SU1201232A1 - Device for automatic control of process of industrial waste water neutralization - Google Patents

Abstract

A DEVICE FOR AUTOMATIC CONTROL OF THE NEUTRALIZATION PROCESS OF INDUSTRIAL WASTE WATER, containing a flow-through mixer-reactor, a pH meter at the reactor inlet and a pH meter at its outlet, connected to the input of the isodromic regulator. “,,,%: ..:. the output of which is connected to the reagent dispenser, and the proportional limits tuning unit connected to the regulator, characterized in that, in order to improve the quality of the neutralization process and economy of the reagent, it additionally contains a third pH meter, located between other pH meters, water, delay unit, adder, correcting elements, threshold element, while the pH meter at the input through the delay element and the third pH meter are connected to the adder, the output of which is connected to the first correcting element m and a threshold element, connected, (Linked to a proportional band setting unit, a flow meter is connected to the second and third correction elements, the first and second correction elements are connected to the controller inputs, and the third to the delay element. iNd 00 tc

Description

The invention relates to wastewater treatment and can be used in reagent treatment plants for industrial effluents contaminated with phosphorus salts in the chemical and metallurgical industries. The circuit of the invention is the improvement of the quality of the neutralization process, the economy of the reagent and the simplification of the device. In FIG. 1, a diagram of the device is shown; FIG. 2 - neutralization curves (change of pH value) along the reactor length The device contains a mixer reactor 1, an isodrom regulator 2 for stabilizing the pH at the reactor outlet, pH meters 3, 4 and 5 with sensors, delay element 6, adder 7, threshold element 8, unit 9 for setting the proportional limits of the regulator, the actuator JO of the reagent dispenser, the flow meter 11 of the waste water, the corrective element 12, 13 and 14 (compensators). The length of the mixing reactor, for example, is 12 m, the pH meters meters 5, 4, 3 are located respectively at a distance of 2, 4, 10 meters and along the length of the mixer reactor 1. The pH meter output 3 is connected to the regulator 2, which acts on the actuator 10 of the reagent dispenser. The output of the pH meter 5 through the delay element 6 and the output of the pH meter 4 are connected to the adder 7, the output of which is connected to the input of the correction element 13, as well as through the threshold element 8 to the block 9, which changes the tuning parameters of the controller Torus 2, the sensor of the flow meter 11 is connected to a correction element 12, the output of which is connected to the regulator 2, as well as a correction element 14, the output of which is connected to the delay element 6. The device works as follows. Sensor 5 measures the pH at point a and sends a signal through delay element 6 to adder 7, delay element 6 delays C1 (it drives sensor 5 for the time the water volume passes from point a to point b. Sensor 4 measures pH at point b sends a signal to adder 7. In adder 7, the difference in pH is determined at points ai 322 in. By this difference one can indirectly judge the composition of acids in the reactor volume. The signal from adder 7 is fed to a correction element 13 and further to regulator 2. Submission correction signal from adder 7 allows you to compensate for the effect perturbation on the object, i.e., on the reactor, on the change of acid acid. water allows you to change the reactant supply to the reactor in advance, without waiting for the deviation of the pH from the specified value at the reactor code. torus. Therefore, a correction for a change in the value of the delay time in the element 6 is introduced from the flow meter 11 through the correction element 14. This allows an objective value of the pH change to be obtained from point a to point c. The selection of quince points for measuring the pH difference at the reactor inlet in each particular object is carried out experimentally, the isodromic regulator 2 is tuned to work with weak acids. If the difference between the signals from sensors 5 and 4 is large enough, which corresponds to the presence of ileic acid in the waste water (this and further changes in the composition of strong acids can lead to a deterioration in the dynamic mode of operation of the regulator 2), then with this critical difference, the threshold element 8 which starts to pass a signal from the adder 7 to the block 9. adjustment of the parameters of the regulator 2. This allows you to change the proportional limits of the regulator 2 in order for it to work optimally for the changed composition islot in the waste water.

Retention allows improving the quality of process control to neutralize the reagent consumption for neutralization by 15%.

1Z

Reagent 10

Claims (1)

DEVICE FOR AUTOMATIC CONTROL OF THE INDUSTRIAL WASTE WATER NEUTRALIZATION PROCESS, containing a flow mixer-reactor, a pH meter at the inlet of the reactor and a pH meter at its outlet, connected to the input of the isodromic regulator, the output of which is connected to the reagent dispenser, and the proportionality limit adjusting unit connected with a regulator, characterized in that, in order to improve the quality of the neutralization process and save the reagent, it additionally contains a third pH meter, located between other pH meters, a waste flow meter ode block za-. holders, adder, correction elements, threshold element, while the pH meter at the input through the delay element and the third pH meter are connected to the adder, the output of which is connected to the first correction element and to the threshold element connected to the proportionality adjustment unit, flowmeter connected to the second and third correction elements, the first and second correction elements are connected to the inputs of the controller, and the third to the delay element. SU, 1201232>