DE2349310C3 - Sewage treatment plant - Google Patents

Description

The invention relates to a sewage treatment plant, consisting from a primary clarification room, a digestion room and one from a secondary clarification room through a den Cross-section of the secondary clarification room, baffle plate narrowing downwards, partially separated aeration basin, in which near the lower edge of the guide plate, which is arranged at a distance from the container bottom, is angled upward running suction shaft for an aerator opens.

Such a sewage treatment plant is known from US Pat. No. 3,028,011. The suction shaft of this well-known system however, has a constant cross-section and ends with its upper edge approximately in the middle of the container. The ventilation takes place here by means of a compressed air lifter, which increases the rate of ascent of the The air bubbles rising in the intake duct are unnecessarily large, which contributes to the desired renewal of the boundary surface is disadvantageous for the introduction of oxygen.

The object of the invention is to avoid these disadvantages for optimal circulation and for to ensure an adapted oxygen input.

This object is achieved according to the invention in that the intake duct extends up to the aerator has upwardly widening cross-section and above the aerator in a vertically arranged Ventilation shaft of a large cross-section compared to this merges, and that the ventilation shaft through a trailing edge provided a little below the water surface with the aeration basin in Connection.

Due to the expansion of the cross section of the intake duct, the gravity will be the result Settling sludge parts, which are returned to the smallest possible area due to the construction of the sewage treatment plant are kept in suspension, and at the highest possible speed. On the other hand, decreased This training increases the rate of ascent of the water to such an extent that the amount of water slowly rises in the ventilation shaft, causing a high oxygen input as a result of increasing Interface renewal can be achieved, which in turn is only possible if the speed of the water compared to the air speed is low This interaction is obtained through the separate ventilation shaft with a fraction of the Amount of water which, in comparison, is required in the known system is achieved in this way at the same time a good, constant oxygen diffusion and the effect that the sludge particles settle out be kept in suspension.

In comparison to the known system, this means that it can be put into operation with a significantly lower amount of equipment Amount of water to achieve the effect of the activated sludge process.

Using an exemplary embodiment, the invention is illustrated in the drawing and in the following explained; shows in the drawing

F i g. 1 shows a schematic section through the sewage treatment plant according to the invention,

F i g. 2 is a plan view of the plant.

The raw water reaches the primary clarification room via inlet 1 of the steel tank designed as a clarification tank 2. The settling sludge slides over an Emscher channel 3 into the septic tank 4. Over one Slot 11, the water enters the aeration basin 5 and via a further slot 12 into the secondary clarification room 6, where it runs over the runoff edge 10.

The wastewater is in the aeration basin 5 via an aggregate that consists of the intake 8 7 and an aeration shaft 8 consists, ventilated

In order to get by with the lowest possible circulation rates and, on the other hand, the necessary To ensure oxygen entry, the rooms of the aeration basin 5 and the secondary clarification room 6 are designed in such a way that that the sludge settles on as small an area as possible. For this purpose, the cross-section is on The transition where the sludge occurs is kept small. At this point the sludge is drawn through the suction shaft 7 sucked off. The ventilation duct 7 expands at the point where a fan 19 is used for ventilation (Aerator 13), to such an extent that the rate of ascent of the water is reduced so much, that the amount of water in the ventilation shaft 8 rises slowly, so that the rising in the water mixture Air bubbles have the longest possible dwell time and thus a more frequent renewal of the boundary surfaces have optimal oxygen delivery capacity.

By changing the Aufste ^; At the same speed, the incoming air is swirled with the inflowing water, so that the efficiency of the compressed air lifter is increased. The trailing edge 9 of the ventilation shaft 8 lies below the water level. This has the consequence that the delivery height of the compressed air lifter is limited to the necessary minimum in the interests of good efficiency. The resulting outflow cross-section 14 is selected to be so large that there is a low delivery height of the compressed air lifter, but the rate of ascent is still high enough. that air bubbles are drawn into the aeration basin and the oxygen input is improved by swirling and rising again.

At the air supply line 15 of the aerator 13, a small amount of air is branched off, which is below the Emscherrinnenfläche 16 is directed. An air cushion builds up in space 17, which periodically occurs at edge 18 enters the primary clarification room 2 through a surge of air, in order to arise on the surface of this basin Destroying floating sludge and causing it to sink.

For this purpose I sheet drawings

Claims (1)

Claim: ^ " ^/ Sewage treatment plant, consisting of a primary clarification room, a digestion room, as well as one of a final clarification room through a cross section of the final clarification room downwardly narrowing baffle partially separated aeration basin, in which near the at a distance from the bottom of the container, the lower edge of the baffle is an upwardly sloping edge Suction duct for an aerator opens out, characterized in that the suction duct (7) extends up to the aerator (13) has upwardly widening cross-section and above the aerator (13) in a vertical arranged ventilation duct (8) merges with a large cross-section in comparison, and that the ventilation shaft (8) through a trailing edge provided a little below the surface of the water (9) is in communication with the aeration basin (5).