DE9112947U1 - Device for centric feeding of round basins with waste water - Google Patents

Description

Device for centric loading of

Round pool through waste water

The invention relates to a device for the centric feeding of circular basins with waste water by means of a vertical pipeline.

In the field of wastewater technology, it is well known that round tanks with considerable diameters are used in municipal sewage treatment plants for primary treatment or as secondary treatment tanks for sludge separation after the aeration. What these round tanks have in common is that the inflow in the center of the round tank takes place via a pipe leading vertically into the tank. The jet is then diverted horizontally by constructions of various designs in order to achieve the most even, radially symmetrical outflow into the round tank. However, all of these devices have the disadvantage that they are very complex to construct and no targeted guidance of the radial flow is possible in order to compensate, for example, for possible density differences that exist due to the differences in temperature and solids content between the jet and the external flow.

The technological background is that the density of the fluid is changed by the sedimentation of the sludge particles in the tank. The fluid is fed via a so-called "central structure". After the fluid exits from the central structure into the outside area, the density differences of the suspension compared to the clear water come into effect.

In the radial direction, the geometry of the circular basin causes a strong deceleration of the flow in the direction of flow. Since delayed movements are generally very sensitive to disturbances and there is a tendency to detachment

, the careful guidance of the radial flow is of great importance. It should be noted that when flowing out into the outer area, the solid-laden flow is deflected downwards in accordance with its higher density (Prof. Valentin, Chair of Hydraulics and Hydrology, Technical University of Munich, Dept. 50, 1988 ISSN 0343-1177).

The invention is based on the object of creating a structurally simple device for the central feeding of circular basins with waste water, in which the deflection of a vertical jet and a uniform radially symmetrical distribution of the flow are to be achieved. The new device should also be able to counteract the fact that fluid jets loaded with solids are deflected downwards in accordance with their higher density when flowing out of the device into the circular basin.

This is achieved according to the invention in a surprising way in that a centrally inserted horizontal circular control disk in the area of the transition from the vertical pipe to a seamlessly continuously adjoining trumpet-shaped widening, whereby the control disk forms an annular gap with the inner circumference of the edge.

It is not overlooked that devices and processes are known that use the so-called Coanda effect to give a gas or liquid jet a different direction. However, this is not the case in wastewater technology.

As is well known, the density at the inlet of these middle structures is higher than the density later on. However, due to the higher density, the flow goes downwards and stirs up the deposited sludge again. In practice, only an efficiency of 60% was achievable instead of the required 80%. Here, the measure according to the invention means

-3-a surprising step forward.

The advantages achieved with the invention are in particular that the deflection and guidance of the jet after flowing out over the annular gap, at the edge of the trumpet-shaped or torus-like body, takes place using the Coanda effect and is therefore precisely predictable. The exit speed over the entire circumference of the annular gap is constant and depends only on the dynamic pressure. Furthermore, the expansion of the jet due to the turbulent mixing of the outer flow, the desired reduction in jet speed and the separation criterion at the edge of the trumpet-shaped or torus-like body are predictable.

Trumpet-shaped means a ring-shaped body that, for example, diverts from the pure vertical in a continuous transition to the horizontal or almost horizontal. The Coanda effect at the outlet means that the flow remains attached to the edge.

According to an advantageous embodiment of the invention, the direction of the jet flowing into the round basin can be specifically influenced by varying the deflection angle ß of the trumpet-shaped or torus-like body, since the separation point is precisely specified. This makes it possible to compensate for density differences that exist between the jet and the outer flow due to differences in temperature and solids content. With appropriate dynamic pressure and an appropriate ratio of the torus radius or the radius R of the trumpet-shaped body to the width of the ridge gap, deflections of up to 180° can be achieved at the edge of the trumpet-shaped body.

It is important that the device according to the invention makes it possible to change the exit area of the annular gap by replacing the control disks. This makes it possible to subsequently make adjustments to operational changes in a simple manner. A suitable design is given in further subclaims. It is advisable to provide a lamellar ring arrangement as an attachment over the entire circumference of the trumpet-shaped body at equal intervals and at a certain angle to the direction of flow. This is a particularly simple and reliable way of imparting an additional tangential component to the jet in addition to the radial component. This primarily lengthens the flow path in the round tank, which leads to better sedimentation in the clarification tanks and the so-called teacup effect.

In addition, in the design with the slat attachment, the size of the tangential component can also be influenced by uniformly rotating all slats by a predetermined angle to the flow direction.

In a further embodiment of the invention, the device can be rotated by 180° around its horizontal axis. This is especially the case if, for example, for operational reasons, the supply line is introduced vertically into the round basin from above instead of from below.

The invention also relates to a method for feeding round tanks. This method is characterized by the fact that the Coanda effect is used to deflect and guide the vertical feed jet into the horizontal and to bring about a radially symmetrical distribution.

According to a special embodiment of the invention, work can also be carried out rotated by 180°.

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&Igr; Example embodiments of the invention will now be explained in more detail with reference to the accompanying drawings. These show in:

Fig. 1 is a plan view of a first

embodiment;

Fig. 2 is a sectional side view of Fig. 1;

Fig. 3 to 6 Variation and supplementary possibilities to

the embodiment shown in Fig. 1.

In the embodiment of the invention shown in Fig. 1 and 2, a trumpet-shaped or torus-like body (4), hereinafter referred to as a trumpet-shaped body, is provided. To create the annular gap (3), a circular control disk (2) is inserted at the level of the flange, the diameter of which must be smaller than the inner diameter of the vertical pipe (2). The control disk (2) is attached to a solid cylinder (1) located centrally in the vertical pipe (7), which also acts as a jet splitter when the flow is in the direction of the arrow. The solid cylinder (1) is in turn attached to the vertical pipe (7) via four centering rods (5). A curvator effect occurs. Jet separation inevitably occurs at a deflection of around 85°.

Fig. 3 and 4 show an embodiment in connection with a swirl chamber (9). The waste water is fed into the swirl chamber (9) via the horizontal pipe (10) in the direction of the arrow. The spiral flow thus generated leaves the swirl chamber (9) via the vertical pipe (7). The spiral movement of the flow is also maintained after exiting via the annular gap (3) and thus causes an additional tangential component to be present after the vertical flow is diverted to the radial component at the edge of the trumpet-shaped body (4). This creates a

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Spiral flow sets in and the path becomes larger, the flow speed is greatly reduced, for example from 1 m/sec. to 10 cm/sec. The arrangement of the swirl chamber compensates for the distortion of the pipe flow through the velocity profile.

Fig. 5 and 6 show a modified embodiment of an attachment (11; 12) on the trumpet-shaped or torus-like body. This is provided with such lamellae (12) on the tear-off edge (4), where the flow separates at the edge of the trumpet-shaped body (4). The lamellae (12) are distributed at equal distances around the tear-off edge (8) of the trumpet-shaped body (4) and are held at the top by a ring (11) and at the bottom by quivers that are attached to the tear-off edge (8) of the trumpet-shaped body (4). This gives the jet an additional tangential component in addition to the radial component. One consequence is that the flow path in the round basin is extended. This in turn results in better sedimentation and leads to the so-called teacup effect. The slats (12) can be rotated evenly, for example by a predetermined angle, to the direction of flow, whereby the size of the tangential component can also be influenced.

Regarding the definition of the torus, it should be added that it is a body of revolution that is to be regarded as having arisen from a convexly curved continuous space curve, whereby "trumpet-shaped" is to be regarded as a simplified definition.

Claims (8)

-1- Anton Felder, Schlotthauerstr. 5, 8000 Munich 90 F 1588 - Lw/Pi Device for centric loading of Round basin through wastewater Expectations i. Device for the centric feeding of round basins with waste water by means of a vertical pipeline, characterized by a centrically inserted horizontal circular control disc (2) in the area of the transition from the vertical pipeline (7) to a seamlessly continuously adjoining trumpet-shaped widening (4), whereby the control disc (2) forms an annular gap (3) with the inner circumference of the edge. 2. Device according to claim 1, characterized in that the trumpet-shaped expansion is a separate trumpet-shaped expanding body (4) which is connected to the pipeline (7) via a flange (6). 3. Device according to one of the preceding claims, characterized by utilization of the Coanda effect, such that a deflection of the vertical beam into the horizontal as well as a horizontally symmetrical distribution can be brought about. 4. Device according to one of the preceding claims, characterized in that the deflection angle (ß) of the trumpet-shaped or torus-like body (4) is designed to be variable. -2- 5. Device according to one of the preceding claims, characterized by control disks (2) of different size and shape for changing the exit area of the annular gap (3) 6. Device according to one of the preceding claims, characterized in that over the entire circumference of the trumpet-shaped or torus-like body (4) at equal intervals and at a certain angle to the flow direction, attachment blades (12) are arranged in a ring arrangement. 7. Device according to one of the preceding claims, characterized in that it is acted upon by a per se known upstream swirl chamber (Fig. 3; 9). 8. Device according to one of the preceding claims, characterized by an operating position rotated by 180° about the horizontal axis of the device, wherein the loading takes place from above.