CH651280A5 - METHOD AND DEVICE FOR TREATING STANDING WATERS. - Google Patents

Description

The present invention relates to a method and an apparatus for treating still water, in which a gaseous medium is introduced. An oxygen-containing medium, such as air, is particularly suitable as the gaseous medium. In view of the fact that the oxygen balance of most inland lakes in Europe is more or less disturbed, targeted attempts have been made in Germany and Switzerland in the past ten years to protect against further over-fertilization (eutrophication).

There are already a number of practical experiences with internal measures at sea. In some cases it has been shown that a targeted individual measure can delay the progression or even decrease the eutrophication. For example, the literature points to good results, which were achieved by ensuring an adequate oxygen content in the water-mud contact zone with the help of artificial aeration or by removing deep water from lakes.

The newer methods of artificial aeration are limited to the aeration of the deep zones of the lakes (hypolimnion). These methods have the advantage that there is no destruction (layer dissolution) and therefore no increase in the mean temperature of the lake or a change in the overall biological conditions. Compressors were used as aeration units, with the help of which large amounts of air are introduced into the water body through compressed air lines laid on the lake bed. The oxygenated water is returned to the hypolimnion.

In these known methods, pressure is applied by means of compressors mounted above the water level

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Air introduced at the bottom of the lake. Very large compressors (piston compressors) are required, which require a large building with sound insulation. With such piston compressors, the air also takes oil with it and thus pollutes the water. Otherwise, such a procedure cannot be used for deep lakes.

The conventional method of deep water drainage is that, as a result of an artificially created flooding of the lake, the hypolimnic water is pressed outwards into the receiving water through a special pipeline laid on the lake bed. If the water is not allowed to be dammed, this means that the pipeline must be continued on land until the required discharge point in the receiving water is reached.

Another useful measure for internal water purification is sea water circulation or forced circulation. In winter an almost homogeneous density distribution occurs in the lakes. If this density distribution is not provided by natural influences, the stratification of the lake can be broken down so far and so early by artificial circulation that a full circulation already occurs in early winter and this persists during winter stagnation.

The purpose of the present invention is to provide a method and a device which is versatile and can therefore be used for different types of treatment, and is also usable and very environmentally friendly for very deep lakes (no noise and no pollution).

For this purpose, the method mentioned at the outset is characterized in that a partial water flow is conveyed upward from a lower point below the water level of the water and gaseous medium is introduced at a higher point into the conveyed partial water flow by suction during the conveying process, so that an upwardly increasing water flow is created by the effect of mammoth pumps, and the device for carrying out the method has a pump arrangement which comprises a mechanical pump, a water jet compressor and a mammoth pump which are connected in series in the direction of flow of the water flow to be conveyed, the suction part of the water jet compressor communicates with a line for the supply of the gaseous medium, the whole in such a way that a partial water flow is conveyed through the mechanical pump and the water jet compressor, the partial water flow and the residual water flow after the gas supply point medium in the partial water flow can be combined to form the water flow to be pumped.

The method and the device can be used either for deep water aeration, for forced circulation or for deep water drainage.

The invention is explained below with reference to the drawing, for example. Show it:

1 shows a device in longitudinal section in use for deep water aeration.

Fig. 2 shows the device according to Fig. 1 with attachment in use for deep water drainage, and

Fig. 3 shows the device of FIG. 1 with an attachment in use for the forced circulation of water.

The device designated 1 for use for deep water aeration according to FIG. 1 stands upright in a standing body of water, the water level of which is designated 2 and the bottom of the lake is designated 3. For this purpose, the device has buoyancy bodies 13 and it is connected by means of an anchor chain 5 to an anchor weight 6 anchored in the sea bed. In order to illustrate the order of magnitude, a dimension line interrupted in the lower area with information in meters is drawn in addition to the device. The sea depth can be several hundred meters.

5 The device I has a vertical riser pipe with a lower and an upper riser pipe section 7 and 12, the inlet of which is in the vicinity of the lake bottom 2. The cable line section 7 communicates at its upper end with a housing-like extension io 8, in which a submersible motor pump 9 connected to a power source via an underwater cable 24 and, viewed in the direction of flow, a water jet compressor 10 are arranged directly downstream. An air duct 11 communicates with the suction part of the water jet compressor 10 and opens into the free atmosphere. The riser section 12, which acts as a mammoth pump together with the supply air line 11, communicates with the outlet of the housing-like extension. The riser section 12 opens into a pressure and degassing container 20 12, the riser section 12 being central to the latter. The pressure and degassing container 13 also serves as a buoyancy body. In the air space of the pressure and degassing container 13 opens a degassing line 14, 25 which ends at the bottom and slightly below the water level and is closed at the lower end with a pressure relief valve. With outlets of the pressure and degassing container 13, two or more vertical 30 down pipes 15 are connected radially symmetrically to the axis of the riser pipe comprising the two coaxially arranged riser sections 7, 12 the tapping point. The pressure and degassing container 13 is sealed off at the top with a releasably attached lid 17. The device works as follows:

The water flowing into the riser section 7 is pumped up into the housing-like extension 8 by the pump arrangement, comprising the mechanical pump 9, the water jet compressor 10 and the mammoth pump 12. In the housing-like extension 8, the water flow is divided. A small part of the water flow (about 1/20 of the delivered water flow) is conveyed through the mechanical submersible pump 9 and the water jet compressor 10. Due to the suction effect generated in the water jet 45 compressor, air is introduced into the small partial water flow via the supply air line 11. The large residual water flow flows in the housing-like extension bypassing the underwater pump 9 and the water jet compressor 10 by means of a mammoth pump effect and mixes again with the small partial water flow containing air after the water jet compressor 10 before entering the riser section 12 belonging to the mammoth pump.

The specifically lighter water-air mixture is guided 55 through the riser section 12 into the pressure and degassing tank 13 attached above. As a result, the total pressure, which is a decisive factor for the solubility of oxygen in water according to Henry's law, is used in the riser section 12 and in the pressure-60 container 13. Due to the overpressure generated in the pressure vessel, the aerated water is discharged through the down pipe system 15 into the hypolimnion, namely a few meters above the removal zone. The depth of the extraction point is determined by the length of the suction pipe. The air collecting in the degassing container 13 escapes via the degassing line. The underwater motor pump 8 is supplied with power by an underwater electric cable 24.

651280

The air space created in the degassing container 13 has the effect that the device floating in the water is under buoyancy and is thus held upright in the water. The anchor weight 6 prevents the device from drifting and rising. A buoy 4 is provided for the supply air line 11 and the degassing line 14.

The principle of operation is as follows:

1) Generation of a partial water flow by means of a submersible motor pump;

2) Utilization of the partial water flow for the air intake according to the principle of the jet pump and

3) Promotion of the required amount of water according to the principle of the mammoth pump.

The device described with reference to FIG. 1 can also be used for deep water drainage according to FIG. 2. For this purpose, the cover 17 (see FIG. 1) is removed, and instead of the cover 17, a riser pipe extension 18, which has a coaxial connection with the riser section 12 and has a connection piece 19 for a floating transport line 20, is placed on the container 13. Here, the container 13 has only a buoyancy function, and the end 18 'of the straight and vertical riser extension 18 serves as a degassing chamber and partly. as a float. A degassing line 21 leads into the air space of the top tube 18, which leads into the free atmosphere and has a pressure relief valve at the lower end. Otherwise, it is the same device as in Fig. 1, and the same parts have been given the same reference numerals.

The deep water is drained off by the floating transport line 20, which is located a few meters below the lake level. The transport line is supplied by the ventilation device that has been converted according to the above. The same funding principle is used here. The fall pipe system 15 has no function here.

The air space created in chamber 13 is responsible for keeping the device upright. The air collecting at the end 18 'of the riser pipe extension 18 escapes via a degassing line 21. The pressure required for water transport in the floating line is applied in the above-mentioned degassing chamber 18'.

The end of the transport line 20 is introduced into the outlet funnel of the natural lake runoff.

This procedure avoids sea damming and a long land transport line. In addition, the water taken from the bottom of the lake is aerated, whereby any immissions in the lower reaches of the lake are reduced.

The device described with reference to FIG. 1 can also serve for the forced circulation of water in the water according to FIG. 3. For this purpose, instead of the attachment part 18 according to FIG. 2, a modified, straight riser pipe extension 22 coaxial with the riser section 12 is placed, the end 22 'of which in turn serves as a degassing chamber with degassing pipes 21 and pressure relief valve, and the distribution pipes 23 for the Has outlet of the pumped water flow. The outlet 15 of the water conveyed upwards takes place in the upper layer of the lake, the epilimnon. Otherwise, this is also the same device as in FIG. 1, and the same parts have been given the same reference numbers. Here too, the down pipe system 15 20 has no function.

The described device with its combinations can largely be built from commercially available products. The pressure or degassing containers must be specially manufactured, as must the device for a radial distribution of the water quantities to be entered.

The only controllable mechanism of a created device is the underwater motor pump. It is designed for speed-regulated pump operation. Electrical speed regulation with the help of a frequency converter eliminates the notorious pressure surges in the water circuit and the electricity surges in the mains when starting. The air supply and water flow can be regulated accordingly.

The ongoing operation requires no maintenance and care. Contamination of the air and water are completely excluded (in contrast to compressed air ventilation).

The system can be dimensioned according to needs and performance.

In a modification of the device 40 described, the chamber 13 in the embodiment according to FIG. 1, or the chambers 18 'or 22' in the embodiment according to FIG. 2 or with respect to the water level, can be open above and above. In the device according to FIG. 1, an additional buoyancy body would then have to be provided. 45 The gas pressure of the degassing chamber 13, 18 'or 22' can be limited.

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3 sheets of drawings

Claims (16)

651280 2nd PATENT CLAIMS 1. A method for treating standing water, wherein a gaseous medium is introduced, characterized in that a partial water flow is conveyed upwards from a lower point below the water level of the water and during the conveying process at a higher point in the partial water flow being conveyed gaseous medium is introduced by suction, so that an upward rising water flow is created by the mammoth pump effect. 2. The method according to claim 1, characterized in that for deep water aeration the water flow after the introduction of the gaseous medium is diverted downwards and released again at a lower point. 3. The method according to claim 1, characterized in that for forced circulation of the water flow after the introduction of the gaseous medium is further promoted upwards and released again in the upper water layers. 4. The method according to claim 1, characterized in that for deep water discharge, the water flow is derived after introducing the gaseous medium and introduced into the outlet funnel of the water drain. 5. The method according to any one of claims 1 to 4, characterized in that on the water flow exerts from the water flow, excess gaseous medium pad exerts a pressure exceeding the atmospheric pressure. 6. The device for carrying out the method according to claim 1, characterized in that it has a pump arrangement which comprises a mechanical pump (9), a water jet compressor (10) and a mammoth pump (11, 12) which in the flow direction of the water flow to be conveyed Are connected in series, the suction part of the water jet compressor communicating with a line (11) for the supply of the gaseous medium, the whole in such a way that a partial water flow is conveyed through the mechanical pump and the water jet compressor, the partial water flow and the residual water flow after the supply point of the gaseous medium in the partial water flow can be combined to form the water flow to be pumped. 7. The device according to claim 6, characterized in that the line (11) for the supply of the gaseous medium opens into the free atmosphere. 8. The device according to claim 6 or 7, characterized in that seen in the direction of flow, a degassing chamber (13, 18 'or 22') with limited gas pressure, which optionally serves as a buoyancy body for the device (1), is connected downstream of the pump arrangement. 9. The device according to claim 8 for aeration of the water, characterized in that the degassing chamber (13) serves as a pressure chamber, the gas pressure being higher than the atmospheric pressure. 10. The device according to claim 8, characterized in that the pump arrangement and the degassing chamber is followed by a down pipe system (15) in order to guide the water provided with gaseous medium, in particular oxygen, to a lower point of the water. 11. The device according to claim 6 or 8 for forced circulation, characterized in that the pump arrangement is followed by one or more outlet lines to guide the water to the desired location in the body of water. 12. The device according to claim 6 or 8 for deep water drainage, characterized in that the pump arrangement is followed by a floating transport line (20). 13. The apparatus according to claim 6, characterized in that the inlet of the mechanical pump (9) communicates with a riser section (7) to supply the water to be treated to the pump arrangement, and that the outlet of the water jet compressor (10) with one to the riser section ( 7) coaxial riser section (12), which forms part of the mammoth pump, communicates. 14. Use of the device according to claim 6 either for deep water ventilation, for forced circulation or for deep water drainage. 15. Use according to claim 14, characterized in that, seen in the flow direction, the pump arrangement is followed by a chamber (13) which communicates with a drain line system (15), the chamber (13) being a degassing and pressure chamber and, if appropriate, in the case of deep water aeration Buoyancy body with adjustable gas pressure is used and the downpipe system injects the oxygenated water back into the water at a lower point and, in the event of forced circulation or deep water discharge at a prepared point in the chamber (13), a riser pipe extension coaxial with the riser section (12) 18 or 22) can be fitted with connections for discharge pipes, the end (18 'or 22') of the riser pipe extension possibly serving as a degassing chamber and buoyancy body. 16. Use according to claim 15, characterized in that the chamber (13) has only a buoyancy function in the case of deep water drainage and forced circulation.