RU229388U1 - DEVICE FOR PROCESSING ACTIVATED SLUDGE - Google Patents

Abstract

The utility model relates to the field of water treatment, namely to equipment for biological treatment of wastewater using activated sludge. A device for treating activated sludge comprises a gas suction chamber, in which a liquid-gas phase boundary is formed, and a feed and an outlet manifold, connected to each other. The chamber is connected to a vacuum pump. The feed manifold is configured to be connected to a tank for aerating a mixture of wastewater with activated sludge, and the outlet manifold is configured to be connected to a secondary settling tank. A flow swirler is installed in the feed manifold. At the outlet of the feed manifold, a device for collecting trapped gases is installed, one end of which is inserted into the feed manifold and has an overall dimension "z" smaller than the overall dimension "a" of the feed manifold. The device for collecting trapped gases is fixed equidistantly from the walls of the feed manifold so as not to block the flow of the mixture around it. The technical result consists in increasing the efficiency of activated sludge degassing. 6 clauses, 1 fig.

Description

FIELD OF TECHNOLOGY TO WHICH THE UTILITY MODEL RELATS

The utility model relates to the field of water treatment, namely to equipment for biological treatment of wastewater using activated sludge.

LEVEL OF TECHNOLOGY

A technology for wastewater treatment is known from the prior art [RU2201405, C02F 3/02, published 27.03.2003; RU2220112, C02F 3/02, published 27.12.2003; RU2228915, C02F 3/02, published 20.05.2004], which includes a unit where preliminary aerobic-anoxic biological treatment of wastewater is carried out with aerobic activated sludge, after which the pre-treated water with sludge enters an aeration tank-activation reservoir, where the final destruction of organic pollution occurs, after which the water enters a settling tank. The settled sludge accumulates at the bottom of the settling tank, and the water, having passed through porous filters, is discharged from the installations.

The disadvantages of this technology are the technological complexity of implementing two-stage purification, insufficiently effective regeneration of activated sludge, and the need for periodic regeneration of the porous filters used.

The closest analogue (prototype) is a plant for processing activated sludge in biological wastewater treatment, containing a tank for aeration of a mixture of waste with activated sludge and a secondary settling tank, connected to each other by feed and outlet collectors through a gas suction chamber, which is connected to a vacuum pump, and a pipeline for supplying purified water is connected to the feed collector at a distance of 1-2 m from its lower end, and the suspension level in the aeration tank is higher than the liquid level in the secondary settling tank.

When the vacuum pump is switched on, water enters the lower part of the feed manifold from the tank with purified water, forming a layer of liquid with a higher specific gravity in the feed manifold compared to the suspension, which creates a kind of hydraulic seal, ensuring, during the initial period of the unit's operation, a faster and more uniform movement of the purified suspension into the gas suction chamber, where accelerated degassing of sludge particles in the upper layers of the liquid occurs in a rarefied space. Degassed particles, being heavier, descend to the lower layers and enter the secondary settling tank through the outlet manifold [RU2367619, C02F 3/02, published 20.09.2009].

The disadvantage of the prototype is that the prototype does not provide sufficiently effective degassing, since some of the gas bubbles entering the gas suction chamber do not have time to reach the liquid-gas phase boundary and are carried out with the sludge mixture through the discharge manifold into the secondary settling tank.

The objective of a utility model is to create a device that eliminates the disadvantage inherent in the prototype.

DISCLOSURE OF THE ESSENCE OF THE UTILITY MODEL

The technical result is an increase in the efficiency of activated sludge degassing.

The technical result is achieved in that a device is proposed for processing activated sludge, comprising a tank for aerating a mixture of wastewater with activated sludge and a secondary settling tank, connected to each other by feed and outlet collectors through a gas suction chamber, in which a liquid-gas phase boundary is formed, wherein the chamber is connected to a vacuum pump, characterized in that a flow swirler is installed in the feed collector, and at the outlet of the feed collector a device for collecting trapped gases is installed, one end of which is inserted into the feed collector and has an overall dimension "z" smaller than the overall dimension "a" of the feed collector, wherein the device for collecting trapped gases is fixed equidistantly from the walls of the feed collector in such a way as not to block the flow of the mixture around it.

There is an option in which the overall dimension “a” is 100 – 1600 mm.

There is an option in which the flow swirler is placed at a distance from the device for collecting the captured gases, corresponding to 3-4 overall dimensions “a”.

There is a variant in which the device for collecting captured gases is made in the form of a hollow cylinder.

There is a variant in which the overall dimension "z" is the nominal diameter of the hollow cylinder, while the ratio of overall dimensions "a": "z" is 2:1.

There is a variant in which the device for collecting the captured gases is made in the form of a hollow truncated cone.

There is a variant in which the overall dimension "z" is the larger nominal diameter of a hollow truncated cone, while the ratio of overall dimensions "a": "z" is 2:1.

BRIEF DESCRIPTION OF DRAWINGS

Fig. 1 shows a general diagram of a device for processing activated sludge.

The claimed device comprises a tank 1 for aerating a mixture of wastewater with activated sludge and a secondary settling tank 2, connected to each other by a feed 3 and outlet 4 collectors through a gas suction chamber 5, in which a "liquid-gas" phase boundary 6 is formed. The chamber 5 is connected to a vacuum pump 7. A flow swirler 8 is installed in the collector 3, and a device 9 for collecting trapped gases is installed at the outlet of the collector 3. The overall dimension "z" of the device 9 is smaller than the overall dimension "a" of the collector 3. One end of the device 9 is inserted into the collector 3. The device 9 is fixed equidistantly from the walls of the collector 3 in such a way as not to block the flow of the mixture around it.

IMPLEMENTATION OF A UTILITY MODEL

Below are examples of the implementation of the utility model.

Example 1.

In the claimed device, according to its disclosure in the section "Disclosure of the essence of the utility model", the flow swirler 8 is an Archimedes screw, which is rigidly fixed in the collector 3, for example, by welding or fasteners (fittings). The overall dimension "a" of the collector 3 is 400 mm. The device 9 is made in the form of a hollow cylinder and has an overall dimension "z" = 200 mm, corresponding to the nominal diameter of the cylinder. The flow swirler 8 is located from the device 9 at a distance of 1600 mm, which corresponds to 4 overall dimensions "a".

Example 2.

In the claimed device, according to its disclosure in the section "Disclosure of the essence of the utility model", the flow swirler 8 consists of two identical blades installed in a cylindrical body with a circular cross-section, each of which has a profile of a half of an ellipse cut along its major axis into two blades. The overall dimension "a" of the collector 3 is 100 mm. The device 9 is made in the form of a hollow cylinder and has an overall dimension "z" = 50 mm, corresponding to the nominal diameter of the cylinder. The flow swirler 8 is located from the device 9 at a distance of 350 mm, which corresponds to 3.5 overall dimensions "a".

Example 3.

In the claimed device, according to its disclosure in the section "Disclosure of the essence of the utility model", the flow swirler 8 is a hollow cylinder, on the end of which narrow slits are made. The overall dimension "a" of the collector 3 is 1600 mm. The device 9 is made in the form of a hollow cylinder and has an overall dimension "z" = 550 mm, corresponding to the nominal diameter of the cylinder. The flow swirler 8 is located from the device 9 at a distance of 4800 mm, which corresponds to 3 overall dimensions "a".

Example 4.

In the claimed device, according to its disclosure in the section "Disclosure of the essence of the utility model", the flow swirler is made similar to example 1. The overall dimension "a" of the collector 3 is 1200 mm. The device 9 is made in the form of a hollow truncated cone and has an overall dimension "z" = 600 mm, corresponding to the nominal larger diameter of the cone.

Example 5.

In the claimed device, according to its disclosure in the section "Disclosure of the essence of the utility model", the flow swirler is made similar to example 2. The overall dimension "a" of the collector 3 is 1000 mm. The device 9 is made in the form of a hollow truncated cone and has an overall dimension "z" = 600 mm, corresponding to the nominal larger diameter of the cone.

The device operates as follows. When the vacuum pump 7 is operating, a mixture of waste water with activated sludge enters the lower part of the collector 3 and passes through the flow swirler 8.

When rising along collector 3, the pressure in the mixture gradually decreases due to the increase in vacuum. At the same time, dissolved gases are released in the entire volume of the mixture in the form of small bubbles, which are concentrated in the center of the vortex flow due to the centrifugal force and the difference in the density of the liquid in the mixture and the gas.

The mixture flow, partially passing through device 9 and exiting at its upper part, ends up in chamber 5 and moves in a horizontal direction to the entrance to collector 4. If boundary 6 is located below the exit from device 9, only gases will exit from it.

The presence of device 9 ensures the separation of the gas component of the vortex flow formed in its central part, as well as the transportation of gas bubbles to boundary 6 in chamber 5 if boundary 6 is located above the outlet of device 9, which leads to an increase in the efficiency of degassing of activated sludge in the mixture.

Otherwise, in the absence of device 9, due to the fact that the vertical speed of the rise of bubbles in the mixture is significantly lower than the horizontal speed of their movement in the mixture in chamber 5, and also due to the presence of turbulence of liquid flows in chamber 5, some of the gas bubbles do not have time to reach the phase boundary 6 and enter the collector 4, in which, as the mixture moves downward, the pressure increases due to a decrease in vacuum, and the gases dissolve in water, which leads to a decrease in the efficiency of their removal.

The presence of gaps between the manifold 3 and the device 9, due to the fact that the overall dimension "z" is smaller than the overall dimension "a", is necessary for dividing the mixture flow conditionally into two components. The part of the mixture degassed due to the formation of a vortex will pass along the outer wall of the supply manifold 3 (i.e. in the space between the walls of the manifold 3 and the device 9), and either gases or a part of the mixture with gases dispersed in it will exit through the device 9 in the central part of the flow, depending on the level of the boundary 6 of the "liquid-gas" phase separation relative to the outlet of the device 9.

In chamber 5, the degassed particles of the mixture, being heavier, descend to the lower layers and enter through collector 4 into secondary settling tank 2.

Thus, the possibility of implementing the claimed utility model with the achievement of a technical result is demonstrated.

Claims (7)

1. A device for processing activated sludge, comprising a gas suction chamber, in which a liquid-gas phase boundary is formed, a feed and an outlet manifold, connected to each other, wherein the chamber is connected to a vacuum pump, the feed manifold is designed with the possibility of being connected to a tank for aerating a mixture of wastewater with activated sludge, and the outlet manifold is designed with the possibility of being connected to a secondary settling tank, characterized in that a flow swirler is installed in the feed manifold, and at the outlet of the feed manifold a device for collecting trapped gases is installed, one end of which is inserted into the feed manifold and has an overall dimension "z" smaller than the overall dimension "a" of the feed manifold, wherein the device for collecting trapped gases is secured at an equal distance from the walls of the feed manifold in such a way as not to block the flow of the mixture around it. 2. The device according to paragraph 1, characterized in that the overall dimension “a” is 100-1600 mm. 3. The device according to item 1, characterized in that the flow swirler is located at a distance from the device for collecting the captured gases corresponding to 3-4 overall dimensions “a”. 4. The device according to paragraphs 1-3, characterized in that the device for collecting the captured gases is made in the form of a hollow cylinder. 5. The device according to item 4, characterized in that the overall dimension “z” is the nominal diameter of the hollow cylinder, and the ratio of the overall dimensions “a”: “z” is 2:1. 6. The device according to paragraphs 1-3, characterized in that the device for collecting the captured gases is made in the form of a hollow truncated cone. 7. The device according to item 6, characterized in that the overall dimension “z” is the larger nominal diameter of the hollow truncated cone, while the ratio of the overall dimensions “a”: “z” is 2:1.