RU57273U1 - WASTE WATER TREATMENT PLANT - Google Patents

Abstract

A biological wastewater treatment plant is disclosed, comprising a sewage inlet pipe, a bioplate, a water drainage pipe to a non-filtering bottom basin, the base of which is provided with a filter charge, and a sewage drainage pipe.

It differs from the known ones in that the bioplate is an artificial surface stream made in the form of a serpentine with pits, dams and a bypass ditch, with higher marsh plants planted between willow ridges along the banks of the stream and into the water, while the distribution of wastewater from the sewage inlet pipeline to the bioplate is carried out through slots or openings of a pipe flooded at the level of the macadam loading of the pit of the stream. The pool is lined with stone at the height of the filter load on the sides of the inlet and outlet of wastewater through slots or openings of pipes connected to the pipelines for supplying water to the pool and for discharging treated wastewater from the pool, and the pipeline for discharging treated wastewater from the pool is located below the pipeline for supplying water to the pool .

Between ridges of willows, higher marsh plants, E. Pratense Rehrh., D. Glomerata L., C. Palustre L, were planted along the banks of the stream, and plants C. Aquatilis Wahlenb and Caltha arctica R.Br.Hult were planted in the water.

The construction of wastewater treatment allows you to switch to environmentally friendly technologies, to avoid the use of chemicals that can accumulate in natural objects and reduce the level of pollution of water bodies.

1 s.p. f-ly, 2 ill.

Description

A facility for biological wastewater treatment, which can be used to purify household wastewater from fine and minute fractions of suspended solids and dissolved impurities with the help of plants capable of developing a large adsorbing surface, working in cold periods of the year, is also announced. There are various methods of biological wastewater treatment (patent for the invention of the Russian Federation No. 2186738 dated 10/09/02, patent for the invention No. 2181703 dated September 16, 1999, No. 2061663 dated August 10, 1993) consisting in the supply of biologically treated wastewater through a water distribution channel on a bioplate, which can be used biological ponds, canals and other reservoirs. Various types of plants (hygrophytes and mesophytes) are used to clean effluents, capable of developing root systems when growing them in an aqueous medium, which are superior in adsorption capacity to root hydrophyte systems and their combinations.

Their disadvantage is the construction of gratings in tanks or pools in which plants are planted, as well as the need for periodic removal of green surface mass. In addition, for efficient operation in winter time, it is necessary to place a pool or tank in a greenhouse type building with walls and a roof made of opaque materials, which increases operating costs for the maintenance of treatment facilities.

The closest is a biological wastewater treatment plant (RF patent No. 2220922 dated 10.22.02), containing a sewage inlet pipe, a sump with a distribution chute in the form of a gear spillway, and a water drainage pipe into the pool with a non-filtering bottom, on which the filter loading with a nozzle of higher aquatic plants, gravity drains at the base of the pool for removal of cleaned

sewage and a well with a device that regulates the water level in the pool. Its disadvantage is the high cost of construction and operation due to the fact that for the construction to operate in the winter, the pool and sump are buried as much as possible in the ground and in winter they must be covered to protect against freezing, since 30-50% of cleaning from normalized ingredients occurs for account of the ground part of higher aquatic plants, planted in the filter loading of the pool.

The inventive structure, as well as known, contains a sewage inlet pipeline, a bioplate, a drainage pipe for a pool with a non-filter bottom, the base of which is equipped with a filter charge, and a sewage drainage pipe from the pool to the reservoir.

The problem solved in the development of this utility model was to create a system for the purification of domestic wastewater, especially discharged into drinking water sources for supplying cities and towns or to habitats of valuable fish species, based on the use of natural water treatment mechanisms.

The technical result of the utility model is to increase the treatment of domestic wastewater without increasing the cost of energy and chemicals with the maximum use of natural conditions without additional environmental impact and minimal costs for the construction and operation of the facility.

The technical result is achieved by the fact that the bioplate is an artificial surface stream made in the form of a serpentine with dams and a bypass ditch, with higher bog plants planted between ridges and willows, while the distribution of wastewater from the sewage inlet pipe to the bioplate is carried out through slots or openings of the pipe, a creek pit flooded at the level of macadam loading.

The pool is paved with stone at the height of the filter load on the sides of the inlet and outlet of wastewater through slots or openings of pipes connected to the pipelines for supplying water to the pool and drainage of treated wastewater

from the pool, moreover, the pipeline for treating wastewater from the pool is located below the pipeline for supplying water to the pool.

Between ridges of willows, higher marsh plants, E. Pratense Rehrh., D. Glomerata L., C. Palustre L, were planted along the banks of the stream, and plants C. Aquatilis Wahlenb and Caltha arctica R.Br.Hult were planted in water.

A bioplate in the form of a serpentine laid artificial surface stream with dams, a pit and a bypass ditch, with higher marsh plants planted between ridges and willows allows you to create natural wastewater treatment mechanisms, remove fine fractions of suspended solids and dissolved impurities and enrich the wastewater with oxygen, which ensures an increase in biochemical purification of domestic wastewater without increasing the cost of energy and chemicals with the maximum use of natural conditions without additional environmental impact. Dams slow down the movement of water and increase the rate of precipitation. Macrophyte plants growing on a bioplate provide wastewater treatment for nitrogen, phosphorus and other chemical and microbiological parameters due to the large adsorbing surface of the root systems and the surface part, as well as due to the action of microorganisms. A bypass ditch prevents storm and rainwater from entering areas adjacent to the bioplate.

The distribution of wastewater from the sewage inlet pipeline to the bioplate through slots and openings of a pipe flooded at the level of the crushed stone loading of the stream pit provides optimal conditions for the development of higher bog vegetation on the surface of building blocks due to the movement of water due to warm wastewater in winter, regulation feed mode. So, for example, during the onset of frost, they artificially raise the water level in the pool 0.2-0.5 m above the load level, and the cleaning processes go in the thickness of the drains. Even in very cold periods, the temperature of the wastewater at the exit from the bioplate and the basin did not decrease below + 7 ° С. The temperature of the water provides a favorable temperature regime for microbiological processes of water purification.

The implementation of the pool, lined with stone at the height of the filter load on the sides of the inlet and outlet of wastewater, carried out through slots or openings of pipes connected to the pipelines for supplying water to the pool and the discharge of treated wastewater from the pool, with the placement of the pipeline for the disposal of treated wastewater from the pool below the pipeline water supply to the pool, provides the movement of water through a bioactive film covering the load, through the filter load itself, where the water is exposed to physico-chemical, biochemical and biological processes, and is cleaned to the required quality.

The construction as a whole effectively treats wastewater according to 14 chemical and microbiological indicators, while having a dechlorinating effect. The cost of construction of the facility is minimal due to the use of natural conditions of the terrain, the lack of construction of aboveground premises for protection against freezing of higher aquatic plants, planted on gratings on the surface of the bioplate. Not required and the costs of operating the facility.

Thus, the claimed construction of wastewater treatment does not require energy, chemicals and maintenance, as it is based on the use of natural mechanisms of water purification, effectively treats wastewater in both summer and winter periods.

The inventive utility model is illustrated using the drawings, where in Fig.1. presents a diagram of the structure in plan, figure 2 is a section aa of the structure.

The wastewater treatment plant (see Fig. 1) consists of two aftertreatment units: a bioplate 1 (plant construction block) and a pool 2 (filter construction block) connected by a piping system. The piping system consists of a sewage inlet pipe 3 on a bioplate 1, a drainage pipe 4 from a bioplate 1 into a pool 2, and a sewage pipe 5 from a basin 2 to a reservoir. The sewage inlet pipe 3 is connected to slotted pipes 6 flooded

in the pit 7 with gravel loading. The slots of the pipes 6 can be made of any shape, both in the form of a slit and in the form of round holes.

Pipelines 3-5 are made with devices 9 that regulate the water level in the pool 2, and, if necessary, on the bioplate 1. Devices 9 can be made in the form of valves, for example, and installed in wells. An additional conduit 10 may be drawn connecting the conduit 4 to the conduit 3 to return the wastewater to a bioplate 1 for further treatment.

The plant site of bioplate 1 is made in the form of a serpentine-laid stream 8 with small dams 11, which slow down the movement of sewage and, together with vegetation, allow creating an artificial upland swamp with a developed bacterial film, limited by a bypass ditch 12. The sizes of bioplate 1 can be different depending on the terrain . The wastewater treated on the bioplate is discharged into the pool 2 by a pipeline 4 from the sump 13 located at the end of the bioplate 1. In the sump 13, a ring was laid (not shown in the drawing), filled with gravel loading, which in this embodiment of the plant section of the bioplate strengthens the banks at the site of narrowing and increasing flow rate. Rows of willows 14 were planted between the bending channel of stream 8. On the banks of stream 8 plants were planted: E. Pratense Rehrh., D. Glomerata L., C. Palustre L. C. Aquatilis Wahlenb and Caltha arctica R.Br.Hult were also planted in water. .

Pool 2 (filter block) is made (see figure 2) with a non-filter bottom 15, the base of which is equipped with a filter load 16 of any inert coarse material (for example, gravel or gravel). The pool 2 at the level of the filter load 16 is made with a stone outline 17 on the sides of the inlet and outlet of wastewater carried out through slotted pipes 18 and 19. The pipe 5 for discharging treated wastewater from the pool 2 is located below the pipeline 4 for supplying water to the pool 2 at the level of the stone outline 17 filter media 16.

Bioplato 1 is built on a growing area of several native species of willows. Until 2003, the following plants grew on the surface of the plot:

- Salix lapponum L., S. borealis (Fries) Nas., S. Phylicifolia L., S. Xerophila B. Floder, S. Pentandra L., S. Glauca L., Dactylis glomerata L., Festuca pratensis Huds., Rumex confertus Willd.

In June 2003, the following plants were still planted and taken root: Comarum palustre L., Caltha palustris L., Carex acutatilis L., Marchantia polymorpha, Polytrichum commune, Phragmites australis

The above plants, together with the structural features of the structure, regulating the level and flow of water, provide post-treatment efficiency and optimal living conditions of biocenoses in winter and summer.

The construction carries out post-treatment of sewage in a village with a population of 2000 people. The wastewater discharge after treatment is about 186 thousand m ³ / year.

The wastewater of the village is first treated at mechanical and biological treatment facilities with a primary sump, a pre-treatment biofilter, a secondary sump - a contact tank where contact with chlorine takes place, and then they are delivered to the claimed artificial wastewater treatment plant.

During the operation of the complex since 2003, no environmental risk and residual impacts on the environment have been identified. The construction was commissioned in 2005.

Despite the cold climate, the structure is functioning well. Chemical and microbiological analysis indicates high cleaning efficiency. The stability of the reaction medium (pH). The complex of facilities works as a self-adjusting system and provides wastewater treatment up to 90%.

Sampling for analysis of the degree of wastewater treatment at this facility was carried out regularly at points located after the plant site - bioplato 1, and after the filtration site - pool 2.

The measured parameters included: pH, BOD5, suspended solids, chlorides, total nitrogen, ammonium nitrogen, nitrite nitrogen, nitrate nitrogen, phosphorus phosphorus, surfactants, petroleum products, iron, zinc, chromium, copper, manganese, nickel, COD. Water flow rate and outdoor temperature, inlet / outlet temperature, common coliform bacteria, thermo-tolerant coliforms, coliphages, and helminth eggs were also measured. All analyzes were carried out in accordance with Russian water standards.

Comparing the wastewater treatment data for the summer and winter months, we can conclude that long-term dynamics to increase efficiency is observed in both winter and summer.

For example, in winter and summer 2004 compared with winter and summer 2003, the cleaning efficiency is increased in all respects:

For suspended solids - by 9%,

Ammonium nitrogen - by 13%,

By total phosphorus 3 times.

The same trend was observed in 2005.

The construction of this wastewater treatment system allows you to switch to environmentally friendly technologies, to get away from the use of chemicals that can accumulate in natural objects and reduce the level of pollution of water bodies.

Claims (2)

1. The facility for biological wastewater treatment, containing a sewage inlet pipe, a bioplate, a drainage pipe for a pool with a non-filter bottom, the base of which is equipped with a filter charge, and a sewage drainage pipe, characterized in that the bioplate is made in the form of a serpentine artificial surface stream with pits, dams and a bypass ditch, with higher marsh plants planted between willow ridges along the banks of the stream and into the water, while the distribution of wastewater from the wastewater inlet piping to the bioplate is through slots or openings of a pipe flooded at the level of the rubble pit of the stream pit, and the pool is lined with stone at the height of the filtering load on the sides of the wastewater inlet and outlet through slots or openings of pipes connected to the water supply pipelines to the pool and drainage of treated wastewater from the pool, and the pipeline for the disposal of treated wastewater from the pool is located below the pipeline supplying water to the pool. 2. The construction according to claim 1, characterized in that between the ridges of willows on the banks of the creek are planted higher bog plants E. Pratense Rehrh., D. Glomerata L., C. Paluster L, and plants C. Aquatilis Wahlenb and Caltha are planted in water arctica R.Br.Hult.