FR2682302A1 - Process for dissolving a gas in a liquid and device for its use - Google Patents

Abstract

Process for dissolving a gas in a liquid, characterised in that it consists in making the liquid flow in an enclosed space (6) kept at atmospheric pressure, so as to fractionate it into particles, droplets or the like, while injecting the gas to be dissolved into this space and in collecting the said particles or the like of liquid after passage through the said space (6). Application especially to the oxygenation of water in fish farming.

Description

PROCESS FOR THE DI8SOLUTION OF A GAS IN A LIQUID
AND DEVICE FOR IMPLEMENTING IT
The present invention relates to the dissolution of a gas in a liquid and in particular, although not exclusively, to the oxygenation of water intended for fish farming.

 There are various techniques for increasing the amount of dissolved oxygen in the water of a fish farm.

 These techniques use a source of pure oxygen, use various means, such as jet platforms, hydro-ejector, covered turbine, bicone, U-tube, to dissolve the oxygen in the water and each have both advantages and disadvantages.

 The jet and hydro-ejector installations aim to reach a degree of saturation of water with oxygen of the order of 1.5 times that reached by oxygenation with atmospheric air, for the same temperature conditions and pressure.

 These installations operate at atmospheric pressure but have limited performance and require civil engineering work.

 Covered turbines have the advantage of being mobile and not requiring civil engineering, but have limited performance and involve a high investment.

 Bicone type installations or those known under the names "OXYJET" and "AQUATECTOR" have the advantage of being mobile, not requiring civil engineering and reaching up to three times the air saturation, but involve high investments and a high operating cost because they use the pressure generated by pumps. In addition, they can only process small debits.

 Finally, U-type installations use hydrostatic pressures and allow large flows to be treated with a low operating cost but at the cost of a high investment and significant civil works.

 The object of the invention is to propose a new technique bringing together the advantages of known techniques, namely in particular: low investment, absence of civil works, good performance.

 To this end, the subject of the invention is a process for dissolving a gas in a liquid, characterized in that it consists in causing the liquid to flow in an enclosed space maintained at atmospheric pressure, so as to fractionating into particles, droplets or the like, while sending into said space the gas to be dissolved and collecting said particles or the like of liquid, after crossing said space.

 Preferably, the water is forced to run into said space, which is filled with fractionation elements of the "biorings" type or the like.

 The invention also relates to a device for implementing the above method, characterized in that it comprises a vertical column divided into three superimposed zones, namely an upper zone open to the atmosphere and receiving the liquid to be treated, an intermediate zone separated from the upper zone by an perforated partition intended, on the one hand, to permanently constitute a reserve of liquid and, on the other hand, to allow the latter to run off, said intermediate zone containing appropriate fractionation elements and being connected to a source of the gas to be dissolved and a lower zone, partly immersed in a basin or the like for collecting the treated liquid, communicating with said basin and with said intermediate zone.

 Preferably, the liquid to be treated is introduced into said upper zone in the form of a current substantially tangent to the treatment column, which is cylindrical.

 The fractionation elements are constituted for example by elements of the "biorings" type or the like, contained or supported in an appropriate structure.

 Such an installation, especially, but not exclusively, designed for the oxygenation of the water of a fish farm, makes it possible to treat the water in an oxygen atmosphere maintained at atmospheric pressure, with a saturation rate of the water in oxygen of the order of twice the saturation obtained with air, for the same temperature and pressure conditions, and this, with a limited investment, due to the simplicity of the device, consisting of a simple column which can be mobile and therefore be installed at will anywhere in the fish farm and moved and does not require any particular civil engineering.

Other characteristics and advantages will emerge from the description which follows of an embodiment of the device of the invention, description given by way of example and with reference to the appended drawing in which
- Figure 1 is a schematic view in axial section
vertical of a compliant water oxygenation column
to the invention and
- Figure 2 is a top view of the column
illustrating a particular mode of introduction of
the water to be treated.

 In Figure 1 is shown in 1 a vertical cylindrical column resting on the bottom of a basin or channel 2 for example of a fish farm.

 Column 1 is for example made of plastic, 2.5 meters high, 0.5 meters in diameter, open at its upper end and partially submerged in the water of the basin or channel 2, for example over a height of 0.7 meters.

 Column 1 internally delimits three superimposed zones, namely an upper zone 3, for example 0.4 meters in height, for receiving water to be treated, supplied by a conduit 4, and for permanently building up a reserve, thanks to a perforated horizontal separating partition 5 to allow the water retained by said partition 5 to run into an underlying intermediate zone 6.

 The intermediate zone 6 is the oxygenation zone of the water. It is, for the most part, filled with water fractionation elements symbolized in 7, constituted by individual elements such as those known as "biorings" or other elements capable of fulfilling the same role breaking or splitting water into multiple droplets, particles or the like.

 The elements 7 are contained in an openwork structure 8 integral with the column 1, constituted for example by a basket which can easily be crossed by batten.

 Furthermore, zone 6 is connected by a pipe 9 to a source of pure oxygen (not shown).

 The "biorings" 7 or the like are loose in the basket 8, the height of which is, for example, 1 meter.

 The third zone or lower zone 10 communicates with zone 6, with the basin or channel 2 through one or more openings 11 formed at the lower end of the column 1. The lower part of zone 10 is filled with water from the basin or channel 2, the level 12 of which is a few tens of centimeters from the bottom of the basket 8.

 A degassing tube 13 is placed in column 1 so that its lower end is immersed in the water of zone 10 and its upper end is in the atmosphere.

 The partition 5 is a grid or perforated or perforated plate so, on the one hand, to maintain a reserve of water to be treated 14 above the partition 5 and, on the other hand, to allow regular and well distributed runoff of water through the partition towards the oxygenation zone 6.

 The grid 5 is dimensioned as a function of the desired flow rate.

 The permanent presence of the reserve 14 seals the upper part of the zone 6 inside which the atmospheric pressure applied by the water in the basin or channel 2 constantly prevails.

 The water flowing from the grid 5 crosses the basket 8, dividing, by a multitude of small waterfalls on the "biorings" 7, into an infinity of droplets and particles, within an atmosphere charged with pure oxygen in so that the water gets the most oxygen.

 The fractionated water charged with oxygen is collected in the lower zone 10 of the column and flows by gravity into the basin or channel 2 where it mixes with the water thereof.

 The tube 13 is responsible for preventing the pressurization of the gases in the column.

 FIG. 2 illustrates a method of supplying column 1 in which the water to be treated is brought into zone 3 by a conduit 4 discharging the water substantially tangentially to column 1. This creates a vortex at the inside of column 1 which prevents the formation in the water of air bubbles harmful to the dissolution of oxygen.

 The device described above makes it possible to obtain, for small flow rates, oxygen saturation rates of the order of twice the air saturation.

 The device working at atmospheric pressure can operate by gravity or by pumping. In the latter case, pumping is inexpensive since it does not require pressure.

 The device is simple in design and installation.

It does not require civil works. Being mobile, it can be installed anywhere in the fish farm and moved at any time.

 It should be noted that the method of the invention can be applied in general to the dissolution of any gas in any liquid.

 Finally, the invention is obviously not limited to the embodiment shown and described above, but on the contrary covers all variants thereof, in particular as regards the shapes and dimensions of column 1, the nature of the perforated partition or grid 5 as well as the arrangement of the water passages formed therein, the nature and arrangement of the means 7 for fractionating the water to be treated.

Claims (6)

CLAIMS =: =: =: =: =: =: =: =: =: =: =: =: =: =  1. Method for dissolving a gas in a liquid, characterized in that it consists in causing the liquid to flow in an enclosed space (6) maintained at atmospheric pressure, so as to fractionate it into particles, droplets or analogues, while sending in said space the gas to be dissolved and to collect said particles or analogs of liquid after crossing said space (6).  2. Method according to claim 1, characterized in that the liquid is forced to run into said space (6), which is filled with elements or means (7) for fractionating said liquid.  3. Device for implementing the method according to claim 1 or 2, characterized in that it comprises a vertical column (1) divided into three superimposed zones, namely an upper zone (3) open to the atmosphere and receiving the liquid to be treated, an intermediate zone (6) separated from the upper zone (1) by an openwork partition (5) intended, on the one hand, to permanently constitute a reserve of liquid (14) and, on the other hand part, to allow the latter to run off, said intermediate zone (6) containing suitable fractionation elements (7) and being connected (9) to a source of the gas to be dissolved and a lower zone (10), partially submerged in a basin or the like (2) for collecting the treated liquid and communicating with said basin (2) and with said intermediate zone (6).  4. Device according to claim 3, characterized in that it comprises a conduit (4) for introducing the liquid to be treated into said upper zone (3) disposed substantially tangentially inside said column (1), which is cylindrical.  5. Device according to claim 3 or 4, characterized in that said fractionation elements are individual elements of the "biorings" type (7) or the like, arranged in bulk in a support structure (8) integral with the column (1) , occupying all or part of said intermediate zone (6) and being easily traversed by the liquid.  6. Application of the method according to claim 1 or 2, to the oxygenation of the water of a fish farm.