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Abstract
Two things are needed for any technology to be suitable for use in the industry, viz.
1. Technical feasibility and 2. Economical feasibility. The use of ultrasound for
waste water treatment has been shown to be technically feasible by numerous reports
in the literature over the years. But there are hardly any exhaustive reports which
address the issue of economical feasibility of the use of ultrasound for waste water
treatment on industrial scale. Hence an attempt was made to estimate the cost for
the waste water treatment using ultrasound. The costs have been calculated for 1000
L/min capacity treatment plant. The costs were calculated based upon the rate constants
for pollutant degradation. The pollutants considered were phenol, trichloroethylene
(TCE) and reactive azo dyes. Time required for ninety percent degradation of pollutant
was taken as the residence time. The amount of energy required to achieve the target
degradation was calculated from the energy density (watt/ml) used in the treatability
study. The cost of treatment was calculated by considering capital cost and operating
cost involved for the waste water treatment. Quotations were invited from vendors
to ascertain the capital cost of equipments involved and operating costs were calculated
based on annual energy usage. The cost was expressed in dollars per 1000 gallons of
waste water treated. These treatment costs were compared with other established Advanced
Oxidation Process (AOP) technologies. The cost of waste water treatment for phenol
was in the range of $89 per 1000 gallons for UV/US/O(3) to $15,536 per 1000 gallons
for US alone. These costs for TCE were in the range of $25 per 1000 gallons to $91
for US+UV treatment and US alone, respectively. The cost of waste water treatment
for reactive azo dyes was in the range of $65 per 1000 gallon for US+UV+H(2)O(2) to
$14,203 per 1000 gallon for US alone. This study should help in quantifying the economics
of waste water treatment using ultrasound on industrial scale. We strongly believe
that this study will immensely help the researchers working in the area of applications
of ultrasound for waste water treatment in terms of where the technology stands today
as compared to other available commercial AOP technologies. This will also help them
think for different ways to improve the efficiency of using ultrasound or search for
other ways of generating cavitation which may be more efficient and help reduce the
cost of treatment in future.
Copyright 2009 Elsevier B.V. All rights reserved.