HU197277B - Equipment for introduction of gases into liquids, primarily for airing of sewages - Google Patents

Abstract

System for feeding gases to liquids especially for aerating waste waters, with a main pump, a gas line and a mixing chamber, which are connected to a liquid projection pump for the gases, whereby the liquid projection pump is provided with a projection nozzle and a diffuser is connected to the mixing chamber. The further development of the invention lies in the fact that the wall of the gas line (5) and/or of the mixing chamber (10) is provided with apertures (7), and in the projection direction downstream of the projection nozzle (8) a rotation element (9) with curved blading is incorporated as well as an eddy element (12) downstream and/or upstream of the diffuser (11).

Description

The present invention relates to an apparatus for introducing gases into liquids, in particular for aeration of wastewater. This apparatus is provided with a liquid jet gas pump having a liquid jet nozzle connected to an actuation pump, a gas pipe connected thereto, and a mixing chamber with a diffuser connected to the mixing chamber. The device according to the invention can be advantageously used in biological sludge treatment in fish farms, in the chemical industry.

Known installations for aeration of waste water fall into three groups:

surface aeration equipment; underground aeration equipment, underground aeration equipment for the supply of pure oxygen.

Two types of surface aerators are known. There are many types and types of vertical and horizontal air hoods. Their common feature is that they are positioned above the mixture to be aerated so that they are slightly immersed in the liquid. Rotating the gear at a controlled speed, the aeration wheel (vertical axis) and rotor (mammutrotor) (horizontal axis) spray some of the liquid into the air in the form of smaller or larger droplets of water, thereby ensuring diffusion of oxygen into the fluid that the aerobic microorganisms utilize.

However, the rotating rotor also performs sufficient agitation of the mixture to be aerated to such an extent that the activated sludge flakes cannot settle into the aeration basin. In practice, the specific oxygen delivery capacity of the above equipment is 1.0 - 1.5 kg

In case of aeration of Oz / kWh activated sludge. This relatively low value requires significant energy use for wastewater treatment, since large plants do not require hundreds of kg / h of oxygen.

In addition to the significant investment required to install the equipment (the cost of one rotor is in the order of millions), there are operational problems due to the fibrous material adhering to the rotor blades and the winter icing. The maintenance of the above-mentioned equipment is also significant, since the continuous operation of serious mechanical equipment (gear motor, gear) must be solved. All these problems increase the cost of oxygen supply.

Underground aeration differs from surface aeration by delivering air or pure oxygen through diffusers of varying hole size (porosity) located below the surface of the liquid to a certain depth. By reducing the size of the air bubbles, the size of the gas / liquid interface can be increased and thus the amount of oxygen introduced into the liquid proportionally but not linearly. The oxygen supply can also be controlled to some extent by the height of the liquid column above the diffuser. The above solution has resulted in the production of fine bubble aeration units having a specific oxygen delivery capacity of about 2.0 kg Cte / kWh. The diffusers are located on long, larger sewage plants, on hundreds of meters of piping connected to a compressor system. In the case of pure oxygen administration, several times the specific oxygen supply can be achieved, but this requires the production of oxygen locally, which entails high investment and operational costs, calling into question the economics of using the equipment. The most common operating problems encountered with the use of air blower aerators are clogging of diffusers when forced to stop aeration and operating difficulties with compressors. The specific energy consumption of the air supply cannot be economically increased because of the extremely high flow resistance of the long pipe network and the fine porosity diffusers. Another disadvantage is the high noise level when operating compressors. The advantage of air blowing systems over surface aeration systems is that multiple compressors can be used to more easily control the oxygen supply to the load at the wastewater treatment plant. If rotors are used, the possibility of partial shutdown or immersion! is limited to changing depth.

Another group of underground aerators are injector-based equipment. A device for the regeneration of sludge water is disclosed in German Patent No. 181365. The essence of this is that the water jet air pump compresses the air sucked into the air intake pipe into a double-walled float near the water surface, which increases the residence time of the bubbles. This is because in this case - unlike activated sludge aeration pools - it is necessary to prevent sludge mixing. Its use in aeration basins is questioned by its poor mixing ability and the obstruction of the internal air-permeable wall of the double-walled duct.

Hungarian Patent No. 174256 discloses an injector for pumping a sewage sump, for the homogenization and aeration of wastewater, the air inlet pipe of which is below the maximum level of sewage and the air supply pipe is located near the bottom of the shaft. The design of the device serves the reliable implementation of oxygen supply and homogenization 3 at variable water levels, and its primary function is not to achieve good oxygen delivery specific performance.

The nozzles of the aeration apparatus of the Austrian Patent No. 177018, which runs parallel to the liquid supply line of the aeration device, operate on the principle of an injector and mix the water-air into the pool. The advantage is that the air intake and mixing are uniform due to the many nozzles used throughout the pool. A disadvantage is that the use of many nozzles is possible only by reducing the diameter of the nozzle, which increases the risk of clogging of nozzles, which are difficult to clean due to their construction.

The object of the present invention is to eliminate the drawbacks of the known equipment and to provide a device which provides higher specific gas input, its power can be controlled according to the particular need, its operation is economical and its maintenance is minimal.

The apparatus of the present invention is based on the recognition that when a fluid jet in the mixing chamber of a liquid jet is used, a swirling element is applied downstream of the mixing chamber, thereby ensuring rapid mixing and finer bubbling, since the efficiency of . The high shear stresses occurring during flow through the vortex-breaker element cause the gas bubbles in the mixture to crush and leave the device in the liquid space. Part of the material transfer process between the gauze and the liquid phase takes place in the apparatus itself, where the actuating fluid contacts and mixes with the sucked gas. However, most of this occurs during the ascent of the fine bubbles leaving the vortex, while the bubble flow induces a useful fluid movement in the fluid space (e.g., aeration pools).

Through the formation of slots in the air duct and / or the mixing chamber of the apparatus, preferably through holes or partial or complete closure thereof, it is possible to adjust the operating state to the load of the pool and to increase the mixing intensity in the initial section of the mixing chamber.

The essence of the device according to the invention is a liquid gas jet pump having a liquid jet nozzle connected to an operating pump (e.g. a centrifugal diving pump), a gas pipe connected thereto, and a mixing chamber, a diffuser connected to the mixing chamber. Slots (eg holes) are formed in the gas line and / or in the mixing chamber. Further, a flushing element for increasing the efficiency of the mixing and a vortex forming element for at least one-way rotation of the mixture before and / or after the diffuser are provided after the liquid jet nozzle.

In one embodiment of the apparatus according to the invention, an air compressor (e.g., a blower) is connected to the gas line.

In another embodiment of the invention, regulating rings are provided for partially or completely closing the gaps in the gas line and / or the mixing chamber.

In a further embodiment of the invention, a pressure line is provided between the actuation pump and the liquid jet pump, and a fluid flow control element (e.g. a gate valve) is inserted into the pressure line.

In yet another possible embodiment, at least two liquid jet pumps arranged in parallel operation are connected to one or more actuator driven pressure lines.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will be explained in more detail with reference to the drawings. The attached drawings show

Figure 1 illustrates a possible embodiment of an apparatus according to the invention,

Figures 2 and 3 are schematic representations of a possible arrangement of the apparatus according to the invention.

As an exemplary embodiment, as shown in Figure 1

- a gaseous pump 4 of a liquid jet 4 having a jet of liquid 8 connected to a centrifugal submersible pump 2, a gas line 5 having an air compressor 6, and a mixing chamber 11 connected to the mixing chamber. The gas line 5 and the mixing chamber 10 are provided with holes 7 and regulating rings 13 for partially or completely closing them. After the liquid jet nozzle 8, a plate-shaped curved blade baffle 9 for increasing the efficiency of the mixing is provided, and a vortex forming element 12 having a high-pitch helical blade for rotating the mixture before and after the diffuser 11 is inserted. The pressure line 2 comprises a slide valve 3 which controls the flow of liquid.

In another exemplary embodiment of the invention as shown in Figures 2 and 3

the apparatus is connected to a pressure line 2 fed by a centrifugal pump 1 and fitted with a valve 3 and arranged in three parallel operating units 4, 5, 7, 8, 9, 10, 11, 12, 13, as described in the first example.

The operation of the apparatus according to the invention is illustrated using the embodiment shown in FIG.

The liquid sucked by the centrifugal submersible pump 1 (e.g., from the aeration pool) is accelerated through the slide valve 3, inserted into the discharge line 2, at the nozzle 8 of the liquid jet gas pump 4 and traps the fluid entering the air line 5 and entrains it. After passing through the transfer element 9, the liquid and gas phases are mixed in the mixing space 10.

The transfer element 9 facilitates rapid mixing and thus reduces the dimensioning length of the mixing chamber. The liquid-gas mixture then passes through the vortex members 12 located before and after the diffuser 11 into the fluid space of the pool. The locking rings 13 of the slider 3 and the holes 1 a set the operating mode according to the changing load of the pool.

The aeration units of the device according to the invention, operated either from a common (Fig. 2) or from a single pressure line, can be arranged at different depths of the aeration pool and / or at different angles to the pool surface. mixing and oxygen intake.

Advantages of the Appliances of the Invention: The apparatus we propose does not contain small diameter bores, nozzles, or porous materials that may become lost in the waste water 2. Your maintenance needs are minimal. The entire structure is located below the water level of the pool, so it does not require any engine room and its operation is extremely quiet. The specific power of Oxignin input 3 is good due to the effect of the vortex and swirl elements used, it is superior to the equipment currently used in Hungary and can be operated economically. In contrast to previous injector systems, the secondary water flow through the air inlet pipe and through the mixing chamber can be adjusted according to the actual oxygen demand and thus the amount of oxygen supplied can be varied according to the daily load fluctuations. 4

A further advantage of using the device according to the invention is that the gaps in the air duct and / or in the mixing chamber are also suitable for chemical application according to technological requirements. 4

Claims (6)

PATENT CLAIMS Apparatus for introducing gases into liquids, in particular for venting wastewater, operating by means of an operating pump, a liquid jet pump having a liquid jet nozzle, a gas pipe or a mixing chamber connected therewith, having a gas diffuser connected to the mixing chamber, ) and / or slots in the mixing chamber (10), preferably bores (7), and in addition to the fluid jet (8), a swivel blade (9) for increasing the efficiency of the mixing, in front of the diffuser (11) and / or After this, a vortex-forming element (12) consisting of at least one-way helical deflection blades is inserted. 0 Apparatus according to claim 1, characterized in that an air compressing element (6) is connected to the gas line (5). Apparatus according to claim 1 or 2, characterized in that control rings (13) for partially or completely closing the gaps (7) in the gas conduits (5) and / or in the mixing chamber (10) are provided. 4. Apparatus according to any one of claims 1 to 3, characterized in that a pressure line (2) is provided between the actuator pump (1) and the liquid jet gas pump (4). The apparatus of claim 4 5, characterized in that the fluid flow control element (3) is inserted into the discharge line (2). The apparatus according to claim 4 or 5, characterized in that you are one or more At least two liquid jet gas pumps (4) arranged in parallel operation are connected to a pressure line (2) fed by a plurality of actuation pumps (1).