RU2771221C1 - Device for selective monitoring of emergency discharges - Google Patents

Abstract

FIELD: measuring technology.

SUBSTANCE: invention relates to the field of measuring technology and concerns a device for selective monitoring of emergency discharges. The device contains a motion channel of the controlled medium with an optoelectronic sensor installed in it and taps with motion blocking elements of the controlled medium connected to the processing and control unit. The optoelectronic sensor contains a block of n emitters with different wavelengths of radiation connected by light guides to a common light guide, and a photodetector. The photodetector and the emitter of the optoelectronic sensor are connected to the processing and control unit. The processing and control unit is designed with the ability to store the values of the optical densities of the components of the medium.

EFFECT: increase in the efficiency and accuracy of the separation of pollutants sent for selective filtration, and the reduction of the level of wastewater pollution.

1 cl, 2 dwg

Description

The invention relates to automatic means for controlling the optical density of liquid and gaseous media and can be used in wastewater filtration systems.

Devices for monitoring pollutants in wastewater are known, for example, a method for determining the content of oil products in water and a device for its implementation (Patent RU 2083971, IPC G01N 21/85, publ. 10.07.1997). The device implementing the method comprises a radiation source with an optical system, a liquid analysis tank in the form of a pipeline, a spectrum analyzer, fiber optic light guides with two photodetectors electrically connected to the amplifier, and a computer-based signal processing unit. A continuous flow of the analyzed liquid is illuminated by a monochromatic coherent radiation source in the wavelength range from 0.2 to 1.1 µm. The determination of the amount of oil products in water is carried out by the total intensity of the spectra of stimulated Raman scattering of a number of characteristic wavelengths of the functional groups of oil products, and the intensity of the Raman spectrum of water is used as a normalizing factor that takes into account the change in the turbidity of the liquid and the background inside the spectrum analyzer. As a result of computer processing of signals from photodetectors, the quantitative content of oil products in water is determined.

The disadvantage of the device is the low accuracy of monitoring pollutants in wastewater due to the need to obtain spectra in the range from 0.2 to 1.1 μm sequentially with a certain time step, which will lead to measurement errors.

It is also known a device for eliminating emergency release (utility model patent RF 105456 IPC ⁷ G01N 15/06; publ. 10.06.2011. Bull. 16). The device comprises a controlled medium movement channel with an optoelectronic sensor installed in it, which is connected to a processing and control unit, an outlet located after the optoelectronic sensor, controlled medium movement blocking elements installed in the channel and outlet, a cleaning filter is installed at the outlet of the controlled medium movement channel, and at the outlet of the outlet there is a recycling unit. As a result of the analysis of the reference and current optical density of the controlled medium, the emergency release is eliminated by diverting the contaminated liquid to the sump and blocking the channel through which the liquid enters the filtration system and further into the environment.

The disadvantage of this device is the low accuracy of monitoring pollutants in wastewater from various accidents, since the device is set to only one type of possible pollutant.

The closest in technical essence to the proposed device is a device for eliminating emergency release (patent for utility model of the Russian Federation No. 153362 MPK ⁷ G01N 15/06; publ. 20.07.2015. Bull. No. 20).

The device contains a controlled medium movement channel, for example, a pipeline with an optoelectronic sensor installed in it, which is connected to the processing and control unit, bends with elements for blocking the movement of the controlled medium installed on them, for example, valves connected to the processing and control unit, while each outlet is also equipped with an optoelectronic sensor connected to the processing and control unit and a cleaning filter designed to filter the corresponding components contained in the emergency discharge products. In the processing and control unit, the values of the reference optical density of the controlled medium and the permissible deviations from it are set. These deviations are monitored by an optoelectronic sensor installed in the pipeline. In addition, the processing and control unit stores the values of the optical densities of the components of the environment of pollutants possible for a given control object. The values of these optical densities and possible deviations from them are monitored by optoelectronic sensors installed in the taps. The choice of the reference value of the optical density of each component of a possible emergency reset with its subsequent storage in the processing and control unit is based on the spectral analysis of this component and the determination of the wavelength of optical radiation at which the optical density of the studied component is maximum. The device allows for the control of a variety of pollutants from various accidents, which leads to an increase in the service life of the cleaning filters.

The disadvantage of the prototype is that when the pollution in the form of a clot moves along the pipe section where pollution is controlled, the structure of the clot, which can have a different shape, changes along the length of the pipe from sensor to sensor, which leads to large errors in measuring changes in optical density controlled aquatic environment at different wavelengths of radiation.

The objective of the invention is to improve the accuracy of monitoring pollutants from various man-made accidents in wastewater and industrial effluents that can enter the main pipe.

The technical result from the use of the invention is to reduce the level of contamination of wastewater and industrial effluents with pollutants due to more efficient and accurate separation of pollutants sent to selective filtration.

The task is achieved by the fact that in a device containing a channel for the movement of a controlled environment with an optoelectronic sensor installed in it, which is connected to a processing and control unit, taps with elements for blocking the movement of a controlled environment connected by a processing and control unit, an optoelectronic sensor contains n emitters with different wavelengths of radiation connected by means of light guides into a common light guide, and a photodetector connected to the processing and control unit, configured to store the values of the optical densities of the components of the medium, while the emitters of the optoelectronic sensor for controlling them are connected to the processing and control unit.

The device is illustrated by drawings, where figure 1 shows a block diagram of a device for selective control of emergency discharges, and figure 2 shows a possible connection of the sensor emitters using light guides into one light guide.

The device for selective control of emergency discharges contains a controlled environment 1, a channel 2 for the movement of a controlled environment, for example, a pipeline, an optoelectronic sensor 3 installed in channel 2, and consisting of a block 4 containing n emitters with different wavelengths, which can be used lasers, photodetector 5 connected to the processing and control unit 6, for example, based on a microcontroller, branches (branches) 7 from channel 2, located after the installation site of the optoelectronic sensor 3, elements 8 for blocking the movement of the controlled medium, for example, valves installed on the branches 7, and associated with the outputs of the processing and control unit 6. To provide a radiation mode that allows you to control the optical density in the selected section of the flow of the aquatic environment, the radiation from each of the radiation sources 9 (figure 2) through the light guides 10 is fed to a common light guide 11. Each of emitters of the sensor receives a control signal to generate a pulse from radiation from the processing and control unit.

In the processing and control unit 4, the values of the reference optical density of the controlled medium and the permissible deviations from it are set. In addition, block 6 stores the values of optical densities in the form of amplitudes of reference pulses (contamination spectra) of possible contaminants in water in the event of an emergency discharge at the control object.

The device works as follows. In the process of monitoring in block 6, the current optical density of the medium obtained as a result of processing the signals coming from the optoelectronic sensor 3 is continuously compared with the reference optical density of the controlled medium. In the normal state, when the optical density of the medium does not exceed the allowable threshold value, one of the valves 8 located on the outlet 7 connected to the common filter of the filtration system is open, and the remaining valves 8 on the outlets 7 are closed. In this case, a controlled medium, for example water, passes through the pipeline 2 through an open valve to carry out general filtration.

Irradiation of the aquatic environment is carried out sequentially by each radiation source 9, in the form of short light pulses. The total analysis time is equal to the pulse duration multiplied by the number of radiation sources. Pulse signals from the photodetector 5, which are proportional to the optical density of the aqueous medium at each radiation wavelength, enter the processing and control unit 6, in which the pulses from each radiation source are separated in time and analyzed. The analysis consists in comparing the measured amplitude of the pulses at each wavelength with the signal standards stored in the memory of block 6 and corresponding to the options of emergency discharges possible for this controlled object.

If there is any contamination in the water, which may be associated with the occurrence of an emergency discharge at the control object, the signal from the photodetector 5 of the sensor 3, containing n emitters with different wavelengths, changes. This signal enters the processing and control unit 6, in which it is analyzed and the type of pollution is determined. After that, a control signal is sent from the processing and control unit 6 to close the valve 8 on the outlet 7, connected to the common filter of the filtration system, and open the valve 8 corresponding to the type of pollution. As a result, the water contaminated with the detected substance enters the corresponding channel for selective filtration. After the passage of the pollutant clot, the optical density of the aquatic environment returns to its original level. As a result, control signals are sent from block 6 to open the damper on the pipeline connected to the common filter of the filtration system, and to close the dampers on the remaining outlets.

Thus, in comparison with the known technical solutions, the proposed device allows, due to more rapid and accurate control of changes in the optical density of the controlled aquatic environment and the separation of pollutants sent for selective filtration, to reduce the level of pollution of wastewater and industrial effluents with pollutants in the form of clots from various accidents for this monitoring object.

Claims (2)

1. A device for selective control of emergency discharges, containing a channel for the movement of a controlled environment with an optoelectronic sensor installed in it, which is connected to a processing and control unit, taps with elements for blocking the movement of a controlled environment connected to the processing and control unit, characterized in that the optoelectronic sensor contains a block of n emitters with different wavelengths of radiation connected by means of light guides into a common light guide, and a photodetector connected to a processing and control unit configured to store the values of the optical densities of the medium components, while the emitters of the optoelectronic sensor are connected to the processing and control unit. 2. The device according to claim 1, characterized in that a laser is used as a radiation source.

Images