Biosorption-membrane reactor with flat filtering elements: the calculation method

Summary

The results of studying the Don River water purification with the use of biosorption-membrane method in a biosorption-membrane reactor with flat-frame filtering elements are presented. An experimental plant with a capacity of less than 2.7 m³/day with addition of powdered activated carbon was constructed at the Novocherkassk water treatment facilities. The specific flow through the membrane was less than 17.6 l/(m²·h). The experimental results showed the high efficiency of natural water purification in a biosorption-membrane reactor that provided for meeting the requirements of Sanitary Rules and Regulations (SanPiN). The efficiency of COD reduction averaged to 41.2%, color – 57.3%, permanganate value – 33.3%. During the entire experiment no suspended solids were found in permeate. The obtained data were used as a basis for calculating the specific rate of organics oxidation estimated by COD and permanganate value. The maximum values of V_max oxidation rate and K_m Michaelis constant were determined by graphical method of double reciprocal. The permanganate value dependence of the specific organics oxidation rate and COD from temperature was obtained. Temperature constant of Van Hoff’s equation was determined by COD and permanganate value to calculate the specific rate of organic pollutants oxidation during winter (10–11 °С) and summer seasons (20–22 °С). The method of calculating a biosorption-membrane reactor is presented.

Key words

powdery activated carbon , natural water treatment , biosorption membrane reactor , specific oxidation rate , biosorption , membrane filtration

Vibromembrane filtration technology: eliminating the negative effect of concentration polarization (international experience)

Summary

Представлена уникальная технология мембранного разделения жидкостей VSEP, которая позволяет минимизировать негативное влияние концентрационной поляризации. Отличие технологии заключается в вибрации поверхности мембран. В результате достигается ряд ключевых преимуществ технологии. Все это существенно раздвигает границы использования мембранных методов и делает возможным применение мембран там, где ранее это было невозможно. Кроме того, процесс разделения различных жидкостей не требует использования антискалянтов, а рабочие значения удельной производительности установок и выхода фильтрата значительно превышают таковые в традиционных системах мембранного разделения. Технология уже находит массовое применение в мировой инженерной практике для самых различных отраслей промышленности.

Key words

membranes , nanofiltration , membrane filtration , VSEP technology , concentration polarization