SU664933A1 - Method of biological purification of waste water - Google Patents

Description

one

The invention relates to methods for the treatment of low contaminated industrial wastewater and can be used for the treatment of effluents from the chemical industry and the production of organic synthesis.

The known method of sewage treatment with the help of hydrocultures of higher aquatic plants, according to which the wastewater is artificially enriched before being contacted with hydrocultures, oxygenated in the reservoir, and then consistently passed through a steady flow through 2-7 basins, in which the higher aquatic plants that are held by the roots above the bottom of the pools 1.

The closest to the invention in its technical essence and the achieved result is a method of biological treatment of industrial wastewater in a flowing pond by contacting them with hydrocultures of higher aquatic plants for 10-15 days at a speed of movement of the treated waters of 0.001-0.002 m / s 2.

The disadvantage of this method is a low degree of purification (60% for suspended solids, up to 50% for BOD2o, 30-45% but COD) and secondary pollution of treated water with dead biomass of hydrocultures due to low velocity in the wastewater pond.

The aim of the invention is to increase the degree of purification.

This goal is achieved by the fact that the contacting is carried out in the channel for 0.8-1.2 days with the speed of movement of treated wastewater 0.08-0.12 m / s, and then in the pond for 3-5 days the speed of movement of the treated water is 0.015-0.02 m / s.

The method is carried out as follows.

Weakly contaminated wastewater from the chemical industry and organic synthesis production is first exposed to contact with the cultivation of higher aquatic plants (with reeds, reed beds and lake reeds) in the channel for 0.8-1.2 days at the speed of movement of treated wastewater 0 , 08-0.12 m / s, and then - in a pond for 3-5 days at a speed of movement of the treated waters of 0.015-0.02 m / s.

Example 1. Production weakly contaminated wastewaters of the chemical and petrochemical synthesis enterprises with a total volume of 3000 M-V4 effluent, whose quality is characterized by: COD - 90 mgO2 / l, BOD20 -20 mgOz / l,

suspended solids - 80 IG / L, are contacted for 0.8 days in the channel with hydrocultures of higher aquatic plants (common reed and rogoz narrow-leaved) at a speed of clearing, water of 0.12 m / s, after which the contact is made pond for three days at a speed of movement of treated water 0.02 m / s.

As a result of the purification, the water quality indicators become as follows: COD - 31.5 mg O2 / L, BOD20 - 3 mg Og / L, suspended solids - 4 mg / L, i.e., the cleaning efficiency is COD, BOD2o and suspended substances, respectively, 65, 85 and 90%.

Example 2. Wastewater under the conditions of example 1 of the following quality: COD - 150 mgO2 / l, BOD20 - 30 mg O2 / L, suspended solids - 120 mg / l, are contacted in the channel for 1.2 days at a water speed of 0 , 08 m / s n in the pond for 5 days at a speed of movement of the purified water of 0.015 m / s.

The cleaning efficiency is: for COD - 78% (33 mg 02 / l), for BODZ - 87% (4 mgO2 / l), for porcine substances - 95% (6 mg / l).

The proposed method in comparison with the known method provides a significantly higher degree of wastewater treatment from 45 to 83% by COD, from 50 to 87% by BODO and from 60 to 95% by suspended substances, and also provides minimal secondary pollution of the treated waste liquid.

The proposed method provides the possibility of reuse of treated wastewater in cooling systems of water supply of industrial enterprises.

The economic effect of the industrial implementation of the method is 1 million 16 thousand rubles. per year (applied to wastewater treatment 72 thousand meters per day).

Claims (2)

1. Forward Germany No. 1484837, cl. C02C 1/02, 1973. 2. Rodziller I. D. and Kanygina A. V. The results of wastewater treatment in a biological flow pond. Proceedings of the symposium on self-purification of water bodies and wastewater mixing. Tallinn, 1969, p. 90-94.