RU2743556C1 - Device for biological waste water treatment - Google Patents

Abstract

FIELD: wastewater processing.SUBSTANCE: invention relates to a device for biological wastewater treatment, including a housing in which a carrier material for an attached biocenosis is located, and can be used to improve wastewater treatment efficiency with a temperature below 15 °C. The carrier material for the attached biocenosis is made with the possibility of heating from the inside and is connected to the energy supply unit by means of a connecting element.EFFECT: invention allows maintaining optimal temperature regime for effective functioning of the biocenosis attached to the carrier material due to the ability to heat the biocenosis attached to the carrier material in cold water.8 cl, 4 dwg

Description

The technical field to which the invention relates

The invention relates to a device for biological wastewater treatment, including a housing in which a carrier material for an attached biocenosis is located and can be used to improve the efficiency of wastewater treatment with a temperature below 15 ° C.

State of the art

The technology of wastewater treatment using a biocenosis attached to a carrier material has been known for a long time. So from the prior art, a device for biological wastewater treatment is known, including a housing in which a carrier material for an attached biocenosis is located, which is described in the RF patent for utility model No. 130603, published on July 27, 2013.

This device is the closest in technical essence and the achieved technical result and was chosen as the prototype of the proposed invention.

The disadvantage of this prototype is that biochemical reactions occurring inside the biocenosis attached to the carrier material proceed slowly at a low temperature of wastewater (less than 15 ° C), which is not optimal for the functioning of the biocenosis. Indeed, it is known that the rate of biochemical reactions in a bioreactor is directly dependent on temperature. It was found that with a change in the wastewater temperature by 10 ° C, the rate of biochemical reactions changes twofold. In practice, the optimum wastewater temperature is determined in the range from 20 ° C to 30 ° C. Exceeding the specified temperature can lead to the death of microorganisms. At lower temperatures, the rate of oxidative processes decreases, the process of adaptation of microorganisms and bacteria to new types of pollution slows down, the processes of nitrification and denitrification, flocculation and sedimentation of biomass of treatment facilities deteriorate. An increase in the temperature of the attached biocenosis in treated wastewater with a temperature below 15 ° C by heating the carrier material of the biocenosis to optimal values accelerates the process of decomposition of organic matter 2-3 times (depending on the temperature of the wastewater).

In the prototype there are no special means for maintaining such an optimal temperature of the biocenosis attached to the carrier material. The only thing that can be done in advance to improve the efficiency of low-temperature wastewater treatment is to warm up the wastewater entering the bioreactor for treatment. However, this way of increasing the efficiency of wastewater treatment requires a large amount of energy, which is not an optimal solution.

Disclosure of invention

The present invention mainly aims to provide a device for biological wastewater treatment, including a housing, which receives wastewater, an outlet of purified water, and in the housing is arranged a heated carrier material for an attached biocenosis, allowing, at least, to smooth out one of the above disadvantages, namely: to ensure the ability to maintain the optimal temperature regime for the effective functioning of the biocenosis attached to the carrier material due to the ability to heat the biocenosis attached to the carrier material in cold water, which is the task at hand.

To achieve this goal, the carrier material for the attached biocenosis is made with the possibility of heating, and is connected to the energy supply unit by means of a connecting element.

Thanks to these advantageous characteristics, it becomes possible to ensure the optimal operation of the bioreactor due to the fact that the carrier material itself will directly heat the community of attached microorganisms that purify wastewater. This will be much more efficient than heating the entire volume of wastewater entering the bioreactor.

There is a variant of the invention, in which the power supply unit is made in the form of a current source, and the connecting element is made in the form of electric wires connected to the current source.

Thanks to these advantageous characteristics, it becomes possible to implement one of the specific implementation of the option of heating the carrier material for the attached biocenosis, namely, using electricity.

There is also a variant of the invention, in which the carrier material for the attached biocenosis contains, connected to the current source by means of connecting elements, heating elements located inside the carrier material for the attached biocenosis.

Thanks to these advantageous characteristics, it becomes possible to implement another variant of heating the carrier material for the attached biocenosis, namely when heating elements inside the carrier material are heated with electricity.

There is an additional embodiment of the invention, in which the carrier material for the attached biocenosis is a heating element.

Due to these advantageous characteristics, it becomes possible to implement another variant of heating the carrier material for the attached biocenosis, namely, when the carrier material itself is heated with electricity.

There is an alternative embodiment of the invention, in which the power supply unit is made in the form of a heat carrier source, and the connecting element is made in the form of pipes through which the heat carrier flows and connected to the heat carrier source, while inside the carrier material for the attached biocenosis there are cavities for passing the heat carrier

This advantageous characteristic provides an alternative opportunity to supply heat to the carrier material for the attached biocenosis. For example, hot water (or other liquid or gas) can be passed inside the carrier material for the attached biocenosis.

In addition, there is a variant of the invention in which the carrier material for the attached biocenosis is made of a porous material.

Due to this advantageous characteristic, it becomes possible to implement a variant of the carrier material for the attached biocenosis, when the flow of the heat carrier can be ensured inside it.

In addition, there is a variant of the invention in which the carrier material for the attached biocenosis is made of a honeycomb material.

Due to this advantageous characteristic, it becomes possible to implement another version of the carrier material for the attached biocenosis, when inside it it is also possible to ensure the flow of the heat carrier.

Finally, there is a variant of the invention, in which the power supply unit is connected to a temperature sensor and to a module for automatically turning off heating when a preset temperature is reached and turning on heating when the temperature drops below a preset level.

Thanks to this advantageous characteristic, it becomes possible to automatically turn off the heating when a preset temperature is reached in the area where microorganisms are located.

Brief Description of Drawings

Other distinctive features and advantages of the invention clearly follow from the description given below by way of illustration and not limiting, with reference to the accompanying drawings, in which:

- figure 1 schematically depicts a side view of a carrier material for an attached biocenosis used in a wastewater treatment device according to the invention, a variant with a heat carrier,

- figure 2 schematically shows a section A-A of a carrier material for an attached biocenosis used in a device for biological wastewater treatment according to the invention, a variant with a heat carrier,

- figure 3 schematically depicts a side view of a carrier material for an attached biocenosis used in a wastewater treatment device according to the invention, a variant with electricity,

- Figure 4 schematically shows a top view of a carrier material for an attached biocenosis used in a biological wastewater treatment device according to the invention, a variant with electricity.

According to Figures 1-2, a carrier material for an attached biocenosis used in a biological wastewater treatment device includes a heat carrier inlet 1, a carrier material for an attached biocenosis 2, and a heat carrier outlet 3. Figures 1 and 2 show an option when the carrier material 2 for the attached biocenosis is heated by a heat carrier and connected to an energy supply unit, which is made in the form of a heat carrier source 4, and cavities 5 for passing the heat carrier are located inside the carrier material for the attached biocenosis. These can be tubes in which the coolant flows.

The carrier material for the attached biocenosis can be made of a porous material or can be made of a honeycomb material. Thus, it is possible to ensure the passage of the heat carrier directly over the volume of the carrier material for the attached biocenosis.

The heat carrier source 4 is connected to the cavities of the carrier material for the attached biocenosis 2 by means of a connecting element 6. In this case, it can be a tube for supplying the heat carrier.

Also, the individual elements of the carrier material for the attached biocenosis can be connected in series and the heat carrier leaving the previous single element enters the subsequent single element.

According to Figures 3 and 4, the power supply unit can be made in the form of a current source 7, and the connecting element is made in the form of electric wires 8 connected to a current source 7.

The power supply unit can be connected to the temperature sensor 9 and to the module for automatic shutdown of heating upon reaching the set temperature and turning on the heating when the temperature drops below the set level. In Figures 1-4, the automatic heating shutdown module is not shown.

The contact of the wire connection 8 with the carrier material for the attached biocenosis is shown as 10.

Implementation of the invention

The device for biological wastewater treatment works as follows.

Stage A1. Waste water is supplied to the device.

Stage A2. The carrier material for the attached biocenosis 2 is heated in order to ensure the optimum temperature in the area where the microorganisms attached to the carrier material are located.

Stage A3. When the set temperature is reached, they stop heating the carrier material for the attached biocenosis 2.

Stage A4. As soon as the temperature drops below the predetermined level, the carrier material for the attached biocenosis 2 is again heated.

Industrial applicability

A device for biological wastewater treatment can be carried out by a specialist in practice and, when implemented, ensures the implementation of the declared purpose, which makes it possible to conclude that the criterion of "industrial applicability" for the invention is met.

In accordance with the proposed invention, a prototype device for biological wastewater treatment has been manufactured.

Tests of a prototype device have shown that it provides the ability to maintain an optimal temperature in the area where microorganisms attached to the carrier material are located in the bioreactor.

Thus, due to the fact that the carrier material for the attached biocenosis is made of a heated material that is heated by electricity or supplied heat carrier in a liquid or gaseous state, and the claimed technical result is achieved, namely: the ability to maintain an optimal temperature regime for the effective functioning of microorganisms due to the ability to heat the biocenosis attached to the carrier material in cold water.

An additional useful technical result of the claimed invention is that in order to achieve an optimal temperature regime for the functioning of the biocenosis attached to the carrier material, less energy is spent than for heating the entire volume of wastewater entering the treatment.

Claims (8)

1. A device for biological wastewater treatment, including a housing in which the carrier material for the attached biocenosis is located, characterized in that the carrier material for the attached biocenosis is configured to heat it from the inside and is connected to the energy supply unit by means of a connecting element. 2. A device according to claim 1, characterized in that the power supply unit is made in the form of a current source, and the connecting element is made in the form of electric wires connected to the current source. 3. The device according to claim. 2, characterized in that the carrier material for the attached biocenosis contains heating elements connected to the current source by means of connecting elements, located inside the carrier material for the attached biocenosis. 4. The device according to claim 2, characterized in that the carrier material for the attached biocenosis is a heating element. 5. The device according to claim 1, characterized in that the energy supply unit is made in the form of a heat carrier source, and the connecting element is made in the form of tubes through which the heat carrier flows and connected to the heat carrier source, while cavities are located inside the carrier material for the attached biocenosis for passing the coolant. 6. A device according to claim 5, characterized in that the carrier material for the attached biocenosis is made of a porous material. 7. A device according to claim 5, characterized in that the carrier material for the attached biocenosis is made of a honeycomb material. 8. The device according to claim 1, characterized in that the power supply unit is connected to a temperature sensor and to a module for automatically shutting off heating when a predetermined temperature is reached and turning on heating when the temperature drops below a predetermined level.

Images