DE1657377B2 - DEVICE FOR ENTERING GASES IN LIQUIDS - Google Patents

Description

60 bubbles are very essential, for example for the Entry of oxygen, which with an increase in the

the area between air and water increases significantly,

thus better results are achieved with the device according to the invention than with the

The invention relates to a device for acquiring known devices. Will carry the same oxygen of gases, especially air, reached in liquid entry, this is the case with the device according to opportunities, especially waste water, with at least the invention only a lower energy consumption a revolving driven approximately horizontally required, so that the device is therefore economical

Higher works In addition, there is the lower work Impact losses caused energy gain. The advantages achieved in this way are supplemented by that, as previously mentioned, the device according to the invention is considerably less prone to failure because it is only exposed to low stresses and is cheaper, since essential parts are made lighter could be.

In particular, the device according to the invention is therefore very suitable for ventilation rotors large dimensions, which are too strong when using the usual arrangement of the ventilation elements Would be exposed to loads. The device according to the invention can therefore have a rotor length of 4.5 up to 10 m and more and a diameter of about 1 m and more without being in continuous operation the stresses would be too great.

It is particularly advantageous if the dislocation is about 3.

A particularly uniform immersion of the blades results when the angular amount is so it is selected that the sum of the angular amounts over the length of the rotor is equal to the pitch angle of a star or an integral multiple thereof. In this case z. B. all ventilation elements of a deer in each next but one axially perpendicular planes very shortly after one another. When the last ventilation element is immersed, then immediately afterwards the first ventilation element of the next row is attached to the other End of the rotor. So there is no interruption in the immersion frequency. Here you can also several ventilation elements in each immerse at a greater distance at the same time. Also other immersion sequences than those described above k be elected inside. It is essential for a uniform immersion that the immersion frequencies are the same and gaps do not occur at certain intervals because there are no ventilation elements are available for an immersion process. However, one can also do this if this For certain reasons it seems appropriate to vary the diving frequency, which is possible without that the aforementioned loopholes occur.

As is well known, the ventilation rotors do not work only an introduction of air into water, but at the same time a circulation of the water in it Aeration basin. The circulation takes place perpendicular to the known devices Rotor axis. If the ventilation elements are moved according to the invention, the circulation takes place no longer perpendicular to the rotor axis as with the aforementioned rotors, but in one more or less large angle to the vertical. This can be beneficial in many cases, namely when not only a circulation should take place around a horizontal axis of the aeration basin, but at the same time a helical circulation in the basin. In particular, this can be useful be to improve the mixing of the basin contents, especially to intensify the Exchange of the different more or less gas-laden liquid layers in aeration basins, in which the liquid is returned horizontally in the manner of a ventilation ditch will. The liquid is then not only circulated through such a circulating basin passed through, but at the same time circulated around a horizontal axis in the direction of flow, so that a helical flow of liquid is created. In this case one will if two ventilation rotors simultaneously driven by a drive unit that is between these two Rotors is arranged, the rotors are arranged in one leg of the circulating basin and rotate in opposite directions operate. In order to then achieve a continuous helical flow, it is advantageous

cautiously move the blades of both rotors in the same direction.

According to the invention it is now the nature and magnitude of these circulation accurate control, and ZWL.T characterized in that the aeration elements are offset in the individual longitudinal sections of a rotor or a multiple rotors ventilation system in the opposite direction In this manner, an A arises "sweep" of the rotor. The circulation then takes place: n both ends

of the rotor in different directions, so that also, for example, when diverging currents occur, otherwise non-circulated parts at the edge of the pool can also be detected. at converging circulating currents can be achieved

as will be that the pelvic walls are relieved and an intensive mix in the middle of the pool he follows. The axial thrust in the rotor can also be compensated by means of an arrow, which occurs when there is a helical flow of liquid is produced.

When using two coaxial rotors, in particular with one arranged in between common drive unit, the ventilation elements are preferably each in the rotors offset in the opposite direction. This arrangement has the same effect as with a a symmetrical »sweep« takes place through the continuous rotor. In this way you can also avoid that there is too little circulation in front of the drive unit.

An unsymmetrical "Pfei'.ung" can be achieved that the length sections with opposite Directions of displacement have unequal lengths. This opens up further possibilities to influence the type of circulation and also to compensate for the axial thrust.

Normally, all ventilation elements will be relocated according to the invention. There are but of course cases are conceivable in which it

'"It is useful to move only part of the ventilation elements or, for example, one Move to make different angular amounts, so that for example in the middle a rotor a lower circulating flow occurs than at the ends. Finally, according to the Invention change the direction of the dislocation more than once. This then creates a number of diverging and converging circulating currents, which are excellent in the circulating basin Effect mixture.

In the drawings, embodiments according to the invention are shown by way of example.

F i g. Fig. 1 shows a device according to the invention with two rotors;

F i g. Figure 2 is a development of part of a rotor according to the invention;

Fig. 3 shows ventilation elements for the rotor of the F i %. 1;

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Fig 4 shows a plan view of the circulating pool elements 7, 10, 8, 11 and 9, 12 (Fig. 2) in one with the device according to the invention; Angular distance of z. B. 15 ° to each other

Fig. 5 is a section through a circulating pool.

according to FIG. 3. According to the invention, those air

The ventilation device according to the invention 5 processing elements, each of the next achsbesteht of a drive motor 1, which are assigned to a vertical plane in Fig. 2, therefore, column 2 with an unillustrated gear reasonable example, the aeration elements 7, 7 ', T or is brought. The motor drives a in the column 10, 10 ', 10 "by 2.5 ⁿ offset from each other, seen mounted, not shown gear a specifically in FIG. 2, from left to right, axle stub 3 for a hollow shaft 4 at. The hollow io upwards.

shaft is with the journal 3 by a coupling In the example shown offset around

ment 5 connected. At its end it is in a 2.5 ° come the ventilation elements of the corre- sponding storage 6 stored. The hollow shaft is equipped with corresponding rows in the thirteenth vertical axis Ventilation elements, e.g. B. 7, 8.9 (Fig. 3). To lie back in the same position as

You can make very large ventilation rotors, 15 the ventilation elements in the second axis creep in which the hollow shaft have a diameter th plane. However, there is then in each case a shift that takes place more than a quarter of the entire opening around a row, so that the dimension of the ventilation rotor is therefore. The ventilation element 8 * in the thirteenth level can advantageously occupy the diameter of the hollow shaft 300, the ventilation element 10 in the second up to 400 mm and in particular 350 to 360 mm bc-20 level. Contribute accordingly then takes. The length of the ventilation element is, for example, the ventilation element 10 * in the fourth level, preferably 300 to 400 mm, in particular the tenth level, the position of the ventilation element T is 300 to 350 mm. In this way you can easily enter the third level. After rotating the rotor shaft six times, a diameter of the rotor shaft of 1000 mm se .- .; n around 2.5 "there is a total offset and more can be achieved. With this diameter 25 of 15 \, so that the ventilation elements in the position can be achieved with a relatively small rotation - come to a position in which they get by in the respective number and still reach a level that is perpendicular to the next axis. The aerators of the required amount of sufficient supply elements in each of the twelfth level high circulation speed. Furthermore, one can beat on the following levels together with the ventilation rotors in this way, which have a 30 ventilation elements of the previous level, a length of over 4.5 m, in particular up to Advantageously, the 10 m is now equipped, with possibly even larger total rotors being chosen so that the number the axis lengths can be achieved. parallel planes or the adjacent

For each of the hollow shafts four and nine stars, a multiple of twelve is possible, see above the ventilation elements, e.g. B. 7, 8, 9, existing 35 so that no gaps when striking the loading ventilation rotor provide a separate drive. Ventilation ^ elements occur. The chosen transfer This is useful when only a single 2.5 ° is generally sufficient for Container or the like is to be ventilated. In this one avoidance of torsional vibrations and The case is not only the repository 6 on one of the conditions on the other side a good screw container wall housed, but also the column 2 40-shaped circulation. If you want a reduction with engine 1 and gearbox. the torsional stress by increasing the

But you can also reach two ventilation rotors immersion frequency, so you can drive it by a single motor 1, as shown in the angle by which the ventilation elements versctzi F i g. 1 is shown. The corresponding hollow shaft 4 'should also be selected so small that the sum dic ^ ci is then also connected to the shaft journal 3' of the gear via a coupling 5 'with an angle over the entire length of the rotor and corresponds to kel, around which the ventilation equipment is offset on its other side in a further, non-adjacent, axially perpendicular plane. The furnishings of this is the _s he latter angle, as in the case of hollow shaft 4 'with Belüftnngselementen is the same game 15 degrees so were the Belüftungselcmcntc be like the hollow shaft 4. 50 100 bucket stars in a corresponding number AEHS

In this case, two aeration tanks can be offset perpendicularly by 0.3 each arranged next to each other and the column 2 on a correspondingly more or \. Fewer stars wiirdei Intermediate wall arranged between these containers then change the angle accordingly be nice. The hollow shafts for the ventilation elements This applies in the event that the displacement practice

Depending on the gear used, the entire length of the rotor can be adjusted by the same angle or driven in opposite directions. and in the same direction Man kan takes place

The ventilation rotors can be fitted with - corresponding to FIG. 1 but also proceed as by means of a V-shaped flat iron or c ^ gi. one can now find the offset in the same direction follow which, as shown at 23, are connected to one another, for example up to the ventilation elements I ^ and so the ventilation elements 7, 8 and 9 60 14, IS. From then on the relocation takes place form. in the opposite direction, in F i g. 1 in the right te

The left rotor that is arranged in a plane perpendicular to the axis is upward. Ventilation; Ventilation elements 7, 8, 9 are each with an element are thus arranged like an arrow, with di angles of z. B. 30 ° arranged in a star shape. In the ventilation elements 13, 14, 15 a type of tip ei the next following radial plane are ventilation 65. With twelve ventilation elements per Stei elements 10, 11, 12 with the same angular distances, one would in this case be arranged on the left side di, but each offset by half the angle - ventilation elements could be offset by about 0.5 °, so that the e ^: Individual ventilation on the right side by about 1 °. It would then

immersion without the occurrence of a gap should also be possible.

In the present case, the circulating currents are changed depending on the position of the tip, so that the possibilities already mentioned arise. The direction and strength of the circulating currents essentially depend on the angular amount by which the offset occurs. The same is true of course also for the compensation of the axial thrust.

To correct the flow and axial thrust, the individual ventilation elements can also be offset by a small angle arrange. The in F i g. 2 of the development shown ventilation elements would then not be perpendicular would be visible to the direction of development, but would be employed at an angle to it.

With aeration basins of the usual type, in which the liquid in a deep basin around a horizontal one Axis is circulated, you can rotate the two ventilation rotors in the same direction let, but advantageously the offset of the ventilation elements opposite is, so that a compensation of the axial thrust of both rotors is possible.

It is particularly advantageous to use the device according to the invention with the one shown in FIG. 4 shown Arrangement of aeration basins. In this case they are between an inlet ditch 60 and a drainage ditch 61, circulation basins 62, 63, 64, 65 are provided. In this circulating pool Ventilation devices are arranged according to the invention with their motors, for example 68, 69, 70, are arranged on the inner walls of the circulation basin. The ones from these engines driven ventilation rotors 71, 72 then each run in the opposite direction of rotation, so that the water flows in a circuit through the circulation basin. In this case, a helical one Upheaval can be achieved. this will

»5 by relocating the ventilation elements according to causes the invention, this offset takes place on both rotors in the same direction, so so that an uninterrupted helical circulation is achieved. However, it can also

ao all the options described above can be used to achieve the most favorable upheaval in each case reach.

You can also set the ventilation rotors themselves at an angle to the direction of rotation or the walls of the aeration basin.

For this purpose 2 sheets of drawings

Claims (8)

axially above the liquid level stored patent claims: rotor with ventilation elements in the form of rods, blades, which are immersed in the liquid 1. Device for introducing gases, especially od. The like. Is equipped, which is perpendicular to the axis special air, in liquids, especially 5 planes in a star shape with a certain angular division, Wastewater, with at least one circumferential adjoining star, if necessary with a displacement of neighboring stars driven approximately horizontally above the by simple fractions of the angular division, angeord liquid level mounted rotor, which are with in net. the liquid-submerged ventilation elements in the known devices are of this type th in the form of rods, shovel flange or the like load a plurality of ventilation elements on one is piece, which in axially perpendicular planes rotor shaft in axially perpendicular planes star-shaped Star-shaped with a certain angular division, arranged. These stars are arranged in such a way if necessary with offset neighboring that their ventilation elements od. Like. Each in the Stars around simple fractions of the angle division, paraxial plane of the bisector of the in are arranged, thereby marked- i $ axis direction arranged in front of or behind net that for at least a part of each star (magazine "Gesundheits-Tngenieur", in the axial direction adjacent ventilation booklet 7, 83rd year, 1962, pp. 201 to 206). elements each have a ventilation element (7, 10) This arrangement has a number of disadvantages, compared to one next to him in the axial direction which primarily consist in the fact that always one or the next but one ventilation element .ient 20 large number of blades simultaneously on the (7 ', 10') strikes or dips into the water surface compared to the angle, The distribution of the stars has a small angular value. This can cause considerable torsional vibrations is set. occur that are caused by proportionately 2. Apparatus according to claim 1, characterized in that high pulse surges when the blades hit, indicates that the offset is approximately Y 25 The invention is based on the object, carries through. an improved arrangement of the ventilation elements 3. The curtain according to claim 1 or 2, there being a reduction in the vibration load of the characterized in that the angular amount is selected so the rotor and at the same time an improvement in the gas that the entry can be achieved over the length of the rotor. summed angular amounts equal to the division 30 This task is performed with a device of the angle of a star or an integer type described at the beginning Are multiples of that. solved by that for at least part of 4. Apparatus according to claim 1 to 3, there in each case adjacent ventilation through in the axial direction characterized in that with the arrangement of elements in each case a ventilation element opposite two rotors driven in opposite directions (71 or 35 of a Be-72 located next to or above it) in each leg of a circulating basin by one ventilation element compared to the angled (62 to 65) the ventilation elements (7, 8, 9 or division of the stars is offset by a small amount of angle. 10, 11, 12) of both rotors in the same direction By the arrangement according to the invention are offset. achieves that at most a very small number 5. Apparatus according to claim 1 to 3, there being 40 of ventilation elements simultaneously on the water characterized in that the ventilation surface hits or dips into the water, elements (7 to 9 or 10 to 12) in individual At the same time there is a very substantial, given length section a rotor or a 100-fold reduction in the individual shock Rotors existing ventilation system impulses with a corresponding increase in frequency are offset in opposite directions. 45 individual immersion processes. This will 6. The device according to claim 5, characterized by the risk of torsional vibrations significantly, that when using two set, which in turn all torsional stress equiaxed Rotors and especially with th components, such as clutches, gears and layers common stanchions arranged in between, can be built more easily or ge-drive unit (1) the ventilation elements (7 50 are protected. up to 9 or 10 to 12) on the rotors in each case. are offset in the opposite direction. put that by means of the device after the 7 The device according to claim 5, characterized in the invention a considerable improvement in the gas, that the length sections can be achieved with de-registration, since the individual lenses are opposed to each other Direction of dislocation unequal 55 shaped gas bubbles, which when after-lengthening to have. knocking in the ventilation elements with 8. Apparatus according to claim 5 or 7, since high frequency are formed, are very small and characterized in that the direction of the flow is achieved by a finer-bubble fumigation Settlement changes more than once. as before. Since the size and shape of the gas