MD761Z - Sewage water treatment plant - Google Patents

Abstract

The invention relates to a sewage water treatment plant and can be used for the treatment of domestic sewage water and similar to them by composition.The plant, according to the invention, comprises a carcass (1) equipped with a sewage water feed pipeline (7) and a treated water drainage pipeline (23), closed with covers (11), in which are installed inspection manholes (9, 13, 15, 19) and an aeration pipe (6), the carcass and the covers are isolated from the outside with heat-insulating material (8). At the same time, inside the carcass, in the water flow direction, are placed three vertical partitions (14, 17) with holes, which divide the carcass into three settlers (2, 3, 4) and a chamber with biofilter (5), in which are placed aeration pipes (20) and a filter material (21) disposed on a lattice (22), mounted on a support (24), under which there is a drainage chamber (25). The last settler (4) communicates with the biofilter (5) by means of siphons (16), to which are connected perforated pipelines (18). In the first two vertical partitions (14) are made several holes in the middle part and one hole in the upper part.

Description

The invention relates to a wastewater treatment plant and can be used to treat domestic water and water similar to it in composition.

A wastewater treatment plant is known, which includes a housing equipped with a wastewater inlet pipe and a purified water outlet pipe and closed with a cover, in which inspection holes are installed, inside the housing there are two vertical dividing walls with holes that divide the housing into two decanters and a biofilter chamber [1].

The disadvantage of this installation is that the water does not clear well enough, the siphon allows grease and foam from the surface of the water to flow onto the biological filter body, which leads to its clogging and, respectively, to damage to the installation.

A wastewater treatment plant is also known, which includes a housing equipped with a wastewater inlet pipe and a purified water outlet pipe and closed with a lid, in which a vent pipe is installed, inside the housing, in the direction of water flow, three vertical partitions with holes are placed that divide the housing into three decanters and a biofilter chamber, in which a filter material is placed, the last decanter communicates with the biofilter via a siphon [2].

The disadvantages of this installation are the lack of a ventilation system inside the biofilter chamber, a system for balancing the pressure between the decanters, a system for exhausting gases from the decanters and a system for evenly distributing water on the surface of the filter material, the filter is inefficient, the unpleasant odor persists and it requires frequent servicing. The processes that occur in such installations do not ensure a high degree of wastewater treatment.

The closest solution is the wastewater treatment plant, which includes a housing equipped with a treated water outlet pipe and closed with a lid, in which a wastewater inlet pipe, inspection holes and a vent pipe are installed. Inside the housing, in the direction of the water flow, there are two membranes with holes and a vertical wall that divide the housing into three decanters and a biofilter chamber, in which the vent pipe and the filter material placed on a grid, installed on a support, are located. The last decanter communicates with the biofilter through a siphon [3].

The disadvantages of this installation are the lack of a system for balancing the pressure between the decanters, the difficult maintenance of the installation, it is not possible to enter each compartment of the installation for repair, the unpleasant smell persists, the water from the last decanter flows onto the surface of the filter material at a single point, which leads to the washing of the biological film at that place. The membranes are not reliable and their holes can become clogged with objects that have entered the installation. This installation has an inefficient filter and requires frequent maintenance involving special equipment.

The problem solved by the invention consists in intensifying the water purification process and eliminating the unpleasant odor, ensuring access inside the decanters for repair or servicing, simplifying the emptying process, increasing the working period between cleaning-emptying processes and more effective operation of underground communications, increasing the effectiveness of the biofilter and simplifying the process of changing it, working without damage in the case of objects falling inside, reducing costs for the construction of the installation.

The problem is solved by the fact that the wastewater treatment plant consists of a module, which includes a housing equipped with a wastewater inlet pipe and a purified water outlet pipe and closed with covers, in which inspection holes and a ventilation pipe are installed, the housing and covers being insulated on the outside with thermal insulation material. At the same time, inside the housing, in the direction of the water flow, there are three vertical partitions with holes that divide the housing into three decanters and a biofilter chamber, in which there are ventilation pipes and a filter material placed on a grid, installed on a support, under which there is a drainage chamber. The last decanter communicates with the biofilter by means of siphons, to which perforated pipes are connected. In the first two vertical partitions, several holes are made in the middle and one hole in the upper part. The installation consists of two or more modules connected consecutively to each other in the horizontal plane.

The result of the invention consists in intensifying the water purification process, eliminating unpleasant odors, simplifying the operation of the entire installation due to the combination of anaerobic and aerobic fermentation processes in one module, advanced filtration and reducing costs.

The covers allow inspection or entry into any segment of the installation, in which inspection holes are incorporated for draining or for breaking the film formed above the wastewater, the upper part of these inspections is 5 cm below ground level. The installation also has a ventilation system. In the case of large installations they are covered with a floor, also having inspection covers, inspection holes and an aerobic biological filter artificially aerated, without the use of electricity.

The decanters are of different sizes, the first being the largest, where the wastewater enters, most of the sediments and fats remain here, the waters flow into the second decanter where they encounter less sediments and fats and from the second to the last, respectively with fewer impurities. In the first two vertical dividing walls, several holes are made in the middle, these holes exclude clogging or damage to the installation, the vertical wall between the biofilter and the last decanter is warm, it radiates heat into the biofilter chamber. The thermal insulation allows the temperature obtained from fermentation to be maintained both in winter and in summer. The siphons do not allow air from the biofilter chamber to enter the anaerobic decanters, they also ensure the removal of gases from the decanters into the biofilter chamber, where they are absorbed by the aeration system. Perforated pipes are connected to the siphons for the uniform distribution of already clarified and partially purified water on the surface of the filter material through a free and uniform flow 3...5 cm from the surface of the biological film.

The construction of the biofilter allows for easy replacement of the filter material. As a filter material, impermeable materials of various sizes are used, which allow water to easily drain through their contents. The filter material is placed on a grid, installed on a support, under which there is a drainage chamber, where the purified water is discharged from the installation through an outlet pipe. Pipes for aeration of the filter are mounted inside the filter.

The installation can be made of two or more modules connected consecutively to each other in a horizontal plane, the number of modules is determined depending on the flow rate, each module being designed for a flow rate of up to 15 m3/day.

The invention is explained by the drawings in Fig. 1, 2, 3, which represent:

- Fig. 1, installation diagram, longitudinal (front) section;

- Fig. 2, section A-A (see Fig. 1);

- Fig. 3, plan view.

The wastewater treatment plant consists of a module containing a housing 1 with covers 11, in which inspection holes 9, 13, 15 are installed for emptying or breaking the film, an inspection hole 19 for seeding the biofilter with aerobic bacteria and a vent pipe 6, the housing is equipped with a wastewater inlet pipe 7 and a purified water outlet pipe 23. Inside the housing are placed vertical dividing walls 14 in which holes (a) and an opening 12 for pressure balance are made, which divide the housing into three decanters 2, 3, 4, the next vertical wall 17 with openings (c) separates the decanters from the biofilter chamber 5, which communicate with each other by means of siphons 16, to which perforated pipes 18 are connected, which continue above the surface of the filter material 21 placed on a grid 22, installed on a support 24, under which there is a drainage chamber 25, in the biofilter there are placed ventilation pipes 20, in the space 10 the accumulation of biological gas takes place, and in the siphons there are made holes (b) for the evacuation of the surplus of accumulated gases. The casing and the covers are insulated on the outside with thermal insulation material 8.

The wastewater treatment plant can consist of several modules, the number of which is determined depending on the flow rate, each module is designed for a flow rate of up to 15 m3/day, the connection between the modules is made using the wastewater inlet 7 and the biologically treated water outlet 23. The modules are provided with the possibility of expanding the treatment plant without changing the technological process.

The installation works as follows.

The wastewater reaches the first decanter 2 through the pipe 7, where the primary sedimentation and fermentation of activated sludge are carried out, where anaerobic bacteria consume the organic matter, decomposing the solids. The heavier matter settles to the bottom due to its weight, and the lighter one floats on top. The water passes into the second decanter 3 through the holes (a) made in the partition wall at an average height and from there into the next decanter 4. The vertical walls 14 delimit the sludge deposition areas. Thus, the waste water, passing through several decanters and staying in them for a certain period of time, was subjected to both anaerobic fermentation: hydrolysis, acidogenesis, acetogenesis, methanogenesis, and the mechanical process of water clarification. The clear water reaches the biofilter 5, passing through the siphons 16 into the perforated pipes 18 that distribute the water evenly over the entire surface of the filter material 21, where the aerobic bacteria continue purifying the organic residues from the water, leaving it in optimal conditions for discharge, it reaches the drainage chamber 25, from where it is discharged through the pipe 23.

This installation presents a construction in which both the decantation of water and the fermentation of the sludge resulting from sedimentation occur simultaneously in a single volume. It is a natural biological treatment installation, in which the long-term preservation and putrefaction of the deposited sediments take place. Here the process of biological degradation of organic substances in the sludge takes place through the activity of bacterial populations, which under certain environmental conditions (pH, temperature, etc.), decompose the organic matter in the sludge through biochemical oxidation-reduction processes into simple molecules of CH4, CO, CO2 and H2, which form the so-called fermentation gas or biogas. The kinetics of anaerobic fermentation takes place under the influence of two main groups of bacteria that live in symbiosis in the same physical and chemical environment, namely anaerobic and aerobic bacteria, which transform, through hydrolysis, complex organic substances (carbohydrates, proteins, fats) into simpler organic substances (lower organic acids, alcohols, etc.) with the help of extracellular enzymes. These substances then serve as a food source for simpler molecules, which with the help of intracellular enzymes are transformed into simple and environmentally harmless compounds: methane, carbon dioxide, etc. The sediments are emptied through revisions 9, 13, 15 once every 3-4 years with the help of special equipment and the filter material 21 is replaced with a new one. After each emptying, a certain amount of old sludge is left in the decanters, i.e. a sludge containing methane bacteria necessary for the fermentation of the fresh sludge that is to be mineralized. These installations can be built with a flow rate of up to 15 m3/day. The use of this installation ensures a high degree of wastewater treatment, technological reliability in the work process due to the sustainable hydraulic regime and simplicity in operation.

1. RU 42519 U1 2004.12.10

2. Cleaning facilities. Biofilters. 2012.10.02 (found on the Internet at 2013.07.17 URL:< http://vodoprovod-24.ru/biofiltry.html>)

3. Septic with biofilter. Construction and principle of operation of a septic tank with a biofilter. 2012 (found on the Internet at 2013.06.03 URL:<http://ekowave.ru/%D1%81%D0%B5%D0%BF%D1%82%D0%B8%D0%BA-%D1%81-%D0%B1%D0%B8%D0%BE%D1%84%D0%B8%D0%BB%D1%8C%D1%82%D1%80%D0%BE%D0%BC>)

Claims (3)

1. Wastewater treatment plant, consisting of a module, which includes a housing equipped with a wastewater inlet pipe and a treated water outlet pipe and closed with covers, in which inspection holes and a ventilation pipe are installed, the housing and covers being insulated on the outside with thermal insulation material, at the same time, inside the housing, in the direction of the water flow, there are three vertical partitions with holes that divide the housing into three decanters and a biofilter chamber, in which some ventilation pipes and a filter material placed on a grid, installed on a support, are located, under which there is a drainage chamber, the last decanter communicates with the biofilter by means of siphons, to which some perforated pipes are connected. 2. Installation according to claim 1, characterized in that in the first two vertical partition walls several holes are made in the middle part and one hole in the upper part. 3. Installation according to claim 1, characterized in that it consists of two or more modules connected consecutively to each other in a horizontal plane.