plants: ƒ The factories manufacturing pharmaceuticals, cosmetics, organic dye-stuffs, glue and adhesives, soaps, synthetic detergents, pesticides and herbicides; ƒ Tanneries and leather factories; ƒ Textile factories; ƒ Cellulose and paper manufacturing plants; ƒ Factories of the oil refining industry; ƒ Brewery and fermentation factories

ƒ Metal processing industry.

As examples, some special types of wastewater produced by the industries mentioned

above are briefly introduced as follows.

Wastewater produced from the pharmaceutical industries

 The quality of the wastes from the production of pharmaceuticals varies a great deal,

owing to the variety of basic raw materials, working processes and waste products. It is a

characteristic of the pharmaceutical industry that very many products as well as

intermediate products are manufactured in the same plant. Thus different kinds of effluent

with widely varying qualities flow from the different production areas.

For large chemical industries it is also usual to manufacture pharmaceutical products

together with other chemical products. Some times waste substances include the

extraction residues of natural and synthetic solvents, used nutrient solutions, specific

poisonous substances, and many other organics.

The wastewater produced by the pharmaceutical industry has a very bad quality for

wastewater treatment. Usually the concentration of COD is around 5000 – 15000 mg/L,

the concentration of BOD5 is relative low, and the ratio of BOD5 /COD is lower than 30%

which means the wastewater has a poor biodegradability. Such wastewater has bad color

and high (or low) pH value, and it needs a strong pretreatment method, followed by a

biological treatment process with a long reaction time.

Wastewater produced by tannery plants

A tannery is one of the most water intensive plants, and its production process consists of

several steps. The quality of water depends only to a slight degree on the type of hides and

the mechanical and chemical methods used in tanning. In a tannery with chrome and bark

tanning, the wastewater resulting from the different processes are as follows:

ƒ Soaking and washing 22.5%

ƒ Liming 17.5%

ƒ Rinsing 5.5%

ƒ Plumping and bating 19.0%

ƒ Chrome tanning 2.0%

ƒ Bark tanning 2.0%

ƒ Washing and drumming 31.5%

In fact the wastewater flow is very uneven. The peak flow can be 250% of the hourly

average flow rate.

The wastewater produced by a tannery (including preparation of the hides) has a fairly

acid pH and high chloride content (up to 5 g Cl/L). It contains a high concentration of

COD (about 1500 – 2500 mg/L), a high amount of settable substances (10 – 20 g/L) and

emulsified fat, and tends to form foam. The dichromate content can reach a peak value of

2000 mg/L. So the tannery wastewater is a killer to the water environment if it is

POINT SOURCES OF POLLUTION: LOCAL EFFECTS AND IT’S CONTROL – Vol. I - Industrial Wastewater-Types, Amounts

and Effects - Hanchang SHI

Bibliography

Alicia Leung, Deepak Si

nha., (1998) Brewery Industry China Hong Kong Management Case Study

,Management Development Center of Hong Kong, Hong Kong. [This report shows the components of

wastewater produced by the brewery industry and its effects.]

Bhaskaran, T. R, () Tannery Wastes, Guidelines for the Control of Industrial Wastes, WHO/WD/ 73.14

[This report presents the components of tannery wastewater and the control methods.]

Czysz W. and Schneider W., (1989)Waste Water Technology: Origin, Collection, Treatment and Analysis

of Waste Water, Springer-Verlag Berlin Heidelberg, New York, pp103-109 [This article show the

wastewater amounts produced by the different processes in a tannery with chrome and bark tanning.]

Julie, Stauffer, (1998) The Water Crisis: Constructing Solution to Freshwater Pollution, Earthscan

Publications Limited, London UK. [This article show the major pollutants in wastewater produced by

different industrial sectors.]

Modern Methods of Plant Analysis Vol. 20 Analysis of Plant Waste Materials, Springer- Verlag, Berlin

Heidelberg, 1999, pp 41-42 [This article presents the characteristic of mixed brewery wastewater.]

Meybeck M., Chapman V.D. and Helmer R., (1990) Global Freshwater Quality ( A First Assessment ),

Published on behalf of the WHO and UNEP, Blackwell Ltd., USA. [This report presents the amounts of

industrial wastewater produced by different industrial sectors and the increasing trend in different areas of

the world.]

Biographical Sketch

Han-chang SHI is a professor of the Department of Environmental Science and Engineering, Tsinghua

University and the director of State Key Joint Laboratory of Environment Simulation and Pollution Control

in P. R. China. He graduated from the Department of Environmental Science and Engineering, Tsinghua

University in 1984 and studied in Water Research Center in the U.K. and University of Michigan in the

U.S.A. as a senior visiting scholar during 1989 and 1994. The major research fields of him are biological

wastewater treatment, refractory and toxic organics treatment using anaerobic acidification process,

modeling and simulation of aerobic biological wastewater treatment process, and low toxic wastewater

                                    

Each country generates their share of effluence depending upon the manufacturing capacity because this is inevitable to happen. When we eat a plantain, its peel is the waste that we produce. If we throw it on the road, some one may fall. It can become degenerate and cause nuisance, attract rats and flies. Produce nasty smell.

 When the whole amount of industrial effluence  starts acting according to their inherent nature and qualities, we get fire  and fumes and froth on the water in lakes as it occurred in Bangalore, well water getting contaminated near tanneries, and chemical factories  etc.

Now these effluence will have the same characteristics of their fine products which is despatched to the markets nationally and internationally, why not make use of the bi- products from them. When milk is

made into cheese and whey,  people throw away the whey. Now major companies collect all the whey and produce excellent health and energy  and stamina boosting products for our athletes who  compete in Olympic !!!

The rare earth production in China left so much waste and discarded them until it was found that even more valuable minerals were hidden in the waste !!

The cotton industry did not knew what to do with the cotton seed which amounts to tons and tons of waste , till some one found that we could produce cotton seed oil from this waste  . !!!

From all these high powered waste we produce fuel also, since just a small portion of vegetables can  produce enough fuel to sustain a small family’s needs, how much more powerful and efficient fuel can be generated from these  toxic powerful waste . Instead of destroying the earth by leaving it to flow

everywhere , inflicting diseases to man and animals and atmosphere,  let us harness its utility side .