RU2398743C1 - Smaller automated sewage sediments complex treatment plant - Google Patents

Abstract

FIELD: process engineering. ^ SUBSTANCE: invention relates to sewage treatment and utilisation of treatment products as fertilisers. Proposed plant comprises vertical casing coupled with reagent preparation unit. Said casing accommodates heating element, flat filtration element and blade mixer linked with motor and reduction gear via clutches. Treated sewage sediments discharge branch pipe with electrically driven gate valve is coupled with said casing. Sediments level and temperature pickups are built in the casing and connected to control unit. Casing incorporates additionally a standby heating element and conical accumulating tank arranged below filtration element. Said accumulating tank is connected with vacuum compressor and furnished with pressure and filtrate level pickups arranged in succession. Sewage sediments loading branch pipe, motor and reduction gear are mounted on casing cover. Pressure and filtrate level pickups are connected to control unit, in its turn, connected with standby heating element, vacuum compressor and electrically driven gate valve coupled with filtrate discharge branch pipe. ^ EFFECT: higher degree of sediment dehydration, reduced labor input, stable temperature conditions of treatment. ^ 1 dwg, 1 tbl

Description

The invention relates to small automated installations for the integrated treatment of sewage sludge, used in the treatment of sewage sludge from small settlements, individual or groups of cottages, as well as stocks of livestock complexes to obtain a comprehensively treated - dehydrated, fermented and disinfected - sediment with the possibility its disposal as fertilizer.

A well-known installation of integrated wastewater treatment and treatment of their sludge, formed by groups of pipes for loading the waste mixture with sludge, equipped with shut-off devices and connected to vertical filter elements. The filter elements are mounted on the flanges in the upper part of the installation and are connected to the hot compressed air supply pipes connected to electric heaters with control valves. The filter elements are made in the form of sleeves of filter fabric having a conical or cylindrical-conical shape. The lower parts of the filter elements are equipped with nozzles with gates for unloading dry treated sludge. At the same time, the nozzles for supplying hot compressed air are elongated inside the filter elements under the sludge sediment layer to the upper parts of the gates for unloading dry treated sludge sediments. The unit is also equipped with receiving storage tanks associated with filter elements, filtrate collection trays and a thermometer. The treated sludge is distributed through the nozzles for loading the waste mixture with sludge through the filtering elements by maintenance personnel. In the filter elements, sludge is subjected to heat treatment at a temperature of 70-85 ° C for 5-10 days. The treated sludge is discharged from the filter elements through the valves manually (patent RU 2239608, IPC ⁷ C02F 11/12, C02F 11/18).

The main disadvantages of the installation of integrated wastewater treatment and sludge treatment are the lack of automation of its management, which allows for the interconnection of the costs of hot compressed air and the processed material; lack of stabilization of the temperature regime; increased laboriousness of manufacturing due to significant dimensions, which is due to the use of several groups of filter elements, several receiving storage tanks and trays for collecting the filtrate.

Closest to the proposed invention in terms of technical nature and the achieved result is a small automated installation for integrated wastewater treatment and / or integrated treatment of their sludge, containing a horizontally mounted case with lids at the ends, connected to the reagent preparation unit, equipped with a reagent level sensor, through a branch pipe for loading sewage sludge, equipped with an electric valve and connected to the outlet pipe of the reagent preparation unit, equipped th electric valve. A horizontal cylindrical filter element connected to the sewage sludge loading nozzle and a mixing device made in the form of a screw mounted inside a horizontal cylindrical filter element with a downward offset relative to its axis and connected to the electric motor and gearbox through the clutch are installed coaxially with it. A working heating element is fixed in the cavity of the screw shaft. The control unit introduced into the installation is connected to an electric motor and a working heating element. Outside the filter element, an irrigation washing system is located coaxially and concentrically to it, which is a regeneration system of the filter element, also enclosed in a housing additionally equipped with a valve for venting fermentation gases. The lateral surface of the filter element is made of a core frame and layers of metal mesh, between which a layer of polymer hydrophobic material is placed, and is connected at the ends with pipe elements. The filtrate collecting tray is connected to the inlet of the irrigation washing system through a pump through its outlet pipe with an electric valve. The discharge pipe for treated sewage sludge, equipped with an electric valve, is connected in series with the filter element and the housing. The filtrate discharge pipe, equipped with a mechanical valve, is connected to the housing and the filtrate collection tray. A sensor for the level of sewage sludge is installed in the cavity of the filter element, and a sensor for the temperature of the sewage sludge is built-in inside the side surface of the filter element, said sensors being electrically connected to the control unit. In turn, the control unit is connected with electric valves on the branch pipe for loading sewage sludge, on the outlet pipe of the reagent preparation unit, on the outlet pipe for unloading the treated sewage sludge and on the outlet pipe of the filtrate collecting tray. The reagent level sensor is also electrically connected to the control unit (patent RU 2330817, IPC С02Р 11/12, B01D 29/11).

The main disadvantages of this installation are the low degree of sludge dewatering, since the pressure of the medium inside it is atmospheric, which does not contribute to a high level of separation of the filtrate from the solid phase of sewage sludge; the increased complexity of manufacturing due to its large dimensions, due to the horizontal execution of the housing with elements built into it, the complexity of the design of the regeneration system of the filter element, the need to install a working heating element inside the cavity of the screw shaft; the lack of stabilization of the temperature regime due to the lack of constructive ability to install a backup heating element.

The objective of the invention is to increase the degree of dewatering of sewage sludge, reducing the complexity of manufacturing and ensuring a stable temperature treatment of sewage sludge.

The problem is achieved in that in a small automated installation for the integrated treatment of wastewater sludge, comprising a housing with a lid connected to a reagent preparation unit equipped with a reagent level sensor-signaling device, through a sewage sludge loading port, equipped with an electric valve and connected to the outlet of the unit preparation of reagents equipped with an electric valve, a working heating element installed in the housing, a filter element made of metal layers a mesh, between which a layer of polymer hydrophobic material is enclosed, and a mixing device connected to the electric motor and gearbox through clutches, a control unit, a discharge pipe for treated sewage sludge, equipped with an electric valve and connected to the housing, a filtrate discharge pipe, equipped with a valve, At the same time, level and temperature sensors for sewage sludge are built into the casing, electrically connected to the control unit, which in turn is connected to an electric motor, will by an electric element, by electric valves on the branch pipe for loading sewage sludge, on the outlet pipe of the reagent preparation unit, on the outlet pipe for unloading the treated sewage sludge, and the sensor-indicator of the level of reagents is also electrically connected to the control unit, according to the invention, the mixing device is made in the form of a paddle mixer, the housing having thermal insulation is installed vertically and equipped with a backup heating element introduced into the installation and a cone-shaped storage tank, located below the filter element, made flat. The storage tank is connected to the vacuum compressor introduced into the installation and is equipped with sequentially installed pressure and filtrate level sensors, and the valve associated with the filtrate discharge pipe connected to the storage tank is electric. Sewage sludge loading nozzle, electric motor and gearbox are installed on the housing cover. The pressure and filtrate level sensors are electrically connected to the control unit, additionally connected to a backup heating element, a vacuum compressor and an electric valve connected to the filtrate discharge pipe.

The increase in the degree of dewatering of sewage sludge is due to the introduction of a vacuum compressor in the unit, which creates and maintains the optimal vacuum pressure to improve the separation of the filtrate from the solid phase of the sewage sludge.

The decrease in the complexity of manufacturing the installation is due, firstly, to a decrease in its dimensions due to the vertical design of the housing connected to a cone-shaped storage tank with elements built into it, and secondly, to simplify the regeneration of the filter element and, consequently, to reduce the rinsing water due to reverse current air supplied by a vacuum compressor under the filter element.

Ensuring a stable temperature regime for the treatment of sewage sludge is due to the introduction of a backup heating element.

The invention is illustrated by the drawing, which schematically shows a General view of a small automated installation for the integrated treatment of sewage sludge, as well as a table showing the types of interaction of the individual elements of a small automated installation for the integrated treatment of sewage sludge.

In addition, the drawing further indicates the following:

- solid lines with arrows show the discharge directions of the treated sewage sludge and leachate;

- dashed lines with arrows indicate the transmission channels of information and control signals.

A small automated installation for the integrated treatment of sewage sludge contains a vertically mounted building 1 equipped with thermal insulation. Inside the housing 1, a filter element 2 is installed, made flat of two layers of metal mesh, between which a layer of polymer hydrophobic material is enclosed. A mixing device made in the form of a paddle mixer 3, a working heating element 4 and a backup heating element 5 made in the form of electric heaters and designed to heat sewage sludge to an optimal temperature of 30-35 ° C is also installed inside the housing 1. The blade mixer 3 is connected to the electric motor 6 and the worm gear 7 through the clutch 8 of the clutch, which are installed on the cover 9 of the housing 1. The nozzle 10 for loading sewage sludge is also located on the cover 9. The cover 9 can be equipped with a nozzle for exhausting gases generated inside the housing 1 ( not shown in the drawing).

An outlet pipe 11 is connected to the reagent preparation unit 12 in a pipe 10 for loading sewage sludge connected to the housing 1. Thus, the supply of sewage sludge is carried out through the pipe 10 into the housing 1, connected through this pipe to the reagent preparation unit 12, and the reagent solution to the reagent preparation unit 12. Cationic flocculants such as Zetag are used as reagents to intensify the process of sludge dewatering, and the Puralat-Bingsti ovicidal preparation is used to disinfect wastewater and its sludge.

Below the filter element 2 there is a cone-shaped storage tank 13 connected to the vacuum compressor 14, and above the filter element 2 there is a pipe 15 for unloading the treated sewage sludge connected to the housing 1. The vacuum compressor 14 is designed to create a reduced pressure, which simplifies the filtrate separation from the solid phase of sewage sludge and improves the degree of dehydration.

The pipe 16 of the discharge of the filtrate is located in the lower part of the storage tank 13 and is connected to it.

In the cavity of the housing 1, a sensor 17 for the level of sewage sludge is installed, electrically connected to the control unit 18, which in turn is connected to an electric valve 20 installed on the nozzle 10 for loading the sewage sludge, with an electric valve 21 installed on the outlet pipe 11 of the cooking unit 12 reagents, an electric motor 6, a working heating element 4, a backup heating element 5 and a vacuum compressor 14.

The control unit 18 is a computer with analog-to-digital converters and software for managing the integrated treatment of sewage sludge.

The vacuum compressor 14 is connected to a conical storage tank 13 by means of a pipe 19 with a valve.

Inside the cavity of the housing 1, a sensor 22 for the temperature of the sewage sludge is connected, electrically connected through the control unit 18 with a working heating element 4 and a backup heating element 5.

Inside the storage tank 13, a filtrate pressure sensor 23 is arranged successively downward, electrically connected through a control unit 18 with a vacuum compressor 14, and a filtrate level sensor 24, electrically connected through a control unit 18 with an electric valve 25, mounted on the filtrate discharge pipe 16.

The pipe 15 for unloading the treated sediments is equipped with an electric valve 26, which is connected to the control unit 18.

In the reagent preparation unit 12, a reagent level sensor-detector 27 is installed that is electrically connected to the control unit 18.

Thus, the sewage sludge level sensor 17, the sewage sludge temperature sensor 22, the filtrate pressure sensor 23, the filtrate level sensor 24, the reagent level sensor-detector 27 are electrically connected to the control unit 18, which in turn is connected to the electric motor 6, a working heating element 4 and a backup heating element 5, a vacuum compressor 14, an electric valve 20 on the pipe 10 loading sewage sludge, an electric valve 21 on the output pipe 11 of the block 12 of the preparation of reagents, electrically valve 26 placed on a nozzle 15 discharging the treated sewage sludge and the electric valve 25 installed on the outlet conduit 16 discharging filtrate.

A small automated installation for the integrated treatment of sewage sludge is as follows.

Sewage sludge is fed into the housing 1 of the installation through the pipe 10 loading sewage sludge. The sensor 17 takes readings of the level of sewage sludge, the received information signals from which are transmitted to the control unit 18. The control signal from the control unit 18 is fed to an electric valve 21, which opens the supply of reagents through the outlet pipe 11 connected to the reagent preparation unit 12, and then according to the readings of the sensor 17, the level of sewage sludge through the control unit 18 closes the electric valves 20 and 21, which allows you to automate the loading of sludge into the housing 1. At a minimum level of reagents in the reagent preparation unit 12, the sensor-detector 27 of the reagent level is triggered.

After loading the sewage sludge into the housing 1, the signal from the control unit 18 is supplied to an electric motor 6, a working heating element 4, and a backup heating element 5, and a vacuum compressor 14.

The inclusion of the electric motor 6 starts the blade mixer 3, which allows you to automate the mixing process.

Heating of sewage sludge to an optimum temperature of 30-35 ° C is carried out by the working heating element 4. The working heating element 4 is turned on through the control unit 18 depending on the level of rainfall measured by the sensor 17 of the sewage sludge level, which allows you to automate the inclusion of the working heating element 4 to work. The temperature of the sewage sludge inside the housing 1 is measured by the sensor 22 of the sewage sludge temperature, the received information signal is transmitted via the control unit 18 to the working heating element 4, which allows optimizing the degree of heating of the sewage sludge. In the event of a breakdown of the working heating element 4 or insufficient heating according to the readings of the sensor 22 for the temperature of the sewage sludge, the backup heating element 5 is switched on via the control unit 18.

The inclusion of the vacuum compressor 14 through the control unit 18 after the readings of the sensor 17 of the level of sewage sludge allows you to automate the decrease in pressure in the installation.

Inside the building 1 of the installation, dewatering and fermentation of sludge occur, as well as decontamination of sewage sludge.

The separating filtrate is accumulated in the storage tank 13. The accumulated filtrate is discharged through the filtrate discharge pipe 16, on which an electric valve 25 is installed, the opening and closing of which is carried out by a control signal from the control unit according to the readings of the filtrate level sensor 24 in the storage tank 13.

Dehydrated, fermented and decontaminated wastewater sludges are discharged through the outlet pipe 15 for discharging the treated sewage sludge, on which an electric valve 26 is installed, the opening and closing of which is carried out by a control signal from the control unit 18, which makes it possible to automate the discharge of the treated sewage sludge depending on the treatment time .

According to the testimony of the pressure sensor 23 installed in the storage tank 13, a control signal is supplied through the control unit 18 to the vacuum compressor 14, which makes it possible to automate the process of maintaining the optimal pressure in the installation.

The regeneration of the filter element 2 is carried out using the reverse air flow, which is supplied by the vacuum compressor 14 after supplying a control signal from the control unit 18.

Thus, the use of the present invention with a small installation size and full automation of control provides complex processed sewage sludge while increasing the degree of dehydration, reducing the complexity of manufacturing, stabilizing the temperature regime. Precipitation treated according to the invention can be used on farms as fertilizer, in forest parks and urban households for landscape formation and reclamation of disturbed lands.

Automation of control of the installation is due to the implementation of the relationship between the flow of sludge and reagent sludge, the level of sediment in the cavity of the filter element, the optimal heating and temperature of the sewage sludge with minimal energy consumption, maintaining the necessary pressure using a vacuum compressor, to increase the efficiency of dewatering and regeneration of the filter element that is regulated by the control unit.

Types of interaction of individual elements of a small automated installation for the integrated treatment of sewage sludge Signal source Signal Cause Control action Drawing item number Title Destination Position Number Title Destination action 17 Wastewater Precipitation Sensor Maximum level eighteen Control block Signal processing twenty
21 Drives
electric gate valves Closing four Working heating element Inclusion 6 Electric motor Inclusion fourteen Vacuum compressor Inclusion eighteen Control block Processing completion 26 Electric valve actuator Opening-closing eighteen Control block Reduced filter element throughput fourteen Vacuum compressor Changing the direction of rotation of the motor Turn on / off the vacuum compressor 22 Sewage Sediment Temperature Sensor Temperature change eighteen Control block Signal processing four Working heating element Voltage change 5 Backup heating element Inclusion 23 Pressure meter Pressure change eighteen Control block Signal processing fourteen Vacuum compressor On-off 24 Filtrate level sensor Maximum-minimum level 19 Control block Signal processing 25 Electric valve actuator Opening-closing 27 Reagent level sensor Minimum level eighteen Control block Signaling

Claims (1)

A small automated installation for the integrated treatment of sewage sludge, comprising a housing with a lid connected to a reagent preparation unit equipped with a reagent level sensor-signaling device, through a sewage sludge loading port equipped with an electric valve and connected to an outlet pipe of a reagent preparation unit equipped with an electric valve, a working heating element installed in the housing, a filter element made of metal mesh layers, between which a layer is enclosed hydrophobic polymer material, and a mixing device connected to the electric motor and gearbox through clutches, a control unit, a discharge pipe for treated sewage sludge discharge, equipped with an electric valve and connected to the housing, a filtrate discharge pipe equipped with a valve, while level sensors and temperature of sewage sludge, electrically connected to the control unit, in turn, connected to an electric motor, a working heating element, an electric valve and on the branch pipe for loading sewage sludge, on the outlet pipe of the reagent preparation unit, on the branch pipe for unloading the treated sewage sludge, and the reagent level signaling device is also electrically connected to the control unit, characterized in that the mixing device is made in the form of a paddle mixer, housing, having thermal insulation, is installed vertically and equipped with a backup heating element introduced into the installation and a cone-shaped storage tank located below the filter element, made flat, while the storage tank is connected to the vacuum compressor introduced into the installation and is equipped with sequentially installed pressure and filtrate level sensors, and the valve associated with the filtrate discharge pipe connected to the storage tank is electric, the sewage sludge loading pipe, an electric motor and the gearbox is mounted on the housing cover, and the pressure and filtrate level sensors are electrically connected to the control unit, additionally connected to the backup heating element ementu, the vacuum compressor and the electric gate valve associated with the pipe discharging the filtrate.