RU118207U1 - LIQUID LIGHTING UNIT - Google Patents

Abstract

An apparatus for clarifying a liquid, comprising a cylindrical body, a cylindrical flocculation chamber concentrically located in it, passing into a truncated cone in the lower part, a system for supplying an initial fluid made with the possibility of supplying an initial fluid tangentially into a flocculating chamber, a system for removing floating impurities, a sludge removal system, a clarified water drainage system, a purification chamber, a post-treatment chamber, inclined thin-layer settling elements placed in the purification chamber, while the purification and post-treatment chambers form a sedimentation zone, characterized in that the upper part of the flocculation chamber protrudes from the housing to the outside, and the sedimentation zone contains several cleaning chambers and post-treatment, which alternate and are interconnected in such a way that the outer surface of the sedimentation zone has the shape of a regular straight prism and is formed by the outer walls of the purification and post-treatment chambers, connected tightly, and the inner surface is a protrusion the upper part of the cylindrical flocculation chamber, and the settling zone is located on top of the cylindrical body of the apparatus and its base is hermetically connected to its body and to the flocculation chamber along the length of their circumferences, while the cleaning chambers do not have a bottom inside the apparatus body and are oblique rectangular in cross-section prisms with vertical inner and outer walls, while the extreme inclined thin-layer settling elements installed in the cleaning chambers are inclined side walls of the prism, and the height of the inner vertical

Description

The invention relates to devices for purifying natural and wastewater from suspended particles and pop-up impurities with a low content of pop-up impurities in the initial liquid or with relatively low requirements for their amount in the purified liquid.

Closest to the proposed device for clarification of liquid according to the patent of the Russian Federation No. 2234357, B01 D 21/08, 04/27/2004. The known apparatus contains a concentrically arranged housing, a flocculation chamber, a cleaning chamber and a purification chamber. The cleaning and tertiary treatment chambers are equipped with radially spaced inclined thin-layer precipitation elements.

In the known apparatus, the liquid from the flocculation chamber enters the purification chamber, in which it moves between the precipitating elements from the bottom up. From the purification chamber, the clarified liquid, radially moving, enters the purification chamber, in which it moves between the precipitation elements from top to bottom. The clarified liquid from the after-treatment chamber through a piping system is discharged outside the apparatus. Separated impurities separated from the liquid phase from the flocculation chamber and the cleaning chamber are collected on the bottom of the apparatus, from where they are removed from the apparatus using a scraper mechanism. Pop-up impurities are collected above the cleaning and post-treatment chambers, from where they are discharged outside the apparatus.

The main technological disadvantage of this apparatus is the reduced coefficient of volumetric use of the cleaning and post-treatment chambers. This is due to the radial orientation of the thin-layer precipitation elements in the cleaning chamber. As a result, the channels for the passage of water between the precipitating elements have a trapezoidal cross-section, which leads to a non-uniformity of the velocity field of the fluid flow in the cross-section of the channels, a decrease in the volumetric utilization coefficient of the cleaning and post-treatment chambers, and, as a result, to a deterioration of the settling process of the deposited and floating particles.

In addition, the annular shape of the chambers for cleaning and post-treatment complicates the manufacture and installation of thin-layer precipitation elements. This is due to the fact that the cleaning and tertiary treatment chambers are cylindrical in shape, as a result of which, to ensure a tight fit of thin-layer precipitating elements inclined to the vertical angle of 30 ° to the cylindrical surface of the chambers and the apparatus body, their longitudinal edges must have a complex curvilinear, respectively, concave and convex shape, which complicates the whole device.

In addition, with a low content of pop-up impurities in the initial liquid or with relatively low requirements for their amount in the purified liquid, or with intense coalescence (droplet coalescence) in the flocculation and purification chambers, which leads to a high rate of impurities floating up in the after-treatment chamber, it is necessary to equip the chamber tertiary treatment by inclined precipitating thin-layer elements is absent. In this case, the presence in the aftertreatment chamber of inclined precipitating thin-layer elements complicates the manufacture of the known apparatus.

Thus, the apparatus closest to the claimed apparatus for clarifying the liquid identified during the patent search during implementation does not allow to achieve a technical result consisting in improving the settling process of the deposited and pop-up particles, in improving the cleaning efficiency, as well as in simplifying the manufacture of the apparatus.

The proposed utility model solves the problem of creating an apparatus for clarifying liquids, the implementation of which allows to achieve a technical result, which consists in improving the settling process of precipitated and pop-up particles, in improving the cleaning efficiency, as well as in simplifying the manufacture of the apparatus.

The essence of the utility model lies in the fact that in the apparatus for clarifying a liquid containing a cylindrical body, a cylindrical flocculation chamber concentrically located therein, passing into a truncated cone in the lower part, a feed fluid supply system configured to feed the feed fluid into the flocculation chamber tangentially, a system for removing pop-up impurities, a system for removing sludge, a system for removing clarified water, a treatment chamber, a post-treatment chamber, inclined oblique sedimentary elements, while the cleaning and tertiary treatment chambers form a settling zone, it is new that the upper part of the flocculation chamber protrudes outward from the housing, and the settling zone contains several cleaning and tertiary chambers that alternate and are interconnected so that the outer surface The settling zone has the shape of a regular direct prism and is formed by the outer walls of the cleaning and tertiary treatment chambers, which are tightly connected, and the inner surface is the protruding upper part of the qi an indigenous flocculation chamber, wherein the settling zone is located on top of the cylindrical body of the apparatus and its base is hermetically connected to its body and to the flocculation chamber along the circumference of the circles, while the cleaning chambers do not have a bottom inside the apparatus and are inclined rectangular prisms with vertical cross sections internal and external walls, while the extreme inclined thin-layer precipitation elements installed in the cleaning chambers are inclined side walls prism, and the height of the inner vertical wall of the cleaning chamber and the inclined side walls exceeds the liquid level in the chamber, and the height of the outer vertical wall is lower than the liquid level, and inclined thin-layer precipitation elements are installed in the cleaning chambers parallel to each other, while the after-treatment chambers are located in the corners of the zone sedimentation, and the extreme inclined thin-layer sedimentary elements of the cleaning chamber are simultaneously the inner side walls of the cleaning and tertiary treatment chambers and hermetically separate chambers from each other, in addition, the after-treatment chambers are equipped with a bottom, which is hermetically connected to its own outer walls, with the outer side surface of the flocculation chamber portion protruding from the housing and with the inner vertical and side inclined walls of the cleaning chambers, in addition, trays are introduced into the settling zone, which are hermetically fixed along the outer vertical walls of the cleaning chambers below the level of the liquid being cleaned, while the drain of the tray is hermetically connected with the after-treatment chamber, and the level of the liquid being cleaned in the after-treatment chamber lower than in the cleaning chamber, in addition, the clarified liquid drainage device and the pop-up impurity removal device are located in the after-treatment chambers, while the clarified liquid drainage device consists of a riser pipe with overflow and a pipe for removing liquid from the apparatus, which extends beyond the apparatus, while the riser pipes are located with their overflow edge below the level of the liquid to be cleaned in the after-treatment chamber, while the device for removing pop-up impurities includes a partition, covering the riser pipe, and means for removing pop-up impurities.

The technical result is achieved as follows. Features of the utility model formula: “An apparatus for clarifying a liquid, comprising a cylindrical body, a cylindrical flocculation chamber concentrically disposed therein, turning into a truncated cone in the lower part, a feed fluid supply system configured to feed a feed fluid into the flocculation chamber tangentially, a pop-up removal system impurities, sludge drainage system, clarified water drainage system, treatment chamber, post-treatment chamber, inclined thin-layer sieges located in the treatment chamber solid elements, while the cleaning and tertiary treatment chambers form a settling zone, ... "are an integral part of the claimed apparatus and ensure its operability, and, therefore, ensure the achievement of the claimed technical result, which consists in improving the settling process of deposited and pop-up particles, in increasing the cleaning efficiency, as well as to simplify the manufacture of the apparatus.

Due to the fact that in the claimed apparatus the zone of sedimentation contains several chambers for cleaning and post-treatment, it is possible to vary their connection. Since the upper part of the flocculation chamber protrudes outward from the housing, and the cleaning and tertiary treatment chambers are connected alternately, it is possible to place the cleaning and tertiary chambers around the flocculation chamber. At the same time, the alternation of the chambers ensures an even distribution of the liquid being cleaned between the chambers, which increases the efficiency of using the volume of the chambers and the quality of cleaning.

The possibility of alternating connection of the chambers is provided due to the fact that the after-treatment chambers are located in the corners of the prism, and the extreme inclined thin-layer precipitating elements of the cleaning chambers are simultaneously the inner side walls of the cleaning and post-treatment chambers and hermetically separate the chambers from each other. Since the settling zone is located on top of the cylindrical body of the apparatus and its base is hermetically connected to its body and to the flocculation chamber along the length of their circumferences, while the aftertreatment chambers are equipped with a bottom that is hermetically connected to its own outer walls, with the outer side surface of the flocculation chamber protruding from the case and with the inner vertical and inclined side walls of the cleaning chambers, and the cleaning chambers inside the apparatus do not have a bottom, this provides the opportunity RGANIZATION displacement liquid to be purified inside the machine in a desired direction.

In addition, in the claimed apparatus, trays are introduced into the settling zone, which are hermetically fixed along the outer vertical walls of the cleaning chambers below the level of the liquid being cleaned. Moreover, due to the fact that the height of the inner vertical wall, the cleaning chamber and the inclined side walls exceeds the liquid level in the chamber, and the height of the outer vertical wall of the cleaning chamber is lower than the level of the liquid being cleaned, overflow of the liquid being cleaned into the after-treatment chamber, bypassing the tray, is excluded. Since the trays are hermetically fixed along the outer vertical walls of the cleaning chambers below the level of the liquid being cleaned, and the level of the liquid being cleaned in the after-treatment chamber is lower than the liquid level in the cleaning chamber, while the trays are hermetically connected to the after-treatment chamber, the level difference ensures the movement of the liquid being cleaned from the cleaning chamber along the tray into the after-treatment chamber. As a result, the trays are included in the settling zone. Moreover, due to the introduction of the trays and fixing them below the level of the liquid being cleaned in the cleaning chamber, the liquid being cleaned from the cleaning chambers is hermetically sealed along the vertical walls of the cleaning chambers; consequently, from the channels formed by the precipitating elements, it is diverted to the side through the weir formed during this. In this case, the liquid to be cleaned is drained simultaneously from all channels, and not sequentially, as in the prototype, where the liquid to be purified first accumulates on the surface of the cleaning chamber, and then flows towards the after-treatment chambers in the horizontal direction. As a result, a single stream from the liquid being cleaned is formed in the claimed apparatus, its uniform discharge is ensured, which, compared with the prototype, increases the uniformity of the velocity field in the cross section of the channels. As a result, the efficiency of using the internal volume of the cleaning chamber is increased, the process of settling of deposited and floating particles is improved. Moreover, since the liquid to be cleaned is diverted from the cleaning chamber to the side through the spillway, the vertical size of the inclined thin-layer sedimentation elements does not affect the uniformity of movement of the liquid to be cleaned from the cleaning chamber, which improves the quality of cleaning and at the same time simplifies the design of the apparatus.

Since the purification chambers are inclined rectangular prisms in the section, and thin-layer precipitation elements are installed parallel to each other in the purification chambers, the channels between the inclined precipitation elements also have the shape of a rectangle, in contrast to the prototype, in which the shape of the channels between the precipitation elements is close to trapezoidal. Thus, in the zone of settling in the claimed apparatus, the cleaning chambers are a system of straight channels. As a result, in the inventive apparatus, the field of the fluid velocity in the channels between the inclined thin-layer precipitating elements is more uniform than the prototype, which increases the efficiency of using the volume of the cleaning chambers, improves the settling process of the deposited and pop-up particles, and improves the efficiency of liquid purification.

In the claimed apparatus, the cleaning and post-treatment chambers have a simpler form compared to the prototype, which structurally simplifies the settling zone and the entire apparatus as a whole. First of all, the simplification of the design is due to the proposed combination of cleaning and after-treatment chambers, which made it possible to hermetically separate them from each other by the extreme precipitation elements of the cleaning chambers. In this case, the after-treatment chambers have a flat bottom, which is hermetically connected to their own outer walls, with the outer side surface of the flocculation chamber portion protruding from the housing and with the inner vertical and lateral inclined walls of the cleaning chambers, and flat walls: two of which are their own vertical outer walls two of them are extreme inclined thin-layer sedimentary elements of the cleaning chamber, two are part of the inner vertical wall of the cleaning chamber. The trailing wall of the tertiary treatment chamber is the outer lateral surface of the protruding part of the cylindrical flocculation chamber. In this case, the cleaning chambers do not have a bottom inside the apparatus body and are inclined rectangular prisms in section with vertical inner and outer walls, while the inclined side walls of the prism are extreme inclined thin-layer sedimentation elements installed in the cleaning chambers.

At the same time, the shape of inclined thin-layer precipitation elements placed in the cleaning chamber and their installation is simplified, since the shape of the side surfaces of the precipitation elements in contact with the walls of the cleaning chamber is simplified, since the latter have a flat surface. In addition, the installation of precipitation elements in parallel simplifies both the design and the assembly of the cleaning chamber.

Thus, both cameras in the claimed apparatus are made of simple in shape flat linear elements. The tray introduced into the settling zone is also structurally simple and does not complicate the design of the apparatus as a whole.

In the claimed apparatus, the settling zone is placed on top of the cylindrical body of the apparatus and its base is hermetically connected to its body and to the flocculation chamber along the length of their circles. In this case, the cleaning chambers inside the circumference of the apparatus body do not have a bottom. However, the hermetic connection of the settling zone with the housing and the flocculation chamber ensures the tightness of the cleaning chambers in the zones protruding beyond the circumference of the housing, i.e. in the claimed apparatus in these zones, the cleaning chambers have a bottom that is hermetically connected to the casing of the apparatus along the corresponding part of the circle and to the corresponding protruding outward parts of the vertical outer and inclined side walls of the cleaning chambers. The possibility of sealing the cleaning chambers in zones protruding beyond the circumference of the casing allows the cleaning chambers to be made in the form of inclined rectangular prisms in the cross section, as well as arranging movement of the liquid to be cleaned in the desired direction inside the apparatus, i.e. to ensure the operability of the claimed apparatus for clarifying the liquid. Moreover, as tests have shown, partial sealing of the entrance window of the cleaning chambers does not affect the performance of the claimed apparatus.

As a result, the clarified liquid introduced into the apparatus tangentially enters the flocculation chamber, after which it flows from the bottom up to the purification chambers, and due to the fact that inclined thin-layer sedimentation elements are installed in the purification chamber in parallel, they are evenly distributed along the channels between the precipitating elements and then move between them from bottom to top with increased, compared with the prototype, the uniformity of the velocity field in the cross section of the channels. When this occurs, the deposition of impurities on the inclined surface of thin-layer precipitating elements, their sliding down and deposition on the bottom of the apparatus. Pop-up impurities coalesce (droplet fusion) and rise up under thin-layer sedimentation elements. After exiting the channels between thin-layer precipitating elements, the liquid from the treatment chambers is drained into trays and moves towards the after-treatment chambers, in which additional separation of the liquid and the pop-up impurities takes place.

In the aftertreatment chamber there are devices for removing clarified liquid and pop-up impurities. A device for draining clarified liquid consists of a riser pipe with overflow and a pipe for removing fluid from the apparatus, which extends beyond the apparatus. At the same time, riser pipes are located with their overflow edge below the level of the liquid being cleaned in the after-treatment chamber. As a result, a constant level of the liquid being cleaned is maintained in the chambers of purification and post-treatment, and clarified liquid is also discharged outside the apparatus. Moreover, the device for removing pop-up impurities includes an immersion baffle covering the riser pipe, and means for removing pop-up impurities, for example, a tray. The submersible baffle prevents the ingress of pop-up impurities into the system to drain clarified water. As a result, the clarified liquid passes under the immersion partitions, drains through the weirs and is removed from the apparatus. Surfaced impurities are held by immersion baffles, after which they are discharged by systems for discharging pop-up impurities outside the apparatus.

From the foregoing, it follows that the proposed implementation of the zone of settling provides the possibility of forming straight channels for the sequential passage of the cleaned fluid through the treatment chamber and further into the after-treatment chamber. As a result, the hydraulic operating mode of the apparatus is optimized, the volumetric coefficient of use of the cleaning chambers increases, and the process of settling of deposited and floating particles improves.

In addition, the rectilinear and rectangular shape of the structural elements of the chambers for cleaning and tertiary treatment and inclined thin-layer precipitation elements and, compared with the prototype, the lack of their need for a tertiary treatment chamber, the simplicity of the design of the trays, simplifies the design of the claimed apparatus and its manufacture.

Thus, from the foregoing, it follows that the claimed apparatus for clarifying the liquid during the implementation ensures the achievement of a technical result, which consists in improving the settling process of precipitated and pop-up particles, in improving the cleaning efficiency, as well as in simplifying the manufacture of the apparatus.

Figure 1 shows the claimed apparatus for clarifying a liquid, a vertical section; figure 2 is a view of the claimed apparatus in plan.

In the claimed apparatus, the cleaning and post-treatment chambers are contained in an equal amount. As an example, the number of cleaning and post-treatment chambers is chosen to be five.

The apparatus for clarifying the liquid contains a pipeline 1 for supplying the original contaminated liquid, a cylindrical body 2, inside of which a cylindrical flocculation chamber 3 is located coaxially, passing into a truncated cone in the lower part, and a settling zone, which includes cleaning chambers 4 and after-treatment chambers 5, which are placed with the possibility of sequential passage through them. the liquid being cleaned. The upper part of the flocculation chamber 3 protrudes from the housing 2 to the outside. The sedimentation zone contains several cleaning chambers 4 and post-treatment 5, which are alternated and interconnected so that the outer surface of the sedimentation zone has the shape of a regular direct prism and is formed by the outer walls of the cleaning chambers 4 and post-treatment 5, sealed, and the inner surface is a protruding upper part of the cylindrical flocculation chamber 3. The settling zone is placed on top of the cylindrical body 2 of the device and its base is hermetically connected to the body of the device 2 and to the flocculation chamber 3 along the length of their circles.

Cleaning chambers 4 do not have a bottom inside the apparatus body 2 and are inclined rectangular prisms in the cross section with vertical inner 6 and outer 7 walls. Inside the cleaning chambers 4, inclined thin-layer precipitation elements 8 are installed parallel to each other 8. The after-treatment chambers 5 are located in the corners of the settling zone and are provided with a bottom 9. The extreme inclined thin-layer precipitation elements 10 installed in the cleaning chambers 4 are inclined side walls of the prism of the cleaning chamber 4 and, at the same time, the chambers 4 and 5 are hermetically separated from each other. Precipitation elements 8, 10 are inserted into the cleaning chamber with force and are evenly distributed throughout the chamber 4. In the example of the apparatus, the inclination of the precipitating elements was 30 °. The height of the inner 6 vertical wall of the cleaning chamber 4 and the inclined side walls 10 exceeds the liquid level in the chamber 4, and the height of the outer vertical wall is lower than the liquid level. The bottom 9 of the aftertreatment chambers 5 is hermetically connected to its own outer walls 11, to the outer side surface of the flocculation chamber 3 protruding from the housing 2 and to the vertical vertical 6 and side 10 inclined walls of the treatment chambers 4. The level of the liquid to be cleaned in the aftertreatment chamber 5 is below the level the liquid being cleaned in the cleaning chamber 4.

Since the settling zone is hermetically connected to the apparatus body 2 along its circumference, in the zones protruding beyond the apparatus body 2, the cleaning chambers 4 have a bottom (shaded areas in Fig. 1), which is hermetically connected to the corresponding part of the circumference of the apparatus body 2 and with the corresponding protruding outward parts of the vertical outer 7 and the inclined side walls 10 of the cleaning chambers 4.

In the after-treatment chambers 5 there is a device for draining clarified liquid, which consists of a riser pipe with overflow 12 and a pipe 13 for removing liquid from the apparatus, which extends beyond the body 2 of the apparatus. At the same time, riser pipes 12 are located with their overflow edge below the level of the liquid being cleaned in the after-treatment chamber 5.

In the same chambers 5, a device for removing pop-up impurities is installed, which consists of a submersible baffle covering the riser pipe 12, made in the example in the form of a ring 14, and means 15 for outputting pop-up impurities, which can be made, for example, in the form of a tray .

For removal of the obtained sludge from the bottom 16, the apparatus contains a driving scraper mechanism 17 and a nozzle 18. In addition, trays 20 are introduced into the settling zone, which are hermetically fixed along the outer 7 vertical walls of the cleaning chambers 4 below the level of the liquid being cleaned. In this case, the drain 21 of the tray 20 is hermetically connected with the after-treatment chamber 5, the level of the liquid being cleaned in which is lower than the level of the drain 21 of the tray 20.

Pipelines for supplying the initial liquid, pipes for draining clarified liquid, for removing pop-up impurities, for removing sediment are combined into the corresponding systems 22, 23, 24, 25.

The feed fluid supply system 22 is configured to feed feed fluid into the flocculation chamber 3 tangentially. For this, the ends of the pipeline 1 in the flocculation chamber 3 are bent horizontally.

Figure 2: the dimming conventionally shows the bottom 9 of the aftertreatment chamber 5 of the cleaning chamber 4; conditionally shown extreme in a row inclined thin-layer sedimentation elements 10; the plan of the aftertreatment chamber 5 at the level of precipitation elements 8 is conventionally shown.

The device operates as follows. The initial liquid supplied to the apparatus through the pipeline 1 through the system 20 enters the flocculation chamber 3 tangentially, so that a rotational movement is imparted to the liquid chamber 3 with a spiral movement from top to bottom. Impurities falling from the liquid during its movement in the flocculation chamber 3 are collected on the bottom of the apparatus 16. Pop-up impurities are collected on the surface of the liquid in the flocculation chamber, from where they are removed outside the apparatus using, for example, tray 19, through the system 24 for removing pop-up impurities.

The implementation of the lower part of the chamber 3 in the form of a truncated cone preserves the rotational movement of the liquid when it exits into the housing 2 of the device. As a result, from the flocculation chamber 3, the liquid moves in the radial direction and enters the purification chambers 4, where it moves from bottom to top, passing through the channels between the inclined thin-layer sedimentation elements 8. Here, further separation of the deposited and pop-up impurities occurs. The precipitating impurities spontaneously slide down the inclined thin-layer sedimentation elements 8 on the bottom 16 of the apparatus. Pop-up impurities between inclined thin-layer sedimentation elements 8 move up. In this case, coalescence of impurities can occur, leading to their enlargement and accelerated ascent. Surfaced impurities are collected on the surface of the clarified liquid in the purification chambers 4.

From the cleaning chamber 4, the clarified liquid, together with the layer of floating impurities located on its surface, is poured simultaneously from all channels formed by inclined thin-layer precipitating elements through the outer vertical wall 7 into the tray 20 and slowly moves along it into the purification chambers 5. Here, the final separation of the clarified liquid and pop-up impurities. The clarified liquid passes under the immersion ring 14, discharges into the riser pipe 12 and is discharged through the pipe 13 outside the apparatus through the system 21 for draining the clarified liquid. Surfaced impurities are held by the immersion ring 14, and then are discharged through the system 22 to remove the pop-up impurities outside the apparatus.

The precipitate deposited on the bottom of the apparatus 16 rakes the rotating scraper device of the scraper mechanism 17 towards the center of the bottom 16. After that, the sediment is discharged through the nozzle 18 outside the apparatus through the system 23 for sediment removal.

Claims (1)

An apparatus for clarifying a liquid, comprising a cylindrical body, a cylindrical flocculation chamber concentrically disposed therein, passing into a truncated cone at the bottom, a feed fluid supply system configured to feed a feed fluid tangentially to the flocculation chamber, a pop-up impurity removal system, a sediment removal system, clarified water drainage system, purification chamber, after-treatment chamber, inclined thin-layer sedimentation elements located in the purification chamber, while the chambers cleaning and tertiary treatment form a settling zone, characterized in that the upper part of the flocculation chamber protrudes outward from the housing, and the settling zone contains several cleaning and tertiary treatment chambers that are alternated and interconnected so that the outer surface of the settling zone has the shape of a regular direct prism and formed by the outer walls of the chambers of cleaning and post-treatment, tightly connected, and the inner surface is the protruding upper part of the cylindrical flocculation chamber, and the zone test is placed on top of the cylindrical body of the apparatus and its base is hermetically connected to its body and to the flocculation chamber along the length of their circles, while the cleaning chambers do not have a bottom inside the apparatus and are inclined rectangular prisms in cross section with vertical inner and outer walls, with the extreme inclined thin-layer precipitation elements installed in the cleaning chambers are the inclined side walls of the prism, and the height of the internal vertical the shadows of the cleaning chamber and the inclined side walls exceed the liquid level in the chamber, and the height of the outer vertical wall is lower than the liquid level, and inclined thin-layer precipitation elements are installed parallel to each other in the cleaning chambers, while the after-treatment chambers are located in the corners of the settling zone, and the extreme inclined thin-layer precipitation elements of the cleaning chamber are simultaneously the inner side walls of the cleaning and post-treatment chambers and hermetically separate the chambers from each other, in addition, the post-treatment chambers with with a bottom that is hermetically connected to its own outer walls, with the outer side surface of the flocculation chamber portion protruding from the housing, and with the inner vertical and lateral inclined walls of the cleaning chambers, in addition, trays are introduced into the settling zone, which are hermetically fixed along the outer vertical walls of the cleaning chambers below the level of the liquid being cleaned, while the drain of the tray is tightly connected with the after-treatment chamber, and the level of the liquid being cleaned in the after-treatment chamber is lower than in the cleaning chamber in addition, a device for draining clarified liquid and a device for removing pop-up impurities are placed in the after-treatment chambers, while the device for draining clarified liquid consists of a riser pipe with overflow and a pipe for removing fluid from the apparatus, which extends beyond the apparatus body, while - the racks are located with their overflow edge below the level of the liquid to be cleaned in the after-treatment chamber, while the device for removing pop-up impurities includes an immersion partition covering the riser pipe, and means and to remove pop-up impurities.