RU136892U1 - DEVICE FOR DRINKING WATER QUALITY - Google Patents

Abstract

1. A device for monitoring the quality of drinking water, comprising a block of ion-selective electrodes and a reference electrode, a means for measuring water turbidity, a block for determining parameters and an indication means, moreover, ion-selective electrodes, a reference electrode and a means for measuring turbidity are connected to the inputs of the block for determining parameters, and the output of the block for determining parameters is connected to the means of indication, characterized in that it contains at least two ion-selective electrodes selected from the group comprising an ion-selective electrode for i pH control, ion-selective electrode for controlling water hardness, ion-selective electrode for controlling redox systems, ion-selective electrode for controlling iron, ion-selective electrode for controlling copper, ion-selective electrode for controlling sulfates, ion-selective electrode for controlling nitrates, and it additionally contains a temperature sensor connected to the input of the parameter definition block. 2. The device according to claim 1, characterized in that it further comprises a cell for monitoring the ion content and turbidity of the water. The device according to claim 2, characterized in that the cell is made flowing. The device according to claim 1, characterized in that the turbidity measuring means is an open channel optocoupler. The device according to claim 1, characterized in that the turbidity measuring means is a cell equipped with a monochromatic optical radiation source and a photodetector. The device according to claim 1, characterized in that the means of indication is an LED. The device according to claim 1, characterized in that the means of indicating

Description

The technical solution relates to the field of water treatment, namely, the field of means for monitoring the parameters of water, mainly drinking water, and can be used to control the characteristics of drinking water, both in everyday life and in centralized water treatment to the category of "drinking".

Known (http://www.ecounit.ru/goods_634.html) photocolorimeter "EXPERT-003". The well-known photocolorimeter provides control over 100 quality parameters of drinking, natural, waste water, as well as the quality of solutions of samples of vegetable, food products, soils, etc. The device measures the concentrations of various components in a solution, color and turbidity parameters, as well as total parameters, such as phenolic index, surfactants, etc. The device is recommended for use in agrochemical, environmental, chemical-technological, analytical laboratories of industrial enterprises, research institutions, bodies control, inspection and supervision, student workshops. Small size, light weight, built-in powerful battery with constant control of the degree of its charge allows analysis not only in the laboratory, but also in the field or in the workplace.

A disadvantage of the known device should be recognized as the applied control method - photocolorimetry, which requires considerable user experience, as well as providing fairly scarce reagents.

It is known (SU, copyright certificate 1198009) a device for automatic monitoring of wastewater treatment processes, containing an electrode sensor for measuring electrical conductivity, the output of which is connected to a measuring unit equipped with a switch of measurement ranges, and a secondary device, as well as a signal limiter, switching and logic blocks , a pulsator connected in a known sequence.

The design of the device is quite complicated, while the device is not very informative, it requires constant monitoring of the device by maintenance personnel.

The closest analogue of the developed device can be recognized (http://www.kntp.ru/proektv/avtomatizirovannyj-kontrol-kachestva-vody-v-juzhnoj-zone.html) installation of automated water quality control (ASKKV) as part of a hardware-software complex ( AIC), is being introduced in the Southern zone of water supply of St. Petersburg State Unitary Enterprise Vodokanal SPb. Well-known ASKKV installations are developed on the basis of the multifunction controller Hach Lange sc1000 with a built-in GSM modem. This controller has the ability to connect up to eight sensors, and the built-in GSM modem allows you to transfer information taken from sensors in online mode, without using wired information transfer systems. The units also have an internal piping and an electrical wiring diagram, which together with the controller make it easy to install two or three additional sensors. At the moment, according to the wishes of the customer, the following parameters are measured: turbidity, pH, electrical conductivity, total iron, aluminum, total organic carbon, color, hardness and ammonia nitrogen.

Installed at thirty control points of the Southern water supply zone, such as the Southern water supply station, booster pump stations and water measuring units of the ASKKV installation, continuous monitoring of water quality is possible, starting from the outlet from the water treatment station and ending with the end consumer. Information about the measured parameters is transmitted online through a closed GSM communication channel to the central dispatching office of the Water Supply SPb SUE Vodokanal SPb. The information coming from ASKKV installations allows you to quickly respond to changes in water quality, as well as to track the area on which the changes occurred.

A disadvantage of the known installation should recognize its complexity, the need to use qualified personnel for maintenance. In addition, the installation does not provide control of such parameters essential for the quality of drinking water as redox systems, water hardness, and control of the sulfate ion. Also, the use of various principles of analysis, including photocolorimetry, should be recognized as a significant drawback of the known installation, which makes this installation unsuitable for use in everyday life.

The technical result obtained by implementing the developed installation design consists in simplifying the design while simplifying the technology of its use, which makes it possible to use it at home.

To achieve the specified technical result, it is proposed to use the developed device for monitoring the quality of drinking water. The developed device contains a block of ion-selective electrodes and a reference electrode, a means for measuring water turbidity, a block for determining parameters and an indication means, moreover, ion-selective electrodes, a reference electrode and a means for measuring turbidity are connected to the inputs of the block for determining parameters, and the output of the block for determining parameters is connected to an indicator means this it contains at least two ion-selective electrodes selected from the group consisting of an ion-selective electrode for pH control, an ion-selective electrode for controlling water hardness, an ion-selective electrode for controlling redox systems, an ion-selective electrode for controlling iron, an ion-selective electrode for controlling copper, an ion-selective electrode for controlling sulfates, an ion-selective electrode for controlling nitrates, and it additionally contains a temperature sensor connected to the input of the determination unit parameters.

Devices of this composition provide the measurement of all parameters characterizing drinking water according to SanPiN 2.1.4.1074-01 “Drinking water. Hygienic requirements for water quality of centralized drinking water supply systems. Quality control". In addition, the use of a temperature sensor in the device, which allows to determine the temperature of the drinking water sample at the time of analysis, will increase the accuracy of determination. Using only potentiometric methods of analysis to determine the impurity composition of the analyzed water can significantly simplify the design of the installation itself, as well as the technology of its application. In this case, in most applications, the use of the installation consists in bringing the electrode block into contact with the analyzed water and observing the indication means. A pre-configured unit for determining the parameters will alternately poll ion-selective sensors, as well as a temperature sensor and means for determining turbidity, and, comparing the data obtained with the limit values for each parameter previously stored in the memory of the unit for determining parameters, will make a judgment on the suitability or unsuitability of the analyzed water for drinking.

In some embodiments of the device, it may further comprise a cell for monitoring the ion content and turbidity of the water. This can be either a flow cell (preferred) or a non-flow cell. The flow cell mainly contains a fitting for connecting the analyzed water supply in the lower part of its body, and a fitting for draining the analyzed water in the upper part. On these fittings can be installed means of interrupting the flow. This will ensure that the cell is filled with water in the intervals between measurements and contributes to good storage conditions of ion-selective electrodes.

Depending on the field of application of the developed device, the turbidity measuring means can be performed in various ways. In particular, when using the developed device as a "home" means of monitoring the quality of drinking water, it can be an optocoupler with an open channel. A similar solution can be used for the case of using the device for selective control of samples in places of water purification or transportation of purified water to the consumer. The design of an open-channel optocoupler due to the open gap between a monochromatic radiation source (mainly an LED) and an optical radiation receiver (mainly a photodiode) ensures that monochromatic radiation flux is transmitted through controlled water and the transmitted light is recorded by a photodetector. For a case integrated into the device’s water treatment and water supply system, the turbidity control means can be made in the form of an optically transparent cell, preferably a flow cell, equipped with a monochromatic optical radiation source (preferably a semiconductor laser or a broadband optical radiation source between the output of which and the cell wall a filter providing transmission of optical radiation of only one wavelength) and a photodetector (preferably photo diode house). However, a photoresistor, a phototransistor, or a photomultiplier can also be used as a photodetector. In this case, the source of monochromatic radiation and the photodetector can be installed both against each other, and at an angle of 90 °. It should be noted that the source of monochromatic radiation and a photodetector can be installed both on the same cell in which the content of the mineral composition of the analyzed water is measured, and on an additionally installed cell. In any case, the photodetector, regardless of its design, should be connected to the parameter determination unit.

Depending on the use cases of the developed device, the indicator can be an LED that lights up depending on the execution of the parameter determination unit with good or poor quality of the analyzed water. This option is preferably used in the case of selective analysis of samples, including at home or when monitoring water supply networks. In the case of a device integrated in the water treatment and water supply system, the indicating means is preferably a line of digitally-sign indicators providing indications of the numerical value of the measured parameter.

Depending on the field of application of the developed device, it can be electrically powered both from electric elements and from a battery, as well as from an electric current network.

The parameter determination unit is, in fact, an electronic device that, in one implementation option, can be performed by comparing each parameter measured by ion-selective electrodes or by means of measuring the turbidity of a parameter with a predetermined limit value taking into account the temperature of the analyzed water. If the value of the measured parameter is less than a predetermined value, a signal is generated that characterizes the compliance of the analyzed water with the requirements of SanPiN 2.1.4.1074-01 “Drinking water. Hygienic requirements for water quality of centralized drinking water supply systems. Quality control ”, if the value of the measured parameter is greater than a predetermined value, a signal is generated that characterizes the mismatch of the analyzed water with the specified requirements. The indication may include both a signal characterizing each parameter being checked and one common resultant signal, moreover, the block generates a signal of non-compliance at the first non-compliance of the parameter. Further verification is usually not carried out. Preferably, the parameter determination unit is configured to be connected to a personal computer and comprises means for storing information about the measurement results, moreover, said information is not limited to monitored parameters only.

The developed device can be implemented in various ways.

The simplest embodiment of the device comprises a reference electrode and a block of ion-selective electrodes, which includes at least a portion of ion-selective electrodes selected from the group consisting of an ion-selective electrode for controlling pH, an ion-selective electrode for controlling water hardness, and an ion-selective electrode for controlling oxidation reduction systems, ion-selective electrode for controlling iron, ion-selective electrode for controlling copper, ion-selective electrode for controlling sulfates, ion-bearing Native electrode for nitrate control. The specific choice of a set of ion-selective electrodes is determined by the composition of the source water and the features of the water treatment equipment. In addition, the device also includes a means of measuring the turbidity of the water in the form of an optocoupler with an open channel, a temperature sensor, as well as a parameter determination unit and an indication means. All of the listed elements, except for the indication means, are placed in the housing. Additionally, an electric power element, a battery, is introduced into the case. An indication means in the form of an LED is fixed on the housing. Also, a switch can be placed on the housing, mounted in the device’s electrical circuit between the battery and other elements of the electrical circuit — electrodes, a parameter determination unit, an LED, an optocoupler. In the housing or on the housing can be placed a cell, mainly made flowing, designed to determine the mineral composition and turbidity of the sample of the analyzed water. The technology for measuring the quality of the analyzed water depends on the logic by which the unit for determining the parameters of the analyzed water is designed and manufactured, containing an LED as an indication.

A more complex version, designed to monitor water purification and water supply systems, differs from the previously described by a set of ion-selective electrodes (all electrodes of the group were used), as well as a block for determining the parameters. In addition, this option may contain an additional flow cell to control the turbidity of the water, or placed on the sides of the cell to measure the mineral composition of the source and receiver of monochromatic radiation. The parameter determination unit in this embodiment may be configured to display values of measured water quality parameters on a line of digitally-sign indicators.

The most complex version differs from the previous version in a more complex unit for determining parameters, the presence of an additional cell for measuring turbidity, as well as powering the device from an electric current network.

Using the developed device in any implementation provides a simplification of the design while simplifying the technology of its use, which makes it possible to use it at home.

Claims (9)

1. A device for monitoring the quality of drinking water, comprising a block of ion-selective electrodes and a reference electrode, a means for measuring water turbidity, a block for determining parameters and an indication means, moreover, ion-selective electrodes, a reference electrode and a means for measuring turbidity are connected to the inputs of the block for determining parameters, and the output of the block for determining parameters is connected to the means of indication, characterized in that it contains at least two ion-selective electrodes selected from the group comprising an ion-selective electrode for i pH control, ion-selective electrode for controlling water hardness, ion-selective electrode for controlling redox systems, ion-selective electrode for controlling iron, ion-selective electrode for controlling copper, ion-selective electrode for controlling sulfates, ion-selective electrode for controlling nitrates, and it additionally contains a temperature sensor connected to the input of the parameter definition block. 2. The device according to claim 1, characterized in that it further comprises a cell for monitoring the content of ions and turbidity of the water. 3. The device according to claim 2, characterized in that the cell is made flowing. 4. The device according to claim 1, characterized in that the turbidity measuring means is an open channel optocoupler. 5. The device according to claim 1, characterized in that the turbidity measuring means is a cell equipped with a monochromatic optical radiation source and a photodetector. 6. The device according to claim 1, characterized in that the means of indication is an LED. 7. The device according to claim 1, characterized in that the indicating means is a line of digitally-sign indicators. 8. The device according to claim 1, characterized in that the parameter determination unit is configured to connect to a computer. 9. The device according to claim 1, characterized in that the parameter determination unit comprises means for storing information about the measurement results.