DE2443568A1 - Aerating dying lakes by deep introduction of bubbles - in downward liquid flow at speed exceeding bubble ascent speed - Google Patents

Abstract

A method of introducing gas depp into a liquid consists of using a downward jet of liquid to generate downward flow of bubble-containing liquid in a pipe projecting downwards through the surface; the flow speed exceeds the upward flotation speed of the bubbles. The bubbles may leave the lower end of the tube either directionally or non-directionally. For any gasifying or aerating of liquids, e.g. in chemical processes, but esp. for aerating deep lakes which are dead or dying. Deep penetration of bubbles is obtained with economical equipment.

Description

Method and device for removing gas bubbles in liquids The invention relates to a method and a device for lowering of gas bubbles in liquids, for example for energy-efficient removal of air at great depths in lakes and waterways.

The creation or introduction of gas bubbles in liquids represents is a very old problem that a number of technical uses is topical, for example when cleaning liquids by flotation performing various chemical processes, etc. To produce a The gas bubbles should be as small as possible to achieve a favorable effect to maintain a large contact area with the surrounding liquid, and in the Size as evenly as possible. A number of different constructive solutions to achieve this end have been proposed. One of these exists in that you put the liquid with a gas dissolved in it in a pressure vessel saturates. Sudden decompression results in a swarm or a cloud of gas bubbles xit very uniform, small size. This solution is however with high Investment and operating costs connected. Another, structurally simpler Solution is under pressure standing gas through various To introduce types of porous bodies directly into a liquid. In this procedure However, there are significant difficulties in the size and spread of the gas bubbles to control.

A third solution is through Swedish patent specification 161 969 known when small drops of liquid against a free liquid surface Injected with the formation of bubbles, creating the desired bubbles on very can be generated in an advantageous manner. However, these are important with this solution do not go deep enough into the liquid.

The object of the invention is to overcome the disadvantages of the previous Solutions to eliminate the problem.

The invention solves the problem according to the method in that in one in a free liquid communicating tube by means of a liquid jet Gas bubbles formed by the jet directed downwards through the liquid generated liquid flow downwards will be XitgeriDgen that the Geschwinffi If the flow is higher than the buoyancy of the gas bubbles.

The invention also solves the problem by a device that is characterized by the fact that a vertical shielding wall with a closed circular Contour is provided which opposes an area of a free liquid surface a gas, preferably air, shields against this area a finely divided Jet of the same liquid is directed at a certain speed, so that Gas bubbles are formed in the liquid within the shielding wall, the Shielding wall extends to the desired depth to expel the gas bubbles into the open Liquid extends and the finely divided FluasigkeitsGtrshl such a mass flow Per Time unit has that a substantially vertical flow in the liquid cross-section exists inside the shielding wall, which has a greater speed than that ; #development speed of the gas bubbles of the desired maximum size in the liquid.

This solution uses the well-known physical law of communicating Tubes used to limit the size of the gas bubbles to desired maximum values and lowering the formed bubbles to the desired depth below the to reach free liquid surface.

This has advantages in many designs, for example in chemical processes or the like, but especially when air is larger Is to introduce water depth, for example in connection with the introduction of oxygen into the bottom of polluted or dying lakes.

It is then no longer necessary to air up to one of the hydrostatic ones To compress pressure in the desired depth exceeding pressure, but one can be a lot simpler and more energy efficient the bubbles by making a vertical one Bring the liquid flow down to the desired depth.

A pressure of only a few tenths of a Kp / cm² in the liquid in the The spray nozzle is usually enough to achieve the desired effect.

Further features and advantages of the invention emerge from the following Description of the embodiments shown in the accompanying drawings. 1 shows a schematic section through a device according to the invention, 2a and 2b another embodiment according to the invention, in which the Shielding wall is closed at the top to form a closed space, wherein this Space either at a certain distance above the free liquid surface or lies at a certain depth below the same, Fig. 3a shows a screen wall, which are closed at the top and at the bottom to form a closed space and is provided with at least one outlet opening, and Fig. 3b shows a device according to Fig. 3a, the entire closed space outside the container in which the free liquid is located, is arranged.

From Fig. 1 of the drawing it can be seen that at a certain distance a nozzle 2 is arranged above a free liquid surface 1 in such a way that that a liquid jet is directed against the liquid surface. Of the According to the invention, the jet is finely divided so that the jet emerging from the nozzle 2 Liquid when it hits the free surface of the liquid in a multitude is atomized by individual drops. A drop that occurs with sufficient speed hits a free liquid surface, is known to produce a wave motion, which is a constriction of a small amount of the above the liquid surface the gas in place to form a gas bubble in the liquid. This occurs, for example, when raindrops hit a surface of water.

In accordance with the present invention, this principle becomes very much advantageously used to the fact that in a known manner the area of the free Liquid surface 1 struck by the finely divided liquid jet 3 is shielded by means of a shielding wall 4, which is a closed circular Has contour and protrudes into the liquid.

That of the liquid jet 3 in the liquid within the screen wall 4 formed gas bubbles are then either against the liquid flow ascend, provided they are relatively large and have a rate of climb, which is greater than the flow velocity of the liquid, or the vertical, Follow the downward flow of liquid within the screen wall 4. Through this you get a very simple way to precisely regulate the maximum size of the gas bubbles formed, and the mass flow per unit of time in the jet is chosen 3 such that the flow rate of the liquid in cross section within the screen wall 4 is greater than the rate of rise of the gas bubbles desired Maximum size in the liquid.

The liquid jet 3 of the nozzle 2 is preferably substantially directed perpendicular to the free liquid surface 1 The shielding wall 4 extends to a depth in the liquid in which the gas bubbles are free in the liquid should exit. This has the technical effect that by using the well-known law of the communicating tubes a downward run of the educated Gas bubbles can reach to very great depths, which is when using the invention in connection with the purification of polluted or dying lakes by introduction of air in the bottom of the same is particularly advantageous.

However, the present invention is not limited to this embodiment limited. As can be seen from Fig. 2a and 2b of the drawing, the shielding wall 4 must be closed at the top to form a closed space. This room can either in accordance with FIG. 2a with the liquid surface in a certain Distance above the free liquid surface 1 or according to FIG. 2b with the liquid surface arranged below the free liquid surface 1 be. As in the first embodiment, the liquid is thereby formed a finely divided liquid jet 3 fed through nozzle 2, this being the liquid surface formed within the closed space meets. Above this liquid surface is in the upper part of the closed Space an adjustable gas inlet arranged, which with the environment or a separate gas container is in communication and creates an atmosphere with which the necessary prerequisites to achieve the desired gas bubble formation be created. This of course also makes it possible to use different gas atmospheres above the liquid surface within the closed space or above the remaining part of the liquid surface to be used. Same description also applies to the closed space shown in FIG. 2b, the one below the rest free surface of the liquid.

Flow at the lower edge of the shielding wall 4 or the closed space that is, the gas bubbles entrained by the vertical flow of liquid in all directions out and rise to the free surface of the liquid. The bubbles are preferable of so-called micro-size, i.e. H. they are of the order of 0.1 mm or less, which have a slow rate of climb. In general it can be said that the The rate of rise of a gas bubble roughly proportional to the square of the diameter the bubble is (Stokes law). When passing into the liquid outside the Shielding wall 4 sometimes collide with some bubbles, so that larger bubbles are formed which then get a greater rate of climb and move faster to the Move surface.

In some designs, where in particular gas bubbles become larger Are to be led down below the free liquid surface 1, can it may be desirable to control the velocity of the downward gas bubbles to be kept constant in the liquid flow despite the compression.

This is easy to achieve in that the cross-section the Shielding wall 4 decreases progressively downwards.

It was described above that the gas bubbles at the bottom the shielding wall 4 or the closed space freely emerge in all directions to be allowed to. Under certain circumstances, however, it may be desirable to reduce the expelled gas bubbles to give a special direction at the bottom of the shielding wall 4. Then it is 3a and 3b, it is possible to close the lower end of the shielding wall 4 and laterally below one or more slots or throttle openings in the shielding wall 4 train so that the flow there to a higher speed w than that Flow velocity v of the downward flow in the cross section within the shielding wall 4 is accelerated, whereby the desired direction of the gas bubble swarm is achieved.

From Fig. 3b of the drawing it can be seen that the shielding wall 4 or the closed space not necessarily in the rest of the free liquid must lie, but according to the law of the communicating tubes also outside these can lie.

Expectations:

Claims (10)

Claims: 1. A method for removing gas bubbles in liquids, d u r c h e k e n n n z e i c h n e t that in a in a free liquid located communicating tube formed by means of a liquid jet Gas bubbles by a downward directed, generated by the liquid jet Liquid flow will be entrained downwards by the fact that the speed the flow is higher than the upward speed of the gas bubbles. 2. The method according to claim 1, d a d u r c h g e k e n n -z e i c h n e t that the gas bubbles from the free end of the communicating tube are independent of direction be expelled into the free liquid. 3. The method according to claim 1, d a d u r c h g e k e n n -z e i c h n e t that the gas bubbles are ejected in a certain direction. 4. Device for performing the method according to the claims 1 to 3, that a vertical shielding wall (4) is provided with a closed circular contour, which is an area of a free liquid surface (1) against a gas, preferably air, shields, wherein against this area a finely divided jet (3) of the same liquid with a certain Speed is directed so that in the liquid within the shielding wall (4) Gas bubbles are formed, the shielding wall (4) extending up to the desired Depth to expel the gas bubbles extends into the free liquid and the finely divided ~ Liquid jet (3) has such a mass flow per unit of time that an im substantial vertical flow in the liquid cross-section within the shielding wall (lot) which has a greater speed than the rate of climb the gas bubbles of the desired maximum size in the liquid. 5. Apparatus according to claim 4, d a d u r c h g e -k e n n z e i c h n e t that the shielding wall (4) is closed at the top and in this wall part a nozzle (2) is arranged to form the liquid jet. 6. Device according to one of claims 4 or 5, d a -d u r c h -g It is not noted that on the wall part of the upper end of the shielding wall (4) an adjustable air circulation line is connected through which into the free Space above the liquid level within the shielding wall (4) gas or air is insertable. 7. Device according to one of claims 5 or 6, d a -d u r c h g It is not noted that the closed shielding wall (4) except for the outlet opening is arranged outside a free liquid surface (1). 8. Device according to one of claims 5 or 6, d a -d u r c h g It is not noted that the closed shielding wall (4) is completely underneath the free #lüisigkeitsfläche (1) is arranged. 9. The device according to at least one of claims 4 to 8 d a d u R e k e k e n n z e i n e t, that the shielding edge is also closed at the bottom formed #st and one or more openings on the side. 10. The device according to claim 9, d a d u r c h g e -k e n n z e i c h n e t that the shielding wall (4), which is closed at the top and bottom, is outside the free one Liquid is arranged and a side opening with the free liquid communicates.