HU196138B - Reactor for educing the solid phase from liquid particularly for carrying out coagulation cleaning and/or precipitation water softening operations - Google Patents

Abstract

The proposed reactor comprises upper and lower portions, which are pref. of cylindrical and conical shape respectively. - The upper portion of the reactor has an inlet opening, leading to a drop pipe located along the axis of the reactor. - Openings are located, in the surface of the drop pipe, parallel to the axis. The bottom part of the drop pipe has an outlet opening shaped as the surface of a truncated cone. The lower part of the reactor has a sludge discharge connection. The upper part (1) is provided with a discharge opening (2) and overflow channel. - The proposed equipment is based on the principle of the vertical flow, counter-current, sludge blanket reactor, in which the inner space of the drop pipe is open to the clarifier space. The incoming liq. stream is speeded up and thus induces liq. from the clarifier space through the openings in the drop pipe, removing the top of the sludge blanket. In the proposed equipment the openings of the drop pipe are controlled so that the velocity at the throat maintains the floating sludge blanket.

Description

FIELD OF THE INVENTION The present invention relates to a reactor for the selection of a solid phase from a liquid, in particular for conducting coagulation clarification and / or precipitation water softening (precipitation) operations.

Coagulant and / or precipitator reactors are most commonly used in the field of water treatment, namely for the treatment of surface waters or other waters containing colloidal impurities, for the treatment of tertiary effluents, and for the reduction of calcium, magnesium and hydrogen content in natural waters. by softening lime-soda. As is known, coagulation forms a solid phase from colloidal solution (eg water purification) and precipitates from a real solution (eg water softening) in precipitator (precipitator) reactors.

Consistent coagulation, flocculation / agglomeration and sedimentation sedimentation processes take place in such reactors, and in the state of the art, all processes are carried out in the same equipment. Accordingly, the basic technological feature of reactors is, firstly, residence time, which is primarily determined by the speed of the flocculation / aggregation process, and secondly, the surface load, which depends on the deposition rate of the fluctuations, sludge or precipitation formed.

By using plastic tubular settling pads (based on Hazen's theory), the surface loading of coagulator and / or precipitator reactors is known to be multiplied, and polyelectrolytes, which produce large, strong, well settable flakes, also contribute to the loading.

No. 4,346,005. For example, U.S. Pat.

The increase in the power and / or efficiency of the coagulator and / or precipitator reactors is basically limited by the available flocculation / aggregation rate, the means of which is to increase the flow of flocculation energy and to increase the particle concentration. Practical applications include, for example, flocculator mixer, pump or injector, sludge recirculation, addition of micro-sand ("Cyclofloc" process), or floating sludge cloud formation to increase the flocculation / aggregation rate.

For these reasons, only vertical-flow, floating sludge cloud coagulators and / or precipitator reactors are used today.

Vertical-flow floating sludge cloud reactors are either DC, sludge dewatering, or DC, with increased sludge flowing in the opposite direction to the upstream water.

In countercurrent reactors, higher sludge concentration can be achieved, external and / or internal sludge recirculation can be achieved, and flocculation energy can be provided for internal sludge recirculation. However, these reactors have the disadvantage that they are unstable, that the sludge cloud often breaks down, that it is difficult to control and that the system is quite sensitive to load fluctuations.

27.47.322. For example, U.S. Pat. No. 5,198 discloses a device for extracting solids from a liquid having a vertical downflow tube concentrically disposed in a cylindrical basin. The water to be purified is introduced through the drain pipe :. For contacting the liquid sludge, there is provided a mixing device built into the spout or in the raw water feed channel, which collides with the sludge sucked from the sludge space with the downstream fluid to be treated. The treated liquid is decanted.

No. 4,226,714. Also, in the settling device described in U.S. Pat. No. 4,600, the liquid to be treated is fed through a central drain, while the treated liquid is removed by decantation. There is no sludge recirculation, and they intend to increase performance or efficiency by incorporating a sludge scraper.

172.107. U.S. Patent No. 5,279,011 discloses apparatus for the softening and / or clarification of raw water. In its cylindrical vessel, two reaction tubes are arranged coaxially with the vertical geometric center axis, the outwardly extending conical lower end of the inner reaction tube extending downwardly in the similarly formed lower end of the outer reaction tube. The inner reaction tube acts as a Nammut pump and draws in some of the sludge already settled on the bottom of the tank to be mixed with the liquid to be treated.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a coagulant and / or precipitator reactor, in other words a reactor for coagulation clarification and / or water softening, generally a liquid phase solid state reactor, which can be substantially expanded by comparing flocculation, rate of phase formation, thereby reducing the residence time of the liquid to be treated in the reactor, the volume of the reactor itself, processes in the reactor space, and improved clarification efficiency and / or chemical conversion.

The invention is based on the discovery that when a vertical flow, countercurrent, floating sludge cloud: in the coagulator and / or precipitator reactor, on the one hand, besides lower sludge uptake, the possibility of sludge digestion, on the other hand, the throat velocity maintaining sludge cloud is independent of the reactor hydraulic load, phase formation speed can be reduced, residence time and control load capacity can be significantly increased.

Based on these findings, the object of the present invention has been solved by the use of a reactor for selecting a solid phase from a liquid, in particular for carrying out coagulation clarification and / or precipitation water softening operations, in other words a coagulant and / or precipitator reactor. means for discharging a solid phase selected from the liquid and for discharging the liquid separated from the solid phase, and having a circumferential opening between the lower end of the spout and the wall of the vessel, the reactor being provided with a or has a plurality of orifices in the region of the reservoir containing sludge cloud formed during the solid phase selection process and the feed line is drawn in the fall pipe has a downwardly extending conduit section having a lower end 21 spaced in the region of the lower portion of the opening (s), preferably below the opening (s). Preferably, the orifice opening (s) extend into or out of the container clearing and / or softening space, preferably the degree of opening, in the upper third of the falling pipe. Accordingly, the present invention relates to a vertical flow, countercurrent, floating sludge cloud reactor having a clarifying and / or softening space which is opened by a flocculator space delimited by the downpipe (s). Preferably, the nozzle is provided with a nozzle capable of increasing the velocity of the outlet fluid at the end of the fall pipe, preferably at a speed of about 2-6 m / s. With the help of the nozzle, the fluid stream can be introduced at an increased rate into the flocculator space, i.e. the drop tube, below its lateral openings, whereby this increased velocity fluid stream sucks the clarifying and / or softening space through the openings, thereby squeezing the suspended sludge cloud A circulating flow is created in the tank between the tapered reactor wall through the opening, i.e. the throat cross-section.

Another embodiment of the reactor is characterized in that the vessel is formed by a cylindrical wall and a downwardly tapered conical wall attached below it, and a sludge outlet at the bottom end of the sludge space delimited by this conical wall, and the inlet pipe and the downwardly extending downstream section of the conduit extends along the vertical geometric center axis of the container. Further, it is desirable that the lower end of the fall pipe is formed as a downwardly increasing cross-section, preferably a tapered pipe end, and its flange forms an aperture which preferably circulates with the container wall, preferably the conical wall below. The lower, tapered end of the downpipe has a velocity-reducing role for sludge settling there. The gap, on the other hand, has the function of increasing the velocity of the liquid-slurry mixture flowing up, since the upward stream must capture smaller, less sedimentable, particles of the slurry.

According to a further feature of the invention, the spout opening is formed at least about 1.0 m below the operating fluid level in the container. Preferably, the drop pipe has a variable orifice opening or apertures. In the latter case, it is desirable to have an adjustable sleeve, preferably formed of a cylindrical pipe piece, for changing the cross-sectional flow of the spout (s) within the spout, in the region of the spout.

A further embodiment of the reactor is characterized in that the spout has elongated, narrow orifices whose longitudinal direction is parallel to the longitudinal vertical geometric center axis of the apparatus.

If necessary in the upper part of the tank - tubular or lamellar sedimentation insert can be installed in the area of the settling chamber.

It is preferable to have, in order to remove the liquid phase separated from the solid phase, an upwardly sloping trough in the upper part of the container, from which a drain line protrudes from the container laterally.

Finally, it is expedient that the cross-sectional flow rate is selected in a manner that allows for a skimmed sludge amount of 0.5-1.0 times the amount of fluid flow at the nominal load. This also means that a throat velocity that maintains a steady or stable floating cloud of mud is formed at the bottom, in the circumferential opening between the spout flange and the tapered tank wall.

The invention will now be described in more detail with reference to the accompanying drawings, which illustrates a preferred embodiment of the reactor in a schematic vertical axis section.

The reactor of the present invention has a container of diameter D, denoted by reference numeral 1, and having a drop pipe 3, i.e. a reaction tube, having a diameter d in the vertical central axis of x, whereupon D> d. The upper part of the container 1 is constituted by a cylindrical wall 14 in the form of a stationary cylinder, the lower part of which is joined by a conical wall 16 with a decreasing cross-section. The downpipe 3 has a conical tube end 18 with a downwardly increasing cross-section, the lower edge of which extends at a distance below the lower end of the cylindrical wall 14 in a space bounded by a lower conical wall. Between the conical wall 16 and the circumferential flange 18a there is an annular opening 9, the width of which is denoted by the reference letter f.

The reactor according to the invention comprises the following spaces: flocculator space 2 delimited by the downpipe 3, clarification and / or softening space 4 in the lower and middle region between the cylindrical wall 14 and the downpipe 3, and above the settling space 5 6 slugs bounded by a 16 tapered wall. The effluent outlet for the removal of sludge is denoted by reference numeral 17.

. Apertures 7 are formed in the upper third of the M length (height) dropping pipe 3, preferably below the liquid level v formed in the tank 1 at least about 1.0 m, which in the present embodiment are elongated, narrow apertures with their longitudinal axis x parallel. (The distance H is from the upper end of these openings.) The horizontal line 8a of the feed line 8 for supplying the fluid to be treated into the tank 1 extends laterally above the upper edge of the openings 7 to the tank 1 and its vertical section 8b it is concentric with the cylindrical wall and the downpipe 3 and ends at a distance h below the lower end of the openings 7. A nozzle 11 is connected to the end of the vertical conductor section 8b.

Preferably, the flow cross-section of the apertures 7 is adjustable. In the case of the present embodiment, this is conveniently achieved by placing a slightly smaller diameter cylinder inside the drop tube 3, which can be moved up and down, at the height of the openings 7, by raising and lowering the cross-section of the openings 7.

In the upper part of the container 1 there is provided a rotating trough 13, which is known per se, for collecting the treated liquid, for example clarified or sedimented liquid. The drain pipe 12 extends from the trough 13, which is led from the tank 1d.

In the container 1, above the foot feed line 8, the settling space 5, also known per se, is provided with a tubular or lamellar settling insert 15.

The reactor described above operates as follows:

According to the arrow a, the fluid to be treated is introduced through the feed lines 8 into the flocculator space 2, i.e. the drip pipe 3. The chemical (s) required for coagulation and / or precipitation are also introduced into the fall pipe. Since the flocculator space 2 is opened through the openings 7 of the drain tube 3 to the clarifying and / or softening space 4, in order to prevent the flow of liquid from the flocculator space 2 to the clarifying and / or softening space 4 through the openings 7 rather than sliding upwardly over the lower edge 18a of the door tube 3, when the throat velocity formed in the orifice 9 maintains the sludge cloud 10, the fluid to be treated is introduced into the flocculator space 2 through the orifices 7 at intervals h. The feed stream is thus directed downwards and is provided at a speed of 2 to 6 m / s by means of properly selected and / or nozzle 11. The flow of liquid feeds is like a jet pump and, by its pulse, the fluid moves down the fall pipe.

At its increased velocity fluid rates, it moves the fluid mass in the drop tube 3, i.e. the flocculator space 2, and sucks the clarifying and / or softening space 4 through the apertures 7. This results in skewing a portion of the sludge cloud 10 (shown in the drawing by the dashed arrows k) and mixing the sludge cloud with the liquid stream to be treated via the feed line 8. The small but large specific surface area of the sludge cloud in the skimmed sludge cloud inoculates the fluid introduced into the apparatus and provides faster than usual coagulation and / or crystallization and flocculation. This advantage is due in large part to the inoculation of the liquid to be treated with fresh active sludge, as opposed to the aging of large sludge particles introduced by the external or internal sludge recirculation routinely used in similar equipment.

In the downpipe 3 (i.e., in the flocculator space 2), the fluid introduced in the direction of the arrow flows downward with the skimmed sludge mixed with it and then upwards through the opening 9, and the resulting throat velocity is not the inlet fluid stream but the skewed sludge. fluid flow is determined collectively.

By increasing or decreasing the throughput of the orifices 7, the amount of skimmed sludge can be controlled so that the combined amount of fluid flow and skimmed sludge is constant, so that the throat velocity in the orifice 9 is constant, or keep.

As stated above, the control of throat velocity by circulating between the clarifying and / or softening space and the flocculator space is by hydraulic control, previously this task could be accomplished by incorporating at most mechanical structures.

The amount of skimmed sludge - at nominal load - is usually 0.5 to 1.0 times. With a reactor load below nominal, this ratio may be higher in order to keep the throat speed constant. Thus, in the reactor of the present invention, the throat cross-section is about 1.5 to 2.0 times that of a conventional or conventional one.

The efficiency of the sedimentation can be increased by the tubular sedimentation pad 15, but it is not necessary to install it.

The treated liquid enters the trough 13 at the top, from where it is discharged through the drain line 12 in accordance with arrow c. The sludge can be removed from the sludge space 6 via the outlet 17 in accordance with arrow g.

An advantage of the invention is that the flocculation / aggregation rate in the reactor is increased, the suspended sludge cloud is stable, the plant is insensitive to load fluctuations, and simple flocculation energy can be provided. The coagulator and / or precipitator reactor of the present invention is capable of performing the same functions as conventional vertical flow countercurrent reactors, but with a higher specific efficiency and load capacity.

The invention is, of course, not limited to the exemplary embodiment detailed in the drawing, but may be embodied in a number of ways within the scope of the claims, e.g.

Claims (12)

PATENT CLAIMS A reactor for selecting a solid phase from a liquid, in particular by coagulation purification and / or precipitation, e.g. water softening operations having a hopper containing a hopper, a feed line for transferring liquid into the hopper, means for discharging a solid phase selected from the liquid, and for discharging the liquid separated from the solid phase, and an orifice, characterized in that the spout (3) has one or more openings (7) in the region of the reservoir (1) containing the sludge cloud (10) formed during the solid phase separation process, and the feed line (8) in the spout (8). 3) has a downwardly extending downstream conduit section (8b), the lower end of which is located in the region of the lower part of the opening (s) (7), preferably at a distance (h) below the opening (s) (7). Reactor according to Claim 1, characterized in that the container (1) is formed by a cylindrical wall (14) and a conical wall (16) with a downwardly decreasing cross-section connected thereto, and the conical wood e. (16) delimited from the lower end of the sludge compartment (6) by a sludge outlet (17) and the downstream conduit (8b) of the circular drop tube (3) and the downstream conduit (8b) of the feed line (8). ) lies on its vertical geometric central axis (x). Reactor according to Claim 1 or 2, characterized in that the lower end of the spout (3) is formed as a downwardly increasing cross-section, preferably a tapered end (18), and its flange (18a) forms it with the wall of the tank (1). - preferably with a conical tree (6) located beneath - preferably a circumferential opening (9). 4. A reactor according to any one of claims 1 to 4, characterized in that the opening (s) (7) of the spout (3) is or is inserted into the clarifying and / or softening space (4) of the container, preferably the opening. 196.138 (7) is formed in the upper third of the drop pipe (3). 5. A reactor according to any one of claims 1 to 5, characterized in that the opening (7) of the spout (3) is formed at least about 1.0 m below the operating fluid level (v) in the tank (1). 6. A reactor according to any one of the preceding claims, characterized in that the drop tube 10 (3) has a variable orifice opening (7) or apertures. Reactor according to Claim 6, characterized in that it can be moved up and down - preferably cylindrical mirrors - to change the cross-sectional area of the opening (s) (7) within the region of the opening (s) (7). has a control sleeve. 8. A reactor according to any one of claims 1 to 3, characterized in that the spout has elongated, narrow openings (7), the longitudinal direction of which 20 is parallel to the longitudinal vertical geometric center axis (x) of the apparatus. 9. A reactor according to any one of claims 1 to 3, characterized in that the feed line (8) has a nozzle (11) capable of increasing the outlet fluid velocity at the end of the downpipe (8), preferably at a speed of about 2 to 6 m / s. 10. A reactor according to any one of the preceding claims, characterized in that a tubular or lamellar settling insert (15) is provided in the upper part of the tank (1) - in the region of the settling chamber (5). 11. A reactor according to any one of claims 1 to 3, characterized in that a liquid-separating trough (13) is arranged in the upper part of the tank (1) to remove the liquid phase separated from the solid phase, from which a drain line (12) protrudes from the tank (1). 12. A reactor according to any one of claims 1 to 3, characterized in that the through-flow cross-section of the blank (s) is selected in such a way as to allow for a skimmed sludge amount of 0.5 to 1.0 times the amount of liquid stream entering.