CS249673B1 - Method of flocculation and separation in flocculent cload in water treatment plants' clarifiers and equipment for its application - Google Patents

Abstract

A method for flocculating and separating in a cloud of flocs, during which flocs are enlarged and thickened by a common effect of hydrodynamic and physical-chemical forces in a concentrated suspension at a non-turbulent flow in water cylinders. Water cylinders rotate between a sinusoidally rising vertical flow of water and walls. The average rate gradient is constant or decreases in the direction of flow. The clarifying effect is achieved by adding an auxiliary coagulant and by a periodically repeated change of hydrodynamic forces in the liquid. The space of the cloud of flocs is divided into partial sections by means of a system of vertical submersible walls, which are undulated sinusoidally or with sharp edges, or are flat and provided with deflectors. The upper edge of the walls projects above the overflow edge for sludge. Geometrical shapes of walls and their surfaces, as well as dimensions of defectors are dependent on the width of the partial section. <IMAGE>

Description

BACKGROUND OF THE INVENTION The invention relates to a process for flocculating and separating in a flocculant cloud in a water treatment plant, and to an apparatus for carrying out it in a flocculant clarifier provided with a raw water inlet with precipitators and and an overflow edge of the sludge separating the flake cloud space from the sludge thickening space provided with sludge removal means.

So far, the flocculation and separation in the flocculent cloud in the clarifiers of the water treatment plant is carried out by passing the flocculent water suspension obliquely upward through the inclined spaces, limited by the lower inclined wall and the upper inclined wall.

The devices required for this are provided with deflectors on the underside of the upper inclined wall. These deflectors support flocculation ·

The upper side of the lower inclined wall is smooth. The formed flakes drop onto it and slide downwards against the flow direction of the suspension. When the flakes reach the bottom edge of the bottom sloping wall, they are entrained by the upward flow of the slurry upwards ·

The clarification effect is enhanced by periodically repeating the suspension flow rate. ·

In this way, and with this device surface is achieved. zaHžení ^{C RIC} 15-20 mv "^ ·

The disclosed method and apparatus have numerous disadvantages. The inclined spaces are used for floatation only or in the volume of water at the bottom inclined wall sludge decreases. The deflectors are located only on one side of the sloping slope so that they do not act in its entire volume. In the case of devices with the installation of inclined walls in a rectangular tank of the clarifier with vertical walls, unused spaces arise.

These disadvantages are eliminated in the flocculation and sepa-

-2-. 249 873 of the flake cloud in the water treatment plant of the present invention, which is characterized in that the flake water suspension is introduced from below into the vertical flat partial spaces of the flake cloud where it is not allowed to flow ^; the vertical layer of the rising slurry corrugates by imparting side impacts alternately on both sides of the layer and on. concave side of the suspension layer waves are formed by rotating horizontal suspension cylinders for at least two superimposed waves in which the flakes are thickened and enlarged, whereupon the upper portion of the suspension layer is allowed to fall outside the overflow compartments below the suspension level in the compartments ·

An underlying device for carrying out the method according to the invention is that the flake cloud space is divided by a plurality of vertical burst walls into sub-compartments, means on both sides of each sub-compartment are arranged to undulate the vertical slurry layer in the sub-compartment.

The advantage of the flocculation and separation method in the flocculant cloud according to the invention is that the undulating trajectory of the flowing suspension causes the formation of horizontal suspension cylinders on both sides of the ascending suspension stream and thus more intensive flocculation and separation of flocs. walls with means for crimping the vertical layer of the suspension are easy to install in tanks with rectangular and circular plan views, while the tank space is fully retracted.

In the apparatus of the invention can be obtained using lezítběho srážedta povrctov ^ ^ o ^ ERA load 15 m> ^h "^ and adding ^the auxiliary oagulantu and ²⁰ MH" \

Exemplary embodiments of the flocculation and separation process in a flocculant cloud in water treatment plants are described below, and examples of the apparatus for carrying it out are shown in the drawings, Figs. 1c shows the same device in a vertical cross-section, FIG. 2a. A plan view of the device with a cylindrical tank,. Fig. 2b shows the same device in a transverse axial vertical section, obi? 3 normal walls of the device sinusoidal undulating, fig. 4 normal walls of the device curled in a sagging pattern;

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The process of flocculation and separation in the flocculent cloud in clarifying water treatment plants according to the invention is carried out by introducing a slurry of water with flocculant into the flat partial spaces of the flocculent cloud from below, in which the slurry is allowed to rise upwards. · Horizontal, rotating suspension cylinders are formed on the concave side of the suspension layer waves, in which the precipitated flakes are thickened and enlarged. These rollers are formed with at least two waves one above the other, but it is advantageous to produce more of them, up to fifteen. Thereafter, the sludge from the slurry is allowed to fall outside the partial spaces of the flocculent cloud on the overflow side lying below the water level in the partial spaces.

The rising slurry can be imparted to a rate whose mean gradient remains constant. In the case of brittle flakes, however, it is preferable that the gradient of the slope rate of the slope decreases upwards in the range of G = 200 to 20 s.

The non-vortex flow of the suspension is obtained when the dimensions of the individual partial spaces of the snowflake cloud are selected so that the Reynolds number is less than 600 according to the equation

Re = ----- <600

Where Re is the Reynolds number, v is the mean sequential speed,

R is the hydraulic radius of the partial space and is the kinematic viscosity of the suspension.

Some of the flakes escape from the cylinder and advance up to the next suspension cylinder where the process is repeated.

Binding between the flakes can be enhanced by adding an auxiliary coagulant. This coupling can also be enhanced by periodically varying the hydrodynamic forces in the suspension at a frequency of n = 0.01 to 0.1 Hz, for example by means of pulsations caused by the movement of the pendulum paddle, alternating at the inlet of the flake cloud. These pulsations also aid in the sludge overflow from the flocculent cloud space into the sludge forging space, so that many of the flakes entrained in the treated water are small.

The clarifier according to FIGS. Ia, 1b, and 10o is formed by a rectangular tank, “4” 249 673 in the middle part of which is a flocculation space 2, provided with a raw water inlet 1 with precipitators. In the flocculation space 2 there are paddles 3 swinging towards the lower arrow from left to right and back.

At the bottom, the flocculation space 2 is provided with an outlet 4, shown as perforated piping in Figs. 1a and 1c.

The flake poppy space is divided by bursting walls 6 into sub-spaces 6, which are alternately provided with deflectors 7 on both sides, as means for corrugating a vertical suspension layer consisting of plates fixed by an upper edge and inclined at an angle of 45 ^° to 70 ^° from the horizontal. These plates may extend from 1/6 to 1/3 of the width of the partial space 10, the distances between the deflectors 7 on the same side of the partial space 5 being equal to 0.5 to 3 times the width of the partial space 60.

Below the upper edge of the steep walls 6 lies the overflow edge 8 for the sludge separating the compartments 5 from the sludge thickening space 11 from which the sludge duct 12 exits. At the top the clarifier is provided with treated water troughs 9 provided with a treated water outlet.

The design with cylindrical clarifier tank according to Figs. 2a and 2b is similar, only the bursting walls 6 are arranged in a fan-like manner, the overflow edge of the sludge 8 is formed by slits separately for each subspace 5. The partial cloud 6 is again surrounded by the sludge thickening space 11. The paddles 3 in the flocculation space 2 do not oscillate but rotate together about a vertical axis. The outlet 4 here is formed by the gap between the flocculation space 2 and the partial spaces 60.

Giant. 3 shows the burst walls 6, in which the means for corrugating the vertical layer of the suspension consist of a crimped corrugation of the burst walls 6. FIG. 4 then shows the angled corrugation of the burst walls 6. For all burrows 6, the corrugations are at the same level and are bent in the wall direction. Preferably, the section of one undulation wall of the flush wall -6 is equal to 2 to 6 times the width of the partial space 6 and the deviation from the common axis of the waves is equal to 1/4 to 1/2 of the width of the partial space 6;

The device according to the invention operates as follows:

Raw water with basic precipitants flows through inlet 1 into flocculation area 2 · Flocculation aids movement of paddles

3. The resulting slurry flows via exit 4 into the compartments 6 where a flocculent cloud is formed. Vertical suspension layer, rising -

249 673, with its partial spaces 2, impinge on the corrugating means thereof, in a corro- sive manner. 3 and 4 alternately on the flush wall 6 according to FIGS. right and left hand on the walls of the waves of their ripples. peaks extending from their partial spaces. 5 ·. As a result, the rising slurry ripples and horizontal, rotating slurry cylinders are formed on the concave side of the slurry layer waves in which the flakes are thickened and enlarged.

FIG. 5 shows the undulations of the downgrading suspension layer by means of deflectors 2 &apos;

In Figures 3 to 5 it is dashed between the normal walls 6. an undulating rising slurry stream and individual slurry cylinders are shown on the concave sides of the waves of the slurry stream.

Said process is epipened in at least two slurry cylinders one above the other, preferably their number.

The treated water flows through the troughs 9 and out of them through the outlet 10 »

The sludge from the surface of the flake poppy overflows over the overflow edge 8 into the sludge thickening space 11, from which this sludge is periodically discharged through the sludge pipe 12.

Equipment. according to the invention can also be used in the separation of water softening particles and bioflocculents.

Claims (11)

A process for flocculation and separation in a flocculent cloud in a water clarifier, characterized in that the flocculent water suspension is introduced from below into vertical flat partial spaces of the flocculent cloud in which it is allowed to flow non-vortexly upwards, in wherein the vertical layer of the rising slurry is corrugated by imparting side impacts alternately on both sides of the layer and on the concave side of the slurry layer waves forming horizontal rotating slurry cylinders, at least two waves above each other in which α® flakes thicken and enlarge, It allows the layers to fall outside the partial spaces on the overflow edge lying lower than the suspension level in the partial spaces. 2o The method of claim 1, wherein the rising slurry is imparted at a rate the mean gradient of which remains constant. Method according to claim 1, characterized in that the rising water is given a velocity whose mean gradient decreases in the direction of suspension flow in the range G = 200 to 20 s. 4. A method according to any one of claims 1 to 3, wherein the binding between the flocs is enhanced by the addition of an auxiliary coagulant. 5. A method according to any one of claims 1 to 4, characterized in that the bond between the flocs is enhanced by periodically varying the hydrodynamic forces in the suspension at a frequency of change of n = 0.01 to 0.1 Hz. 6. Apparatus for carrying out the method according to items 1 to 5 in a flake clarifier provided with a raw water inlet with precipitators and an outlet leading to an inlet cloud space provided at the top with a means for discharging treated water and a sludge overflow edge separating the flake cloud space. from a sludge thickening space provided with sludge evacuation means, characterized in that the flake cloud space is divided by a plurality of vertical burst walls (6) into sub-compartments (5), on both sides of each sub-compartment (5) being arranged the corrugation of the vertical slurry layer in the partial space (5) and the scouring wall (6> extend beyond the overflow edge (8) of the sludge · Device according to claim 6, characterized in that the distance of the individual means for crimping the vertical flow of the suspension on each side of the partial space (5) increases in the direction of flow of the suspension. - 7 249 673 The device according to claim 5, characterized in that the means for corrugating the vertical flow of the suspension are formed by corrugation of the normal walls (6), preferably sinusoidal or angled, wherein the corrugations are corrugations. for all flush walls (6): at the same level and bent in the same direction * 9f A device according to claim 8, characterized in that the section of one wave of the undulating wall (6) is equal to 2 to 6 times the width of the partial space (5) and the deviation from the common wave axis is equal to 1/4 to 1/2 the width of the partial space (5) « Apparatus according to claim 5, characterized in that the means for corrugating the vertical layer of the suspension consist of deflectors (7) arranged alternately on one and the other side of the compartment (5). Device according to claim 10, characterized in that the deflectors (7) are formed by plates inclined at an angle of 45 ° to 70 ° from the horizontal, fixed on their upper edge and extending to 1/6 to 1/3. the width of the compartment (5), the distances between the deflectors (7) on the same side of the compartment (5) being equal to 0,5 to 3 times the width of the compartment (5) *