CH631686A5 - Process for preparing a substantially homogeneous lime water solution - Google Patents

Description

The invention relates to a method for producing an essentially homogeneous lime water solution for use in the purification of waste water, a lime slurry being used as the starting material for the homogeneous lime water solution.

The invention has for its object to enable lime water treatment that fully utilizes the flake-forming properties of the lime, so that the smallest possible amount of lime has to be added in order to achieve optimal flake formation.

This object is achieved according to the invention in that the lime slurry is introduced into the lower part of a room in which it is conducted upwards and discharged at the upper part, the lime slurry being passed between lamellae during their upward movement, the lower parts of which filter the rising lime slurry Form sludge zone and the upper parts of which form a clarification zone in which the finer particles are separated.

In this way, the annoying carbonate formation, which forms deposits on mechanical equipment, basins, channels and pipes, is to be prevented. In addition, the residual content of calcareous particles in the outflowing, purified water should be kept extremely low.

The invention is described in more detail below with reference to the drawing illustrating an apparatus for carrying out the method. Show it

1 schematically shows a complete sewage treatment plant with the device for carrying out the process,

Fig. 2 in. ein.eta.en and on a larger scale a section through the actual device, i.e. a lime water heater, and

Fig. 3 shows the same device in plan view.

The sewage treatment plant shown in Fig. 1 consists of six successively attached pools 1-6, through which the water to be cleaned flows in sequence. The basin

I includes a sand trap and a mechanically cleaned rake. The basin 2 is an aeration basin to which activated sludge is added. The basin 3 is an intermediate sedimentation basin. The lime water solution prepared by means of the proposed method in the device designated 7 is added to the basin 4. 5 is a flocculation tank and 6 is a flotation tank from which the purified water is removed. The wastewater treatment plant can of course be modified in a number of ways without affecting the process.

The device 7 consists of a lime dissolver 8 and a lime water maker 9. The lime dissolver 8 comprises a dissolving container for dissolving dry, extinguished or non-extinguished lime. In this container, an agitator 10 mixes the lime with the dissolving water supplied. The outflowing, purified waste water (pH 10-12), biologically cleaned waste water or tap water can be used as the dissolving water. The amount of dissolving water is said to be about

II water per 1.7 g of lime.

From the dissolving tank 8, the lime slurry is passed to the actual lime water maker 9, into which it is introduced centrally through a pipe 11 into the lower part of a conical space 12, which serves as a lime sludge bag. The lime slurry is passed upwards between a number of lamellae 13 and 14, after which it is delivered to channels 16 via overflows 15.

The slats 13 and 14 are of varying lengths. In the trap illustrated in the drawing, every other lamella 13 is long, while the lamellas 14 in between are short. The slats 13 have a length of 2 m and are arranged at a mutual distance of 15 cm, while the slats 14 are only 1 m long and are also arranged at a mutual distance of 15 cm.

The only the long slats 13, i.e. the lower half of the plate pack, the comprehensive zone, is dimensioned such that a stationary sludge zone is created in this area. The sludge zone filters the upstream lime slurry. The upper lamella area with twice the number of lamellae 13 and 14 forms a clarification zone in which the finer particles are separated during the upward movement of the lime water.

The sludge zone for the rising lime sludge is thus formed in that the surface loading of the fins 13 in the lower part is significantly higher than the surface loading of the fins 13 and 14 in the upper part, which includes the clarification zone. Thus, the surface loading of the fins 13 in the lower part comprising the sludge zone is approximately twice as high as the surface loading of the fins 13 and 14 in the upper part comprising the clarification zone. The surface loading of the slats 13 in the lower part comprising the sludge zone is expediently 2.5 m3 / m2 / h, while the surface loading of the slats 13 and 14 in the upper part comprising the clarification zone is expediently approximately 1.25 xn3 / m2 / h. The surface loads are calculated based on the projected areas of the slats.

The sludge following the slats and collected in the bottom cone 12 is about 10-15 times denser than the sludge water in the sludge zone and takes up about a tenth of the space between the slats 13. The one in

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Bottom cone 12 of lime sludge collected is pumped to a certain extent back to the lime dissolving tank 8, while the remaining lime sludge is led downward via slopes to the units in front of the point of addition of the lime water to the waste water (for example the pretreatment plant) of the sewage treatment plant 5. The amount of lime sludge pumped back to the dissolving tank 8 can be practically calculated in each individual case, including due to the amount of sand and impurities in the lime used. With 17 a lime slurry pump is called, the lime via the line

18 returns to the lime dissolving tank and via the line

19 returns the lime to the pretreatment system. Lime is dosed at 20 and lime water solution is dosed at wastewater at 21.

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2 sheets of drawings

Claims (5)

631686 1. A process for producing a substantially homogeneous lime water solution for use in the treatment of waste water, wherein a lime slurry is used as the starting material for the homogeneous lime water solution, characterized in that the lime slurry is introduced into the lower part of a room in which it is directed upwards and is discharged at the upper part, the lime slurry being passed as it moves up between lamellae, the lower parts of which form a sludge zone which filters the rising lime slurry and the upper parts of which form a clarification zone in which the finer particles are separated. 2. The method according to claim 1, characterized in that the sludge zone for the rising lime sludge is formed in that the surface loading of the lamellae at the lower part is substantially greater than the surface loading of the lamellae at the upper part, which includes the clarification zone. 2nd PATENT CLAIMS 3. Method according to claims 1 and 2, characterized in that the surface loading of the slats on the lower part comprising the sludge zone is approximately twice as large as the surface loading of the slats on the upper part comprising the clarification zone. 4. The method according to claims 1 and 3, characterized in that the surface loading of the slats on the lower part comprising the sludge zone is approximately 2.5 m3 / m2 / h, while the surface loading of the slats on the upper part comprising the clarification zone is approximately 1 , 25 m3 / m2 / h. 5. The method according to claims 1 and 2, characterized in that the lime sludge leaving the lamellae, which sinks to the floor of the room, is wholly or partly recycled in order to be taken up by the lime sludge serving as the starting material.