RU150523U1 - SEWAGE TREATMENT PLANT - Google Patents

Abstract

1. Installation for the treatment of wastewater from oil products, surfactants, heavy metal ions and ammonium ions, consisting of two sorption filters located in the underground space in separate wells, connected in series by technological pipelines, characterized in that the first is loaded in the direction of travel the filter water is made of activated carbon, and the loading of the second filter along the movement of the water filter is made of zeolite. 2. Installation according to claim 1, characterized in that at least one of the filters comprises a fibrous filter material. The apparatus according to claim 1, characterized in that the first filter in the direction of movement of the water contains, in addition to activated carbon, another ion-exchange material and / or chemically modified activated carbon. Installation according to claim 1, characterized in that the second filter in the direction of movement of the water contains, in addition to zeolite, another ion-exchange material and / or chemically modified zeolite. 5. Installation according to claim 2, characterized in that the fibrous filter material is chemically modified. Installation according to any one of paragraphs. 1-5, characterized in that at least one of the sorption filters is made in the form of a cartridge with a waterproof upper and lower ends and an impermeable side wall.

Description

Technical field

The utility model relates to the field of wastewater treatment, namely, to devices for purification of suspended solids, oil products, surfactants, heavy metal ions and ammonium ions.

State of the art

A known installation for the purification of industrial water from suspended solids, oil products, surface-active substances, including two filters, connected in series with each other by a system of process pipelines, in which the loading of the first filter along the movement of water is made of mineral or synthetic fibers, and the loading of the second filter along the way the movement of the filter water is made of modified nitrogen-containing activated carbon, and the filters can be located in the underground space in separate concrete columns dtsakh (Utility Model Patent No. 38751 published July 10, 2004, C02F1 / 00).

The disadvantage of this technical solution is the inability to provide additional water purification from other inorganic pollutants, such as heavy metal ions and ammonium.

Utility Model Disclosure

The objective of the utility model is to develop the design of the installation, which provides the best comprehensive water purification from various pollutants by nature for technical and technological purposes in water circulation, as well as its discharge into water and fishery reservoirs or urban sewers.

The technical result consists in expanding the range of application of the utility model to the field of additional water purification from ions of heavy metals and ammonium while purifying them from suspended solids, petroleum products, surface-active substances.

In the prior art, no solutions have been identified that are similar in combination of essential features to the claimed solution of the utility model, aimed at achieving the above technical result.

The claimed technical result is achieved by using an installation consisting of two filters located in the underground space in separate wells, connected in series by technological pipelines, characterized in that the loading of the first filter in the direction of travel of the water is made of activated carbon, and the loading of the second one in the direction of travel Water filter made of zeolite.

In one embodiment of the utility model, at least one of the filters comprises a fibrous filter material.

In another embodiment of the utility model, the first filter in the direction of movement of the water contains, in addition to activated carbon, another ion-exchange material and / or chemically modified activated carbon.

In another embodiment of the utility model, the second filter in the direction of movement of the water contains, in addition to the zeolite, another ion-exchange material and / or chemically modified zeolite.

In yet another embodiment of the utility model, the fibrous filter material is chemically modified.

In another embodiment of the utility model, at least one of the sorption purification filters is made in the form of a cartridge with a waterproof upper and lower ends and an impermeable side wall.

Brief Description of the Drawings

For a better understanding of the essence of the utility model, drawings are further discussed along with their accompanying description.

FIG. 1. General view in section of the installation with filters placed in underground concrete wells. (Option 1).

Figure 2. General view in section of the installation with filters placed in underground concrete wells. (Option 2).

The accompanying drawings illustrate only the two most preferred embodiments of the utility model, therefore, cannot be considered as limitations of the content of the utility model, which do not include other options.

Utility Model Implementation

In FIG. 1 shows one of the placement options for a wastewater treatment plant, consisting of a sorption filter 1 with activated carbon and a sorption filter 2 with zeolite located in underground concrete wells 3 and 4, respectively, sequentially located along the direction of the water flow.

For accumulation of water and its uniform supply to the filters of the installation, a storage tank 5 in the form of a well is mounted in front of them, and for quality control of the water purified by the filters, a control well 6 is provided in which water samples are taken for analysis.

The movement of water that flows down the sewer network 7 into the storage tank (well) 5 is due to the difference in hydrostatic heights in the well (tank) 5 and the discharge pipe 10, through which purified water is drained from the well 4 into the control well 6.

Coming from the tank (well) 5 through the pipeline 8 to the lower part of the filter 1 in the well 3 and passing through the filter 1 from the bottom up, water from the well 3 through the pipeline 9 enters the well 4 into the upper part of the filter 2 and passing through it from top to bottom drains through a 10 v pipeline

a control well 6, after which, through a pipe 11, it is discharged to a sewer network or reservoir.

Figure 2 shows the second variant of the placement of the installation for wastewater treatment, consisting of a sorption filter 1 with activated carbon and a sorption filter 2 with zeolite located in the underground concrete wells 3 and 4, respectively, sequentially located in the direction of the water flow. Wastewater through the network 7 enters directly into the well 3 to the filter 1 (above). The movement of water through the filters of the installation occurs due to the difference in hydrostatic heights in well 3 and well 4.

Coming from the network 7 to the well 3 from the top of the filter 1, water passes through it from top to bottom, after which through the pipeline 9 it enters the lower part of the well 4 and the filter 2, passes through the filter 2 from the bottom up and is drained from the bottom of the well 4 through the 10 the control well 6, and from it through the pipe 11 is discharged into a sewer network or reservoir.

The technical result consists in expanding the range of application of the utility model to the field of additional water purification from ions of heavy metals and ammonium while purifying them from suspended solids, petroleum products, surface-active substances.

The claimed technical model provides the technical result due to the fact that the granular loading of the first filter in the direction of movement of the water is made of activated carbon absorbing oil products, surface-active substances, as well as other organic substances and trapping suspended substances, and the loading of the second filter in the direction of movement of water from zeolite that absorbs heavy metal and ammonium ions and also delays suspended solids.

Table 1 presents a comparison of the cleaning efficiency of model industrial water containing suspended solids,

petroleum products, anionic surfactants, as well as additional heavy metal ions (manganese, copper, zinc and cadmium) and an ammonium ion.

The initial concentration of suspended particles (fine quartz sand) was obtained according to the method of GOST 71 51871-2002.

The initial concentration of anionic surfactant (lauryl sulfate) was obtained by dissolving it in water.

The initial concentration of petroleum products (turbine oil ТН-22с) was obtained by dispersing it in a predetermined amount in an apparatus with a stirrer.

The initial concentration of ions in solution was obtained by dissolving their salts in the form of sulfates and chlorides in an appropriate amount in distilled water.

The tests were carried out on the installation of two filter cartridges with a diameter of 100 mm and a height of 1800 mm each, connected in series.

The concentrations of heavy metal ions in water samples before and after the installation for cleaning during testing were determined by atomic absorption spectrometry according to GOST 51309-99, and the ammonium ion by the photocolorimetric method with Nessler reagent according to GOST 4974-72.

Certain concentrations of suspended solids were carried out according to the method of RD 52.24.468-95. The concentration of petroleum products was determined according to FR 1.31.2007.03234, and anionic surfactants - according to PNDF 14.1: 2.258-10.

From table 1 it can be seen that at close efficiency of purification of model process water by the content of suspended solids, oil products and anionic surfactants, the claimed utility model additionally purifies water with high efficiency from heavy metal ions (manganese, copper, zinc and cadmium) and ammonium ion.

Thus, it is obvious that the use of the claimed utility model makes it possible to purify water not only from suspended solids, oil products, surfactants, but also from heavy metal ions and ammonium ions, and thereby expanding the range of applications of the known technical solution to the field of water purification from heavy metal ions and ammonium.

The presence of at least one filter of the fibrous filter material leads to the achievement of the purpose of the utility model, since this material helps to detain suspended solids from the source waste water, which reduces the load on the removal of suspended solids on the filter charge (activated carbon or zeolite). A smaller amount of suspended solids absorbed by the filter charge improves its work of removing dissolved substances from water (including heavy metal and ammonium ions). Thus, the presence of at least one filter of fibrous filtering material increases the efficiency of the utility model for heavy metals and ammonium ions, thereby contributing to the expansion of the range of application of the utility model to the area of additional water purification from heavy metal and ammonium ions while simultaneously cleaning them from suspended solids, petroleum products, surfactants.

The presence of chemically modified coal in the composition of the first, along the water, filter also contributes to the achievement of a technical result, since chemical modification of coal leads to a change in surface charge, and hence an increase in the number of active centers that are ion-exchange groups. An increase in the number of ion-exchange groups leads to an increase in the efficiency of activated carbon for heavy metal ions, thereby contributing to the expansion of the range of application of the utility model to the field of additional water purification from heavy metal and ammonium ions

their simultaneous cleaning of suspended substances, oil products, surfactants.

The presence in the composition of the first, along the water, filter, in addition to activated carbon, another ion-exchange material, also contributes to the achievement of a technical result, since the ion-exchange material, in contrast to activated carbon, has good ion-exchange properties for heavy metal ions to an ammonium ion, and these properties contribute to the absorption of heavy metal ions and ammonium ion on the first, along the course of the water, filter, thereby contributing to the expansion of the spectrum of application of the utility model to the area of additional cleaning water from heavy metal ions and ammonium with simultaneous clearing them from the suspended solids, oil, surfactants.

The presence in the composition of the second, along the water, filter, in addition to zeolite, another ion-exchange material, also contributes to the achievement of a technical result, since another ion-exchange material has other selective properties for heavy metal ions. Consequently, the cleaning efficiency for some heavy metal ions will be higher on another ion-exchange material than on zeolite. Consequently, another ion-exchange material included in the second, along the water, filter will expand the spectrum of those heavy metals, according to which the filter will work efficiently, thereby contributing to the expansion of the range of application of the utility model to the field of additional water purification from heavy metal and ammonium ions their simultaneous cleaning of suspended substances, oil products, surfactants.

The presence of chemically modified zeolite in the composition of the second, along the water, filter also helps to achieve a technical result, since chemical modification of zeolite leads to a change in the selective properties of zeolite for heavy metal ions. Hence

the cleaning efficiency for some heavy metal ions will be higher on chemically modified zeolite than on unmodified zeolite. Consequently, the chemically modified zeolite included in the second filter along the water will expand the range of those heavy metals, according to which the filter will work efficiently, thereby contributing to the expansion of the spectrum of application of the utility model to the area of additional water purification from heavy metal and ammonium ions their simultaneous cleaning of suspended substances, oil products, surfactants.

The presence of a chemically modified filter material in the filters also contributes to the achievement of a technical result, since chemical modification of the filter material leads to a change in the surface charge of this filter material, and therefore an increase in the number of active sites that are ion-exchange groups. An increase in the number of ion-exchange groups leads to an increase in the efficiency of the filter material for heavy metal ions, thereby contributing to the expansion of the range of application of the utility model to the field of additional water purification from heavy metal ions and ammonium while purifying them from suspended solids, oil products, surface-active substances.

The implementation of filters in the claimed utility model in the form of a cartridge also contributes to the achievement of a technical result, that is, expanding the range of application of the utility model to the area of additional purification from heavy metal and ammonium ions, since their design (cartridges) assumes the presence of an upper and lower end filter open to all sections . In this case, water enters the cartridge, moves inside it and exits the cartridge uniformly over its cross section, without creating stagnant zones or zones with a lower linear velocity than the velocity of water in the main filter stream. In filters without

open inlet and outlet cross sections, that is, in point-fed filters (for example, a pipe inserted into a sealed filter housing), stagnant zones are much larger than in cartridges with open upper and lower ends, since water passing through a layer of medium (granular , fibrous) with a certain resistance to flow, moves along the path of least resistance. In this case, the linear flow rate will be maximum at the point of entry (withdrawal) of water into (from) the filter, and minimum (or even close to zero) at distant points from the point of entry (for example, in pockets near the walls). In the case of an open upper and lower ends of the filter (as is the case in the cartridge), water is supplied uniformly at all points of its cross section. Water is released in a similar way through the open end, which ensures the absence of stagnant zones, that is, an increase in the volume of the filter that is actually involved in the process of absorption of pollution, which means that it helps to expand the spectrum of application of the utility model to the area of additional water purification from heavy metal and ammonium ions, while cleaning them from suspended solids, petroleum products, surfactants.

Claims (6)

1. Installation for the treatment of wastewater from oil products, surfactants, heavy metal ions and ammonium ions, consisting of two sorption filters located in the underground space in separate wells, connected in series by technological pipelines, characterized in that the first is loaded in the direction of travel the filter water is made of activated carbon, and the loading of the second filter in the direction of movement of the water filter is made of zeolite. 2. Installation according to claim 1, characterized in that at least one of the filters contains a fibrous filter material. 3. Installation according to claim 1, characterized in that the first filter in the direction of movement of the water contains, in addition to activated carbon, another ion-exchange material and / or chemically modified activated carbon. 4. The apparatus according to claim 1, characterized in that the second filter along the movement of the water contains, in addition to the zeolite, another ion-exchange material and / or chemically modified zeolite. 5. Installation according to claim 2, characterized in that the fibrous filter material is chemically modified. 6. Installation according to any one of paragraphs. 1-5, characterized in that at least one of the sorption filters is made in the form of a cartridge with a waterproof upper and lower ends and an impermeable side wall.

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