SU887475A1 - Device for automatic control of waste and natural water purification process - Google Patents

Description

The receiver, while the electrochemical converter is equipped with a gravity valve, and the sample preparation unit is equipped with a dosage controller and a gearbox.

The drawing shows a block diagram of the proposed device.

The device contains an electrochemical converter 1, equipped with reagent dosing unit 2 and sample preparation unit 3, connected via converter 1 to normalized unit 4 and balanced converter 5, thermo-correction unit 6 and matching unit 7, equipped with a power source 8, and to a regulating device 9. Converter 5 is formed by the bridge circuit 10 and the null organ I.

The electrochemical converter 1 is equipped with a gravity valve 12, the saddle 13 of which separates the overflow chamber 14 and the displacement chamber 15, the chamber 14 is hydraulically connected to the drain chamber 16, which is equipped with an injector 17 with a neck 18, a sensing element 19 and a bypass tube 20. In chamber 15 a pearesiTOs supply nozzle 21 is installed, and a discharge nozzle 22 is installed in the chamber 16. Element 19 is formed by cathode 23 and anode 24.

The reagent dosing unit 2 is equipped with tanks 25 and 26 for the reagents, micro-dispensers 27 and 28 and a mixer 29.

The sample preparation unit 3 is equipped with an inlet pressure regulator 30 with a pressure gauge 31, a metal mesh filter 32, a dynamic dosage regulator 33, a drain tank 34 and a gearbox 35 formed by successively connected output pressure regulators 36 and 37.

The device works as follows.

The analyzed sewage or natural water is pumped from the sewage treatment plant through the pressure inlet regulator 30, and the required pressure of the supplied water is set by the pressure gauge 31. Filter 32 removes suspended solids and various undissolved impurities with periodic replacement of the filter cartridge. Gear 35 stabilizes the pressure of water after passing the filter 32, which then flows through injector 17 into chamber 15. Simultaneously with the water being analyzed, chamber 15 receives the appropriate reagents from mixer 29 of unit 2. Hence most of the water passes through tube 20 to sensitive element 19, and the smaller part is through a gravity valve 12, which maintains a constant water pressure in the chamber 15, in the chambers 14 and 16.

Together with the water circulating through the element 19, the abrasive sand, previously introduced into the chamber 16 and cleaning during the movement, also moves.

the electrode surface of the cathode 23 and the anode 24.

Water from chamber 16 enters tank 34, which is connected to regulator 33, which ensures overall stabilization of the hydrodynamic regime in the device and sampling for chemical analytical determinations.

In the sensitive element 19, as a result of electrochemical reactions, an output signal is generated that is proportional to the chlorine content in the water being analyzed. The output signal is given by node 4 to

the normalized value is adjusted for the temperature of the analyzed water by node 6 and converted by block 7, bridge circuit 10 and null organ II for supply to control device 9 included in the automatic control system of sewage treatment plants.

This ensures that the technological regime of wastewater and natural water treatment is maintained within optimal limits.

Due to the fact that, in the proposed device, the electrochemical converter is equipped with a gravity valve, and the sample preparation unit is equipped with a dynamic dosage regulator and a reducer, and

In this case, the reagent dosing unit and the sample preparation unit are connected through an electrochemical converter with an additionally installed standardizing unit and a balanced converter, unit

thermocorrection and matching unit with the power source connected to the normalizing unit and with the regulating device, a significant increase in the accuracy of the content control is achieved

dissolved chlorine (up to 4-5%) and reliability of the device.

Claims (2)

1.Smirnov D.N. Automatic control of wastewater and natural water treatment processes. M., stroiizdat, 1974, p. 196-199. 2. Manusova N. B. and others. Automation of wastewater treatment processes in the textile industry. M., Easy Industri, 1979, p. 86-88.