FR2734810A1 - PROCESS FOR DEPURING WATER CONTAINING A POLLUTING CHARGE, AND ADDITIVE FOR IMPLEMENTING THE PROCESS. - Google Patents

Abstract

Method for purifying water containing pollutants, including subjecting the water to be purified to at least one treatment step, particularly a clarification and/or biological activation step, followed by a separation step into a purified water component and an optionally activated sludge component. A mineral additive added to the water to be purified has the following properties: it is non adsorbent and chemically inert relative to the pollutants present in the water to be purified, it is insoluble or weakly soluble, i.e., with less than 5 % solubility, in water under normal treatment pH conditions, it has a specific surface area of more than 0.4 m<2>/g (as measured by BET), a microporosity of less than 0.1 cm<3>/g, a residual cloudiness of less than 300 NTU and a rate of fall of less than 35 m/h. The invention is useful for purifying industrial or municipal waste water and for producing drinking water.

Description

Process for purifying water containing a polluting load, and additive Dour ia implementation of the process
The invention relates to a method for purifying water containing a polluting load, as well as to an additive for carrying out the method.

The studies and experiments which made it possible to obtain the results of the invention were carried out thanks to the collaboration of the team of Mr. Jean CANTET of the University of Research in Biological Processes at INSA of
Toulouse and thanks to the collaboration of the team of Mr.
Alain GRASMICK from the Department of Water Sciences and Technologies of the Institute of Engineering Sciences of Montpellier.

The invention applies generally to the purification and purification of water using treatment units operating chemically, physicochemically, or even biologically.

The term “water” is currently intended to denote either waste water of industrial or municipal origin, or water to be made drinkable.

The term “purification” is intended to denote both purification of waste water and purification with a view to obtaining drinking water.

The expression “polluting load” is intended to designate at present all compounds of all kinds, organic or inorganic, of all chemical nature, rendering either waste water unsuitable for fish life (and therefore its discharge into a river), or water to be made drinkable unsuitable for consumption. This polluting load is expressed by its flow at the inlet of the purification unit, that is to say the mass related to the unit of time, which it describes carbon pollution (COD or BOD), particulate pollution (MES), nitrogen pollution (N-NH4, N-NO3,
Total N) or phosphorus pollution (P-PO4, total P).

COD refers to the chemical oxygen demand, expressed in mg / liter of dioxygen equivalents.

BOD denotes the biological oxygen demand expressed in mg / liter of dioxygen equivalents.

MES designates the Materials in Suspension expressed in mg / liter.

N-NH4 denotes the ammoniacal nitrogen content expressed in mg / liter.

N-NO3 denotes the nitric nitrogen content expressed in mg / liter.

Total N denotes the total nitrogen content expressed in mg / liter.

P-P04 denotes the phosphorus content of orthophosphates expressed in mg / liter.

P total denotes the total phosphorus content expressed in mg / liter.

During its purification, the water is usually subjected to a preliminary operation, known as "pretreatment", by screening and / or grit removal and / or grinding. The purpose of this operation is to eliminate solid particles of all sizes and of all kinds, which carry pollution and create deposits or mechanical breakdowns in subsequent treatment installations.

When it comes to drinking water, the latter is first screened and sanded and can then undergo various additional treatments by simple or accelerated settling in the presence or absence of chemical additives, by filtration on a gravity bed or on support, or by flotation using air bubbles.

Then, the water to be made drinkable is subjected to specific treatments for the elimination of pollutants by passage through resins, activated carbon or even by ultra-filtration, nanofiltration, chlorination, ozonation, etc.

After screening and de-sanding, the wastewater can undergo additional treatments by simple or accelerated settling with or without the addition of chemical additives, by filtration, by flotation using gas bubbles (generally air), before being sent to biological tanks. As a variant, this wastewater can be sent directly to these biological ponds after the de-sanding.

In biological basins, also called "activation basins", the water to be purified is subjected to biological degradation in the presence of a biomass composed of purifying microorganisms, that is to say bacteria.

For the treatment of wastewater, biological degradation is carried out by bacteria of various kinds with the aim of eliminating carbon and / or nitrogen and / or phosphorus pollution, this degradation taking place in one or more biological basins undergoing phases aerobic, anoxic and anaerobic. Microorganisms or bacteria generally agglomerate to form flocs which are separated from the purified water by density difference with the treated water or by size exclusion in a "secondary clarifier". The term "secondary clarifier" is understood to mean a device where separation is carried out by flotation, by settling, by hydrocycloning, by centrifugation or by filtration. The purified water can then be directly discharged into the river, while the thickened flocs called "sludge" collected in the secondary clarifier is partially recycled to the biological basins in order to maintain a high number of purifying microorganisms there and to maintain biological activation, the other part being waste to be treated.

In all types of treatment, the water to be purified is subjected to at least one particular operation, in particular by settling and / or biological activation, with subsequent separation of purified water and possibly activated sludge.

Whatever the treated water, the ultimate sludge resulting from the various settling operations is withdrawn, thickened, then conditioned in order to reduce their volume and their mass for agricultural use by spreading, deposit in landfill or incineration.

The operators of water treatment plants are faced with various problems, the most important of which are the following - incomplete treatment due to poor sizing of the equipment in relation to the pollution to be treated; - particular pollution that cannot be treated by known biological processes; - in the case of a biological process, poor flocculation of the microorganisms making separation difficult, random, or even impossible in the secondary clarifier; and - in the case of water to be made drinkable, poor settling of the colloidal particles in suspension.

To solve these problems, the operators of wastewater treatment plants must increase the size of their treatment units, make major changes to existing installations, or resort to coagulation and / or chemical flocculation additives and solid products with a high water capacity. adsorption or absorption of pollutants.

These solutions have the drawback, on the one hand, of introducing additional pollution, often harmful to microorganisms in the case of chemical additives and, on the other hand, of causing a permanent circulation of products strongly adsorbed or absorbed by pollutants. .

According to HAMODA and FAHAIM, Environmental Pollution (Series A) 36 (1984) 283-294, a process for the purification of wastewater is known which comprises the addition of activated carbon or kaolin as an adsorbent of carbon pollution, in a biological basin.

However, this is an experimental process, unsuitable for industrial use, because the mineral used leaves purified water cloudy, incompatible with discharge into the river.

In addition, in the particular case described, part of the pollution is transferred from the water to the sludge, not improving the purification quality of the biological system.

The authors have also noticed a slight increase in the sedimentation rate, of 20%, generally observed during the addition of dense minerals which compress, by simple piston effect, the flocs of microorganisms present.

Also known from PCT application WO 94 20425, a method of purifying wastewater of the activated sludge type making it possible to increase the purification yields.

This is a process using biological basins or activation basins, in which the wastewater is brought into contact with a biomass and with a hydrophobic powder of talc, pyrophyllite or mica, to ballast the micro flocs. -organisms.

This process is applicable only in the case of flocs exhibiting hydrophobic sites and the authors have not been able to extend the patent application to the physicochemical separation of solid or colloidal particles which exhibit essentially hydrophilic characteristics.

The addition of clay in biological water purification ponds is known from CHUDOBA and PANNIER, Environmental
Technology, 1994, Vol. 15, pages 863-870, sometimes to improve wastewater treatment.

The authors find a reduction in the volume of sludge of 30% which, as in the case of the publication of HAMODA and
FAHAIM, is due to a piston effect which is all the more important as the clay particles used are of large size and weight.

The particles of 100 to 200 micrometers used sediment very quickly at the bottom of the basins, requiring heavy and specific recirculation installations to avoid the formation of a compact and dense deposit. This problem is particularly damaging in installations stirred and aerated by gas diffusion at the bottom of the basin.

Also known from Japanese Patent Publication JP-A-4 253 793 of August 24, 1992 in the name of SHIKOKU
KASEI KOGYO, the use of gel and polyelectrolyte to agglomerate microorganism flocs. The authors recommend ballasting this preformed synthetic gel with clays. In this article, the authors do not prejudge the specific effect of mineral additives.

Finally, the so-called “ACTIVELO” (registered trademark) process is known, developed by the company OTV which, in primary tanks, combines the addition of microsands to coagulants and chemical flocculants to make colloidal particles heavier.

This process is similar to the Japanese process described above but is aimed more particularly at the primary settling of solid and colloidal charges. It associates couples of chemical agents with ballast loads. This process is limited to the treatment of very dilute water.

The last two methods described require large amounts of chemical additives.

The object of the invention is in particular to overcome the drawbacks of the known purification processes.

It is yet another object of the invention to provide such a purification process which makes it possible to improve the purification performance of wastewater treatment units, operating by chemical route, by physicochemical route, by biological route, without inducing additional pollution or recirculating inside biological basins, adsorbed pollution.

The invention provides for this purpose a method for purifying water containing a polluting load, in which the water to be purified is subjected to at least one treatment operation, in particular by settling and / or biological activation, with subsequent separation. purified water and possibly activated sludge.

In accordance with the invention, at least one mineral additive in the form of powder, granules or suspension is added to the waste water to be treated, and which meets the following properties - non-adsorption (as defined below) and chemical inertness to with regard to the polluting load present in the water to be purified; - insolubility or low solubility, less than 5%, in water, under the usual pH conditions (pH5 to pH9) encountered during the treatment; - specific surface greater than 0.4 m2 / g (BET method); - microporosity less than 0.1 cm3 / g; - residual turbidity of less than 300 NTU, as measured in a solution of pure water at 3 g / l after 30 minutes of decantation; and - fall speed less than 80 m / h.

The adsorption capacity, by the mineral additive, of the pollutant load is calculated, on the one hand, by measuring the difference in D.C.O. soluble between the raw water to be treated and this same water after 5 h of contact with I g of additive. This difference in D.C.O. soluble must be less than 60 mg / g of additive, to qualify this product as non-adsorbent.

On the other hand, the nitrogen adsorption capacity N-NH4 is determined in the same way. This adsorption capacity must be less than 10 mg per gram of additive.

The BET method designates a method by measuring the gas adsorption isotherm according to BRUNAUER, EMMET and TELLER, the gas used being argon.

The microporosity is determined by measuring the adsorption-desorption isotherm of gas according to BET, the gas used being nitrogen.

The fall speed is measured, when the settling takes place in a laminar regime, using a device called "Sedigraph" from the company MICROMERETICS, and, when the settling takes place in a non-laminar regime, at the using a one meter water column. The rate of fall characterizes the sedimentation of 95% of the additive. The measurement with the "Sedigraph" device is carried out in a 4 cm high sedimentation cell. The calculation is carried out by monitoring the concentration as a function of time by reading the optical density.

NTU is the abbreviation for Nephelometric Turbidity Unit (see
ASTM 1880-81).

Thus, the invention is based on the addition of at least one specific mineral additive with predetermined physicochemical characteristics, which makes it possible to modify the flocculation of particles and / or colloids in suspension, as well as the bioflocculation of microorganisms, to improve the purification performance of water treatment units.

According to another characteristic of the invention, the mineral additive is a natural or synthetic product chosen from at least one of the chemical families formed by silicates, aluminates, carbonates, sulphates and glasses which are insoluble or poorly soluble in water. usual pH conditions described above.

The mineral additive can be synthesized by different routes to obtain particular physicochemical characteristics, such as specific surface area or rate of fall.

The mineral additive can be obtained naturally or else be ground before being chosen (passage through the selector) in order to obtain specific physicochemical properties such as porosity, turbidity or rate of fall.

The mineral additive is preferably chosen from one of the following chemical families, given without limitation and characterized by all the criteria described above - aluminosilicates, - magnesium aluminate, - hydrated calcium carbonate, - double calcium carbonate and hydrated magnesium, - amorphous or crystallized calcium carbonate, - hydrated magnesium silicate, - hydrated aluminum silicate, - double hydrated magnesium aluminum silicate, - hydrated calcium sulphate.

Advantageously, the mineral additive is chosen from at least one of the following groups of products, given without limitation feldspar, wollastonite, cristobalite, quartz, nepheline, micas, muscovite, chlorites, talc, sepiolite, serpentine, calcite, dolomite , giobertites, aragonite, gypsum, kieserite, kaolinites, pyrophyllite, olivine, andalusite, basalt or even alluvium. A particular example according to the invention consists in using solid residues from wastewater treatment plants.

A significant synergy is obtained when the mineral additive used in the process of the invention comes from mixtures of families of the minerals described above, whether this mixture is prepared in advance or whether it is produced on site by successive and alternating additions. of different types of minerals.

The invention applies in particular to a process in which the water to be purified is water to be made drinkable and is subjected to a primary separation operation in a primary clarifier, with settling.

The mineral additive according to the invention is then added before or during the primary separation operation, so that the daily mass (also called "daily mass") of the added mineral additive is equal to 1 to 500 times the daily mass of the pollutant load contained in the water.

Thus, a drinking water treatment station receiving 100 kg of
COD per day will use 100 to 50,000 kg of additives per day.

The invention also applies to a process in which the water to be purified is waste water and is subjected to a primary separation operation in a primary clarifier, with settling, and without treatment in biological tanks.

According to the invention, the mineral additive is added before or during the primary separation operation, so that the daily mass of the added mineral additive is equal to 0.1 to 10 times the daily mass of the polluting load. contained in water.

In the two aforementioned processes, an inorganic additive is used which advantageously has a residual turbidity in water generally less than 200 NTU and a fall speed of between 0.03 and 80 m / h.

The process thus makes it possible to improve the flocculation of the colloidal particles and of the particles in suspension present in the primary clarifier. This results in particular in the following advantages: improvement of settling speeds in the primary clarifier, whether simple or accelerated (case of primary clarifiers); - increase in the abatement (decrease) of pollution in the primary clarifier, whether simple or accelerated; and - reduction, or even elimination, of the amount of chemical additive, namely iron or aluminum salts and cationic polymers based on acrylamine, acrylamide or epichlorohydrin.

The mineral additive is then introduced, either into the primary clarifier, or upstream thereof, to improve its performance, sedimentation, sludge height and sludge thickening, the introduction of additive being produced by the direct route in the form of powder, granules or suspension.

The invention also applies to a process in which the water to be purified is water to be made drinkable and is subjected to a primary separation operation by flotation. In accordance with the invention, the mineral additive is added before the primary separation operation, so that the daily mass of the added mineral additive is equal to 1 to 100 times the daily mass of the pollutant load contained in it. 'water.

Preferably, the mineral additive has a residual turbidity in water generally less than 250 NTU and a falling speed of less than 5 m / h.

The invention also applies to a process in which the water to be purified is waste water and is subjected to a primary separation operation in a primary clarifier, with settling and before treatment in biological basins. According to the invention, the mineral additive is added before or during the primary separation operation, so that the daily mass of the added mineral additive is equal to 0.1 to 10 times the daily mass of the polluting load. contained in water.

Preferably, the mineral additive has a residual turbidity in water generally less than 300 NTU and a fall speed of between 0.01 and 80 m / h.

Also, the invention applies to a process in which the water to be purified is waste water and is subjected to a primary separation operation by flotation before treatment in biological basins. According to the invention, the mineral additive is added before the primary separation operation, so that the daily mass of the mineral additive added is equal to 0.1 to 10 times the daily mass of the polluting load contained in the water.

In this case, it is preferred to use an inorganic additive having a residual turbidity in water generally less than 300 NTU and a fall speed of less than 5 m / h.

In the case of a process in which the water to be purified is waste water and is subjected to a primary separation operation by flotation before treatment in biological tanks, it is possible to use an excess of mineral additive relative to to the pollutant load contained in the incoming water. Indeed, the process leaves a part of the mineral additive in suspension in the water, to penetrate into the biological basins where it will react with the flocs of microorganisms ensuring an optimization of the use of the mineral additive in the two stages of water treatment, namely the primary separation and the bio-flocculation of the microorganism flocs.

The invention also applies to a purification process in which the water to be purified is subjected to a biological activation operation in at least one biological basin in the presence of a biomass composed of purifying microorganisms and to a secondary separation operation in a secondary clarifier with subsequent separation of purified water and activated sludge.

According to the invention, the mineral additive is added before or during the secondary separation operation, with a selected quantity of mineral additive depending on the biomass concentration at any time, the quantity of added mineral additive representing 10 150% by weight of the biomass in the aeration tank.

In such a process, the mineral additive advantageously has a residual turbidity in water generally less than 300 NTU and a falling speed of less than 80 m / h.

The mineral additive can be added in the various biological basins or else between the primary clarifier and these, preferably in the aeration basin.

As in the previous variant, the mineral additive is introduced directly in the form of powder, granules or suspensions.

The mineral additive can also be introduced into the secondary clarifier in the event of very poor settling or to reduce the height of the sludge bed.

The mineral additive can alternatively be introduced into the excess sludge before recirculation and / or thickening and dehydration.

To improve the yields of biological ponds, the amount of mineral additive added is determined according to the biomass (mass of microorganisms present), the nature and size of the equipment, as well as the type of operation. low, medium or heavy load units.

As already indicated, the quantity of mineral additive to be added to the biological basin represents from 10 to 150% by weight of the concentration of the biomass in the aeration basin.

At the start, the quantity of mineral additive necessary to obtain the desired performance is added. Then, an additional addition of mineral additive is carried out, either continuously by servo-control, or discontinuously, depending on the amount of active biomass present at any time, or alternatively to replace the amount of mineral additive in the mixture. excess biomass, extracted as secondary clarifier sludge.

Thus, in the particular case of purification processes using activated sludge, the mineral additive of the invention makes it possible to improve the bio-flocculation of the microorganism flocs.

The mineral additive of the invention, which is fine, inert, non-adsorbent and non-polluting, makes it possible to modify the size, volume and weight of the microorganism flocs in order to adapt them to the problems encountered by station operators. purification, and this without creating additional constraints.

The mineral additive must be, among other things, characterized by its rate of fall and its residual turbidity in water in order to be compatible with the size of the microorganisms and the rate of fall of the flocs of microorganisms, with a view to optimize bio-flocculation and avoid any solid deposit in water purification units.

Also, the mineral additive is determined by its chemical composition, its structure and its specific surface to bind preferentially to microorganisms and to microorganism flocs in order to optimize bio-flocculation and avoid absorption. or adsorption of impurities present in the water to be treated.

Thus, the mineral additive is characterized, among other things, by its rate of fall, its chemical composition and its structure, to bind to microorganisms and form large diffuse flocs capable of being floated.

In certain cases, it may be advantageous to add, to the mineral additive, a cationized additive with a short chain, that is to say one of which the carbon chain is less than 25 atoms. The concentration of this additive must remain less than 5% by weight of the mineral additive.

The invention is compatible with the use of other additives already known for their specific actions on toxic pollution or on soluble pollution which cannot be degraded by the usual biological purification processes. The additional additive can in particular be an activated or activated carbon, a zeolite, lignite, bentonite, and the like.

The improvement in the separation between the soluble phase and the colloids or particles in suspension, obtained according to the invention, makes it possible to improve the specific action of these additional additives. This results in a greater efficiency of these additives for adsorbing, on the soluble fraction to be purified, toxic cations, dyes, etc.

The method of the invention makes it possible to improve the performance of water treatment installations. It leads to a standardization of the physicochemical properties of the flocs, allowing a reliable separation of the purified water from the sludge and avoiding the displacement of the problem of pollution from the water to the sludge, the management of which is increasingly difficult. .

By improving the bio-flocculation of the microorganism flocs, the following performances are obtained: reduction of the volume of sludge in the secondary clarifier; - reduction in the size of the secondary clarifier for a given mass of microorganisms; - increase in the volume of settling water for a secondary clarifier of given dimensions; - reduction of the losses of non-settling filamentous microorganisms, with a compact or open structure, under the usual conditions; - reduction of the losses of non-flocculated or deflocculated microorganisms and therefore not settable under usual conditions; - reduction of foaming phenomena due to the presence of microorganisms on the surface of secondary clarifiers; - increase in biological purification yields, carbon and / or nitrogen and / or phosphorus pollution ;; - reduction in the size of the biological treatment basins for a determined quantity of carbon, nitrogen and / or phosphorus pollution; - increase in the quantity of carbon and / or nitrogen and / or phosphorus pollution treated in a basin of given dimensions.

Moreover, the presence of a predetermined quantity of mineral additive in the sludge resulting from the primary clarifier and / or from the secondary clarifier makes it possible to lead to the following performances: improvement of the thickening yields of the excess sludge by gravity; - improvement in the yields of excess sludge dewatering equipment; - improved handling of excess, thickened or dehydrated sludge, by reducing the sticky effect; and - improvement of the behavior of excess, thickened and / or dehydrated sludge during compacting or granulation operations.

The method according to the invention makes it possible to make the so-called “high and medium charae” water treatment systems more reliable by reducing the mass load with, if necessary, supply of external carbon and nitrogen (N-NH4). According to the invention, it also appears possible to carry out floc separation operations of microorganisms by flotation and / or sedimentation in a suitable secondary settling tank.

The mineral additive of the invention also allows the following performances - improvement of the performance of chemical additives known as “coagulants” or “flocculants” (iron salts, aluminum salts, cationic or anionic acrylic polymers, epichlorohydrin polymers , etc.) in secondary settling tanks by reducing the volume of sludge produced and increasing settling speeds; - reduction, or even elimination, of chemical additives called "coagulants" or "flocculants" during secondary settling operations in the presence of lamellar processes; - improvement of the separation yields between the treated water and the flocculated microorganisms when using dynamic devices such as lamellar settling tanks, hydrocyclones, centrifuges, etc .; and - improvement of the separation yields of the filtration processes by gravity beds or on supports.

The process of the invention appears particularly advantageous because it makes it possible, by a judicious choice of the mineral additive, to improve the performance of primary clarifiers without chemical additives, mainly in the case of lamellar clarifiers where it can make it possible to double the speed. pollution abatement (reduction).

The process of the invention also makes it possible, again by the judicious choice of the mineral additive, to control the size, the volume or the weight of the microorganism flocs in a predictable manner with unique performances for the treatment of the mineral. 'water. The process makes it possible, by complementary or successive additions, first to flocculate the microorganisms with an appropriate mineral additive, then to increase their density by adding a second suitable mineral additive.

It is also important to point out that the process of the invention is particularly specific, given that it does away with the volumes of water treated to take into account only the masses of microorganisms present in the biological basins or pollution flows at the inlet of the primary clarifier.

The performances obtained by implementing the method of the invention are quite unexpected.

Indeed, the process of the invention brings into contact fine mineral additives whose sedimentation is low, or even zero, with flocs of microorganisms (or colloidal suspensions) whose sedimentation is difficult, if not impossible, to produce a clear and limpid purified water (or increase pollutant abatement rates). In other words, the process makes it possible to sediment a poorly settling product by adding a poorly settling additive.

The performances are also unexpected due to the fact that the addition of the mineral additive makes it possible to produce flocs whose buoyancy performances by assisted flotation or mechanical flotation are superior to those of unballasted flocs.

It is also surprising that the fine and non-adsorbing mineral additive of the invention exhibits, in pure water, residual turbidities incompatible with the standards required for discharges at the outlet of water treatment stations. Nevertheless, the mineral additive makes it possible to produce purified water whose turbidity is lower than that measured in the secondary settling tank in the presence of microorganism flocs alone, therefore in the absence of the mineral additive.

The process of the invention can include, in certain cases, an operation of partial or total recycling of the mineral additive.

The recycling of the mineral additive is carried out using hydrocyclones, centrifuges, or other separation devices commonly used for the separation of solids and liquids in industry.

In another aspect, the invention also relates to the mineral additive used for carrying out the process.

Reference is now made to the accompanying drawings, in which - Figure 1 shows the diagram of a water purification installation comprising a primary separation, with biological basins, a secondary separation and a sludge thickener which allows the setting up. implementation of the method of the invention; and - Figure 2 shows the diagram of a water purification plant by lamellar settling which allows the implementation of the process of the invention.

With reference to the installation in figure 1, the water to be purified
E passes successively through a screening device 1 and through a grit-removing device 2 before reaching a primary settling tank or clarifier 3 in which settling water 4 is formed, situated between a layer of supernatant fat 5 and a layer of sludge 6 at the bottom of the decanter.

The settled water 4 is withdrawn and sent, via a line 7, successively to a first biological basin 8 (optional), called "anoxic basin", a second biological basin 9 (optional), called "anaerobic basin and a third biological basin 10 operating in aerobic mode. The basin 10 is aerated by means of a stirring device 11. In these various biological basins, the water to be purified is brought into the presence of a biomass composed of appropriate microorganisms playing The water is then sent to a secondary settling tank 12 which makes it possible to separate the water 13 from the activated sludge 14, which is, at least in part, recycled in the biological basins through a line 15.

Furthermore, the sludge is collected at the base of the primary settling tank 3 by a line 16 and at the base of the secondary settling tank 12 by a line 17 to be sent to a treatment line making it possible to possibly reduce the putrescible power of the sludge via a digester. 18 (optional). From there, the sludge can be sent through a line 19 to a device 20 for dewatering the sludge (possibly after a thickener). The role of this device is to dehydrate the sludge mechanically, for example by centrifugation or by pressing. On leaving the device 20, the dehydrated sludge is sent either to the landfill or to the incinerator.

According to the invention, the mineral additive A can be added in the primary clarifier 3 or upstream thereof, in one of the biological basins 8, 9, 10, preferably in the aeration basin 10, or else in the secondary clarifier 12. The additive can also be introduced into the excess sludge before thickening and dewatering before line 19 and device 20.

Reference is now made to the installation of FIG. 2 which allows the implementation of a process with a lamellar settling tank and a sludge contact column, the method also applying to lamellar settling tanks with direct counter-current, with co- current and cross current.

The water to be purified E is brought into contact with an additive A previously suspended in a stirred tank 21, before being injected, by means of a pump 22, at an inlet point 23 located at the base of a flocculation column 25 (also called sludge column). The water to be purified passes through, from bottom to top, the sludge column 25 to enter a settling tank 26 and come into contact with the lamellae 27 thereof.

The purified water leaves the settling tank 26 via an outlet S fitted at its upper part.

The accumulated sludge is withdrawn from pouring points 24 provided in the column 25 and the settling tank 26.

The invention will now be described with the aid of the following nonlimiting examples.

Example 1
This example shows the increase in the efficiency of a lamellar column settling tank in contact with sludge, by introducing a mineral additive. it is implemented in a laboratory pilot having the following characteristics
Flocculation column
Height: 1.1 m
Width: 0.14 m
Depth: 0.12 m
Section: 0.0168 m2
Volume: 0.1848 m3.

Lamellar settling tank
Number of slats: 4
Tilt angle: 60 "
Slat width: 1.25 m
Width: 0.12 m
Depth: 0.12 m
Section: 0.0144 m2.

The example refers to wastewater of municipal origin characterized by its Chemical Oxygen Demand (COD), its
Suspended Solids (SS) and its Turbidity expressed in
FTU (Formazin Turbidity Unit). This last characteristic is measured by absorption of light through the sample to be tested with formazin standards as a reference.

The effectiveness of the purification device is essentially measured by the continuous reduction in turbidity on the incoming water and the settled water.

The mineral additive used has been prepared in the laboratory and has the following characteristics: hydrated magnesium silicate 40%, double hydrated aluminum and magnesium silicate 46%, double calcium and magnesium carbonate 2% and quartz 12%. The solubility in water at pH 7 is less than 0.1%, the specific surface area is 2.5 m2 / g, the porosity is less than 0.1 mg / cm3, the residual turbidity in water is 160 NTU; and the falling speed is less than 35m / h. This additive has a residual turbidity in water of 60 F.T.U., index used for this example.

The amount of the mineral additive added was adjusted to 0.5 times and 0.7 times respectively the Raw Materials.
Incoming suspension (MES) for a COD of 600 mg / l.

The efficiency of the lamellar settling tank without additive was determined as a function of the initial turbidity, because this device quickly reaches the limit of efficiency when this is less than 350 F.T.U.

It can be seen from the tests carried out that, firstly, the additive makes it possible to maintain an efficiency of the order of 45% by treating 60% more water. Second, at high speed, greater than 15 m / h, the efficiency of the settling tank is doubled.

it is more important to know that if the mineral additive increases the mass flow of the sludge, the volume flow of the sludge to be extracted and treated is reduced by 20 to 30%, which correspondingly increases the period of use of these lamellar settling tanks operating discontinuously.

The example is further illustrated by Tables I and II in the appendix.

Example 2
This example deals with the characterization of the bio-flocculation of microorganism flocs by use of a mineral additive. This property is obtained in the laboratory after the mineral additive has been brought into contact with the microorganisms for 3 minutes under rapid stirring (100 revolutions / min), then 10 minutes under slower stirring (60 revolutions / min) in cylindrical reactors, followed by unstirred decantation for 30 minutes.

The observation is carried out under an optical microscope to measure the diameter of the microorganism flocs and the settling is determined by the mud index.

The concentration of mineral additive is 100% by weight of the biomass with which it is brought into contact. The additives in this example have the following characteristics
Addendum A
95% hydrated magnesium silicate, 3% hydrated aluminum magnesium double silicate, 2% calcium magnesium double carbonate. Specific surface: 3.5 m2 / g, residual turbidity: 160 NTU and fall speed: less than 5 m / h.

Addendum B
Double aluminum magnesium silicate 95%, hydrated magnesium silicate 4%, double calcium magnesium carbonate 1%. Specific surface: 10.5 m2 / g, residual turbidity: 200 NTU and fall speed: less than 3 m / h.

Addendum C
94% hydrated calcium carbonate, 3% hydrated magnesium silicate, 3% hydrated aluminum magnesium double silicate. Specific surface: 1 m2 / g, residual turbidity: 300 NTU and fall speed: less than 30 m / h.

All these additives have porosities of less than 0.1 cm3 / g and adsorption capacities of D.C.O. and N-NH4 respectively less than 60 mg / g and 10 mg / g. Example 2 is further illustrated by Table III in the appendix.

By acting on the flocculation of microorganisms, the additives improve the sedimentation of these microorganisms (measured by the sludge index), which was expected in the light of previously known information. The mineral additive also modifies the size of these microorganism flocs to create very large, diffuse and stable flocs exhibiting properties of flotation using air bubbles, much greater than the flocs of unmodified microorganisms.

In fact, the sludge introduced into a flotation cell shows an increase of 50% and 30% respectively for additives A and B. On the other hand, additive C mainly promotes sedimentation.

TABLE I
Raw water turbidity> 350 FTU

Without <SEP> additive <SEP> Additive
<tb> 0.5 <SEP> times <SEP> the <SEP> MES <SEP> entran- <SEP> 0.7 <SEP> times <SEP> the <SEP> MES <SEP> entries <SEP> trantes
<tb> Turbidity <SEP> Speed <SEP> Efficiency <SEP> Turb. <SEP> Vit.col. <SEP> Eff. <SEP> Turb. <SEP> Col.speed <SEP> Clear.
<tb>

incoming <SEP> column
<tb> FTU <SEP> m / h <SEP>% <SEP> FTU <SEP> m / h <SEP>% <SEP> FTU <SEP> m / h <SEP>%
<tb> 365 <SEP> 10.5 <SEP> 47 <SEP> 425 <SEP> 9.8 <SEP> 57 <SEP> 430 <SEP> 13.7 <SEP> 57
<tb> 425 <SEP> 11.9 <SEP> 47 <SEP> 370 <SEP> 10.7 <SEP> 50 <SEP> 430 <SEP> 14.3 <SEP> 52
<tb> 370 <SEP> 15.5 <SEP> 37 <SEP> 350 <SEP> 15.7 <SEP> 38 <SEP> 370 <SEP> 16.7 <SEP> 45
<tb> 350 <SEP> 15.5 <SEP> 23 <SEP> 400 <SEP> 19 <SEP> 40
<tb> TABLE II
Raw water turbidity <350 FTU

Without <SEP> additive <SEP> Additive
<tb> 0.5 <SEP> times <SEP> MES <SEP> 0.7 <SEP> times <SEP> MES
<tb> Turbidity <SEP> Vit.col <SEP> Efficiency <SEP> Turb. <SEP> Vit.col. <SEP> Eff. <SEP> Turb. <SEP> Col.speed <SEP> Clear
<tb>

FTU <SEP> m / h <SEP>% <SEP> FTU <SEP> m / h <SEP>% <SEP> FTU <SEP> m / h <SEP>%
<tb> 270 <SEP> 10 <SEP> 47 <SEP> 320 <SEP> 12.2 <SEP> 40 <SEP> 350 <SEP> 16.7 <SEP> 40
<tb> 300 <SEP> 10.5 <SEP> 50 <SEP> 310 <SEP> 13.1 <SEP> 39
<tb> 320 <SEP> 11.9 <SEP> 37 <SEP> 350 <SEP> 15.7 <SEP> 38
<tb> 320 <SEP> 12.5 <SEP> 27
<tb> 320 <SEP> 15.5 <SEP> 19
<tb> 300 <SEP> 18.4 <SEP> 5
<tb> TABLE III

Biomass <SEP> of <SEP> Additive <SEP> A <SEP> Additive <SEP> B <SEP> Additive <SEP> C
<tb> reference <SEP> 100% <SEP> of <SEP> the <SEP> the <SEP> 100% <SEP> of <SEP> the <SEP> 100% <SEP> of <SEP> the <SEP> biobiomass <SEP> biomass <SEP> mass
<tb> Size <SEP> of the <SEP> flocs
<tb> 100 <SEP>#<SEP> 20 <SEP> 260 <SEP>#<SEP> 40 <SEP> 240 <SEP>#<SEP> 40 <SEP> 160 <SEP>#<SEP> 20
<tb> of <SEP> microorganisms
<tb> in <SEP> micro-meters
<tb> index <SEP> of <SEP> sludge <SEP> ml / g <SEP> 110 <SEP> 90 <SEP> 80 <SEP> 60
<tb>

Claims (20)

Claims 1.- A method of purifying water containing a polluting load defined by its flow, in which the water to be purified is subjected to at least one treatment operation, in particular by settling and / or biological activation, with subsequent separation a purified water and possibly activated sludge, characterized in that one adds to the water to be treated at least one mineral additive in the form of powder, granules or suspension, and meeting the following properties - non-adsorption and chemical inertness with regard to the polluting load present in the water to be purified, - insolubility or low solubility, less than 5%, in water under the usual pH conditions (pH5 to pH9) encountered during the treatment, - specific surface greater than 0.4 m2 / g (BET method), - microporosity less than 0.1 cm3 / g, - residual turbidity in water less than 300 NTU, and - falling speed less than 80 m / h . 2.- Method according to claim 1, characterized in that the mineral additive is a natural or synthetic product chosen from at least one of the chemical families formed by silicates, aluminates, carbonates, sulphates and insoluble glasses or poorly soluble at the usual pH conditions encountered during treatment. 3.- Method according to one of claims 1 and 2, characterized in that the mineral additive is chosen from at least one of the following chemical families - aluminosilicates, - magnesium aluminate, - hydrated calcium carbonate, - carbonate double hydrated calcium and magnesium, - amorphous or crystallized calcium carbonate, - hydrated magnesium silicate, - hydrated aluminum silicate, - double hydrated magnesium and aluminum silicate, and - hydrated calcium sulfate. 4.- Method according to one of claims 1 to 3, wherein the water to be purified is water to be made drinkable and is subjected to a primary separation operation in a primary clarifier, with settling, characterized in that one adds the mineral additive before or during the primary separation operation and that the daily mass of the added mineral additive is equal to 1 to 500 times the daily mass of the polluting load contained in the water. 5.- Method according to one of claims 1 to 3, wherein the water to be purified is waste water and is subjected to a primary separation operation in a primary clarifier with settling and without treatment in biological basins, characterized in that the mineral additive is added before or during the primary separation operation and that the daily mass of the added mineral additive is equal to 0.1 to 10 times the daily mass of the polluting load contained in the water . 6.- Method according to one of claims 4 and 5, characterized in that the mineral additive has a residual turbidity in water generally less than 200 NTU and an upward speed of between 0.03 and 800 m / h. 7.- Method according to one of claims 1 to 3, wherein the water to be purified is water to be made drinkable and is subjected to a primary separation operation by flotation, characterized in that the mineral additive is added before the primary separation operation and that the daily mass of the mineral additive added is equal to 1 to 100 times the daily mass of the polluting load contained in the water. 8. A method according to claim 7, characterized in that the mineral additive has a residual turbidity in water generally less than 250 NTU and a falling speed of less than 5 m / h. 9. A method according to one of claims 1 to 3, wherein the water to be purified is waste water and is subjected to a primary separation operation in a primary clarifier, with settling, and before treatment in biological tanks, characterized in that the mineral additive is added before or during the primary separation operation and that the daily mass of the added mineral additive is equal to 0.1 to 10 times the daily mass of the polluting load contained in the water. 10. A method according to claim 9, characterized in that the mineral additive has a residual turbidity in water generally less than 300 NTU and a fall speed of between 0.01 and 80 m / h. 11.- Method according to one of claims 1 to 3, wherein the water to be purified is waste water and is subjected to a primary separation operation by flotation before treatment in biological basins, characterized in that one adds the mineral additive before the primary separation operation and that the daily mass of the added mineral additive is equal to 0.1 to 10 times the daily mass of the polluting load contained in the water. 12. A method according to claim 11, characterized in that the mineral additive has a residual turbidity in water generally less than 300 NTU and a falling speed of less than 5 m / h. 13.- Method according to one of claims 1 to 3 and 7 to 12, wherein the water to be purified is subjected to a biological activation operation in at least one biological basin in the presence of a biomass composed of micro- purifying organisms and a secondary separation operation in a secondary clarifier with subsequent separation of purified water and activated sludge, characterized in that the mineral additive is added before or during the secondary separation operation with a quantity chosen mineral additive depending on the biomass concentration at any time, which represents 10 to 150% by weight of the biomass in the aeration tank. 14.- The method of claim 13, characterized in that the mineral additive has a residual turbidity in water generally less than 300 NTU and a falling speed of less than 80 m / h. 15.- Method according to one of claims 13 and 14, characterized in that the mineral additive is added depending on the amount of active biomass present at any time or replacing the amount of mineral additive in the biomass excess, extracted as active sludge from the secondary clarifier. 16.- Method according to one of claims 1 to 15, characterized in that one adds to the mineral additive a cationized short-chain additive. 17.- Method according to one of claims 1 to 16, characterized in that one adds to the mineral additive a complementary additive known for its specific action on toxic pollution or soluble pollution not degradable by biological route, including the specific action is increased by synergistic effect due to the mineral additive. 18.- Additive for the implementation of the method according to one of claims 1 to 18, characterized in that it is a mineral additive as defined in one of claims 1 to 3. 19. Additive according to claim 18, characterized in that the mineral additive is mixed with a cationized short-chain additive. 20.- Additive according to claim 18, characterized in that the mineral additive is mixed with a complementary additive chosen according to the treatment operation.