ELECTROCOAGULATION TREATMENT OF JOINT OIL-EMULSION AND CHROME-CONTAINING WASTEWATER OF METALWORKING ENTERPRISES

The results of studying the process of electrocoagulation processing of joint oil-emulsion and chromium-containing wastewaters, which are formed at metal-working enterprises, are presented. Objective: to optimize the process of electrochemical neutralization of a joint effluent stream containing emulsified oil products and hexavalent chromium ions, and to study the composition and structure of sludge. Data were obtained on the study of the properties and composition of the sludge formed during the electrical treatment of a joint effluent containing emulsified oil products and hexavalent chromium ions to develop a disposal technology using thermogravimetric and x-ray phase analyzes. The results of the research during the planning of the experiment made it possible to determine the optimal regimes by pH and contact time.

Color Removal and COD Reduction of Organic Effluent Stream from a Petrochemical Plant

The best known procedures for effluent treatment from petrochemical industry are to be discussed and systematized. This article briefs the concerns raised due to wastewaters released by petrochemical industry, treatment methods presently used for treating the petrochemical industrial effluents and new innovative processes proposed for the petrochemical industrial effluents. This paper investigates the various effluent treatment methods for the removal of color and COD reduction in caprolactam effluent. The results demonstrated that advanced oxidation processes are found to be effective for the removal of color and COD reduction from caprolactam effluent.

MATHEMATICAL MODELLING OF THE REMOVAL OF ORGANIC MICROPOLLUTANTS IN THE ACTIVATED SLUDGE PROCESS: A LINEAR BIODEGRADATION MODEL

Before wastewaters can be released into the environment, they must be treated to reduce the concentration of organic pollutants in the effluent stream. There is a growing concern as to whether wastewater treatment plants are able to effectively reduce the concentration of micropollutants that are also contained in their influent streams. We investigate the removal of micropollutants in treatment plants by analysing a model that includes biodegradation and sorption as the main mechanisms of micropollutant removal. For the latter a linear adsorption model is used in which adsorption only occurs onto particulates.The steady-state solutions of the model are found and their stability is determined as a function of the residence time. In the limit of infinite residence time, we show that the removal of biodegradable micropollutants is independent of the processes of adsorption and desorption. The limiting concentration can be decreased by increasing the concentration of growth-related macropollutants. Although, in principle, it is possible that the concentration of micropollutants is minimized at a finite value of the residence time, this was found not to be the case for the particular biodegradable micropollutants considered.For nonbiodegradable pollutants, we show that their removal is always optimized at a finite value of the residence time. For finite values of the residence time, we obtain a simple condition which identifies whether biodegradation is more or less efficient than adsorption as a removal mechanism. Surprisingly, we find that, for the micropollutants considered, adsorption is always more important than biodegradation, even when the micropollutant is classified as being highly biodegradable with low adsorption.