RU56644U1 - DEVICE FOR DETERMINING ABSORPTION ABILITY OF SORBING SCREENS FOR PROTECTION OF UNDERGROUND WATERS - Google Patents

Abstract

The utility model relates to the field of environmental protection and can be used to monitor the process of migration of potential pollutants over time, with the aim of taking measures to protect groundwater and soil from pollution by toxic or radioactive substances in industrial waste disposal areas. The result of the utility model is the development of a device for determining in laboratory conditions the absorption capacity (relative concentration of potential pollutants contained in a solution over time) of natural and artificial materials intended for use as sorbing screens while maintaining a constant filtration rate, the absence of wall filtration and washing the screen material in the process of conducting the experiment. The essence of the utility model consists in the fact that the device for measuring the absorption capacity of natural or artificial screen material containing a screen sample, a reservoir with a solution containing potential pollutants with a given concentration, a set of interchangeable samplers, a filter column, an additional unit for measuring the concentration of pollutants a container for placing a screen sample, first and second filters, a filtration rate measuring sensor, a first pump, a control unit first by suction, moreover, the reservoir with the solution containing the studied pollutants with a given concentration is connected in series by pipelines through the first pump, the filter column, the shut-off valve and a set of replaceable samplers with the input of the pollutant concentration measuring unit, and the second pump is connected by an air duct through the discharge valve to the second input of the filtration columns between its inner side surface and the elastic container, the output of the concentration measuring unit

pollutants is connected by a communication line to the input of the calculator, the output of which is connected to the input of the memory block, while the output of the timer is connected to the second input of the shut-off valve, and the filtration rate sensor is located in the pipeline connecting the output of the first pump to the input of the filter column, while the output of the sensor’s electrical signal filtration rate is connected to the input of the control unit of the first pump. 1p.p.f.2ill.

Description

The utility model relates to the field of environmental protection and can be used to monitor the process of migration of potential pollutants over time, with the aim of timely adoption of measures to protect groundwater and soil from pollution by toxic or radioactive substances in industrial waste disposal areas.

A device for measuring the rate of diffusion of ions in soils is known, which determines changes in soil properties depending on the time of contact with the source of diffusing ions at a certain distance from the source. The ion diffusion rate in the soil is determined by the beginning of the change in the potential difference between the ion-selective electrode to the ion, the diffusion of which is studied, and the reference electrodes located on the soil surface. As the changing soil property, the beginning of the change in the activity of diffusing ions on the surface of the soil sample opposite from their source is selected (patent RU No. 2243557 C1 7, G 01 N 33/24).

A disadvantage of the known device is the fact that when using this device only the diffusion nature of the transfer of pollutants is taken into account. In places of waste storage, as a rule, in addition to diffusion transfer of pollutants, there is a transfer of toxic and radioactive substances as a result of water filtration from the place of storage of waste to the underlying aquifers.

The closest technical solution, i.e. the prototype is a device containing a screen sample, a reservoir with a solution containing potential pollutants with a given concentration, a set of interchangeable samplers, a filter column, a unit

measuring pollutant concentrations (“Workshop on General Hydrology”, edited by B.C. Samarina, ed. LSU, 1965, pp. 34-35).

A disadvantage of the known device is the presence of wall filtration, the inconsistency of the filtration rate and the mechanical leaching of the soil sample during the experiment.

The result of the utility model is the development of a device for determining in laboratory conditions the absorbing capacity of sorbent screens (changes in the relative concentration of pollutants over time when filtering a contaminated liquid through a screen sample) at a constant rate of filtration of a solution with pollutants through samples of natural and artificial screens in the absence of wall filtration and mechanical leaching a sample of screen material.

The essence of the utility model consists in the fact that the device for determining the absorbing capacity of sorbent screens for protecting groundwater, which contains a screen sample, a reservoir with a solution containing potential pollutants with a given concentration, a set of replaceable samplers, a filter column, an additional unit for measuring the concentration of pollutants a container for placing a screen sample, first and second filters, a filtration rate sensor, a first pump, a control unit for the first pump, and a tank with a solution containing potential pollutants with a given concentration is connected in series by pipelines through the first pump, filter column, shut-off valve and a set of interchangeable samplers with a block for measuring the concentration of pollutants, while the second pump is connected through an air valve through the discharge valve to the second inlet of the filter column between inner side surface and an elastic container, and the output of the unit for measuring the concentration of pollutants is connected by a communication line to the input the numerator, the output of which is connected to the input of the memory unit, while the timer output is connected to the control input of the shut-off valve, and the speed sensor

filtering is placed in the pipeline connecting the output of the first pump to the input of the filtration column, while the output of the electrical signal of the filtering rate sensor is connected to the input of the control unit of the first pump.

Figure 1 shows a functional diagram of the device, where: a screen sample - 1, an elastic container - 2, a filter column - 3, a discharge valve - 4, a reservoir with a solution containing potential pollutants with a given concentration - 5, the first pump - 6, the second pump - 7, first filter - 8, second filter 9, filter speed sensor - 10, control unit of the first pump - 11, timer - 12, shutoff valve - 13, a set of interchangeable samplers - 14, block for measuring the concentration of pollutants - 15, calculator - 16, the memory unit is 17.

Figure 2 shows an example of an experimental assessment of the absorption capacity of a sorbent screen (changes in the relative concentration of pollutants over time when filtering a contaminated liquid through a screen sample).

A device for determining the absorption capacity of sorbent screens made of natural or artificial materials works as follows.

The test sample of the screen 1 (Fig. 1) is loaded into an elastic, for example, rubber container 2, which is placed in a filter column 3, in which a second inlet is additionally provided through the discharge valve 4.

An initial solution is prepared with a given concentration of potential pollutants C _Ref , for which the absorption capacity of a specific screen sample is examined, a reservoir is filled with it, and from the outlet of the reservoir with a solution containing potential pollutants with a given concentration - 5, it is fed to the first input through the first pump 6 under pressure P ₁ filter column 3. The second input of the filter column 3 through the discharge valve 4 is connected to the second pump 7 with pressure

P ₁ <P ₂ and thereby provide lateral compression of the screen sample and exclude wall filtration. To prevent mechanical washing out of the sample, filters 8 and 9 are applied to its input and output surfaces, made, for example, in the form of thin layers of glass wool. In the pipeline, between the filtration column 3 and the first pump 6, a filtration rate sensor 10 is connected, the output of which is connected to the control unit 11 of the first pump 6 to adjust the pressure P ₁ in order to maintain a constant filtration rate.

The timer 12 at predetermined time intervals Δt generates a control signal that is supplied to the shut-off valve 13 and the metered volume of the filtrate enters the first replaceable set of sampler 14. The sampler is made, for example, in the form of replaceable sets of “K” sterile tanks in each, where the number “ K "determines the amount of pollutants studied. Accordingly, the total number of sets depends on the selected time interval Δt, the method and duration of the study, which should continue until the main zone of change in the concentration of the pollutant in the pore space of the screen is 0.01 <C _i <0.95.

After filling the first interchangeable set with filtrate, it is fed to the block for measuring the concentration of pollutants 15, for example, to an atomic absorption spectrophotometer (in the case of using an instrument for measuring the concentration of all elements in one sample, one interchangeable tank is sufficient in the sampler). Corresponding signals for each of the pollutants from the output of the block for measuring the concentration of pollutants 15 are fed to the input of the first calculator 16, in which the concentration of each element under study is determined relative to its concentration in the initial solution for the first reference time t ₁ (relative concentration) according to the formula:

Where - the concentration of the element "k" in the "i" point in time, - the concentration of the element "k" in the initial solution.

At time intervals Δt, for example, after one hour (day), control signals are supplied from valve 12 to valve 13 and the procedure for determining the change in the concentration of each element under study relative to its concentration in the initial solution is cyclically repeated; corresponding electrical signals are generated at the output of the first calculator 16, which fed to the input of the memory block 17, and sequentially stored in the corresponding section, i.e. form a database of the relative concentration of the investigated element in the pore space of the studied screen sample in time C _i (t).

Using the claimed utility model will significantly increase the accuracy of measurements of the absorbing ability of natural and artificial protective screens and, accordingly, increase the accuracy of assessing the degree of protection of the region. This is of particular importance when undertaking measures to protect groundwater and soil from the effects of pollutants in places of storage of industrial waste containing toxic and radioactive substances.

Claims (1)

A device for determining the absorption capacity of sorbent screens for protecting groundwater, containing a screen sample, a reservoir with a solution containing potential pollutants with a given concentration, a set of interchangeable samplers, a filter column, a unit for measuring the concentration of pollutants, characterized in that it also includes an elastic container for the placement of the screen sample, the first and second filters, the filtering rate sensor, the first pump, the control unit of the first pump, and the reservoir with the solution A rum containing potential pollutants with a given concentration is connected in series by pipelines through the first pump, filter column, shut-off valve and a set of interchangeable samplers with a block for measuring the concentration of pollutants, while the second pump is connected via an air duct through the discharge valve to the second inlet of the filter column between its inner side surface and an elastic container, and the output of the unit for measuring the concentration of pollutants is connected by a communication line with the input of the calculator, the output otorogo connected to the input of the memory block, while the timer output is connected to the control input of the shutoff valve, and the filtration rate sensor is located in the pipeline connecting the output of the first pump to the input of the filter column, while the output of the electrical signal of the filtration speed sensor is connected to the input of the control unit of the first pump .