FR2930118A1 - Device for in-situ germicidal and/or oxidizing treatment of aqueous or gaseous medium by germicidal aerosol, comprises tank for production of aerosol generated by suction of air in ejector venturi, and nascent oxygen obtained from reactor - Google Patents

Abstract

The device comprises a tank (1) for production of aerosol generated by suction of air in an ejector venturi (3), and nascent oxygen obtained from a reactor introduced to the aerosol in the upper part of the tank. The aerosol/nascent oxygen mixture is transported from storage reservoir or suction tube integrated with the pump and the discharge nozzle through a suction tube by a second ejector venturi for an immediate reaction with the contaminating elements contained in the fluid or gas or liquid to be treated by permanent circulation during the treatment. The device comprises a tank (1) for production of aerosol generated by suction of air in an ejector venturi (3), and nascent oxygen obtained from a reactor introduced to the aerosol in the upper part of the tank. The aerosol/nascent oxygen mixture is transported from storage reservoir or suction tube integrated with the pump and the discharge nozzle through a suction tube by a second ejector venturi for an immediate reaction with the contaminating elements contained in the fluid or gas or liquid to be treated by permanent circulation during the treatment. The ejector is fed by a pump (4) carrying water, and another pump carrying either water or gas, or the mixture of both depending on the type of fluid to be decontaminated. The decontamination of the fluid is carried out when the aerosol and nascent oxygen are introduced in the fluid to be treated or when contacting the ejector body with its turbulent flow. The germicidal agents are made by mixing aerosol/effluent in the ejector thus chemically producing extremely active nascent oxygen from the germicide in a reactor integrated into the device for the simultaneous reduction of the biochemical oxygen demand and chemical oxygen demand. The nascent oxygen is obtained from a catalytic reactor by controlled decomposition of a peroxide, electrolysis, or by any other process capable of producing oxygen in nascent form. The oxidizing aerosol is generated by the sucked ambient air and introduced in water tank by a plunging tube connected to the outlet of the engine fluid of the ejector. The air sucked by the ejector for the production of germicidal aerosol is replaced by inert gas, nitrogen, argon, carbon, or opposed by any other reactive gas.

Description

The present invention relates to a device for germicidal treatment of aqueous or gaseous media, by the introduction of a germicidal and / or oxidizing aerosol in the said aqueous or gaseous media, during an intimate contact between the germicidal aerosol and the media. concerned to be decontaminated, generated within an ejector using as the driving fluid the medium to be treated, aqueous or gaseous, which itself will use its suction capacity by venturi, to ensure the intimate mixture between the germicidal aerosol and / or oxidant sucked and the fluid to be treated during the contact in the body of the ejector and its flow. The device makes it possible to introduce into the fluid to be treated germicidal agents resulting from the chemistry, by injection, or aspiration by venturi, but also germicidal agents made upstream of the aerosol effluent mixture, such as the production of nascent oxygen which is extremely active on the germicidal plan, but also chemically, for the simultaneous reduction of biological oxygen demand (BOD), and the chemical oxygen demand (COD). The present invention will treat, for the example of a germicidal aerosol, carried out in-situ of the process, composed of incipient oxygen-loaded water micelles to be introduced into an aqueous effluent, with a view to lowering its bacteriological contamination, in seeds. aerobic and anaerobic, and reduce the COD by oxidation of mineral or organic compounds present in the medium to be treated. The nascent oxygen may be from a catalytic reactor, the controlled decomposition of a peroxide, an electrolysis, or any other process capable of producing this element in its nascent form, the amorphous form being only very not reactive, or not at all, depending on the environment, for the reduction of BOD or COD. Various methods are known to reduce bacterial contamination by spraying a germicidal aerosol on a contaminated surface, as mentioned in the patent registered under number US4678658.

Also known from patent US5688387, the production of incipient oxygen by electrolysis, using electrodes made of perforated aluminum, through which the electrolyte is pumped or sprayed to ensure maximum of contact. Patent US5424032 also discloses the production of oxidants for the treatment of contaminated water, in combination with UV treatment, cooling towers.

Also known are other methods for the decontamination of aqueous media, such as the use of halogens or compounds derived therefrom, as mentioned in the patent registered under number US481853 2, referring to brominated compounds.

The introduction of decontaminants in the media to be treated is either by pumping or spraying. Finally, it is known from the patent registered under the number WO / 1998/047826, the introduction of ozone gas under pressure in a hydro-ejector in aqueous medium, for a bacteriological only decontamination. In total opposition to this state of the art, the effectiveness of which remains very hypothetical when the bacterial flora is varied and fed continuously by the significant presence of organic, as is the case in industrial effluents, and which generate a demand chemical oxygen (COD) consequent for their oxidation for their discharge as non-polluting effluent, the present invention ensures, by the oxidizing germicidal aerosol, the microbiological decontamination and the lowering of the COD to a residual threshold close to zero, because nevertheless continuously fed in a continuous normal cycle in industrial production. For this purpose, the subject of the invention is the production of a germicidal and oxidizing aerosol, introduced into the effluent to be treated in bi-phasic gas / water form, the micelles of water being between 0.2 and 10 microns, for an immediate oxidation reaction in the flow of an ejector.

For the record, the engine fluid that comes under pressure in the ejector flows in a pipe whose section decreases. This results in an increase in the flow velocity, and consequently a decrease in the static pressure. The latter makes it possible to draw a liquid or a gas in the ejector, through the suction port in turbulent flow, generating an immediate mixing of the driving fluid and the aspirated fluid. The device comprises two ejectors / venturi, supplied with motor fluid by two pumps separately. The present description postulates for two identical ejectors, powered by two pumps also identical, without this being limiting. The first ejector is mounted on a reservoir containing water, as a driving fluid, at three quarters of its capacity for the example, permanently recycled by the first circulation pump through the ejector. Part of the recycled water, at the pump outlet, before the ejector, passes through a reactor capable of generating nascent oxygen, to reach the aforementioned tank, thus allowing the circulating water to be then sip of nascent oxygen. The aerosol, thus oxidizing, is generated by the ambient air sucked, and introduced in a very divided form in the water of the tank by a plunger connected to the output of the ejector fluid. The second ejector is powered by the working fluid consisting of the fluid to be treated. The suction pipe of this second ejector is connected to the upper part of the tank / balloon emitter of the aerosol which is filled with water only three-quarters. The micelles of water containing nascent oxygen and entrained by the air thus sucked, are introduced by the second ejector into the fluid to be treated, thus generating an eminent contact between the two phases, oxidizing product and product to be treated.

There is thus no direct contact between the fluid of the aerosol emitter-containing reactor containing the nascent oxygen, and the fluid to be treated which undergoes the elimination of the bacterial, aerobic and anterobic flora, as well as the reduction of the COD, in proportion to the treatment time, which is dependent on the bacterial flora present and the concentration of elements to be oxidized initially. A small portion of the balloon water is entrained, in aerosol form only, with the oxidant by suction in the fluid to be treated. On the basis of a volume entrainment of one cubic meter per hour of aerosol, at atmospheric pressure, the quantity of water extracted from the flask is of the order of 540 grams / hour for an operating temperature of 20. ° C, and 760 15 grams / hour of water for an operating temperature of 50 ° C, for a volume of fifty liters of water engaged in the balloon emitting the aerosol. The compensation for water losses is achieved by an addition determined by the detection of the level established in the tank 20 emitting the aerosol. The duration of the treatment is dependent on the concentrations of the elements to be eliminated by oxidation. A device for the germicidal treatment of aqueous or gaseous media is thus produced by the introduction of a germicidal and / or oxidizing aerosol in the said gaseous or liquid media to be decontaminated, without the use of electrolysis or UV radiation. , or the use of halogens or compounds derived therefrom. The invention will in any case be better understood with the aid of the description which follows, with reference to the appended diagrammatic drawings showing, by way of example, an embodiment of the bacteriological decontamination and abatement device of the present invention. COD in an aqueous medium, as well as the device applied to the gas treatment.

Figure 1 is a block diagram of the hydraulic circuit, and the positioning in space of the elements constituting the germicidal and oxidizing device for the treatment of a contaminated liquid phase.

Figure 2 is an extension of the device, positioned at the outlet of the venturi ejector subject to the closed circulation of the liquid to be treated. Figure 3 is a schematic diagram of the hydraulic circuit, and the positioning in space of the elements constituting the germicidal and oxidizing device for the treatment of a contaminated gas phase. The device comprises a water tank 1, filled to three quarters of its capacity 2. A first venturi ejector 3, whose physical characteristics are in adequacy with the flow rate and the pressure available on the circulation pump 4 which feeds it, is positioned on the upper part of the balloon 1, to ensure the permanent circulation of the motor fluid constituted by the water 2 contained in the balloon 1, by means of the tubing 5.

A bypass 6 mounted on the tubing 5 feeds a reactor 7 for producing incipient oxygen in situ, and joined by the tubing 8 the top of the balloon 1 without water in its upper part 17. A tubular 9, ensures the setting in the air of the balloon 1.

The ejector 3 draws ambient air through the tube 10. The aerosol generated by the water 2 contained in the balloon 1 and by the air sucked by the tube 10 is introduced into the body of water of the balloon. the outlet 11 of the ejector 3, and is positioned naturally in the upper part 1.7 of the balloon 1.

A second venturi ejector 12, whose physical characteristics are also in adequacy with the flow rate and the pressure available on the circulation pump 13, is supplied by the fluid to be decontaminated 14, in constant circulation during the treatment period, from the reservoir storage 15 fluid 14, by the suction pipe integral with the pump 13 and the discharge pipe 16.

The ejector 12 sucks the aerosol charged with incipient oxygen into the upper part 17 of the balloon 1., which incipient oxygen is produced by the reactor 7, whose aqueous flow rate is regulated by the valve 18.

The aerosol and nascent oxygen are introduced into the fluid to be treated 14, during an eminent contact in the body of the ejector 12 and its turbulent flow within the latter. The continuous production of nascent oxygen in the reactor 7 continuously mixed with the aerosol in the upper part 17 of the balloon 1, limits the corrosion of the material or materials constituting the balloon 1 and its hydraulic annexes, due to the extreme reactivity under its nascent form, and prolongs its life. The immediate reaction of the nascent oxygen with the contaminating elements contained in the fluid to be treated 14 requires a transfer in a few seconds of the upper part 17 of the balloon 1 to the ejector 12 where instead of the decontamination reactions. The aerosol mixture and nascent oxygen are thus conveyed by the tubing 19 into the body of the ejector 12, with a transfer speed at least equal to twenty meters per second, the length of the tubing 19 not exceeding two thousand millimeters. The suction efficiency of the venturi ejector can be improved by eliminating the so-called singular pressure losses encountered with the bi-phasic flow (air + water) by an increase in pressure downstream of the ejector. This type of improvement is possible when it is a question of treating an aqueous fluid, by the addition of an overflow tank 20, at the outlet of the ejector 12 in which circulates the effluent to be treated, thus causing a rupture of the pipe 16, connecting the ejector 12 to the storage tank 15 of the product to be treated. The aqueous liquid 14 then flows by gravity from the so-called overflow tank 20, to the storage tank 15 of the aqueous medium to be decontaminated, by a pipe 21 dimensioned for this purpose.

The decontamination of a gas in sealed circuit requires the replacement of the air 9 of the balloon 1, by an automatic purge valve 22 to prevent overpressure in the device, and the storage of the gaseous effluent to treat: 23 in the upper part of the sealed storage tank 24, which contains in its lower part of the water 25 which ensures the proper operation of the ejector 12 fed by a liquid driving fluid 25. The gas 23 is recycled continuously during the duration of the treatment in a permanent sealed circuit, being sucked successively by the ejector 3 located on the balloon 1 emitter of the germicidal aerosol, by the tubing 28, thus generating a first reaction contact, then by the ejector 12 by the tubing 19 for intimate contact with the germicidal aerosol, and returns to the upper portion 23 of the storage tank 24, filled to three quarters of its capacity. The addition of water to maintain the level 2 of the latter in the balloon 1 emitter of the aerosol, is achieved by the tubing 27.

The device for the germicidal treatment of aqueous or gaseous media, by the introduction of a germicidal and / or oxidizing aerosol in the said gaseous or liquid media to be decontaminated, and previously described, is applicable to the treatment of industrial effluents, effluents from agri-food, aqueous effluents from cooling towers, effluents from the hospital environment, both for biological oxygen demand (BOD) and chemical oxygen demand (COD). It goes without saying that the invention is not limited to the embodiments that have been described above as examples; it embraces, on the contrary, all variants of implementation and application respecting the same principle. Thus, it would not be possible to depart from the scope of the invention by applying this device to cold sterilization in the agri-food industry, such as, for example, for milk, fruit or vegetable juices, or wine, or still the disinfection of washing water of fresh products intended for human consumption. It is the same for the disinfection of swimming pool water, and the BOD and COD removal of agro-industrial effluents.

One would not move away either, by replacing the air sucked by the first ejector 3 intended for the production of the aerosol, by an inert gas, nitrogen, argon, carbon dioxide, or on the contrary by any Another reactive gas intended to modify the BOD and / or the COD of a fluid to be treated, whether in gaseous or liquid form. The introduction of air, inert or reactive gas, can also be carried out in the balloon 1 by injection under pressure, without the use of an ejector 3, as, for example, by a compressor for the air, and from compressed gas cylinders for inert or reactive gases. Finally, one would not move away from the scope of the invention by applying the device to the decontamination of the ambient air, limiting it to the production of a germicidal aerosol as described above, and taking into account only the material configuration of the balloon 1, comprising a single ejector 3, supplied with water by the pump 4, and nascent oxygen by the reactor 7. The tubing 19 sucks the air to be treated and which returns to the middle ambient by venting 9, obviously considering the performance of equipment in line with the volume of air to be treated in air conditioning.

Claims (4)

CLAIMS1 - Germicidal and / or oxidizing treatment device, in an aqueous or gaseous medium, by germicidal aerosol, characterized in that it essentially comprises a balloon (1) for producing aerosol generated by suction of air in a venturi ejector ( 3), and nascent oxygen from a reactor (7) introduced to the aerosol in the upper part (17) of the balloon (1), this incipient aerosol / oxygen mixture being conveyed through a tube (19). ) by suction by a second venturi ejector (12), for an immediate reaction with the contaminating elements contained in the fluid (14) or (23) gaseous or liquid to be treated in constant circulation during the treatment period, from the reservoir of storage (15) or (24) by the suction pipe integral with the pump (13) and the discharge pipe (16). 2 - germicidal and / or oxidizing treatment device, in an aqueous or gaseous medium, by germicidal aerosol, according to claim 1, characterized in that the ejector (3) is fed by a pump (4) carrying water , and the ejector (12) is fed by a pump (13) carrying either water or a gas, or a mixture of both, depending on the type of fluid to be decontaminated. 3 - Germicidal and / or oxidizing treatment device, in an aqueous or gaseous medium, by germicidal aerosol, according to claims 1 and 2, characterized in that the fluid is decontaminated when the aerosol and nascent oxygen are introduced. in the fluid to be treated (14) or (23), during an eminent contact in the body of the ejector (12) and its turbulent flow within the latter. 4 - Germicidal and / or oxidizing treatment device, in an aqueous or gaseous medium, by germicidal aerosol, according to claims 1 and 3, characterized in that it makes it possible to introduce into the fluid (14) or (23) to be treated germicidal agents from the chemistry, but also germicidal agents made upstream of the aerosol / effluent mixture in the ejector (12) intended for this purpose, such as the production of nascent oxygen extremely germically active in a reactor ( 7) integrated in the device, but also on the chemical level, for the simultaneous reduction of the biological oxygen demand (BOD), and the chemical oxygen demand (COD). - A germicidal and / or oxidizing treatment device, in an aqueous or gaseous medium, by germicidal aerosol, according to claims 1, 3 and 4, characterized in that the nascent oxygen may be derived from a catalytic reactor (7), controlled decomposition of a peroxide, an electrolysis, or any other process capable of producing this element in its nascent form. 6 - A germicidal and / or oxidizing treatment device, in an aqueous or gaseous medium, by germicidal aerosol, according to claims 1, 3, 4 and 5, characterized in that the oxidizing aerosol (17) is generated by the ambient air sucked (10), and introduced in a very divided form (11) into the water tank (1) by a plunger connected to the output of the driving fluid of the ejector (3). 7 - A germicidal and / or oxidizing treatment device, in an aqueous or gaseous medium, by germicidal aerosol, according to claims 1, 4 and 6, characterized in that the air sucked by the ejector (3) intended for the production of the germicidal aerosol (17) can be replaced by an inert gas, such as nitrogen, argon, carbon dioxide, or the opposite by any other reactive gas 8 - Germicidal and / or oxidizing treatment device, in an aqueous medium or gaseous, by germicidal aerosol, according to any one of claims 1 to 7, characterized in that the production of the germicidal and / or oxidizing aerosol can be generated by the injection of a compressed gas into the liquid (2 ) of the balloon (1).