CS204357B1 - Device for the biological purification of waste water with active spaces for aerobic activation and with separating space for the separation of activated sludge by the fluid filtration - Google Patents

Abstract

An apparatus for the biological treatment of waste waters comprises aerobic activation space (5 and 6) separation space (4) for separating activated sludge by fluid filtration, a bottom inlet (14) for the separation space and a channel (10) between the separation and activation spaces, both channel ends being connected with the activation space and between these ends with the inlet (14), the total area of a number of holes (12) connecting the upper channel end with the activation space (5) being smaller than one tenth the area of the inlet (14), the area of channel (10) in front of the connection to the inlet (14) being greater than ten times the total area of the holes (12). <IMAGE>

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plant for biological treatment of wastewater with activation spaces for aerobic activation and a separation space for separating activated sludge by fluid filtration, further with an entrance to the separation space at its bottom and the ends are connected to the • activation space and between these ends are connected to the entrance to the separation space.

In biological wastewater treatment, a certain load of activated sludge in the activation process taking place in the activation space is usually envisaged. Therefore, the greater the volume concentration of activated sludge in the activation, the greater the activation power at a given volume. The volume concentration of activated sludge is usually measured by the volume of activated sludge after half an hour of sedimentation, and can be conveniently expressed by the dimensionless value of the relative volume, i.e. the volume of sludge in the unit of activation volume. The higher concentration of activated sludge in the activation is achieved by separating the activated sludge from the purified water and returning the separated sludge back to the activation.

In a known device with separate separation and return of activated sludge after sedimentation by external recirculation, the volume concentration of sludge in activation depends on the relative size of the recirculation and on the degree of thickening of the recirculated sludge. However, with increasing recirculation and increasing degree of thickening of the recirculated sludge, the demands on the volume of separation increase. In terms of plant optimization, ie minimizing the total volume given by the volume of activation and separation volume, a degree of recirculation has been found to be most appropriate in fecal wastewater treatment in a practical application where the relative volume of activated sludge in activation is about 0.3.

In newer plants, where the separation of activated sludge from purified water by fluid filtration forms a single unit with the activation, the separated sludge is concentrated and returned to activation automatically and therefore recirculation is not visible and can be difficult to measure. The achieved relative volume of activated sludge in the activation of these plants again under normal load in faecal waters is around 0.3.

A device of this type has separate activation and separation spaces in a common tank, the separation space having an inlet in its lower part and extending upwards. In the activation space, prior to entering the separation space, a wall is formed which forms an interconnecting channel which is connected at both ends to the activation space and is further connected thereto to the entrance to the separation space in which the sepa204357 race takes place. Purified water flows into the activation, where there is a very intense flow caused by the aeration system. By means of said channel, a current is separated from the activation flow, which, after passing through the channel, is returned to the active cuff. This stream is directed from top to bottom and the activation mixture is withdrawn from it for separation. The withdrawal takes place by entering the separation space, where the activation mixture stream is turned upwards. · The separated activated sludge is then returned to the said stream via the same input, which is then returned to the activation. , '

It is an object of the present invention to achieve a substantially higher volumetric concentration of activated sludge and thus a significantly higher throughput with the same size. According to the invention, the total flow area of the inlet openings connecting the upper end of the channel to the activation space is less than one-tenth the size of the flow area of the entry into the separation space and the flow area of the channel before it is connected to the entry into the separation space. greater than ten times the flow area of the inlet openings.

Another feature is that the total flow area of the inlet openings is one tenth to one thousandth of the size of the flow area of the inlet.

An exemplary embodiment of the device according to the invention is schematically shown in vertical section in the accompanying drawing. *

In the longitudinal tank with the peripheral walls 1 and the bottom 100 there are inclined walls 2 and 3, which divide the longitudinal tank into a separation space 4 and into the activation spaces 5 and 6. The lower inclined wall 7 is connected to the inclined wall 2. greater inclination than the inclined wall · 2. Vertical walls 8 and 9 adjoin the lower edges of the inclined wall 3 and the lower inclined wall 7 · The vertical walls 8, 9, the lower inclined wall 7 and the lower part of the inclined wall 2 form a channel 10. the vertical wall 9 is connected to a prismatic sludge outlet 11. In the connection of the lower inclined wall 7 to the inclined wall 2, inlet 12 are formed in the lower inclined wall 7 connecting the upper end of the channel 10 to the activation space 5. The lower end of the channel 10 is connected to the activation space 5 through an outlet 13 formed between the lower end vertical walls 8 and prismatic discharge · 11 sludge. . .

The lower edges of the inclined walls 2 and 3 form an inlet 14 into the separation space 4. The flow surface 15 of the channel 10 before being connected to the inlet 14 into the separation space. 4, is formed between the lower edge of the inclined wall 2 and the opposite portion of the lower inclined wall 7. The total flow area of the inlet openings 12 is less than 10% of the area of the inlet 14, preferably in the range 10% to 0.1%; the flow area 15 of the channel 10 before being connected to the inlet 14 is greater than ten times the total flow area of the inlet openings 12 connecting the upper end of the channel 10 to the activation space 5. Above the inlet 14 there is a bubble trap 16 with compartments not shown outside separation space

4.

Purified water supply 17 leads into the activation space 6. In the upper part of the separation space 4 there are known collecting troughs 18 for the discharge of purified water. The activation spaces 5, 6 are connected to the square-shaped sludge outlet 11, the discharge openings 19 and are equipped with known aeration elements 20. The longitudinal tank with peripheral walls 1 is terminated at both ends in a direction perpendicular to the section shown. channels connecting both activation spaces 5 and 6.

The described apparatus operates as follows:.

Purified water flows through the inlet 17 into the activation space 6. By the action of the aeration elements 20, the activated sludge water is aerated in the activation spaces 5 and 6. Aeration produces a cylindrical flow in the activation spaces 5 and 6 and by means of said oblique channels (not shown), the activation mixture is transferred from the activation space 6 to the activation space 5 and vice versa. Part of the water from the activation space 5 is withdrawn through the inlets 12 into the channel 10 by this flow, where it generates a downstream current which flows through the outlet 13 into the activation space 5. From this stream in the channel 10 a part of the activation mixture is withdrawn through the inlet 14 In the separation space 4, the purified water is then separated from the activated sludge by fluid filtration and discharged through collecting channels 18.

The activated sludge separated from the purified water falls back through the inlet 14 into the downstream stream in the channel 10, through which it is returned via the outlet 13 to the activation space 5.

Because the total flow area of the inlet openings 12 with the upper end of the channel 10 with the activation space 5 is less than 10% of the flow area of the inlet 14 into the separation space 4, the flow rate in the channel 10 is transferred from the flow in the activation space 5 is greatly reduced. Since the flow area 15 in the channel 10 before entering 14 into the separation space 4 is greater than ten times the total flow area of the inlet openings 12, the flow velocity in the channel 10 before entering the separation 14 is further slowed.

Due to the effects of both of these effects - limiting the flow intensity in the channel 10 and slowing down the flow rate of this flow before entering 14 into the separation space 4 - the flow in the region of the separation entrance 14 is so mild that it does not create undesirable eddy currents entry. In fact, the disturbing eddy currents in the region of the inlet 14 sweep and dilute the concentrated activated sludge returning from the separation space 4 to the stream in the channel 10, making it impossible to achieve a high activated sludge concentration by volume. Suppression of these disturbing currents by the described mechanism therefore makes it possible to significantly increase the concentration of activated sludge returned from separation to activation and thus to increase the concentration of activated sludge returned from separation to activation, thereby increasing the activated sludge concentration in activation zone 5. the sludge passes into the activation space 6 as described above.

The invention is not limited to the described example of apparatus; can be used equally well, for example, in a concentric tank configuration.

In particular, the device according to the invention has the advantage that, when used in existing systems with fluid filtration separation, it is possible to achieve approximately twice the volume concentration of activated sludge and thus to significantly improve the quantitative and qualitative parameters of water purification.

Claims (3)

OBJECT OF THE INVENTION 1. Equipment for biological wastewater treatment with aerobic activation and separation space - for separation of activated sludge by fluid filtration, as well as entry into the separation space in its lower part and interconnection of separation space with activation space by means of a channel on both is connected to the activation space between the ends and connected thereto to the entrance to the separation space, characterized in that the total flow area of the inlet openings (12) connecting the upper end of the channel (10) to the activation space (5) is less than one tenth the flow area of the inlet (14) of the separation space (4) and the flow area of the channel (10) before it is connected to the inlet (14) of the separation space (4) are greater than ten times the flow area of the inlet openings (12). Device according to claim 1, characterized in that the total flow area of the inlet openings. (12) is one tenth to one thousandth of the size of the flow area of the inlet (14). Device according to claim 1, characterized in that the flow area of the channel (10) is ten times the area of the inlet openings (12) before it is connected to the inlet (14) into the separation space (4).