INDUSTRIAL WASTE MANAGEMENT 535
furniture, and containers. There are approximately 35,000
establishments in the United States. The industry uses approx-
imately 32 billion cubic meters of water per year. Four per-
cent of the plants use 92 percent of the water. These industriesgenerate wastewaters which vary in quantity and quality.
Table 8 provides the reader with a brief summary of the major
liquid wastes, their origin, characteristics, and methods of
treatment in four major metals industries.TABLE 6
Summary of industrial wastes from several major chemical industriesIndustries Producting Wastes Origin of Major Wastes Major Characteristics Major Treatment and Disposal MethodsAcids and Alkalies Dilute wash waters; many varied
dilute acids and basesLow or high pH, low organic content Unflow or straight neutralization,
coagulation and sedimentation
Detergents Washing and purifying soaps and
detergentsHigh in BOD and saponified soaps Flotation and skimming, precipitation
with CaCl 2
Explosives Washing TNT and guncotton for
purification, washing and
pickling of cartridgesTNT, colored, acid, odorous, and
contains organic acids and
alcohol from powder and cotton,
metals, acid, oils, and soapsFlotation, chemical Precipitation,
biological treatment, aeration,
chlorination of TNT, neutralization,
adsorption
Pesticides Washing and purification of
productsHigh organic matter, benzene ring
structure, toxic to bacteria and
fish, acidDilution, storage, activated-carbon
adsorption, alkaline chlorinationPhospate and phosporus Washing, screening, floating
rock, condenser bleed-off
from phospate reduction plantClays, slimes and oils, low pH, high
suspended solids, phosphorus,
silica and fluorideLagooning, mechanical clarification,
coagulation and settling of refined
waste
Formaldehyde Residues from manufacturing
synthetic resins and from
dyeing synthetic fibersNormally high BOD and
formaldehyde, toxic to bacteria in
high concentrationsTrickling filtration, absorption on
activated charcoalPlastics and resins Unit operations from polymer
preparation and use; spills and
equipment washdownsAcids, caustic, dissolved organic
matter such as phenols,
formaldehyde, etc.Discharge to municipal sewer, reuse,
controlled-dischargeFertilizer Chemical reactions of basic
elements. Spills, cooling
waters, washing of products,
boiler blowdownSulfuric, phosphoric, and nitric
acids; minerals elements, P, S, N,
K, Al, NH 3 , NO 3Neutralization, detain for reuse,
sedimentation, air stripping of NH 3 ,
lime precipitationToxic chemicals Leaks, accidental spills, and
refining of chemicalsVarious toxic dissolved elements
and compounds such as Hg and
PCBsRetention and reuse, change in
production, neutralization and
precipitation, carbon adsorptionTABLE 7
Summary of wastes generated from various oil refinery operationsMajor Industrial Operations Origin of Major Wastes Major Characteristics Major Treatment and Disposal MethodsCrude oil and product storage Primary fractionation of oil and
water, spills and leakagesHigh concentrations of emulsified
oil, COD, TSSAPI separation, DAF, settling, aerationCrude desalting Chemical desalting, heating and
gravity separation of oilEmulsified and free oil, ammonia,
phenol, sulfide, TSS, high BOD
and CODAPI separation, DAF, activated sludge,
carbon adsorptionCracking Thermal cracking or catalytic
cracking, fractionation, steam
stripping, and overhead
accumulators or fractionatorsBODs, COD, ammonia, phenol,
sulfides, cyanides, and alkalinityChemical oxidation, biological treatment
carbon adsorptionPolymerization Catalytic reaction, acid, removal
action, and gas stabilizerAlkaline waste stream, high in
sulfide, mecaptans, and ammoniaAcid catalysts recycled, carbon
adsorption
Alkylation Catalytic reaction caustic and
water wastes, neutralization of
hydrocarbon streamsOil, sulfides, TSS, fluoride Neutralization, chemical oxidation,
sedimentationC009_004_r03.indd 535C009_004_r03.indd 535 11/18/2005 10:31:55 AM11/18/2005 10:31:55 AM