DE1657377C - Device for introducing gases into liquids - Google Patents

Description

The invention relates to a device for introducing gases, in particular air, into liquids, in particular sewage, with at least one circumferentially driven approximately horizontal axis stored above the liquid level. Rotor with aeration elements immersed in the liquid in the form of rods, blades or the like, which is star-shaped in planes perpendicular to the axis with a certain angular division, if necessary with the offset of neighboring stars by simple fractions of the angular division are.

In the known devices: of this type

ίο a plurality of ventilation elements on one Rotor shaft arranged in a star shape in planes perpendicular to the axis. These stars are arranged in such a way that their ventilation elements od. Like. Each in the axis-parallel plane of the bisector of the in Axis direction in front of or behind the arranged star (magazine "Gesundheits-Ingenieur", Issue 7, Volume 83, 1962, pp. 201 to 206).

This arrangement has a number of disadvantages, the main being that there is always one

so large number of blades at the same time on the Strikes or dips into the water surface. This can cause considerable torsional vibrations occur which are caused by relatively high impulse bursts when the blades hit.

The invention is based on the object, through an improved arrangement of the ventilation elements a reduction in the vibration load on the rotor and, at the same time, an improvement in the gas input to reach.

This object is achieved in a device of the initially described type according to the invention characterized in that for at least one Tei ¹ of each axially adjacent ventilation elements in each case a ventilation element against

a ventilation element lying next to it or the next but one by one compared to the angular division the star is offset by a small amount of angle. By the arrangement according to the invention achieves that at most a very small number of aeration elements simultaneously on the water surface hits or dips into the water. At the same time, a very important, if necessary, takes place ! OOfold reduction of the individual shock pulse with a corresponding increase in frequency of the

individual immersion processes. This significantly reduces the risk of torsional vibrations, whereby, in turn, all torsionally stressed components, such as clutches, gears and bearings, can be built more easily or be spared.

It was also surprisingly found that by means of the device according to the Invention can achieve a considerable improvement in the gas input, since the individual lenticular

shaped gas bubbles, which are formed when the ventilation elements strike one after the other at a high frequency, are very small and thereby a more fine-bubble gassing is achieved than before. Since the size and shape of the gas bubbles are very important, for example for the oxygen input, which increases significantly with an increase in the interface between air and water, better results are achieved with the device according to the invention than with the known devices. If the same oxygen input is achieved, the device according to the invention only requires less energy, so that the device is therefore economical.

prefer to work. In addition, there is the lower one F.nergiegevinn caused shock losses. 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 iu ". 'H of the invention is therefore suitable for ventilation rotors with very greet dimensions that 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 to I Om and more and a diameter of about 1 m and more without the stresses becoming too great in continuous operation.

It is particularly advantageous if the offset is approximately 3 '.

A particularly uniform immersion of the blades results when the angular amount is so it is chosen 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, al? O z. B. all ventilation elements in a row in each case 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 immersed in the other End of the rotor. So there is no interruption in the immersion frequency. Here you can also immerse several ventilation elements at a greater distance at the same time. Immersion sequences other than those described above can also be selected. Is essential for a uniform immersion that the immersion frequencies are the same and not about certain Intervals gaps occur because no ventilation elements are available for an immersion process stand. However, if this appears expedient for certain reasons, the Immersion frequency vary, which is possible without the aforementioned gaps occurring.

As is known, the aeration rotors not only bring air into the water, but at the same time cause the water to circulate in the aeration basin. In the known devices, the circulation takes place perpendicular to the rotor axis. If the ventilation elements are displaced according to the invention, the circulation no longer takes place perpendicular to the rotor axis, as in the case of the known rotors, but at a more or less large angle to the perpendicular. This can be advantageous in many cases, namely if not only a circulation is to 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 to improve the mixing of the basin contents, especially to intensify the exchange of the various more or less gas-laden liquid layers in aeration basins, in which the liquid is returned horizontally in the manner of an aeration system. The liquid is then not only circulated through such a circulating basin, 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, if two ventilation rotors are driven simultaneously by a drive unit S, which is arranged between these two rotors. Arrange the rotors in each leg of the circulating basin and operate them in opposite directions. In order to then achieve a continuous helical flow, the blades of both rotors will advantageously be offset in the same direction.

According to the invention you can now the type and Exactly control the size of this circulation, namely by the fact that the ventilation elements in one

'5 individual length sections of a rotor or a ventilation system consisting of several rotors are offset in the opposite direction. This creates a kind of "sweep" of the rotor. The circulation then takes place at both ends

so of the rotor in different directions, so that also, for example, when there are diverging currents occur, otherwise non-circulated parts at the edge of the pool can also be detected. Bc-i converging circulating currents can be achieved that the pool walls are relieved and intensive mixing takes place in the middle of the pool. An arrow can also compensate for the axial thrust in the rotor that occurs when there is a helical flow of liquid is produced.

When using two coaxial rotors, in particular with a common drive unit arranged in between are preferred the ventilation elements on the rotors are offset in opposite directions. This anora tion has the same effect as if a symmetrical »sweep« of a continuous rotor he follows. It is also possible in this way to avoid too little circulation in front of the drive unit he follows.

An asymmetrical "sweep" can be achieved by making the length sections with opposite directions Directions of displacement have unequal lengths. This results in 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. However, cases are of course conceivable in which it is expedient to relocate only some of the ventilation elements or, for example, to carry out an offset by different angular amounts, so that, for example, a lower circulating flow arises in the middle of a rotor than at the ends. Finally, according to the invention, the direction of the offset can also be more than e ^; Change n times. This then creates a number of diverging and converging circulating flows, which cause an excellent mixture in the circulating basin.

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

F i g. 3 shows ventilation elements for the rotor of FIG. 1 ;

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 e.g. 15 ° to each other

F i g. 5 is a section through a circulating pool,

according to Fig. 3. According to the invention, those Belüf-

The ventilation device according to the invention 5 processing elements, each of the next but one axis

consists of a drive motor 1 which is assigned on a vertical plane, that is to say in FIG. 2

Column 2 with a gear (not shown) attached, for example, the ventilation elements 7, 7 ', 7 "or

is brought. The motor drives via a column 10, 10 ', 10 "offset by 2.5 ° to each other,

attached, not shown gear one and that seen in Fig. 2 from left to right,

Achszapfcn 3 for a hollow shaft 4. The hollow io upwards.

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

ment S connected. At its end it is in a 2.5 ^l come the ventilation elements of the cntsprc-

Repository 6 stored. The hollow shaft is equipped with corresponding rows in the thirteenth vertical axis

Ventilation controls, e.g. B. 7, 8.9 (Fig. 3). To lie back in the same position as

One can manufacture very large ventilation rotors, 15 the ventilation elements in the second axis-cross section of which the hollow shaft has a diameter plane. However, there is then in each case a shift that takes place more than a quarter of the entire opening by one row, so that the dimension of the ventilation rotor is therefore equal to. The ventilation element 8 * in the thirteenth level can advantageously occupy the diameter of the hollow shaft 300 in the position of the ventilation element 10 in the second up to 400 mm and in particular 350 to 360 mm above ao level. Then contributes accordingly. 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. This way you can enter the third level without a toilet. After six times Vcrtcrcs a diameter of the rotor shaft of 1000 mm is set by 2.5 °, so a total offset and more can be achieved. With this diameter 25 of 15 ", so that the ventilation elements can be placed in the plug with a relatively small rotation zr, in which they get by in the respective number and still reach a plane to the next axis-inclined plane. The Belüfilinbringcn the required amount of sufficient processing elements in each of the twelfth level high circulation speed. Furthermore, on the following levels it is possible, together with these, to produce these Wrisp ventilation rotors, which incorporate a ventilation terminal on the previous level. Length of more than 4.5 m, in particular up to Advantageously, the equipment of the Ulm will now have, with possibly even larger overall shading selected so that the number of axis lengths can be achieved. parallel planes or the side by side angcord-

For each of a hollow shaft four and net stars, one can be a multiple of twelve, see above

the ventilation clamps, e.g. B. 7, 8, 9, existing 35 so that there are no gaps when hitting the Bc-

Provide a separate drive for the ventilation rotor. Ventilation clints could 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

Case is not only the repository 6 on one of the conditionally on the other side a good screw

hältigc 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 by a single motor 1, as shown in the angle by which the ventilation element c offset F i g. I is shown. The corresponding hollow shaft 4 'are also selected so small that the sum of these is then also connected via a coupling S' with a 45 angle over the entire length of the rotor to the Win-Achszapfcn 3 'of the gearbox and corresponds to the angle the other side of the ventilation elements is offset in a further, non-adjacent, axially perpendicular plane. If this latter angle is the same as in the present case with a hollow shaft 4 'with ventilation elements, the ventilation elements would be 15 ° as in the case of the hollow shaft 4 Levels to be offset by 0.3 ° each, arranged next to each other and the column 2 on a partition wall between these containers with corresponding tnenr or fewer stars, then change the angle accordingly,
be nice. The hollow shafts for the ventilation elements This applies to the FaTl that the offset can be driven over the entire length of the rotor by the same angular amount or in opposite directions, depending on the gear used. and takes place in the same direction. One can

The equipping of the ventilation rotors can also proceed according to FIG. 1 in such a way that

By means of flat iron or the like bent in a V-shape, the sedimentation can only be seen in the same direction

follow, which, as shown in bet 23, are connected to one another, for example up to the ventilation elements 13, the are and so the ventilation elements 7, 8 and 9 60 14, 15 makes. From then on the transfer takes place

form. in the opposite direction, in Fig. 1 in the right part

The left rotor, which is arranged in a plane perpendicular to the axis, is upward. The ventilation

Ventilation elements 7, 8, 9 are each with an element are thus arranged like an arrow, with the

Angle of z. B. 30 arranged in a star shape. In the ventilation elements 13, 14, IS a kind of cracks next Radial level are ventilation 65 give. With twelve Belöftongselements j-star

elements 10, H, 12 with the same angular spacing would in this case be on the left-hand side

arranged, but can be offset by half the Whikel ventilation elements at about 04 °,

amount offset so that the individual ventilation on the right side mn about 1. It would then

(ο

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. Jic Direction and strength of the currents of the university 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.

The individual ventilation elements can also be used to correct the flow and axial thrust Arrange them offset by a small amount of angle. The in F i g. 2 of the settlement shown Ventilation elements would then not be visible perpendicular 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.

The use of the device according to the invention with that shown in FIG. 4 is particularly advantageous Arrangement of aeration basins. In this case, eggs are between an inlet ditch 60 and a drainage ditch 61 circulation basin 62.

63, 64, 65 are provided. In this circulating tank are ventilation devices according to the invention arranged with their motors, for example 68, 69, 70, on the inner walls of the circulating basin are arranged. The ventilation rotors 71, 72 driven by these motors run then each time with the opposite direction of rotation, so that the water circulates through the circulating basin flows. In this case, a helical circulation can be achieved. this will caused by a displacement of the ventilation elements according to the invention, this displacement takes place on both rotors in the same direction, so see that an uninterrupted helical Upheaval is achieved. However, it can also

ao all the options described above can be used to achieve the most favorable circulation zi reach.

You can also or the ventilation rotor itself at an angle to the direction of rotation the walls of the aeration basin.

For this purpose 2 sheets of drawings

Claims (8)

Patent claims: 1. Device for introducing gases, in particular Air, in liquids, in particular waste water, with at least one circulating drive The rotor is mounted approximately horizontally above the liquid level and is connected to in the liquid immersed ventilation elements in the form of rods, blades or the like. Equipped is, which is star-shaped in planes perpendicular to the axis with a certain angular division, if necessary with the displacement of neighboring stars by simple fractions of the angular division, are thereby marked e t that for at least some of the ventilation elements that are adjacent in the axial direction there is one ventilation element (7, 10) with respect to a ventilation element lying next to it or next to it in the axial direction (7 ', 10') offset by a small angular amount compared to the angular division of the stars is. 2. Apparatus according to claim 1, characterized in that the offset is about 3 °. 3. Apparatus according to claim 1 or 2, characterized in that the angular amount is so it is chosen that the sum of the angular amounts over the length of the rotor is equal to the pitch angle of a star or an integer Are multiples of that. 4. Device nac! Claim 1 to 3, characterized in that with the arrangement of two rotors (71 or 72) driven in opposite directions in each leg of a circulating basin (62 to 65) the ventilation elements (7, 8, 9 or 10, 11, 12) of both rotors in the same direction are offset. 5. Apparatus according to claim 1 to 3, characterized in that the ventilation elements (7 to 9 or 10 to 12) in individual Lengths of a rotor or a ventilation system consisting of several rotors are offset in opposite directions. 6. Apparatus according to claim 5, characterized in that when using two coaxial rotors and in particular with a common one arranged between them Drive unit (1) the ventilation elements (7 to 9 or 10 to 12) on the rotors in each case are offset in the opposite direction. 7. Apparatus according to claim 5, characterized in that the length sections with opposite Directions of displacement have unequal lengths. 8. Apparatus according to claim 5 or 7, characterized in that the direction of the offset changes more than once.