FR3031910A1 - PROCESS FOR CLARIFYING AQUEOUS FLUID BY CONTACT WITH A FLUIDIZED BED OF CONSTANT FLOW HYDROXIDE SLUDGE - Google Patents

Abstract

The present invention relates to a method for clarifying in a fluid bed settler of hydroxide sludges for the treatment of aqueous fluids, in particular water, by contact with the fluidized bed of hydroxide sludge, characterized in that introduction of the aqueous fluid is done in the decanter in a constant flow upflow, via an intake system consisting of a distributor in the form of a plurality of dispersion booms pierced with orifices. disposed relative to each other so as to emit a divergent flow together and directed towards the bottom of the settler. The present invention also relates to an aqueous fluid clarification plant comprising a fluid bed settler of hydroxide sludge.

Description

FIELD OF THE INVENTION The present invention relates to the field of treatment of aqueous fluids. More particularly, the present invention relates to a clarification process for the treatment of aqueous fluids in a fluid bed settler of hydroxide sludge, in particular water to be treated and wastewater, to remove suspended solids and materials. dissolved organic aqueous fluids. The present invention also relates to an aqueous fluid clarification plant comprising a fluid bed settler of hydroxide sludge.

STATE OF THE ART Sludge bed clarifiers are commonly used to treat drinking water, wastewater or urban or tertiary waste water. The sludge bed clarifiers allow the removal of suspended solids (MES) and dissolved organic matter from aqueous fluids, in particular by flocculation. Sludge, also known as hydroxide sludge, is formed by flocculation of suspended solids and organic matter from the aqueous fluid to be treated. The sludge therefore constitutes an expanding mass due to an aqueous fluid passage within it. Various method of treating aqueous fluid by means of sludge bed settlers have been implemented. For example, it has been proposed in French patent FR 1115038, a decantation method with pulsed sludge bed, in which a hydraulic stirring is performed by pulsations. The previously coagulated water is pulsed in the bottom by a set of ramifications fed from a central bell equipped with a vacuum pump which empties at regular intervals. The sludge bed is therefore subjected to reciprocating movements from bottom to top and from top to bottom. Flocculation reagents are injected in the vicinity of the vacuum bell. These settlers with a bed of pulsed sludge typically operate at climbing speeds of between 2 and 4 m3 / m 2 · h. One of the disadvantages of the prior art is therefore related to limited ranges of climbing speeds. In order to improve these climbing speeds, additional elements have been added to the pulsation settling tanks, such as plates inclined with respect to the horizontal within the sludge bed.

Another disadvantage of the prior art is related to the size relative to this type of installation. Indeed, the sludge bed settling tanks have a central vacuum bell with a strong footprint, responsible for variable flow. According to the Water Technical Memo (Volume 2, 1989, page 661), only sludge bed settlers operating by pulsation are envisaged. Indeed, the feed of the constant flow fluidized bed settler is treated as impossible because the sludge does not remain in suspension and cup, allowing the water to create preferential passages. Under these conditions, there is no longer any effective contact between the water to be treated that passes through the sludge bed and the sludge that constitutes it. Anyone working in the field would therefore have naturally departed from this orientation if it had not identified an inventive and differentiating means of solving the problem raised by the authors of this document. Therefore, there was a need to develop a process and a treatment plant for effectively treating aqueous fluids, particularly water, by clarification in a fluidized bed settler of hydroxide sludge not exhibiting the disadvantages of the methods and devices of the prior art. The present invention fills this need. SUMMARY OF THE INVENTION The present invention relates to a method of clarifying in a fluid bed settler of hydroxide sludges for the treatment of aqueous fluids, in particular water, by contact with the fluidized bed of hydroxide sludge. , characterized in that the introduction of the aqueous fluid is done in the decanter in constant flow upflow, via an intake system consisting of a distributor in the form of a plurality of dispersal ramps pierced with orifices arranged relative to each other so as to emit a divergent flow together and directed towards the bottom of the settling tank. The present invention also relates to a clarification plant for the implementation of the method comprising a single fluid bed settler of hydroxide sludge 30 for the treatment of aqueous fluid, operating in a constant flow upflow, comprising an admission system. consisting of a distributor in the form of a plurality of dispersion booms pierced with orifices arranged relative to each other to emit a divergent flow together and directed towards the bottom of the settler.

BRIEF DESCRIPTION OF THE FIGURES FIG. 1 represents an example of a clarification installation according to the present invention. Figure 2 shows the turbidity monitoring of the water before and after treatment according to the present invention. FIG. 3 represents the height of the bed of hydroxide sludges as a function of the fluidization speed of the fluid. DEFINITIONS The term "aqueous fluid" as used in the description of the present invention refers to water, preferably surface water, groundwater, industrial water or urban wastewater. The term "aqueous fluid to be treated" refers to an aqueous fluid that is desired to remove suspended matter and / or dissolved organic matter by coagulation and clarification. The term "treated aqueous fluid" refers to the state of an aqueous fluid after treatment according to the present invention. The term "sludge bed" refers to a suspension formed by coagulation and / or flocculation of suspended solids and organic matter of the aqueous fluid to be treated. SUMMARY OF THE INVENTION Surprisingly, the applicant has discovered that the use of a high density of orifices arranged in staggered rows on dispersion ramps typically in the form of tubes, oriented towards the bottom of the decanter and advantageously arranged on the The total area of the flat-bottomed slab allowed for the efficient treatment of aqueous fluid. The orifice output velocities of the aqueous fluid being substantially the same for each of the orifices. Thus, the present invention relates to a method of clarifying in a fluid bed settler of hydroxide sludges for the treatment of aqueous fluids, in particular water, by contact with the fluidized bed of hydroxide sludge, characterized in that the introduction of the aqueous fluid takes place in the constant-flow upflow settler, via an inlet system consisting of a distributor in the form of a plurality of drilled dispersion ramps orifices 3031910 4 disposed relative to each other so as to emit a divergent flow together and directed towards the bottom of the settling tank. According to an advantageous embodiment, the introduction of the aqueous fluid to be treated is done in the lower part of the settling tank, via a feed pipe, and the treated aqueous fluid is recovered in the upper part of the settler, advantageously by several chutes or pipes. perforated. Advantageously, the introduction of the aqueous fluid to be treated in the decanter is at a constant rate and at a rate of increase of between 2 m 3 / m 2 · h and 8 m 3 / m 2 · h, advantageously between 4 m 3 / m 2 · h and 6 m3 / m2.h. The flow rate of the aqueous fluid in the feed pipe and during its introduction into the settling tank is constant, that is to say that the flow rate (m3 / h) at the orifice outlet is constant over time. whatever the orifice chosen on the dispersion ramp. Advantageously, the aqueous fluid to be treated is coagulated with metal salts upstream of its introduction into the decanter. The metal salts are then injected into the aqueous fluid supply line to be treated and the aqueous fluid thus arrives coagulated in the decanter. Advantageously, the aqueous fluid to be treated flocculates by contact with the fluidized bed of hydroxide sludge, leading to the formation of sludge in the clarifier. Advantageously according to the invention, flocculation agents of mineral or organic origin can be injected into the feed line of the aqueous fluid to be treated after the coagulation step. The use of flocculation agents makes it possible to improve the flocculation of the MESs during the contact between the aqueous fluid to be treated and the fluidized bed of hydroxide sludge. Flocculation agents can be injected to meet important quality requirements in terms of turbidity and MES aqueous treated fluid.

They are then typically injected in dilute solution into the aqueous fluid supply line to be treated, advantageously previously coagulated. Thus, the technology used makes it possible to obtain a fluidized bed of coagulated and flocculated hydroxide sludge. The flow of aqueous fluid to be treated in ascending flow within the fluidized bed of hydroxide sludge ensures the treatment and removal of suspended solids and organic matter. No mechanical stirring is necessary in the context of the invention. The stirring with the aid of the aqueous fluid to be treated of the bed of hydroxide sludge created by the distributor hydraulics composed of a plurality of dispersion ramps pierced with orifices makes it possible to prevent progressive settlement of the bed 3031910 5 hydroxide sludge at the bottom of the work. It is thus sought to avoid settling of the hydroxide sludge bed which generally leads to the creation of preferential passages of the aqueous fluid, resulting in a reduction of the effective contacts between the fluid to be treated which passes through the bed of hydroxide sludge and the sludge which constitute it.

Advantageously, at least a portion of the sludge formed is poured into at least one sludge pit disposed within the settling tank. During the flocculation of the aqueous fluid to be treated, sludge is formed in the decanter. Thus, the amount of sludge formed increases over time. In order to maintain the fluidized bed of hydroxide sludge stable in height and concentration in the settler, it is therefore necessary that at least a portion of the sludge formed be poured into at least one sludge pit disposed within the settler. Advantageously, the sludge discharged is extracted from the sludge pit by a withdrawal circuit, typically by gravity or a set of pumps. The present invention also relates to a clarification plant for carrying out the process according to the invention, comprising a single fluidized-bed settler of hydroxide sludge for the treatment of aqueous fluid, operating in a constant-rate upflow, comprising an intake system consisting of a distributor in the form of a plurality of dispersion booms pierced with orifices arranged relative to one another to emit a divergent flow together and directed towards the bottom of the settling tank. Such an installation is shown in FIG. 1. The plant according to the present invention comprises a single settling tank defined according to three distinct zones of operation: a bottom part comprising: a reaction zone (A) of aqueous fluid, advantageously previously coagulated; , comprising said aqueous fluid intake system (1), as well as the fluidized bed of hydroxide sludge, - a sludge discharge zone (B), comprising at least one sludge pit arranged inside the decanter - An upper part comprising a settling zone and uniform recovery (C) of the aqueous fluid treated by several chutes or perforated pipes (3).

The perforated chutes or pipes (3) are evenly distributed over the entire surface of the settling zone in order to allow the treated aqueous fluid to be taken up after decantation at any point on this surface. Advantageously, the height of the fluidized bed of hydroxide sludge is delimited by the height of discharge of at least a portion of the sludge formed in the sludge or pits (5). Thus, the maximum height of the fluidized bed of hydroxide sludge can be determined by the height of the discharge zone. The height of the discharge zone is advantageously determined by the height of the wall (4) of the sludge pit. The establishment of the sludge discharge zone makes it possible, by discharging at least a portion of the sludge formed in at least one sludge pit, to maintain the fluidized bed of hydroxide sludge stable in height and concentration. As shown schematically in Figure 1, the installation according to the present invention provides sludge pits (5) installed at the periphery of the central reaction zone. This diagram represents a particular example of an installation according to the present invention.

Advantageously, the intake system (1) provides hydraulic mixing. The hydraulic mixing of the hydroxide sludge bed is created by the introduction of the aqueous fluid to be treated by the intake system (1) consisting of a distributor in the form of a plurality of dispersion ramps (2). ) pierced with orifices. Hydraulic stirring thus avoids settlement in the bottom of work and any preferential passage of aqueous fluid. Advantageously, the dispersion ramps have a tube shape with orifices arranged in staggered rows. The distribution of the orifices being reproduced identically on each dispersion ramp, jets of aqueous fluid to be treated injected into the decanter via these orifices can not intersect.

Advantageously, the orifices are arranged in at least two rows extending along two parallel generatrices of the tube, the generatrices of two adjacent rows being spaced from each other by an angular sector of the tube forming an angle. between 30 ° and 45 °. The distribution of aqueous fluid by the dispersion ramps, provided by the orifices, allows the distribution of the aqueous fluid on the bed of hydroxide sludge homogeneously and at a constant flow rate. This arrangement thus allows the introduction of the aqueous fluid at a high rate of rise while keeping a bed of hydroxide sludge effective in terms of treatment.

Advantageously, the height of the sludge bed is between 2m and 3m, advantageously between 2m and 2.5m. Advantageously, in the process and the plant according to the invention, the extraction of the sludge from at least one sludge pit is carried out intermittently by a gravitational withdrawal circuit (5) or a pump game. Advantageously, the sludge discharged into the sludge pit is concentrated, and extraction of the latter by the withdrawal system takes place at a predetermined frequency and duration. EXAMPLE 10 A particular example of water treatment according to the process of the present invention will be indicated below by way of illustration, in connection with FIGS. 2 and 3. The particular conditions mentioned below have led to particularly satisfactory results in the context of this invention. Operating conditions (for FIGS. 1 and 2): Fluidization upward velocity: 6m / h (8m / h punctual) Coagulation pH: 5.2 Coagulant: Ferric chloride Coagulant dosage: 170 to 180 g / m3 Adjuvant flocculation: without Fluidized sludge bed height: 2.3 m Hydraulic operating balance: Residual turbidity <1 NFU The analysis of FIG. 2 represents the monitoring of the turbidity of the water before and after treatment according to the present invention , makes it possible to emphasize that regardless of the turbidity of the tributary (turbidity between 3 and 7), the turbidity of the decanted water is always less than 1 NFU. As shown in Figure 3, the shutdown of the settler leads to settling of the bed of hydroxide sludge at the bottom of the structure at the inlet ramp of the raw water. These stops which can last from a few hours to several 30 days can lead to a settlement in time. The decanter distribution system ensures a very fast fluidization rebate whatever the downtime.

Claims (16)

REVENDICATIONS1. Method for clarifying in a fluid bed settler of hydroxide sludges for the treatment of aqueous fluids, in particular water, by contact with the fluidized bed of hydroxide sludge, characterized in that the introduction of the aqueous fluid is carried out in the decanter in a constant flow upflow, via an intake system consisting of a distributor in the form of a plurality of dispersion booms pierced with orifices arranged relative to one another to others so as to emit a divergent flow together and directed towards the bottom of the decanter. 2. Method according to claim 1, characterized in that the introduction of the aqueous fluid to be treated is in the lower part of the decanter, via a supply line, and the treated aqueous fluid is recovered in the upper part of the decanter, preferably by several chutes or perforated pipes. 3. Method according to claim 1 or 2, characterized in that the introduction of the aqueous fluid to be treated in the decanter is at a constant flow rate and a rate of climb of between 2 m3 / m2.h and 8 m3 / m2. h, advantageously between 4 m3 / m2.h and 6 m3 / m2.h. 4. Method according to one of claims 1 to 3, characterized in that the aqueous fluid to be treated is coagulated by metal salts upstream of its introduction into the decanter. 5. Method according to one of claims 1 to 4, characterized in that the aqueous fluid to be treated flocculates by contact with the fluidized bed of hydroxide sludge, leading to the formation of sludge in the decanter. 6. Method according to one of claims 2 to 5, characterized in that flocculation agents of mineral or organic origin are injected into the feed line of the aqueous fluid to be treated after the coagulation step. 7. Method according to claim 5 or 6, characterized in that at least a portion of the sludge formed is poured into at least one sludge pit disposed within the clarifier. 30 8. Method according to claim 7, characterized in that the sludge discharged is extracted from at least one sludge pit equipped with a gravity withdrawal circuit or a set of pumps. 3031910 9 9. clarification plant for carrying out the method according to one of claims 1 to 8, characterized in that it comprises a single fluidized bed settling of hydroxide sludge for the treatment of aqueous fluid, operating in flow constant flow ascending device comprising an intake system consisting of a distributor in the form of a plurality of dispersion booms pierced with orifices arranged relative to each other to emit a divergent flow together and directed towards the bottom of the decanter. 10. Installation according to claim 9, characterized in that said decanter is defined according to three distinct zones of operation: - A lower part comprising: - a reaction zone (A) of aqueous fluid, preferably pre-coagulated, comprising said system of admitting the aqueous fluid, as well as the fluidized bed of hydroxide sludge, - a sludge dumping zone (B), comprising at least one sludge pit arranged inside the settling tank, - an upper part comprising a zone decantation and uniform recovery (C) of the aqueous fluid treated by several chutes or perforated pipes. 11. Installation according to claim 9 or 10, characterized in that the height of the fluidized bed of hydroxide sludge is defined by the discharge height of at least a portion of the sludge formed in at least one sludge pit. 12. Installation according to claim 9 or 10, characterized in that said intake system provides a hydraulic mixing. 13. Installation according to claim 9 or 10, characterized in that said dispersion ramps have a tube shape with orifices arranged staggered. 14. Installation according to claim 13, characterized in that the orifices are arranged in at least two rows extending along two parallel generatrices of the tube, the generatrices of two adjacent rows being spaced from each other by a angular sector of the tube forming an angle of between 30 ° and 45 °. 15. Installation according to one of claims 9 to 14, characterized in that the height of the sludge bed is between 2m and 3m, preferably between 2m and 2.5m. 3031910 10 16. Installation according to one of claims 9 to 15, characterized in that the extraction of sludge from at least one sludge pit is carried out intermittently by a gravity withdrawal circuit or a set of pumps. .