HU187368B - Flotatig the flotative contaminations being sewage by expanding gas absorbed in water - Google Patents

Abstract

According to the invention, the task is solved by flushing the fluid to be cleaned from the top of the flotation first, in the first expansion space, from the bottom upwards, whereby a portion of the liquid to be cleaned is passed directly from the expansion space to the second outer space. in the second stage, however, the fluid to be cleaned is reversed and flushed downwardly at a lower speed in the second outer space, and the purified liquid is collected at the bottom of the outer space, applied to the surface of the liquid column, and passed therefrom. The core of the device according to the invention is that the lower part of the submerged basin (4) is divided into two interlocking spaces by a wall (10), preferably with a vertical closed-loop, optionally with windows. arranged in an internal expansion space (11), in the outer space (13), at the height of the distributor (12) or adjacent thereto, is a perforated collar (14) having at least one riser (15) and a riser (15) ) is connected to a trough (16) formed along the upper rim of the flotation pool (4), wherein the self-known drop (1?) is arranged and the trough (16) is provided with a foam collecting space (19). -1-

Description

The present invention relates to a process for microbubble flotation of liquids, especially wastewater, by introducing gas, preferably air, into the liquid to be cleaned at a pressure above atmospheric pressure, initiating the expansion by expelling and expelling foam at atmospheric or near atmospheric pressure. , the foam and the purified sewage are separated separately, and the flotation is supplemented, if necessary, with chemical or other treatment, and an apparatus for carrying out the process comprising a pump, a mixing unit, an absorbent tank and a floating basin with mechanical dredging device; a manifold made up of perforated tubular elements at the end of the basin adjacent to the bottom of the basin; It is connected to the water conduit. Many solutions have been known for the removal of undissolved impurities in liquids, in particular for the removal of grease and oil contamination of wastewater, as well as fiber and fine suspended solids.

Of these, flotation is considered to be the most effective physical process. The essence of flotation is that the bubbles to be removed from the gas introduced into the liquid, preferably air, are applied to the surface.

The lexicon works in the field are e.g. Perry: Manual of Chemical Engineers, or George: Handbook of Water Facilities The basic feature of flotation is that the gas is compressed directly into the wastewater to be treated.

In practice, conceptual solutions have been widely used in modified versions.

Such a modified version is disclosed in U.S. Patent No. 567,439. Swiss patent. The essence of the known process is to supply air at a pressure of at least 1.5 bar to the waste water, distribute the air in the β waste water by means of paddle stirrers, expel the excess gas and then flush the waste water into an atmospheric, horizontal flow basin. to maintain a constant volume of liquid - a portion of the foam already floated is recycled to the waste water to be treated.

The disadvantage of the known solution is that it is not possible to create small bubbles up to 1000 microns in diameter in the wastewater to be treated, even after the air is spilled out, and due to the special regulation, a part of the foam once floated swim, which is time and energy consuming.

A separate expulsion column with foam paddle is installed between the pressure vessel and its atmospheric pool, which is formed as a pressure vessel. The disadvantageous nature of the apparatus lies primarily in its complex construction and high specific material requirements.

One of the most effective solutions in the art in the narrower sense is a variant of microbubble flotation, preferably with bubbles of 20-150 microns in diameter, as described in U.S. Patent No. 175,791. is known from Hungarian patent application. In this case, the bubbling air is introduced into a mixture of wastewater or a partial stream of wastewater with a portion of purified water in two steps, first mixed with a nozzle and then absorbed in a container. The air-saturated liquid is perpendicularly collided within the flotation tank

187,368 with horizontal flow of fluid to be cleaned. The amount of air introduced, i.e. the size and volume of the bubbles, is controlled by a simultaneous but independent change in the pressure of the air and the amount of absorbing fluid.

The most important feature of the apparatus is that the elements for receiving both the floated foam and the treated wastewater are arranged in the upper part of the flotation tank.

The disadvantage of the known solution for some types of wastewater to be treated is that the mixing of the air-saturated liquid and the wastewater is mostly spontaneous and the already "purified" wastewater in the upper layer of the floating vessel liquid mass is perpendicular to the movement of the floating foam particles. besides spontaneous mixing and above all, it further impairs the effectiveness of the grant. It is an object of the present invention to provide a solution for improving the mechanism and efficiency of microbubble flotation. According to the invention, this object is solved by flowing the liquid to be cleaned from the first expansion space with the floating impurities in the first expansion space, optionally passing a portion of the liquid to be cleaned directly from the second outer space In the second stage, however, the liquid to be purified is reversed and, in the second, outer space, is flushed from top to bottom at a rate lower than the impurity buoyancy, and the purified liquid is collected at the bottom of the outer space.

The invention will now be described in more detail with reference to the drawings of embodiments of devices which are preferably designed for waste water treatment. In the drawing it is

1 is a schematic diagram of an embodiment with a rectangular floor plan with a flotation tank and a water jet pump;

Figure 2 is a schematic diagram of an embodiment with a cylindrical flotation tank and a compressor.

Figure 1 is a schematic diagram of an embodiment of the apparatus of the invention having a rectangular planar flotation tank and a water jet pump.

The pump 2, the suction tank 3 and the flotation basin 4 are integrated in the plant's backbone 1 carrying the wastewater to be treated, according to the direction of the waste water flow. The pump 2 is preferably a multistage centrifugal pump having a pressure of 4-5 bar. The absorber 3 is a pressure vessel whose size is determined by the specific capacity of the system, the residence time of the waste water for at least 5 minutes, the wall thickness and the quality of its structural material taking into account the operating pressure and the nature of the waste water.

The main conduit 1 has an auxiliary conduit 5 having an inlet nozzle behind the pump 2 and an outlet nozzle in front of the pump 2 connected to the conduit 1 according to the direction of the waste water flow.

The mixing unit 6 for supplying the high-pressure air to the waste water is connected to the auxiliary line 5. The mixing unit 6 is an apparatus according to the invention

1 is a water jet pump.

A rotameter 9 is installed in the air line 7 of the mixing unit 6 between the valves 8 for controlling and controlling the amount of air discharged into the wastewater.

The flotation basin 4 may be either closed or open, the former operating at or above atmospheric pressure and the latter operating at atmospheric pressure.

The lower part of the flotation basin 4 is divided into two spaces communicating with each other in the upper part of the basin by means of a preferably vertical, horizontal plane wall 10. In the inner expansion space 11, the end of the spinal cord 1 is introduced and a distributor 12 formed of perforated tubular elements is located adjacent to the bottom of the pool.

In the outer space 13, at the height of the distributor 12 or in the vicinity thereof, a perforated collecting crown 14 is arranged.

The collecting wreath 14 has at least one, preferably more symmetrically arranged, ascending leg 15.

In the case where the wall 10 is also provided with windows (not shown in the drawing); these windows are preferably arranged at or adjacent to the height of the distributor 12 or the collecting crown 14.

The riser 15 is connected to trough 16 formed along the upper edge of the floating basin 4. A trough 17 is provided in the trough 16 for receiving the purified sewage. The water pipe 18 is connected to the roll 17.

With its mantle 16, the foam collection space 19 of the floating basin 4 is delimited. Above the foam collecting space 19, the excavator structure 20 of the device is arranged.

In the embodiment of Figure 1, the dredger 20 is designed as a scraper belt. The foam trough 21 is arranged at the "delivery end" of the scraper belt. The foam conduit 22 is connected to the foam trough 21.

In the embodiments shown, a foam breaking container 24 provided with a heat exchanger 23 is connected to the foam conduits 22.

Figure 2 is a schematic diagram of an embodiment of the apparatus according to the invention with a cylindrical float pool and a compressor. Identical parts are denoted by the same reference number and are deviations only.

A compressor 25 with a discharge port 25 is mounted in the air line 7 in front of the rotameter 8 and the valves 9. In this version, the excavator structure 20 of the device is designed as a rotary blade mixer.

The apparatus of the present invention can be varied within the scope of the present invention, so that by way of example only, a chemical dosing unit may be connected to the spinal cord and the aqueduct may be connected to a biological treatment plant. In this description, the fittings necessary for the smooth operation of the equipment, e.g. the floating pool is empty3

187,368 pin valves etc. not mentioned, their incorporation is within the skill of one of ordinary skill in the art.

Hereinafter, the operation of the apparatus and the method according to the invention will be described.

A sub-stream is separated from the wastewater to be purified in the back pipe 1, which is branched behind the pump 2, and the air is compressed into the separated sub-stream by means of the mixing unit 6. The amount of air introduced is controlled by the valves 8 and monitored by the rotameter 9.

In this case, the partial flow, which is supersaturated with air, is introduced into the waste water before the pump 2. Then mix the pump 2 effectively with the wastewater.

It is to be noted that within the scope of the present invention, the introduction of air is otherwise possible.

The air in the sump 3 is then absorbed in the waste water at a pressure of 4 to 5 bar, while the sludge is held in the sump 3 for at least 5 minutes.

At this stage of the technology, optionally, as an additional step, flotation agents may be added to the effluent to enhance flotation efficiency.

The air-saturated sewage is then introduced into the flotation basin 4 and, in the expansion space 11, the flotation is evenly distributed and expanded by means of the distributor 12. In the first stage of the flotation, in the expansion space 11, the wastewater to be purified is flushed from the bottom upwards with the excellent microbubbles and impurities floating on their surface. Optionally, according to technological requirements, a portion of the already "purified" waste water is led directly into the outer space 13 through the windows of the wall 10.

In the second stage of the flotation, the waste water to be purified is recycled to the outer space 13, where the waste water is flowed up and down at a rate lower than the rate of the impurities floating on the surface of the microbubbles.

The cross-section of the outer space 13 in the horizontal plane is, of course, at least equal to the cross-section of the expansion space 11. By the way, the wastewater in the outer space 13 is already much poorer in pollutants, since the pollutants flow up to the surface of the liquid column of the floating basin 4 and into the foam collecting space 19 in a substantially undisturbed stream.

At the bottom of the outer space 13, the cleaned liquid is collected by means of a collecting crown 14 and, in the ascending branches 15, is carried up to the height of the surface of the liquid column, into the trough 16 This also controls the fluid level of the 4 floating basins.

The impurities floating on the surface of the liquid column, the foam in the foam collecting space 19, are guided by the dredger 20 into the foam trough 21 and discharged therefrom by the foam conduit 22.

Hab Foam discharged from the basin 4 is broken, as an additional operation, in this case by means of a steam-heated heat exchanger 23 in the foam container 24.

In the embodiment shown in Figure 2, the only difference in the process is that the air is compressed by the compressor 25 into a partial stream separated from the waste water.

In the practice embodiments of the present invention, the following examples have been achieved:

Example 1

Vegetable oil plant wastewater was purified by the method according to the invention and by the so-called. point value - at the same time - test result:

fat content of raw sewage: 391 mg / l,

COD: 562 mg / l, purified water fat content: 36 mg / l,

The COD value is 180 mg / L, so the fat content efficiency of the invention is 91%,

COD value was 68%.

Example 2

Vegetable oil plant wastewater was treated according to the invention, where the raw wastewater was averaged over three measurements per working week.

fat content: 520 mg / L, COD value: 390 mg / l, suspended solids content 325 mg / l, purified water fat content: 70 mg / L. COD value: 346 mg / L, Suspended solids content: 170 mg / l, hence the efficiency of the present invention Fat content: 86% COD value: 11% Suspended solids content: It was 48%. Example 3 For the treatment of hardboard wastewater, raw sewage COD value: 3700 mg / L. Suspended solids content: 1200 mg / Ί, a cleaned water COD value 1669 mg / l, suspended solids content 156 mg / l, hence the efficiency of the present invention COD 55% suspended solids content It was 87%.

In addition to its simplicity, the present invention is primarily concerned with its effectiveness in terms of its fatty and fibrous suspended solids content.

187,368

Claims (25)

1. A process for microbubble flotation of liquids, especially wastewater, in which gas, preferably air, is introduced and swallowed at a pressure above atmospheric, flotation is initiated by expansion and at atmospheric or near atmospheric pressure; the foam and the purified waste water is removed from ¹⁰ separate, the flotation is optionally supplemented by a chemical or other treatment, characterized in that the first stage of the flotation process, the first expansion chamber to be cleaned fluid flows alulról- ¹⁵ upwardly together with the floating impurities, furthermore, optionally, a portion of the fluid to be cleaned is led directly from the expansion space to the second, outer space, while in a second stage, the liquid to be cleaned is recirculated and the second, outer space, ^{At a} rate of less than ²⁰ velocities, it is flowed from top to bottom, and the purified liquid is collected at the bottom of the outer space, applied to and drained from the surface of the liquid column. 2. The method according to claim 1 embodiment of a method ^25, characterized in that the compressed air is separated from the waste water part-stream back stirred supersaturated with air partial stream of the waste water and the air is absorbed in a manner known per se in the wastewater. ³⁰ 3. A method according to claim 1 or 2, wherein the amount of air introduced into the waste water is controlled. 4. A method according to any one of claims 1 to 4, characterized in that the partial flow of air supersaturated ³⁵ is introduced in front of the pump and mixed with the pump in the waste water. 5. A method according to any one of claims 1 to 4, characterized in that the air ^{40 is} absorbed in the waste water at a pressure of 4 to 5 bar and a residence time of at least 5 minutes. 6. A process according to any one of claims 1 to 3, characterized in that detergents are added to the waste water. 45 7. A method according to any one of claims 1 to 4, characterized in that the lacquer foam is broken by heat treatment. 8. Apparatus according to claims 1-7. A method according to any one of claims 1 to 4, wherein the backbone comprises a pump, a mixing unit, an absorbent reservoir and a floating basin with mechanical dredging means, having a connected aqueduct, characterized in that the lower part of the flotation basin (4) is divided by two vertically enclosed walls (10), preferably with vertical, closed sections, optionally with windows, and the distributor (12) of the spinal conduit (1) arranged in an internal expansion space (11), in an outer space (13), at the height of the distributor (12) or adjacent thereto, a perforated collecting crown (14) having at least one ascending leg (15) and the ascending leg (15) one, a is connected to a trough (16) formed along the upper edge of the floating pool (4), where the well-known tilt (17) is arranged ⁵ and the foam collecting space (19) is delimited by the circumference of the trough (16). The device according to claim 8, characterized in that the backbone (1) has an auxiliary line (5), the inlet of which is behind the pump (2) and the outlet of which is connected in front of the pump (2) to the backbone (I). and the mixing unit (6) is connected to the extension pipe (5). 10. The device of claim 9, wherein the mixing unit (6) is a water jet pump. 11. An apparatus according to claim 9, characterized in that the air line (7) of the mixing unit (6) is connected to the discharge port of a compressor (25). 12. An apparatus according to claim 10 or 11, characterized in that a rotameter (9) is connected to the air duct (7). 13. A 8-12. An apparatus according to any one of claims 1 to 6, characterized in that a chemical dosing unit is connected to the spinal cord (1). 14. A 8-13. An apparatus according to any one of claims 1 to 4, characterized in that a foam breaking container (24) with a heat exchanger (23) is connected to the foam conduit (22) of the flotation basin (4). 15. A 8-14. An embodiment of the apparatus according to any one of claims 1 to 6, characterized in that the water line (18) of the flotation basin (4) is connected to a biological purification plant. Composition Index: 1. spinal cord Pump 2 3. absorption tank 4. floating pool Extension cable 5 6. mixing unit 7. overhead line 8th valve 9th rotameter Wall 10 11th expansion space 12th distributor 13. outside space 14. Collector Wreath 15. take-off branch 55 Trough 16 17th roll 18. water pipe 19. Foam collection area 20. backhoe structure 60 Foam 21 Foam Conduit 22 23. heat exchanger 24. foam container 25. compressor 65 2 pieces of figure