RU63351U1 - BIOLOGICAL WASTE WATER TREATMENT PLANT - Google Patents

Abstract

Installation for biological wastewater treatment, claimed as a utility model, relates to the field of biological wastewater treatment. The most efficient utility model can be used as a small installation intended for wastewater treatment of separate buildings and cottages. The objective of the utility model is to obtain a technical result, which consists in improving the quality of cleaning without hardware and economic costs to achieve this result. The problem is solved in the case when the installation for biological wastewater treatment, made in the form of a monoblock, which is a rectangular tank, buried in the ground, divided by partitions into compartments, performing the functions of an equalizing tank equipped with means for supplying wastewater and their subsequent supply to the activation a tank, an activation tank equipped with means for supplying air and water to the sump and a sump with the release of purified water, so that each of the tank has adjacent partitions with two others, differs from the known one in that the partitions separating the activation tank from the sump and the equalizing tank from the sump have an area and thickness that slows down the flow of thermal energy from the equalizing and activation tanks to the sump, while material for the manufacture of the capacity of the installation for cleaning used sheets of expanded polypropylene.

Description

The installation, claimed as a utility model, relates to the field of biological wastewater treatment. The most efficient utility model can be used as a small installation intended for wastewater treatment of separate buildings and cottages.

Biological wastewater treatment involves the use of filter media, most often activated sludge, which is a mixture of various bacteria and the smallest microorganisms capable of consuming the organic compounds contained in wastewater as nutrients necessary for vital functions during the activation process. For the activation process to occur, continuous oxidation is required, which is ensured by forcing air into the activation tank of the installation. During the cleaning process, part of the filter charge is mixed with waste water, especially when using sludge in suspension, therefore, there is a need for subsequent separation of the filter load and the water to be purified. Accordingly, the main structural elements of most treatment plants are the activation tank and sump, as well as devices for supplying air to the activation tank, pumps for pumping water and sludge from one tank to another.

When operating small installations to comply with a given cleaning mode, including that required for cleaning

concentrations of activated sludge, wastewater, can be supplied to the activation tank from a leveling tank (receiving chamber). Initial sedimentation of wastewater takes place there.

From the standpoint of operational characteristics for biological wastewater treatment plants, especially for small plants, the simplification of their design and operation, as well as improving the quality of treatment, is relevant.

A known installation of biological wastewater treatment [A.S. 952760, IPC C 02 F 3/00, 1982], including a cylindrical-shaped activation tank with a conical bottom, filled with a filter load, and a settling tank (separator tank) installed behind the activation tank. The installation provides a system for returning the washed load to the activation tank, as well as a water recirculation system.

The disadvantage of this installation is the relatively large footprint, an extensive piping system. For this reason, it cannot be used as a small cleaning plant. The absence of a leveling tank implies the operation of the installation in continuous mode, which is also not acceptable when servicing such objects as, for example, detached houses and cottages.

Known installation containing zones of activated sludge, intermediate clarification, final aeration, additional deposition, formed due to the separation of a single cavity by partitions [patent RU 2121981, IPC C 02 F 3/00, 1998]. In this case, the cavity may represent a reinforced excavation.

The volumes of individual zones can be changed and adapted to the flow parameters by displacing the partitions. For example, when undercharging, you can reduce the area of activated sludge in which

aeration, to thereby prevent the death of bacteria. When overloaded, the area of activated sludge, on the contrary, is increased, thereby increasing the productivity of the installation.

However, in order to track the ratio of wastewater and activated sludge necessary to ensure bacterial activity when moving partitions, the introduction of special sensors is required, which complicates the design of the installation. To carry out the movement of the partitions, complexity of the installation design is also required.

For small treatment plants, it is not practical to make a cavity in the form of a fortified earthen excavation, which also occupies a fairly significant area.

A known installation for biological wastewater treatment, [patent RU 2233247, IPC C 02 F 3/12, 2004], made in the form of a compact monoblock, which is a rectangular, buried in the ground tank. The tank is divided into at least four unequal volume compartments that perform the functions of a leveling tank with a wastewater supply, an activation tank, a sump and a collection well with the release of purified water. In the collection well, the final settling of suspended particles of activated sludge takes place. Since a sufficiently long period of time is required for sedimentation, the volume of the sump and collection well is selected to be approximately three times larger than the volume of the activation tank. The volume of the equalization tank is chosen somewhat smaller than the volume of the activation tank.

The equalization tank has an adjacent partition, both with the activation tank and with the collection well. This arrangement of tanks provides a compact installation.

A distinctive feature of the installation, which allows to improve the quality of cleaning, is that the device for supplying air to the activation tank is movable, for example, in the form of a reactive gas turbine, which ensures the creation of local circulation during the sparging of compressed air and the intensification of the oxidation process. In this case, air can be supplied to the activation tank in a pulsating mode.

The installation also provides magnetic treatment of effluents.

The presence of four compartments also improves the quality of treatment, up to the denitrification of effluents.

However, improving the quality of cleaning is achieved by complicating the design of the known installation, which makes it very expensive.

The experience of operating small treatment plants has shown that at least three compartments that perform the functions of a leveling tank with a wastewater supply, an activation tank equipped with means for supplying air and draining water to the sump, and a sump with the release of purified water are sufficient in the installation.

A known installation for biological wastewater treatment [patent RU 2162062, IPC C 02 F 3/00, 2001]. The installation is made in the form of a compact monoblock, which is, in particular, a rectangular, buried in the ground capacity. The capacity is divided by partitions into three compartments that perform the functions of a leveling tank with a wastewater supply, an activation tank and a sump with the release of purified water.

The equalization tank is equipped with means for supplying wastewater and a pump through which the treated water is supplied to the activation tank. The activation tank is equipped with

means for supplying air - an aeration tube attached to the aeration compressor, and drainage of water into the sump. The sump is equipped with a sludge recirculation pump, through which sludge after settling is pumped into the activation tank.

The installation is also equipped with a pump for pumping the contents of the activation tank back to the equalization tank in case the water level in the latter drops below a predetermined level. This technique ensures the uninterrupted operation of the installation with a slight influx of wastewater, for example, at night, or when their flow stops completely within a certain short period of time. From these positions, as for the previous installation, there is a tendency to decrease the volume of the equalizing tank.

The installation does not include any special elements whose functions are aimed at improving the quality of treatment, providing, for example, air sparging or mechanical mixing of a mixture of wastewater and activated sludge.

The objective of the utility model is to obtain a technical result, which consists in improving the quality of cleaning without hardware and economic costs to achieve this result.

The problem is solved in the case when the installation for biological wastewater treatment, made in the form of a monoblock, which is a rectangular tank, buried in the ground, divided by partitions into compartments, performing the functions of an equalizing tank equipped with means for supplying wastewater and their subsequent supply to the activation a tank, an activation tank equipped with means for supplying air and water to the sump, and a sump with the release of purified water, so that each of p reservoir of a related

partitions with two others, differs from the known one in that the partitions separating the activation tank from the sump and the equalizing tank from the sump have an area and thickness that slows down the flow of thermal energy from the equalizing and activation tanks to the sump, while being used as a material for manufacturing tanks of the installation for cleaning use sheets of expanded polypropylene.

The task is also solved in cases where:

- the area of the partition separating the activation tank from the sump, and the area of the partition separating the equalizing tank from the sump is 1.5-2.0 times smaller than the partition wall separating the equalizing tank from the activation tank;

- the thickness of the partition separating the activation tank from the sump, and the thickness of the partition separating the equalization tank from the sump is 1.5-3.0 times greater than the thickness of the partition separating the equalization tank from the activation tank.

These cases can be used both jointly and separately to solve the problem.

The relations are known [Mechanical Engineering Manual, Volume 2, Mashgiz, Moscow, 1963, p. 183, 193], according to which the amount of thermal energy flowing through a partition from a warmer body or volume of liquid to a less heated body or volume of liquid is directly proportional to the area partitions.

In addition, the amount of thermal energy flowing through the partition separating these bodies or volumes of fluid depends on the thickness of the partition.

If the thickness and area are equal, the amount of thermal energy flowing through the partition separating the specified bodies or volumes of liquid depends on the material of the partition.

Considering the fact that sheets of foam polypropylene are used as the material for the manufacture of the capacity of the installation for cleaning, the optimal ratio of the size of the partitions is determined.

The thickness of the walls separating the activation tank from the equalizing tank is less than the thickness of the walls separating the sump from the equalizing and activation tanks, taking into account the standard range of sheet thicknesses by 1.5-3.0 times.

The area of the partition separating the activation tank from the sump, and the area of the partition separating the equalization tank from the sump is 1.5-2.0 times less than the partition wall separating the equalization tank from the activation tank. Going beyond the proposed interval in a smaller direction gives a slight increase in the quality of cleaning. Going beyond the proposed interval to a larger side leads to an increase in the dimensions of the installation while maintaining the volume of the sump.

As already noted, traditionally the volume of the sump is always greater than the volume of equalizing and activation tanks due to the long settling time of suspended sludge particles.

For this reason, the water in the sump always has a lower temperature, and in the cold season it is much lower than the temperature of the wastewater entering the equalizing tank.

The implementation of the partition separating the equalization tank from the sump, with a smaller area and / or greater thickness than the area and / or thickness of the partition separating the equalization tank from the activation tank, allows to reduce the heat outflow from the equalization tank and change its direction towards the activation tank. Performance

the partition wall separating the activation tank from the sump, with a smaller area and / or greater thickness than the area and / or thickness of the partition separating the equalizing tank from the activation tank, allows you to save the heat of the activation tank. If the wastewater supply is not interrupted or the interruption in its supply is short-term, the specified heat balance is stable.

Given the volume ratios of the equalization, activation tanks and sump in known installations [patent RU 2233247, IPC C02F 3/12, 2004, patent RU 2162062, IPC C02F 3/00, 2001], as well as the tendency to reduce the volume of the equalization tank we can conclude about the novelty of the proposed ratio of the area of the partitions between the tanks of the installation.

As for the well-known installation [patent RU 2162062, IPC C02F 3/00, 2001], the limited capacity of the pump designed to supply wastewater from the equalizing tank to the activation tank helps to achieve a condition where even with an uneven supply of wastewater into the treatment plant installation, the hydraulic load of the activation tank remains uniform. As for the temperature of the mixture of wastewater and activated sludge in the activation tank in the winter, it is possible to heat the air supplied to the activation tank.

All of the above allows, in combination with the proposed ratio of the area and / or thickness of the partitions between the tanks, to create and maintain a fairly constant temperature of the contents of the activation tank.The latter is important for the life and reproduction of bacteria, as well as for any other representative species.

Thus, the essence of the utility model is the possibility of using wastewater heat to intensify the oxidation process in the activation tank, which is especially necessary when operating the unit at low temperatures. Moreover, at low temperatures, in the absence of special devices for heating, this technique is necessary for the elementary maintenance of bacterial activity. But even under normal average temperatures, of the order of 10-20 ° C, the quality and uniformity of cleaning increases due to the creation of conditions in the activation tank that are close to isothermal conditions that contribute to the most optimal activation mode.

The utility model is illustrated by drawings:

Figure 1 schematically shows an installation for biological wastewater treatment;

Figure 2 shows a plan view of the installation.

The installation is made in the form of a monoblock, which is a rectangular container, buried in the ground, made of sheets of foamed polypropylene and divided by partitions into compartments. The equalizing tank - compartment 1, is equipped with a supply of 2 wastewater and a pump 3 for subsequent supply of wastewater to compartment 4 - the activation tank. The activation tank is equipped with an aeration tube 5 connected to the compressor 6. The pipe 7 serves to drain the purified water into compartment 8 - the sump with the release of 9 purified water. Each of the tanks 1, 4, and 8 has adjacent partitions 10, 11, and 12 with two others. The installation is also equipped with a sludge recirculation pump 13.

Figure 2 shows a plan view of the installation. The installation in plan has the shape of an elongated rectangle.

Given the same height of the tanks, the ratio of the area of the partitions 10, 11 and 12:

S ₁₀ = 1.8 S ₁₁ ;

S ₁₀ = 1.8S ₁₂ .

The ratio of the thicknesses of the walls 10, 11 and 12:

δ _eleven = 2δ ₁₀ ;

δ ₁₂ = 2δ ₁₀ .

Installation works as follows:

Wastewater enters the equalization tank 1 through the inlet 2. The tank 1 serves simultaneously for the initial sedimentation of wastewater. Next, the wastewater is pumped through the pump 3 to the activation tank 4, into which air is pumped through the aeration tube 5 by means of the compressor 6. After cleaning in the activation tank 4, the mixture of purified water and activated sludge is fed through line 7 to the settling tank 8. After sedimentation of suspended sludge particles, the purified water flows from the treatment plant. Precipitated sludge by a sludge recirculation pump 13 is pumped back to the activation tank. In this case, excess sludge can be stored.

The installation, claimed to be a utility model, in which the area of the partitions between the tanks and their thickness was selected in accordance with the utility model, was tested during the winter-spring period. At the same time, a well-known installation was tested under the same conditions. The results showed an increase in cleaning quality by about 20-30%.

Claims (3)

1. Installation for biological wastewater treatment, made in the form of a monoblock, which is a rectangular, buried in the ground capacity, divided by partitions into compartments, performing the functions of a leveling tank, equipped with means for supplying wastewater and their subsequent supply to the activation tank, activation tank, equipped with means for supplying air and draining water to the sump and a sump with the release of purified water, so that each of the tanks has adjacent partitions with two others, characterized in that the partitions separating the activation tank from the sump, and the equalizing tank from the sump, have an area and thickness that slows down the flow of thermal energy from the equalization and activation tanks to the sump, while as a material for the manufacture of the capacity of the installation for cleaning polypropylene foam sheets are used. 2. The installation according to claim 1, characterized in that the area of the partition separating the activation tank from the sump, and the area of the partition separating the equalizing tank from the sump is less than the partition wall separating the equalizing tank from the activation tank by 1.5-2.0 times. 3. The installation according to claim 1, characterized in that the thickness of the partition separating the activation tank from the sump, and the thickness of the partition separating the equalization tank from the sump is greater than the thickness of the partition separating the equalization tank from the activation tank by 1.5-3.0 times.