RU2771411C1 - Waste water treatment device (options) - Google Patents

Abstract

FIELD: wastewater treatment.

SUBSTANCE: invention relates to the field of biological treatment of domestic and industrial wastewater using activated sludge. The cleaning device comprises a housing with a cover, divided by partitions into a receiving chamber with a water level sensor, at least one sludge stabilization chamber and an outlet chamber, a pneumatic system and an electrical system. Additionally, the device contains a module for communication with sensors for monitoring device parameters. A damper with a heated water level sensor located inside is installed in the receiving chamber. The communication module is made with a temperature sensor, a power battery and the ability to transmit data via wireless communication lines. According to the second embodiment, the device additionally comprises a water turbidity sensor installed in the outlet chamber. According to the third embodiment, the device additionally contains a sludge concentration sensor installed in the sludge stabilization chamber, and a water turbidity sensor in the outlet chamber. According to the fourth embodiment, the device additionally contains an air pressure sensor installed in the pneumatic system, a sludge concentration sensor in the sludge stabilization chamber, and a water turbidity sensor in the outlet chamber. According to the fifth embodiment, the device additionally contains a reed switch or end sensor installed on the cover, an air pressure sensor in the pneumatic system, a sludge concentration sensor in the sludge stabilization chamber, and a water turbidity sensor in the outlet chamber.

EFFECT: high level of wastewater treatment with the possibility of remote monitoring of the parameters of technological processes occurring in the process of treatment.

20 cl, 3 dwg, 5 ex

Description

The invention relates to the field of biological treatment of domestic and industrial wastewater, using activated sludge.

In the state of the art, continuous cleaning plants are known, where the cleaning process must be maintained by a process that requires a lot of energy for a long time without interrupting the operation of the cleaning plant and timely maintenance by qualified personnel.

A device for water purification is known from the prior art, containing a housing in which there are a receiving chamber separated by partitions, an aeration tank, a secondary sump and a sludge stabilizer, as well as an aeration system connected to the control unit and connected to the compressor through a solenoid valve. A flow damper and a purge nozzle are located in the secondary sump (RU 97362 U1, published on September 10, 2010 C02F 1/00).

The disadvantage of this installation is the unstable operation of the secondary clarifier, caused by the possibility of removal of excess activated sludge.

From the prior art, a complex biological wastewater treatment plant is known, consisting of a tank that contains: a receiving chamber with wastewater supply, an aeration tank chamber, a secondary sump with purified water discharge and an activated sludge stabilizer. The receiving chamber has a primary filter and a device for its blowing, float sensors for wastewater levels and an airlift for pumping wastewater. An airlift is located in the secondary clarifier to transfer the fat film to the aeration tank chamber. The activated sludge stabilizer chamber is equipped with an intermediate partition forming an additional sludge stabilization chamber, consisting of two parts, upper and lower, located so as to form a free space between them (EP 2138464 A1, published 12/30/2009, C02F 3/12)

The disadvantage of this device is the lack of an alarm system for the failure of certain units used in the wastewater treatment process, the inability to monitor the parameters of the station.

The closest in technical essence to the proposed group of inventions is a device for biological wastewater treatment containing a body made in the form of a cylinder and divided by partitions into a receiving chamber, an aeration tank, a secondary clarifier, a sludge stabilizer, a control unit and a compressor connected to it through an aeration system through a solenoid valve . The secondary clarifier is formed by vertical walls. The unit is completed with an insulated cover with a ventilation device and an alarm lamp (strobe lamp). In the receiving chamber there is a working level float sensor and an emergency level float sensor (RU 184550 U1, published 10/30/2018 C02F 3/02).

The disadvantage of this device is the inability to provide remote monitoring of the installation of biological wastewater treatment.

The technical result of the claimed group of inventions is the development of wastewater treatment devices that provide a high level of purified water with the possibility of remote monitoring of the parameters of technological processes occurring in the wastewater treatment process.

The claimed technical result is achieved by the fact that the wastewater treatment device according to the first embodiment comprises a housing with a lid, divided by partitions into a receiving chamber with a water level sensor, at least one sludge stabilization chamber and an outlet chamber, a pneumatic system and an electrical system. In addition, it contains a communication module with sensors for monitoring device parameters. A damper with a heated water level sensor located inside is installed in the receiving chamber. The communication module is made with a temperature sensor, a power battery and the ability to transmit data via wireless communication lines.

According to the second embodiment, the wastewater treatment device comprises a housing with a cover, divided by partitions into a receiving chamber with a water level sensor, at least one sludge stabilization chamber and an outlet chamber, a pneumatic system and an electrical system. In addition, it contains a communication module with sensors for monitoring device parameters. At the same time, a damper with a heated water level sensor located inside is installed in the receiving chamber. A water turbidity sensor is installed in the outlet chamber. The communication module is made with a temperature sensor, a power battery and the ability to transmit data via wireless communication lines.

According to the third embodiment, the wastewater treatment device comprises a housing with a cover, divided by partitions into a receiving chamber with a water level sensor, at least one sludge stabilization chamber and an outlet chamber, a pneumatic system and an electrical system. The device additionally contains a communication module with sensors for monitoring device parameters. A damper with a heated water level sensor located inside is installed in the receiving chamber. A sludge concentration sensor is installed in the sludge stabilization chamber. A water turbidity sensor is installed in the outlet chamber, the communication module is made with a temperature sensor, a power battery and the possibility of data transmission via wireless communication lines.

According to the fourth embodiment, the wastewater treatment device comprises a housing with a cover, divided by partitions into a receiving chamber with a water level sensor, a sludge stabilization chamber and an outlet chamber, and a pneumatic system. The device additionally contains a communication module with sensors for monitoring device parameters. A damper with a heated water level sensor located inside is installed in the receiving chamber. A sludge concentration sensor is installed in the sludge stabilization chamber. A water turbidity sensor is installed in the outlet chamber. The pneumatic system is equipped with an air pressure sensor. The communication module is made with a temperature sensor, a power battery and the ability to transmit data via wireless communication lines.

According to the latest embodiment, the wastewater treatment device comprises a housing with a cover, divided by partitions into an inlet chamber with a water level sensor, a sludge stabilization chamber and an outlet chamber, and a pneumatic system. The device additionally contains a communication module with sensors for monitoring device parameters. A damper with a heated water level sensor located inside is installed in the receiving chamber. A sludge concentration sensor is installed in the sludge stabilization chamber. A water turbidity sensor is installed in the outlet chamber. A reed switch or a limit sensor for opening the housing cover is installed on the housing cover. The pneumatic system is equipped with an air pressure sensor. The communication module is made with a temperature sensor, a power battery and the ability to transmit data via wireless communication lines.

Preferably, the water level sensor is installed in the damper by means of a retainer in which holes are made. The temperature sensor of the communication module can be placed on the outer side of the case.

The claimed technical solution is illustrated by the following drawings:

in fig. 1 - general view of the installation according to the first variant;

in fig. 2 - general view of the installation according to the third option;

in fig. 3 is a general view of the installation according to the fifth variant.

The following is a description of the claimed variants of the device in statics.

According to the first option: the wastewater treatment device contains a housing 1 (see fmg. 1) with a lid (not indicated in the figures), divided by partitions into a receiving chamber 2, in which a damper 3 is installed with a water level sensor 4 located inside, at least , one sludge stabilization chamber 5 and an outlet chamber 7. The device also contains a pneumatic system 9 and a communication module 12. The communication module 12 is made with a temperature sensor 13 and a power battery 15 for data transmission when the external power is turned off. In addition, the cleaning device includes an electrical system.

The water level sensor 4 can be installed in the damper 3 using a special retainer (not shown in the figure), which has holes for unobstructed air passage.

The temperature sensor 13 of the communication module 12 can be placed on the outer side of its housing.

According to the second version: the wastewater treatment device comprises a housing 1 with a lid, divided by partitions into a receiving chamber 2, in which a damper 3 is installed with a water level sensor 4 located inside, at least one sludge stabilization chamber 5 and an outlet chamber 7 with a sensor 8 turbidity of the water. The device also includes a pneumatic system 9 and a communication module 12. The communication module 12 is made with a temperature sensor 13 and a power battery 15 for data transmission when the external power is turned off. In addition, the cleaning device includes an electrical system.

The water level sensor 4 can be installed in the damper 3 using a special retainer (not shown in the figure), which has holes for unobstructed air passage.

The temperature sensor 13 of the communication module 12 can be placed on the outer side of its housing.

According to the third option (see Fig. 2): the wastewater treatment device comprises a housing 1 with a lid, divided by partitions into a receiving chamber 2, in which a damper 3 is installed with a water level sensor 4 located inside, at least one sludge stabilization chamber 5 with a sludge concentration sensor 6 located in it and an outlet chamber 7 with a water turbidity sensor 8. The device also includes a pneumatic system 9 and a communication module 12. The communication module 12 is made with a temperature sensor 13 and a power battery 15 for data transmission when the external power is turned off. In addition, the cleaning device includes an electrical system.

The water level sensor 4 can be installed in the damper 3 using a special retainer (not shown in the figure), which has holes for unobstructed air passage.

The temperature sensor 13 of the communication module 12 can be placed on the outer side of its housing.

According to the fourth option: the wastewater treatment device comprises a housing 1 with a lid, divided by partitions into a receiving chamber 2, in which a damper 3 is installed with a water level sensor 4 located inside, a sludge stabilization chamber 5 with a sludge concentration sensor 6 located in it and an outlet chamber 7 with 8 water turbidity sensor. The device also includes a pneumatic system 9 with an air pressure sensor 10 and a communication module 12. The communication module 12 is made with a temperature sensor 13 and a power battery 15 for data transmission when the external power is turned off.

The water level sensor 4 can be installed in the damper 3 using a special retainer (not shown in the figure), which has holes for unobstructed air passage.

The temperature sensor 13 of the communication module 12 can be placed on the outer side of its housing.

According to the fifth option (see Fig. 3): the wastewater treatment device comprises a housing 1 with a cover, divided by partitions into a receiving chamber 2, in which a damper 3 is installed with a water level sensor 4 located inside, a sludge stabilization chamber 5 with a sensor located in it 6 sludge concentration and outlet chamber 7 with water turbidity sensor 8. The device also includes a pneumatic system 9 with an air pressure sensor 10 and a communication module 12. The communication module 12 is made with a temperature sensor 13 and a power battery 15 for data transmission when the external power is turned off. A reed switch or end sensor 11 for opening the housing cover is installed on the housing cover.

The water level sensor 4 can be installed in the damper 3 using a special retainer (not shown in the figure), which has holes for unobstructed air passage.

The temperature sensor 13 of the communication module 12 can be placed on the outer side of its housing.

For all variants of the device, the communication module 12 is preferably provided with a current (voltage) sensor 14 .

The operation of the claimed device is based on the phased monitoring and control of wastewater treatment. The wastewater treatment device includes several chambers connected in one housing 1. The biological treatment process consists in the biochemical destruction (oxidation) of organic substances by microorganisms and the elimination of the decay process in the wastewater, which ensures clarification of the wastewater, which becomes transparent, which significantly reduces bacterial contamination .

Device Implementation Example #1.

Wastewater enters the primary receiving chamber 2, where the incoming wastewater is averaged. The initial biological and mechanical treatment is also carried out here. To measure the level of wastewater in the receiving chamber 2, a water level sensor 4 is installed. As the water level sensor 4, an ultrasonic range sensor or a float sensor is preferably used. The water level sensor 4 can be installed in the damper 3 using a special retainer (not shown in the figure), which has holes for unobstructed air passage. A vertically standing pipe can be used as a damper 3. The damper 3 makes it possible to avoid incorrect measurements of the water level when foam or waves form in the receiving chamber 2 when drains are drained. Water level sensor 4 is heated by the heating system 10 degrees more than the ambient air to prevent condensation on it. The heating system, preferably, is a thin-film heater placed on the sensor body 4. By overflow from the primary receiving chamber 2, the effluents enter the sludge stabilization chamber 5. In the sludge stabilization chamber, anaerobic purification processes take place by oxidation with activated sludge.

For this version of the device, it is permissible to divide the stabilization chamber 5 into several compartments, which enhances the positive effect of wastewater treatment.

Data transmission is carried out via wireless communication lines, such as GSM or Wi-Fi. If one or more parameters are out of range, the communication module sends parameter violation notifications to the client and the service organization. The device allows you to monitor the level of wastewater in the receiving chamber. On the basis of which it is possible to draw a conclusion about the operation of the treatment plant. The rate of level change is used to estimate the operating time of station cycles. If the cycles differ from the normative values, then the treatment plant cannot cope with the supplied volume of wastewater, respectively, the water comes out undertreated.

Thus, the wastewater treatment device according to the first variant provides a high level of water purification with the possibility of remote monitoring of the parameters of ongoing technological processes.

Device Implementation Example #2.

Wastewater enters the primary receiving chamber 2, where the incoming wastewater is averaged. The initial biological and mechanical treatment is also carried out here. To measure the level of wastewater in the receiving chamber 2, a water level sensor 4 is installed. An ultrasonic range sensor or a float sensor can be used as a water level sensor. The water level sensor 4 is installed in the damper 3, for example, using a special retainer (not shown in the figure), which has holes for unobstructed air passage. A vertically standing pipe can be used as a damper. The damper 3 makes it possible to avoid incorrect measurements of the water level when foam or waves form in the receiving chamber 2 when drains are drained. The water level sensor 4 is heated by the heating system 10 degrees more than the ambient air to prevent condensation on the sensor. The heating system can be a thin-film heater placed on the sensor body 4. By overflow from the primary receiving chamber, the effluents enter the sludge stabilization chamber 5. In the sludge stabilization chamber 5, anaerobic purification processes take place by oxidation with activated sludge. Next, the wastewater is sent to the outlet chamber 7, in which the water turbidity sensor 8 is installed. The turbidity sensor 8 of purified water is placed in the last outlet chamber 7, from where water is discharged from the housing and monitors the purity of the outlet water. An optical or ultrasonic sensor can be used as a turbidity sensor.

For this version of the device, it is permissible to divide the stabilization chamber 5 into several compartments, which enhances the positive effect of wastewater treatment.

Data transmission is carried out via wireless communication lines, such as GSM or Wi-Fi. If one or more parameters are out of range, the communication module sends parameter violation notifications to the client and the service organization. The device allows you to monitor the level of wastewater in the receiving chamber. On the basis of which it is possible to draw a conclusion about the operation of the treatment plant. The rate of level change is used to estimate the operating time of station cycles. If the cycles differ from the normative values, then the treatment plant cannot cope with the supplied volume of wastewater, respectively, the water comes out undertreated. If the turbidity sensor 8 indicates insufficient purity of the outgoing water, then the treatment plant cannot cope with the supplied volume of wastewater, respectively, the water comes out undertreated.

Thus, the wastewater treatment device according to the second variant provides a high level of water purification with the possibility of remote monitoring of the parameters of ongoing technological processes.

Device Implementation Example #3.

Wastewater enters the primary receiving chamber 2, where the incoming wastewater is averaged. The initial biological and mechanical treatment is also carried out here. To measure the level of wastewater in the receiving chamber 2, a water level sensor 4 is installed. The water level sensor is preferably an ultrasonic range sensor or a float sensor. The water level sensor 4 can be installed in the damper 3 using a special retainer (not shown in the figure), which has holes for unobstructed air passage. A vertically standing pipe can be used as a damper. The damper 3 makes it possible to avoid incorrect measurements of the water level when foam or waves form in the receiving chamber 2 when drains are drained. The water level sensor 3 is heated by the heating system 10 degrees more than the ambient air to prevent condensation on the sensor. The heating system can be a thin film heater placed on the sensor housing. Overflow from the primary receiving chamber 2 flows into the chamber 5 of the stabilization of the sludge. In the sludge stabilization chamber 5, anaerobic purification processes take place by oxidation with activated sludge. To control the cleaning process, a sludge concentration sensor 6 is installed in the chamber 5. The sludge concentration sensor 6 is sealed, it can be optical and, due to infrared light, changes the translucency of water, or ultrasonic, which monitors the concentration of sludge due to a change in the density of the liquid. Next, the wastewater is sent to the outlet chamber 7, in which the water turbidity sensor 8 is installed. The turbidity sensor 8 of the purified water is placed in the last outlet chamber, from where the water is discharged from the housing 1 and monitors the purity of the outlet water. The turbidity sensor 8 can be an optical or ultrasonic sensor.

For this version of the device, it is permissible to divide the stabilization chamber 5 into several compartments, which enhances the positive effect of wastewater treatment. In this case, the sludge concentration sensor 6 is preferably placed in the first of the sludge stabilization chambers in the course of the technological process.

Data transmission is carried out via wireless communication lines, such as GSM or Wi-Fi. If one or more parameters are out of range, the communication module sends parameter violation notifications to the client and the service organization. The device allows you to monitor the level of wastewater in the receiving chamber. On the basis of which it is possible to draw a conclusion about the operation of the treatment plant. The rate of level change is used to estimate the operating time of station cycles. If the cycles differ from the normative values, then the treatment plant cannot cope with the supplied volume of wastewater, respectively, the water comes out undertreated. If the turbidity sensor 8 indicates insufficient purity of the outgoing water, then the treatment plant cannot cope with the supplied volume of wastewater, respectively, the water comes out undertreated. If the readings of the sludge sensor 6 go beyond the normative values, it can be concluded that there is too much spent activated sludge in the treatment plant and it is time to clean it. If not cleaned in time, excess sludge will lead to pollution of the drainage system of the treatment plant.

Thus, the wastewater treatment device according to the third option provides a high level of water purification with the possibility of remote monitoring of the parameters of ongoing technological processes.

Device Implementation Example #4.

Wastewater enters the primary receiving chamber 2, where the incoming wastewater is averaged. The initial biological and mechanical treatment is also carried out here. To measure the level of wastewater in the receiving chamber 2, a water level sensor 4 is installed. As the water level sensor 4, an ultrasonic range sensor or a float sensor can be used. The water level sensor 4 is installed in the damper 3, for example, using a special retainer (not shown in the figure), which has holes for unobstructed air passage. A vertically standing pipe can be used as a damper 3. The damper 3 makes it possible to avoid incorrect measurements of the water level when foam or waves form in the receiving chamber 2 when drains are drained. The water level sensor 4 is heated by the heating system 10 degrees more than the ambient air to prevent condensation on the sensor. The heating system is preferably a thin film heater placed on the sensor body 4.

Overflow from the primary receiving chamber 2 flows into the chamber 5 of the stabilization of the sludge. In the sludge stabilization chamber 5, anaerobic purification processes take place by oxidation with activated sludge. To control the cleaning process in the chamber 5, a sludge concentration sensor 6 is installed. The sludge concentration sensor 6 is preferably sealed, while it can be optical and, due to infrared light, changes the translucency of water, or ultrasonic, which monitors the sludge concentration by changing the density of the liquid, from which one can judge the sludge concentration in the chamber. With an increased concentration of sludge, cleaning is necessary to avoid contamination of the drainage system. Next, wastewater is sent to the outlet chamber 7, in which the turbidity sensor 8 is installed. The sensor 8 of the turbidity of the purified water is installed in the last outlet chamber 7, from where the water is discharged from the housing 1 and monitors the purity of the outlet water. The turbidity sensor 8 can be an optical or ultrasonic sensor. In the pneumatic system 9, an air pressure sensor 10 is installed, which controls the pressure in the pneumatic system of the device. During the operation of the device, jets, airlifts, aerators become clogged, as a result of which the operation of the device deteriorates. Which in turn leads to a decrease in the quality of wastewater treatment. Also, this sensor 10 shows the operation of the compressor, which may fail.

Thus, the wastewater treatment device according to the latest version provides a high level of water purification with the possibility of remote monitoring of the parameters of ongoing technological processes.

An example of the implementation of the device No. 5.

Wastewater enters the primary receiving chamber 2, where the incoming wastewater is averaged. The initial biological and mechanical treatment is also carried out here. To measure the level of wastewater in the receiving chamber 2, a water level sensor 4 is installed. As the water level sensor 4, an ultrasonic range sensor or a float sensor can be used. The water level sensor 4 is installed in the damper 3, for example, using a special retainer (not shown in the figure), which has holes for unobstructed air passage. A vertically standing pipe can be used as a damper. The damper 3 makes it possible to avoid incorrect measurements of the water level when foam or waves form in the receiving chamber 2 when drains are drained. The water level sensor 4 is heated by the heating system 10 degrees more than the ambient air to prevent condensation on the sensor. The heating system is preferably a thin film heater placed on the sensor housing.

Overflow from the primary receiving chamber 2 flows into the chamber 5 of the stabilization of the sludge. In the sludge stabilization chamber 5, anaerobic purification processes take place by oxidation with activated sludge. To control the cleaning process, a sludge concentration sensor 6 is installed in the chamber 5. The silt concentration sensor 6 is sealed, it can be optical and, due to infrared light, changes the translucency of water, or ultrasonic, which monitors the concentration of sludge due to a change in the density of the liquid, from which one can judge the concentration of sludge in the chamber. With an increased concentration of sludge, cleaning is necessary to avoid contamination of the drainage system. Next, wastewater is sent to the outlet chamber 7, in which the turbidity sensor 8 is installed. The purified water turbidity sensor is placed in the last outlet chamber 7, from where the water is discharged from the housing 1 and monitors the purity of the outlet water. The turbidity sensor 8 can be an optical or ultrasonic sensor. In the pneumatic system 9, an air pressure sensor 10 is installed, which controls the pressure in the pneumatic system of the device. During the operation of the device, jets, airlifts, aerators become clogged, as a result of which the operation of the device deteriorates. Which in turn leads to a decrease in the quality of wastewater treatment. Also, this sensor 10 shows the operation of the compressor, which may fail. The reed switch or end tamper sensor 11 installed on the housing cover ensures the safety of the station elements from theft and unauthorized access to the device. As a result of unauthorized access to the control elements of the treatment plant system, the settings of the station operation can be knocked down, which will instantly affect the quality of water treatment.

Thus, the wastewater treatment device according to the latest version provides a high level of water purification with the possibility of remote monitoring of the parameters of ongoing technological processes.

The information described below applies equally to all device variants. The communication module 12 is provided with a temperature sensor 13, which can be remote, and an additional power source in the form of a battery 15 to maintain autonomous operation when the external power is turned off. Also, the communication module 12 is advantageously provided with a current (voltage) sensor 14 . The communication module 12 is preferably located in the electrical compartment of the device. Inside module 12 there is a processor that polls the sensors at a specified time interval and transmits data to the programmed devices. Data transmission is carried out via wireless communication lines, such as GSM or Wi-Fi. If one or more parameters are out of range, the communication module sends parameter violation notifications to the client and the service organization. In this case, the communication module 12 automatically polls the sensors at a predetermined time interval, which can range from 5 minutes to 24 hours.

The design of the claimed group of devices can be used in the operation of septic tanks and other treatment facilities that provide wastewater treatment. The complex of sensors allows not only to timely notice the failure of the units of the treatment plant, which in turn leads to flooding of the station, the release of excess silt and other debris into the drainage system, but also to monitor the quality of waste water treatment.

The claimed devices can be manufactured on standard industrial equipment.

Claims (20)

1. A wastewater treatment device containing a housing with a lid, divided by partitions into a receiving chamber with a water level sensor, at least one sludge stabilization chamber and an outlet chamber, a pneumatic system and an electrical system, characterized in that the device additionally contains a communication module with control sensors parameters of the device, while in the receiving chamber there is a damper with a heated water level sensor located inside, a communication module is made with a temperature sensor, a power battery and the ability to transmit data via wireless communication lines. 2. The device according to claim 1, characterized in that the water level sensor is installed in the damper using a retainer. 3. The device according to claim 2, characterized in that holes are made in the latch. 4. The device according to claim 1, characterized in that the temperature sensor of the communication module is placed on the outer side of the case. 5. A wastewater treatment device containing a housing with a lid, divided by partitions into a receiving chamber with a water level sensor, at least one sludge stabilization chamber and an outlet chamber, a pneumatic system and an electrical system, characterized in that the device additionally contains a communication module with control sensors parameters of the device, while in the receiving chamber there is a damper with a heated water level sensor located inside, a water turbidity sensor is installed in the outlet chamber, the communication module is made with a temperature sensor, a power battery and the ability to transmit data via wireless communication lines. 6. The device according to claim 5, characterized in that the water level sensor is installed in the damper with a retainer. 7. The device according to claim 6, characterized in that holes are made in the latch. 8. The device according to claim 5, characterized in that the temperature sensor of the communication module is placed on the outer side of the case. 9. Wastewater treatment device, containing a housing with a lid, divided by partitions into a receiving chamber with a water level sensor, at least one sludge stabilization chamber and an outlet chamber, a pneumatic system and an electrical system, characterized in that the device additionally contains a communication module with parameters control sensors device, while in the receiving chamber there is a damper with a heated water level sensor located inside, a sludge concentration sensor is installed in the sludge stabilization chamber, a water turbidity sensor is installed in the outlet chamber, the communication module is made with a temperature sensor, a battery and the ability to transmit data over wireless lines. 10. The device according to claim 9, characterized in that the water level sensor is installed in the damper with a retainer. 11. The device according to claim 10, characterized in that holes are made in the latch. 12. The device according to claim 9, characterized in that the temperature sensor of the communication module is placed on the outer side of the case. 13. Wastewater treatment device, containing a housing with a lid, divided by partitions into a receiving chamber with a water level sensor, a sludge stabilization chamber and an outlet chamber, and a pneumatic system, characterized in that the device additionally contains a communication module with sensors for monitoring device parameters, while in a damper with a heated water level sensor located inside is installed in the receiving chamber, a sludge concentration sensor is installed in the sludge stabilization chamber, a water turbidity sensor is installed in the outlet chamber, the pneumatic system is equipped with an air pressure sensor, the communication module is made with a temperature sensor, a power battery and the ability to transmit data over wireless links. 14. The device according to claim 13, characterized in that the water level sensor is installed in the damper using a retainer. 15. The device according to claim 14, characterized in that holes are made in the latch. 16. The device according to claim 13, characterized in that the temperature sensor of the communication module is placed on the outer side of the case. 17. A wastewater treatment device containing a housing with a lid, divided by partitions into a receiving chamber with a water level sensor, a sludge stabilization chamber and an outlet chamber, and a pneumatic system, characterized in that the device additionally contains a communication module with sensors for monitoring device parameters, while in a damper with a heated water level sensor located inside is installed in the receiving chamber, a sludge concentration sensor is installed in the sludge stabilization chamber, a water turbidity sensor is installed in the outlet chamber, a reed switch or end sensor for opening the housing cover is installed on the housing cover, the pneumatic system is equipped with an air pressure sensor, the communication module is made with a temperature sensor, a power battery and the possibility of data transmission via wireless communication lines. 18. The device according to claim 17, characterized in that the water level sensor is installed in the damper using a retainer. 19. The device according to claim 18, characterized in that holes are made in the latch. 20. The device according to claim 17, characterized in that the temperature sensor of the communication module is placed on the outer side of the case.

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